SFC332 OPERATORS MANUAL - Prover · PDF fileSFC332 OPERATORS MANUAL Smart Flow Computer Liquid Pulse Version 12603 Southwest Freeway, Suite 320 ... Wiring of Calibron Prover:

Date: 7/10/2012

SFC332

OPERATORS MANUAL Smart Flow Computer

Liquid Pulse Version

12603 Southwest Freeway, Suite 320

Stafford, Texas 77477 USA

(281) 565-1118

Fax (281) 565-1119

Date: 7/10/2012

WARRANTY

Dynamic Flow Computers warrants to the owner of the Flow Computer that the product

delivered will be free from defects in material and workmanship for one (1) year

following the date of purchase.

This warranty does not cover the product if it is damaged in the process of being installed

or damaged by abuse, accident, misuse, neglect, alteration, repair, disaster, or improper

testing.

If the product is found otherwise defective, Dynamic Flow Computers will replace or

repair the product at no charge, provided that you deliver the product along with a return

material authorization (RMA) number from Dynamic Flow Computers.

Dynamic Flow Computers will not assume any shipping charge or be responsible for

product damage due to improper shipping.

THE ABOVE WARRANTY IS IN LIEU OF ANY OTHER WARRANTY EXPRESS

IMPLIED OR STATUTORY. BUT NOT LIMITED TO ANY WARRANTY OF

MERCHANTABILITY, FITNESS FOR PARTICULAR PURPOSE, OR ANY

WARRANTY ARISING OUT OF ANY PROPOSAL, SPECIFICATION, OR SAMPLE.

LIMITATION OF LIABILITY:

DYNAMIC FLOW COMPUTERS SHALL HAVE NO LIABILITY FOR ANY

INDIRECT OR SPECULATIVE DAMAGES (INCLUDING, WITHOUT LIMITING

THE FOREGOING, CONSEQUENTIAL, INCIDENTAL AND SPECIAL DAMAGES)

ARISING FROM THE USE OF, OR INABILITY TO USE THIS PRODUCT.

WHETHER ARISING OUT OF CONTRACT, OR UNDER ANY WARRANTY,

IRRESPECTIVE OF WHETHER DFM HAS ADVANCED NOTICE OF THE

POSSIBILITY OF ANY SUCH DAMAGE INCLUDING, BUT NOT LIMITED TO

LOSS OF USE, BUSINESS INTERRUPTION, AND LOSS OF PROFITS.

NOTWITHSTANDING THE FOREGOING, DFM’S TOTAL LIABILITY FOR ALL

CLAIMS UNDER THIS AGREEMENT SHALL NOT EXCEED THE PRICE PAID

FOR THE PRODUCT. THESE LIMITATIONS ON POTENTIAL LIABILITY WERE

AN ESSENTIAL ELEMENT IN SETTING THE PRODUCT PRICE. DFM NEITHER

ASSUMES NOR AUTHORIZES ANYONE TO ASSUME FOR IT ANY OTHER

LIABILITIES

Date: 7/10/2012

CHAPTER 1: QUICK START.................................................................................................................... 1-1 Introduction: ............................................................................................................................................ 1-1 Conventions Used in This Manual: ......................................................................................................... 1-1 Smart Flow Computer : Dimensions ....................................................................................................... 1-2 Website - DFM Configuration Software ................................................................................................. 1-3 Starting and Installing the Software: ....................................................................................................... 1-4

To run off the hard drive of a PC or laptop: ........................................................................................ 1-4 Technical Data ......................................................................................................................................... 1-5 POWER ................................................................................................................................................... 1-5 Parts List .................................................................................................................................................. 1-6 Getting acquainted with the flow computer wiring: ................................................................................ 1-7

Back terminal wiring: .......................................................................................................................... 1-7 Back Panel Jumper .............................................................................................................................. 1-8

INPUT/OUTPUT: Assignment, Ranging, Wiring, and Calibration ....................................................... 1-9 Input/Output Assignment .................................................................................................................... 1-9 How to assign a transmitter to an I/O point: ........................................................................................ 1-9 Ranging the Transmitter Inputs: .......................................................................................................... 1-9

WIRING: ............................................................................................................................................... 1-11 Wiring the analog inputs: .................................................................................................................. 1-11 Wiring the analog inputs 1-4 : ........................................................................................................... 1-12 Wiring the analog inputs 5,6 : ........................................................................................................... 1-13 RTD ................................................................................................................................................... 1-14 Wiring analog output: ........................................................................................................................ 1-15 Turbine input wiring .......................................................................................................................... 1-16 Turbine wiring for passive (dry contact) pulse generators ................................................................ 1-17 Density input wiring: ......................................................................................................................... 1-18 RS-232 connection: ........................................................................................................................... 1-19 RS-485: .............................................................................................................................................. 1-20 Wiring of status inputs: ..................................................................................................................... 1-21 Wiring of switch/pulse outputs: ......................................................................................................... 1-22 I/O Expansion: ................................................................................................................................... 1-23 Wiring of Brooks Prover: .................................................................................................................. 1-26 Wiring of Calibron Prover: ................................................................................................................ 1-27

Calibration ............................................................................................................................................. 1-28 Analog Input 4-20mA or 1-5 volt signal: .......................................................................................... 1-28 RTD Calibration: ............................................................................................................................... 1-29 Calibration of analog output: ............................................................................................................. 1-30 Multi-Variable Transmitters (Model 205)- DP and Pressure ............................................................ 1-31 Multi-Variable Transmitters (Model 205)- RTD ............................................................................... 1-32

Verifying digital inputs and outputs: ..................................................................................................... 1-33 Pulse Interpolation: ................................................................................................................................ 1-34 Double Chronometry: ............................................................................................................................ 1-34 Calculations and Terminology: ............................................................................................................. 1-35

Liquid pulse units .............................................................................................................................. 1-35 Terms ................................................................................................................................................. 1-35

CHAPTER 2: Data Entry ............................................................................................................................ 2-1 Introduction to the Smart Flow Computer Software................................................................................ 2-1 ABOUT ................................................................................................................................................... 2-1 FILE ........................................................................................................................................................ 2-2

Open a File .......................................................................................................................................... 2-2 Open a New File .................................................................................................................................. 2-2 Delete a File ......................................................................................................................................... 2-2 Load File.............................................................................................................................................. 2-3 View File ............................................................................................................................................. 2-3 Save As ................................................................................................................................................ 2-3

Date: 7/10/2012

Save ..................................................................................................................................................... 2-4 Save and Exit ....................................................................................................................................... 2-4 Exit ...................................................................................................................................................... 2-4

PORT ....................................................................................................................................................... 2-5 PC Communication Set Up.................................................................................................................. 2-5 Flow Computer Communication Set Up ............................................................................................. 2-6 Dial ...................................................................................................................................................... 2-8 Phone Book ......................................................................................................................................... 2-8 Modem Setup ...................................................................................................................................... 2-9 Hang-up Phone .................................................................................................................................... 2-9

DIAG ..................................................................................................................................................... 2-10 Read Single Flow Computer Communication Setup ......................................................................... 2-10 Diagnostic Data ................................................................................................................................. 2-10 Turbine Diagnos ................................................................................................................................ 2-10 Smart Flow Computer Configuration Diagram ................................................................................. 2-11

PROVER ............................................................................................................................................... 2-12 Prove Request .................................................................................................................................... 2-12 Prover Temperature Override ............................................................................................................ 2-12 Prover Pressure Override ................................................................................................................... 2-12 Prover Gravity Override .................................................................................................................... 2-12 Prover Shaft Temperature Override ................................................................................................... 2-12 CTL or CPL Override ........................................................................................................................ 2-12 Prove Data ......................................................................................................................................... 2-12 Prover Diagram ................................................................................................................................. 2-18 Previous Prove Report ....................................................................................................................... 2-18 Single Prove Report ........................................................................................................................... 2-18 Prove Abort Report ............................................................................................................................ 2-18

METER ................................................................................................................................................. 2-19 Set Up ................................................................................................................................................ 2-19 METER DATA ................................................................................................................................. 2-20 PRODUCT DATA ............................................................................................................................ 2-22 Product Meter Factor/Specific Gravity .............................................................................................. 2-22 Linear Factor ..................................................................................................................................... 2-22 OTHER PARAMETERS .................................................................................................................. 2-23 BATCH PARAMETERS .................................................................................................................. 2-25 Batch Scheduling ............................................................................................................................... 2-25 Date and Time ................................................................................................................................... 2-25 End Batch .......................................................................................................................................... 2-25 Current Batch Preset .......................................................................................................................... 2-26 Overrides: .......................................................................................................................................... 2-26 Security Code .................................................................................................................................... 2-26

INPUT/OUTPUT .................................................................................................................................. 2-27 Transducer Input Assignment ............................................................................................................ 2-27 Transducer Tag ID ............................................................................................................................. 2-28 Calibration ......................................................................................................................................... 2-28 PID Tuning ........................................................................................................................................ 2-29 PID Configuration ............................................................................................................................. 2-29 PID- Operating .................................................................................................................................. 2-29 Status Input Assignment .................................................................................................................... 2-30 Switch Output Assignment ................................................................................................................ 2-32 Analog Output Assignment ............................................................................................................... 2-34 Flow Computer Display Assignment ................................................................................................. 2-35 Modbus Shift ..................................................................................................................................... 2-36

REPORTS ............................................................................................................................................. 2-37 Current Data - Snapshot Totalizer Updates ....................................................................................... 2-37 Previous Batch Data .......................................................................................................................... 2-37

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Previous Hourly Data ........................................................................................................................ 2-37 Previous Daily Data ........................................................................................................................... 2-37 Previous Alarm Data ......................................................................................................................... 2-37 Audit Trail Report ............................................................................................................................. 2-38 Build User Report .............................................................................................................................. 2-38 View User Report .............................................................................................................................. 2-38 Formatted Ticket Report .................................................................................................................... 2-38 Ticket Report ..................................................................................................................................... 2-38 Auto Data Retrieval ........................................................................................................................... 2-38

WIRING ................................................................................................................................................ 2-39 PRINT ................................................................................................................................................... 2-40

Print "Help" File ................................................................................................................................ 2-40 Print Modbus Registers ..................................................................................................................... 2-40 Print Schematic .................................................................................................................................. 2-40 Print Calibration Data ........................................................................................................................ 2-40 Print Files .......................................................................................................................................... 2-40

CHAPTER 3: Flow Equations ..................................................................................................................... 3-1 FLOWRATES ......................................................................................................................................... 3-1

Mass Flowrate (MASS) ....................................................................................................................... 3-1 PROVE EQUATION .............................................................................................................................. 3-3 DENSITY EQUATIONS ........................................................................................................................ 3-5

Sarasota Density GM/CC .................................................................................................................... 3-5 UGC Density GM/CC ......................................................................................................................... 3-6 UGC Density 2 GM/CC ..................................................................................................................... 3-7 Solartron Density GM/CC ................................................................................................................... 3-8 Propylene Density ............................................................................................................................... 3-9 Ethylene Density ................................................................................................................................. 3-9

CHAPTER 4: MODBUS DATA ................................................................................................................. 4-1 MODBUS PROTOCOL .......................................................................................................................... 4-1

TRANSMISSION MODE ................................................................................................................... 4-1 ASCII FRAMING ............................................................................................................................... 4-1 RTU FRAMING .................................................................................................................................. 4-1 FUNCTION CODE ............................................................................................................................. 4-2 ERROR CHECK ................................................................................................................................. 4-2 EXCEPTION RESPONSE .................................................................................................................. 4-2 BROADCAST COMMAND ............................................................................................................... 4-2 MODBUS EXAMPLES ...................................................................................................................... 4-3 FUNCTION CODE 03 (Read Single or Multiple Register Points) ..................................................... 4-3 Scaled Data Area ................................................................................................................................. 4-9 Modbus 16-Bit Address Table Ends .................................................................................................. 4-10

MODBUS ADDRESS TABLE - 32 BITS ............................................................................................ 4-11 Last Batch/Daily Data Area ............................................................................................................... 4-15 Last Prove Data Area ......................................................................................................................... 4-29 End of Last Prove Data Area ............................................................................................................. 4-32 Current Prove Data Area ................................................................................................................... 4-33 End of Current Prove Data Area ........................................................................................................ 4-33 Last Single Prove Report Data Area .................................................................................................. 4-34 End of Last Single Prove Report Data Area ...................................................................................... 4-34 Last Abort Prove Report Data Area................................................................................................... 4-35 End of Last Prove Abort Data Area ................................................................................................... 4-37

Alarms and Status Codes ....................................................................................................................... 4-47 Previous Audit Data Area: ................................................................................................................. 4-48 CURRENT ALARM STATUS ......................................................................................................... 4-51

Dynamic Flow Computers SFC332 Liquid Pulse Manual Data Entry — 1-1

Date: 7/10/2012

CHAPTER 1: QUICK START

Introduction: A good flow computer must be:

User friendly

Flexible

Easy to understand and configure

Rugged

Economical to install and maintain

Accurate

The model SFC332 Smart Flow Computer incorporates all these features. We hope that your experience

with the Flow Computer will be a very pleasant and friendly experience and not intimidating in any way.

General Description: The SFC332 is a dual meter run bi-directional flow computer for the measurement

of liquid products. Fifty days of previous daily data, fifty previous batch data, and fifty previous hourly

data are stored in the full format type reports. The previous 100 audit trail reports and 100 alarm reports

are stored. User formatted reports and user formatted ticket reports are available. Sixteen different product

files are user-configurable with easy switch feature and product scheduling for batch operation.

Inputs/Outputs: 2 serial conections, RS-232 and RS-485, both of them modbus ready. The RS-232 can

also be used with serial printer. Inputs: two 4 wire RTD; 4 single ended analog inputs; , 4 status inputs;

and density frequency. Outputs: 2 pulse/switch outputs; 3 switch outputs; and 2 analog outputs.

Programmable plasma display.

Conventions Used in This Manual: <ENTER> The “enter” or “return” key on the PC keyboard

<ALT><D> Hit the key (here, hold down <ALT> and strike <D>).

Set Up This type of text indicates a menu item in the software

Meter | Set Up | Common Pressure Two or more items in this font separated by a vertical bar

(bars) is used to indicate a menu item and subitem. In

this example, Meter is on the menu bar, Set Up is a

topic beneath it, and Common Pressure is listed in

turn beneath it.

Meter #[1/2] Use Stack DP The [1/2] is indicates that two menu items exist, one

for Meter #1 and one for Meter #2.

Note: A note has an important piece of information and is boxed to call attention to itself.


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Smart Flow Computer : Dimensions


Date: 7/10/2012

Website - DFM Configuration Software

Step 1. Go to our website WWW.DYNAMICFLOWCOMPUTERS.COM

Step 2. Click on the Software link located on the left hand side of the web page. You will be presented

with two options: Windows software and DOS software. The following flow computer applications have

Windows software:

EChart

MicroMVL

MicroMS4

MicroMVA

Sfc332G Air V.2

Sfc332L

MicroML1

If you don’t see your application listed here it means it only has DOS software.

Step 3. Select either Windows or

DOS software based on Step 2.

Step 4. On the new screen

presented to you click on the

application that you are trying to

download. Once you hit the link it

will ask you if you want to run or

save the file in you computer.

Select SAVE. (See illustration 1)

Step 5. The file will start to

transfer to your computer. The

download time depends on your

Internet connection speed and

the type of application that being

downloaded.

Step 6. When the download if

finish. Press the OPEN button to

start the setup process. (See

Illustration)

Step 7. Follow the steps in the

application setup.

http://www.dynamicflowcomputers.com/


Date: 7/10/2012

Starting and Installing the Software: To acquaint you with your software we will begin the software, create a new configuration file, and save it.

We describe this procedure as though you are running the software from a floppy disk. At the bottom of

the page we give you simple instructions for installing the software onto a PC’s hard drive.

1. Insert the diskette that is provided with the flow computer into your PC or laptop (3.5”

disk drive).

2. Call the drive by entering A: or B: depending on the drive you are using.

3. Type the instructions on the diskette (in this case SFC332) and then press <ENTER>.

4. The software opens ready for you to choose an existing file. The File | Open File

menu topic | subtopic are highlighted. However, we have not configured any files yet;

therefore use your arrow keys to move to Open New File and press <ENTER>.

5. Type in your new file’s name (eight alphanumeric characters or less) and then press

<ENTER>.

6. Now you are back to Open New File. Use the down arrow key to move the cursor

to Save and press <ENTER>. You have just saved the file you just created. Notice that

now the file name will appears in the right top corner of the screen, on the menu bar.

This indicates the name of the currently active file; if you change parameters and Save

again, the changes will be saved to your file.

7. Use the right and left arrow keys to scroll through the menu. All menus have an on-line

help screen that appears when you push the <F1> key. Browse through the program

and use the help menu to understand the purpose for any particular entry. You will also

notice that there is a “prompt” line at the bottom of your screen. This prompts you for

appropriate key choices wherever you are in the program.

To run off the hard drive of a PC or laptop:

1. Create a subdirectory with a name of your choosing, for example, SFC.

2. Copy the contents of the floppy disk to directory SFC. In DOS this could be

accomplished with a command such as COPY A:*.* C:\SFC.

3. Launch the new copy of SFC332 that now resides on your hard drive instead of the

version on your floppy disk.

If you decide to run your Smart Flow Computer software from a floppy disk it is a good idea to make a

copy of your original disk and run from the copy.


Date: 7/10/2012

Technical Data

POWER

VOLTAGE RANGE 12-30 VDC

WATTAGE 4 WATT

OPERATING CONDITIONS

TEMPERATURE - 40 TO 185 °F

HUMIDITY 100%

HOUSING NEMA 4X CLASS 1 DIV. 1

FEATURES

DISPLAY PLASMA 2 LINES 16 CHARACTER

PROCESSOR 32-BIT MOTOROLA 168332 @ 16.7 MHz

FLASH ROM 4 MB @ 70 NANO SECONDS

ROM 2 MB @ 30 NANO SECONDS

FREQUENCY INPUT 3 CHANNELS 0 - 5000 Hz

WITH TURBINE DIAGNOSTIC FUNCTION >70 mV FOR SIN WAVE > 6 VOLTS FOR SQUARE WAVE

ANALOG INPUT FOUR 24-BIT CHANNEL EXPANDABLE TO 6

RTD INPUTS 2 CHANNELS 4 WIRES

ANALOG OUTPUT 2 CHANNELS 12 BIT SINGLE ENDED

DIGITAL OUTPUT OUTPUTS 1 & 2 PULSE/SWITCH 0.5 AMPS RATING

OUTPUTS 3 TO 5 ARE SWITCH OUTPUTS 0.25 AMPS

RATING

STATUS INPUTS 4 ON/OFF TYPE SIGNAL

ALL INPUTS AND OUTPUTS ARE OPTICALLY ISOLATED

SERIAL 1 RS485 @ 38400 BAUDS VARIABLE 1 RS232 @ 19200 BAUDS VARIABLE

COMMUNICATION PROTOCOL MODBUS


Date: 7/10/2012

Parts List

Part Description

332-01P Controller (CPU) Board for SFC332/1000 w/prover option.

332-02 Terminal (BP) Board for SFC332/1000.

332-03 Analog Board for SFC332/1000.

332-04 Display (LCD) for SFC332/1000.

332-05 Rosemount Interface Board for SFC1000.

332-06 Prover Option for SFC332/1000.

332-07 Enclosure for SFC332/1000.

332-08 Mounting Bracket w/captive screws for SFC332/1000 Boards.

332-09 Adapter between SFC1000 and Rosemount 205.

332-10 Center portion of housing for SFC332/1000 enclosure.

332-11 Glass Dome Cover for SFC332/1000 Enclosure.

332-12 Blank Dome Cover for SFC332/1000 Enclosure.

332-13 O'ring for SFC332 Enclosure.

332-14 External I/O Expansion.

332-15 Battery Replacement for SFC332/1000.

332-16 1/2 Amp 250V Fuse for SFC332/1000.

332-17 EPROM for SFC332/1000 (set of two).

RS232 External RS232 Connection for all models.


Date: 7/10/2012

Getting acquainted with the flow computer wiring:

To wire the flow computer, get familiar with the drawings provided in the software’s Wiring menu. Use

the arrow left and right keys to move to and select Wiring, then press <ENTER>.

Back terminal wiring: The back terminal wiring indicates the overall positions of the terminal plugs and their functions. Though

the back panel’s jumpers are also shown, refer to the next drawing, “Back Panel Jumpers”, for information

on their settings and functions.

The Smart Flow Computer receives its power via the two topmost pins on Terminal P1, on the left of the

terminal board. Also on Terminal P1 are, from top to bottom, inputs from the two turbines and the RS-485

serial connection.

To the right (P4), from top to bottom, is status input 1, density frequency input, and switch output 1 and 2.

Terminal P3, at the lower bottom, handles analog inputs and outputs. These are, in order from right to left,

analog inputs 1-4 and analog outputs 1 and 2.

Terminal P5, top middle, is the RTD terminal block, "100 platinum RTD input".


Date: 7/10/2012

Back Panel Jumper In this illustration, a jumper is “ON” when the jumper block is used to connect the jumper’s to wire prongs.

“OFF” means the jumper block is completely removed or attached to only one of the two wire prongs.

Note: R11 and R3 could have a vertical orientation instead of a horizontal orientation on certain Smart Flow Computer models.


Date: 7/10/2012

INPUT/OUTPUT: Assignment, Ranging, Wiring, and Calibration

Input/Output Assignment We will now configure your Smart Flow Computer’s inputs and outputs. The flow computer allows the

user to configure the inputs and outputs. i.e. Analog #1 is pressure for Meter #1. Unassigned inputs are not

used by the flow computer.

How to assign a transmitter to an I/O point: Before beginning the procedure of assigning inputs and outputs, it is advisable to set up the meter (Meter

| Set Up). This is because certain parameters on the Transducer Input Assignment page

change (or may not appear, etc.) based on Meter | Set Up.

1 Use your arrow keys to scroll to menu item I/O (between Meter and Report). Its first

entry is Transducer Input Assignment. Press <ENTER>.

2. Use the down/up arrow key to scroll through this menu. The first four parameters are used to

set the number of decimals you would like to see in your live inputs (these numbers do not

affect the precision of your calculated data). Spare inputs are inputs that the flow computer

will read and display in the diagnostic data but are not used in the calculations. Spare inputs

high and low limit alarms are documented in the historical alarm report.

3. After the parameters used for setting the number of decimals come a series of parameters

ending with the words Assignment (1-n). Assignments 1-4 are analog

inputs attached to terminal P3 of the back panel. These

inputs accept 4-20mA or 1-5 volts input and are suitable for temperature, pressure,

density, BS&W, or spare inputs. Assignments 5 and 6 are strictly RTD (temperature) inputs

only for the meter, prover, densitometer or spare; temperatures are inputted via terminal P5

on the back panel. Assignment 7 indicates a density frequency input; it is assigned

automatically once you choose live density frequency input in the setup menu at density type

selection (and it can only be assigned via Meter | Set Up | Density #n, where n = 1 to

4). Assignment 10 (module 1) and assignment 11 (module 2) are used for Rosemount multi-

variable module only. DP, pressure, and temperature for the meter can be assigned.

Ranging the Transmitter Inputs:

1. Enter the range values: after assigning the inputs scroll down the transducer inputs

assignment menu to scale the 4-20mA. Enter the value at …@4mA and …@20mA. Enter both

values similar to the way the transmitter is ranged. 1-5 volts is equivalent to 4-20mA. Enter

the 1 volt value at the 4mA, and 5 volt value at 20mA.

2. Enter the high and low limits: high limits and low limits are simply the alarm points in

which you would like the flow computer to flag as an alarm condition. Enter these values

with respect to the upper and lower range conditions. Try to avoid creating alarm log when

conditions are normal. For example: If the line condition for the pressure is between 0 to 500

PSIG. then you should program less than zero for low pressure alarm, and 500 or more for

high pressure alarm. High and low limits are also used in the scale for the Modbus variables.

3. Set up the fail code: Maintenance and Failure Code values tell the flow computer

to use a default value in the event the transmitter fails. The default value is stored in

Maintenance. There are three outcomes: the transmitter value is always used, no matter

what (Failure Code = 0); the Maintenance value is always used, no matter what


Date: 7/10/2012

(Failure Code = 1); and the Maintenance value is used only when the transmitter’s

value indicates that the transimtter has temporarily failed (Failure Code = 2).

RTD inputs will skip 4-20mA assignment because RTD is a raw signal of 50 (ohms) to 156. Readings

beyond that range require a 4-20mA signal to the flow computer.

Density coefficients for raw frequency inputs are programmed in this menu. The menu will only show

parameters relevant to the live density selected (i.e., Solartron or UGC, etc.).

NOTE: Solartron density input requires values in US units, i.e. PSI, and

F. Request a calibration sheet in US units from the densitometer manufacturer.


Date: 7/10/2012

WIRING: Wiring to the flow computer is very straight forward and simple. But still it is very important to get

familiar with the wiring diagram.

Wiring the analog inputs: Use your arrow keys to move the cursor to the menu item Wiring and then use up/down arrow keys to

select Analog Wiring. Press <ENTER>. Typical wiring for analog inputs 1 and 2 are shown in the

drawing. Analog inputs 3 and 4 are to the left of analog 1 and 2. Note that the analog input has only one

common return which is the -ve signal of power supply powering the transmitters.

When wiring 1-5 volts, make sure to calibrate the flow computer for the 1-5 volt signal because the flow

computer calibration defaults for the 4-20mA which is different from the 1-5 volts. JP5 must be cut for 1-5

volt inputs. The jumpers for analog 1-4 are in order from right to left. It is possible to cut the first two

jumpers for analog 1 & 2 in for 1-5 volts signal and have analog in 3 & 4 as 4-20mA signal. Signal line

impedance provided by our flow computer is less than 250. Therefore, when using a smart transmitter

that requires a minimum of 250 resistance in the loop, an additional resistor at the flow computer end

needs to be installed in series with the 4-20mA loop in order to allow the hand held communicator to talk to

the transmitter.

NOTE: The 4-20mA or 1-5 volt DOES NOT source power to the transmitters. You can use the DC power feeding the flow computer to power the 4-20mA loop IF that power

supply is FILTERED.


Date: 7/10/2012

Wiring the analog inputs 1-4 :


Date: 7/10/2012

Wiring the analog inputs 5,6 : The ‘Flow Computer’ can be configured as ‘6 analog inputs’ or ‘4 analog inputs and 2 RTD inputs’. (Under

IO Assignment Data Entry – SFC version 3.16, FC version 3.07 and higher)

When RTD is connected, make sure that 115 OHM is installed per drawing.


Date: 7/10/2012

RTD When ‘Flow Computer’ is configured as 4 analog inputs and 2 RTD inputs, go to the wiring menu where it

says RTD and press <ENTER>. The flow computer shows wiring to RTD 1 and RTD 2. 100 platinum

can be used; a temperature range of -43F to +300F can be measured. RTD 1 is to the right where P5

designation is. In the figure below notice that each side of the RTD requires two wire connections. When

using less than 4 wires a jumper must be used to make up for the missing lead. Internal excitation current

source generated is approximately 7mA. .


Date: 7/10/2012

Wiring analog output: The analog outputs are located on the left side of P3 connector. Go to the wiring diagram and scroll down

to Analog Output and press < ENTER>. Wiring diagram shows typical Analog output wiring. Notice

that analog output will regulate 4-20mA current loop but DOES NOT source the power for it. External

power is required.

ASSIGNING /RANGING THE 4-20MA ANALOG OUTPUTS :

Go to the I/O assignment main menu and scroll to Analog Output Assignment. Press

<ENTER>. A selection menu is prompted. Select the analog output number and then enter what the 4mA

output will indicate and the 20mA. Make sure that the 20mA assignment value exceeds the upper range

limit of what you assigned the Analog output for, otherwise the analog output will not update beyond

20mA.


Date: 7/10/2012

Turbine input wiring Scroll to Turbine under Wiring and press <ENTER>. Two drawings above each other will show

typical wiring for turbine meter 1 and turbine meter 2. When dual pick ups from the same turbine are

connected, use the inputs for turbine 1 for pickup 1 and turbine 2 for the second pickup coil. When

connecting sine wave directly from the pickup coil make sure the distance from the pickup coil to the flow

computer is very short--less than 50 feet with shielded cable. In the event there is presence of noise, the

distance must be shortened. When connecting sine wave signal, the R11 jumper for meter 1 must be

installed and R3 jumper for meter 2 must be installed. (JP3 and JP2 must be off when using sine wave).

On the other hand, when using square wave, the square wave signal can be sinusoidal but has to be above 5

volts peak to peak with less than 0.4 volts offset in order for the flow computer to read it. R11 and R3 must

be off and JP3 on for meter 1; JP2 must be on for meter 2.

Note: When connecting square wave input, the JP3 and JP2 connect the turbine return to the flow computer power return. Therefore, signal polarity is very important. Reverse polarity could result in some damage or power loss. When sine wave is used the signal polarity is usually of no significance.

The turbine input is immediately under the power input on terminal P1. The third pin down from the top is

Turbine/PD "minus", and below it is Turbine plus. The second pulse input for Turbine/PD meter 2 or the

second pickup coil is below turbine one input on P1. The fifth pin down from the top is turbine 2 "minus"

signal and below it is Turbine/PD 2 plus signal.

Note : R11 and R3 are oriented vertically in some flow computers.


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Turbine wiring for passive (dry contact) pulse generators

Some mass flow meters have pulse outputs that do not provide power but instead require external power, they are referred to as passive outputs, dry outputs, open collector, etc. (For example the Krohne UFM 3030 Mass meter). In these cases the wiring should be as shown on the below diagram. The pull up resistor can be adjusted to limit the current sink by the Mass meter. For Turbine Input 1 JP3 must be ON and R11 OFF and if using Turbine Input 2 then JP2 must be ON and R3 OFF.


Date: 7/10/2012

Density input wiring: When using a live densitometer input with frequency signal, the signal can be brought into the Smart Flow

Computer in its raw form. The Smart Flow Computer accepts a sine wave or square with or without DC

offset. Example for density wiring can be seen in the wiring diagram. Use the arrow keys to get to

Wiring | Density and press <ENTER>. Find two drawings, one with barrier and the other without.

Barriers are used for area classification. Notice that the RTD wiring is also drawn to show how to hook the

density RTD signal.

Note: When wiring the density input polarity is of significance and reverse polarity could result in some damage or power loss. The density signal is on connector P4, the third and fourth pin down from the top. The third pin down is density plus, the fourth down is density minus. When Density input is 4-20mA it should be connected as a regular 4-20mA signal to the analog input and not the density frequency input.


Date: 7/10/2012

RS-232 connection: The RS-232 is not located on the terminal board. The RS-232 is a green 5 pin terminal block with screw

type connector located on the display side of the enclosure. Scroll to Wiring | New RS-232 and press

<ENTER>. Termination jumpers for the RS-232 are located at the top corner of the board on the same side

of the RS-232 connector. The two jumpers at the top are for terminating the transmit line and below it is

the receive line.

The RS-232 port can be used for printing reports, Modbus communication, or interfacing to the

configuration program. If the port is configured as printer port in the flow computer communication setup,

then reports get printed (i.e. interval and daily reports).

Note: Twisted shielded cable is required.

WARNING: When the RS-232 terminal is used with a modem, external protection on the phone line is required.


Date: 7/10/2012

RS-485: RS-485 wiring is shown in the wiring diagram under RS-485. The RS-485 termination jumper is JP4

located on the back terminal. The maximum distance when 18 gauge wire is used would be 4000 feet.

Note: Twisted shielded cable is required.

WARNING: When the RS-485 terminal is used, external transient protection and optical isolation is required, especially for long distance wiring.


Date: 7/10/2012

Wiring of status inputs: There is one status input standard and an optional three more on the back of the CPU board. The standard

status input is shown in the wiring diagram under Status Input. It has 4 volts of noise hysteresis,

with a trigger point of 5 volts and an off point of 1 Volt. Status inputs 2, 3, and 4 require the I/O expansion

connector and its wires be installed; refer to wiring drawing IO-Exp. Connection numbers 6, 7, and 8 are

the status in (positive) for inputs 2, 3, and 4, respectively, and 11 is the return for all three inputs.


Date: 7/10/2012

Wiring of switch/pulse outputs: Scroll to SWitch output under Wiring and press <ENTER>. The wiring diagram shows switch 1

and 2 and the return. Please note that switches 3, 4, and 5 cannot be used for pulse output; switches 1 and 2

can be used for pulse or switch output. See also I/O Expansion. Notice that the switch outputs are

transistor type outputs (open collector type with maximum DC rating of 350 mA continuous at 24 VDC)

and require external power.


Date: 7/10/2012

I/O Expansion:

The I/O expansion is 16-pin connector next to the RS-232 terminal. Eleven pins of the 16-pin connector

are utilized. When the flow computer is ordered with the I/O expansion feature, the wires and the plug are

provided with the flow computer. There will be 11 wires with the wire number tag at the outer end of the

wire. The tag will indicate the wire number. The following is the sequence for the wires. On the top right

edge of the connector towards the top outer side of the CPU board is pin 1, across from it is pin 9.

Connection Purpose Comments 1 detector switch 1 Requires prover option CPU to operate.

Rating: 5-36 Vdc 2 detector switch 2

3 switch output 3 Maximum rating: 75mA @24 volts Range: 5-36 Vdc

4 switch output 4

5 switch output 5

6 status input 2

Rating: 6-36 Vdc 7 status input 3

8 status input 4

9 Return: detector switches

10 Return: switches 3, 4, 5

11 Return: status 2, 3, and 4


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I/O Expansion


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Prover/Expansion Connection No. Purpose Comments

1 detector switch 1 Requires prover option CPU to operate. Rating: 5-36 Vdc 2 detector switch 2

3 switch output 3 Maximum rating: 75mA @24 volts Range: 5-36 Vdc

4 switch output 4

5 switch output 5

6 status input 2

Rating: 6-36 Vdc 7 status input 3

8 status input 4

9 Return: detector switches

10 Return: switches 3, 4, 5

11 Return: status 2, 3, and 4

12 RS232 TX

13 RS232 RX

14 RS232 RTS

15 RS232 ret


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Wiring of Brooks Prover:


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Wiring of Calibron Prover:


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Calibration

Analog Input 4-20mA or 1-5 volt signal: Calibrations are performed under I/O | Calibration. Use the arrow keys to scroll to

Calibration and press <ENTER>. After you press <ENTER> the screen should show

COMMUNICATION STATUS : OK.

OFFSET CALIBRATION :

For simple offset type calibration simply induce the signal into the analog input and make sure the flow

computer is reading it. After you verify that the flow computer recognized the analog input press <F8>.

The screen will freeze. Scroll down to the analog input you are calibrating and enter the correct mA

reading. Then press <ENTER> followed by <F3> to download. The screen will stay in the freeze mode. To

bring the live readings press <F2> and then the flow computer will display the new calibrated readings.

The offset type calibration is mainly used when a small offset adjustment needs to be changed in the full

scale reading. The offset will apply to the zero and span.

FULL CALIBRATION METHOD:

To perform full calibration be prepared to induce zero and span type signal.

1. Induce the low end signal i.e. 4mA in the analog input.

2. Press <F8> and scroll down to the reading then press <ALT><R>(alternate key and the letter

R simultaneously). Then immediately enter the analog input value i.e. 4mA. Follow that by

<ENTER> and the download <F3> button.

3. Now be ready to enter the full scale value. Simply induce the analog signal and then enter the

value i.e. 20mA, and then download by pressing <ENTER> then <F3>.

4. Now induce live values to verify the calibration.

DEFAULT CALIBRATION

Simply press <F8> and scroll to the analog Input and press <ALT><R> followed by <F3 function key.


Date: 7/10/2012

RTD Calibration: RTD Calibration is a 2-step process. The first step is a one time procedure to verify transducer linearity and is done at the time the meter is being setup. The second step is the routine calibration sequence. Step 1 – Linearity Verification 1. Use a Decade box with 0-150 °F settings. 2. Connect RTD cable to this resistive element for verification of linearity. Verify low and high points. It must be within ½ degree. 3. Connect the actual RTD element and compare with a certified thermometer. 4. If not within ½ degree do a Full Calibration (See Full Calibration below). If problem persists verify other elements such as RTD Probe, connections, shield, conductivity of connectors, etc. The purpose of the above procedure is to verify zero and span and make sure that the two points fall within the expected tolerance. Step 2 – Routine Calibration Once Linearity has been verified through Step 1, the routine calibration procedure is reduced to simply connecting the actual RTD and doing an offset point calibration (see offset calibration below). Calibration after that will be simple verification for the stability of the transmitter. If it drifts abnormally then you need to verify the other parts involved. RESET TO DEFAULT CALIBRATION

To go back to the default calibration simply press <F8> and scroll to the RTD input, and press

<ALT> <R> key followed by <F3> function key.

OFFSET CALIBRATION:

For offset calibration simply go to I/O | Calibration and press < ENTER>. Once the flow

computer shows communication status OK press <F8> function key and scroll to RTD. Induce a

live value and wait for 10 seconds for the reading to stabilize. Then enter the live value followed by <F3> function key to download the direct reading. The value entered must be in ohms only. FULL SCALE CALIBRATION:

1. Prepare low range resistive input (i.e., 80) and High range resistive input (i.e., 120). Go to the calibration menu and press <F8> function key. Scroll to the RTD input you are calibrating and press <ALT> <R> (key <ALT> and the letter R at the same time). Induce the low end

(80) resistive signal and then wait 10 seconds and enter 80 followed by pressing the <F3> function key.

2. Induce higher range signal (120) and wait 10 seconds, then enter the number 120 ohm and

press the <F3> key.

3. Now verify the live reading against the flow computer reading.


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Calibration of analog output: To calibrate the analog output against the end device follow the following steps:

1. Go to the calibration menu and press <F8>. Scroll down to analog output and press <ENTER >

and then <ALT><R>. This will cause the flow computer to output the minimum possible

signal 3.25 mA. Enter the live output value reading in the end device i.e. 3.25 mA and press

<F3> function key. Now the flow computer will output full scale 21.75 mA. Enter the live

output i.e. 21.75 then press the <F3> function key.

2. Now verify the output against the calibration device.


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Multi-Variable Transmitters (Model 205)- DP and Pressure

OFFSET CALIBRATION

1. Induce live value for temperature, pressure, or Spare

2. Go to Calibration - Multi-Variable menu.

3. Press <F8>, point to the value being calibrated, enter the correct value followed by

<ENTER>, then press <F3> function key to download data.

4. Now read induce live values to verify the calibration.

FULL SCALE CALIBRATIO N

1. Press <F8>. Scroll to the parameter to be calibrated, then press <ALT><R>.

2. Induce the low range signal, then press <ENTER> followed by <F3> function key.

3. Induce the low range signal, then press <ENTER> followed by <F3>.


TO USE DEFAULT CALIBRATION

1. Select Multivariable DP or pressure 2. Select Reset calibration method 3. Now verify the live reading against the flow computer reading


Date: 7/10/2012

Multi-Variable Transmitters (Model 205)- RTD Calibrations are performed under I/O | Calibration. Use the arrow keys to scroll to

Calibration-Multi-Variable and press < ENTER>. After you press < ENTER> the screen

should show COMMUNICATION STATUS : OK.

RTD Calibration is a 2-step process. The first step is a one time procedure to verify transducer linearity and is done at the time the meter is being setup. The second step is the routine calibration sequence. Step 1 – Linearity Verification 1. Use a Decade box with 0-150 °F settings. 2. Connect RTD cable to this resistive element for verification of linearity. Verify low and high points. It must be within ½ degree. 3. Connect the actual RTD element and compare with a certified thermometer. 4. If not within ½ degree do a Full Calibration (See Full Calibration below). If problem persists verify other elements such as RTD Probe, connections, shield, conductivity of connectors, etc. The purpose of the above procedure is to verify zero and span and make sure that the two points fall within the expected tolerance. Step 2 – Routine Calibration Once Linearity has been verified through Step 1, the routine calibration procedure is reduced to simply connecting the actual RTD and doing an offset point calibration (see offset calibration below). Calibration after that will be simple verification for the stability of the transmitter. If it drifts abnormally then you need to verify the other parts involved. RESET TO DEFAULT CALIBRATION

To go back to the default calibration simply press <F8> and scroll to the RTD input, and press

<ALT> <R> key followed by <F3> function key.

OFFSET CALIBRATION:

For offset calibration simply go to I/O | Calibration and press < ENTER>. Once the flow

computer shows communication status OK press <F8> function key and scroll to RTD. Induce a

live value and wait for 10 seconds for the reading to stabilize. Then enter the live value followed by <F3> function key to download the direct reading. The value entered must be in degrees only. FULL SCALE CALIBRATION:

1. Prepare low range resistive input (i.e., 80) and High range resistive input (i.e., 120). Go to the calibration menu and press <F8> function key. Scroll to the RTD input you are calibrating and press <ALT> <R> (key <ALT> and the letter R at the same time). Induce the low end

(80) resistive signal and then wait 10 seconds and enter the equivalent temperature in degrees followed by pressing the <F3> function key.

2. Induce Higher range signal (120) and wait 10 seconds, then enter the temperature degrees equivalent to 120 followed by pressing the <F3> function key.



Date: 7/10/2012

Verifying digital inputs and outputs: Use the diagnostic menu. Scroll down by using the arrow keys to Diag | Diagnostic Data and

press <ENTER>. A live input and output is displayed. On the top of the screen pulse inputs and density

frequency input are shown. Compare the live value against the displayed value on the screen. Failure to

read turbine input could be a result of the preamp being bad or the jumper selection for sine and square

wave input are not in the right position. Refer to wiring diagram Wiring | Turbine for proper

turbine input wiring. Density input can be sine or square wave with or without DC offset. Minimum

accepted signal has to be greater than 1.2 volt peak to peak. Status input is shown below the frequency

input to the left of the screen. When the status input is on, the live diagnostic data will show ON.

Minimum voltage to activate the status is 7 volts with negative threshold of 2 volts. Switch outputs are to

the right of the status inputs. To activate the switch outputs to the on and off position press <F8> in the

diagnostic menu. After the screen freeze the cursor will point to switch output one. Use the space bar to

toggle the switch on/off and the <ENTER> key to advance to the next switch. To exit press <ESC>. The

switch outputs are open collector and require external voltage.


Date: 7/10/2012

Pulse Interpolation:

When interfacing with Small Volume Provers (SVP), Dynamic uses Dual chronometry as the pulse

interpolation method which is required for provers providing less then 10,000 unaltered pulses.

Pulse interpolation is a pulse counting technique used to calculate the total number of meter pulses between

two detectors, including fractional pulses. A conventional pipe prover requires a minimum of 10,000

unaltered pulses to ensure an accurate test. This minimum is based upon the assumption there is a potential

error of 1 pulse each time a detector is passed, which equates to a 2-pulse error per run. The value of 2

pulses per 10,000 equates to a potential 0.02 % error. SVPs require less than 10,000 pulses, which would

equate to a potential error greater than 0.02 %.

To enhance the meter's pulse output, Small Volume Provers use pulse interpolation for fractional meter

pulse counting. To interpolate fractional meter pulses or to mathematically interpolate partial pulses,

Dynamic uses the double chronometry method for this purpose since it is the method most widely used.

Double Chronometry:

Double chronometry pulse interpolation increments time precisely every millisecond. A high frequency

master oscillator operates two time counters referred to as Time A and Time B. Time A starts when the first

detector switch is tripped, and Time B starts with the leading edge of the first flow meter pulse after Time

A has started. Time A is stopped when the final detector is tripped and Time B is stopped with the leading

edge of the first flow meter pulse after Time A has stopped (see figure below). Using the ratio of Time A

and Time B allows for counting of a fraction of the flow meter pulse.

D

C

BTime

ATimeK

_

_

K = K Factor, or counts per unit Volume, from the flow meter.

A = Time for displaced volume.

B = Time for whole meter pulses.

C = Total number of whole meter pulses.

D = Displaced Volume

Double Chronometry Figure


Date: 7/10/2012

Calculations and Terminology:

Liquid pulse units Crude refined products use API 2540 equation 5, 6 A & B, 23, 4 A & B, 11-2-1, and 11-2-2. Table 24 C is

used when thermal expansion coefficient is known. Old tables 23 and 24 with GPA16 and 11-2-2 are used

for NGL or light hydrocarbon mixes. API 2565 is used for propylene, and ethylene. In addition, NBS

1045 can be selected for ethylene calculations. ASTM 1550 can be used for butadiene.

Terms

)%1(

3600

BSWLMFCPLCTLIV

LMFCPLCTLIV

CPLCTLIV

L)(Pulses/BBFactor K Nominal

es/sec)Total(Puls

NSV VolumeStandard Net

GSV VolumeStandard Gross

ISV VolumeStandard Indicated

IV VolumeIndicated

Correction Rate Flow Linearized Factor Meter

WaterWeight of SG-BSW)%(LMFCPLCTL IV

WaterWeight of

.

Density-BSW)%(LMF IV

LMF

density) live (without

MASS

applied) is density live (if

MASS

10001

100099901201

Dynamic Flow Computers SFC332 Liquid Pulse Manual Flow Equations — 2-1

Date: 7/10/2012

CHAPTER 2: Data Entry

and Configuration Menus

Introduction to the Smart Flow Computer Software Your SFC332 software is constructed around a menu-driven organization. Begin your SFC software and,

across the top of your screen, you see a bar like this:

This is called the menu bar. It consists primarily of series of topics–Port, Diag, and so forth. When

you move the cursor to a topic you will see a list–we will call it a menu list– of topics related to the main

topic on the menu bar.

At the bottom of the screen is the prompt bar. It informs you of appropriate actions that you can perform

while your cursor is at its present location. In this example:

you are informed that your valid choices are the four arrow (rignt, left,down, and up) keys, the <ENTER>

key, and the <F1> key.

Another important area of the screen is the filename area. This is the rightmost section of the menu bar; it

informs you what configuration file you are presently viewing and editing. In the example above, you are

editing the file . When you first begin the SFC sotware, however, it will display

because no file has yet been chosen. Until you choose a file to edit or view, by opening either an existing

file or a new one, you will not be able to move from the File menu item.

The center portion of the screen is simply called the viewing area. Here you view either various menu lists

or the prompt window associated with an item in a menu list after it is selected (that is, after you press

<ENTER>). When you are in a prompt window the message appears in the filename area.

Under certain conditions you will have a screen where the viewing area takes up the whole screen and the

menu and/or prompt bars disappear. Examples of these are: the wiring diagrams, the calibration windows,

and the Diag windows.

ABOUT Displays the version number of EPROM

and PC configuration menu. Press <Esc> to

Exit.


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FILE

Open a File Use this function to open an existing configuration

file. After a file is opened it becomes the currently

active file; its contents can be viewed and its

parameters can be edited.

Open a New File Create a new file to store all the programmed

information for one Smart Flow Computer. You are

prompted for the new file’s name of eight characters

or less. If you enter the name of a pre-existing file,

the software informs you of this and prompts you

for your file’s name again. After a file is opened it

becomes the currently active file; its contents can be

viewed and its parameters can be edited.

Delete a File Delete a file when that file is no longer needed.

When this function is chosen a list of existing

configuration files is displayed. Use the arrow

keys to move the cursor to your selection, then

press <ALT><D> to delete the file.


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Load File Use this function to exchange parameter values between the PC and the Smart Flow Computer. After this

action is performed all parameter values in the Smart Flow Computer and the currently active file in the PC

are identical.

To read all current parameters from the Smart Flow Computer to the currently active file in the PC, press

the <F2> function key; this is called “uploading”.

To write all current parameters from the currently active file in the PC to the Smart Flow Computer, press

the <F3> function key; this is called “downloading”.

View File Unlike every other file function, View File does not act upon configuration files. Instead, View File allows

the user to view files that were previously captured in a report. For capturing data in a report, look for

these items under the Report menu header:

Prev. Hourly Data

Prev. Daily Data

Prev. Monthly Data

Alarm Data

Audit Trail Report

TicKet Report

Auto Data Retrieval

Current Data

When viewing a file use PageUp and PageDown to browse through it.

Save As Use Save As to save the parameters in the currently active file (that is, the parameter values currently being

edited) to a new file. You are prompted for the new file’s name of eight characters or less. If you enter the

name of a pre-existing file, the software informs you of this

and prompts you for your file’s name again.

The original file will remain in memory.


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Save When permanent modifications are performed on a file,

user must save the new changes before exiting the

program, or proceeding to open a different file.

Save and Exit Exit the program and save the parameters that were

changed.

Exit Exit without saving new modified parameters.


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PORT

PC Communication Set Up

Communicat ion Port Number (1,2,3,4)

Enter the PC port used to communicate with the Smart Flow Computer.

Flow Computer Port Number

There are two available ports in the Flow Computer. Port 1 is the RS-485 port that can only be a Modbus

port. Port 2 is the RS-232 port that can be user configurable as printer/Modbus. The PC set up must match

the Smart Flow Computer port set up.

Unit ID Number

The Unit ID Number is used strictly for communication purposes; it can take any value from 1 to 247. Only

one master can exist in each loop.

Note: Do not duplicate the Unit ID number in a single communication loop! This situation will lead to response collisions and inhibit communications to units with duplicate ID numbers.

Modbus Type

Note: this parameter must be set the same for both the PC and the Smart Flow Computer for communication to occur.

The Modbus Communication Specification is either Binary RTU or ASCII.

Parity


RTU - NONE

ASCII - EVEN or ODD

Set the parity to match the Modbus Type.


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Baud Rate


Baud rate is defined as number of bits per second. The available selections are 1200, 2400, 4800, or 9600.

Transmit Delay

This Delay in milliseconds is used to allow hand-shaking between the PC and the Smart Flow Computer.

The PC will hold the RTS line high for the specified Transmit Delay time. After that time expires the data

stream will begin transmitting. Transmit Delay is applicable regardless of the type of communication with

the Smart Flow Computer (RS-232 or RS-485).

This function can be very useful, especially when using a half-duplex RS-485 port; it allows the RS-485

port to turn off. A delay of 50 milliseconds is normally sufficient.

Flow Computer Communication Set Up

Unit ID Number

The Unit ID Number is used strictly for communication purposes; it can take any value from 1 to 247.

Note: Do not duplicate the Unit ID number in a single communication loop! This situation will lead to response collisions and inhibit communications to units with duplicate ID numbers.

Only one master can exist in each loop.

Port #1 Modbus Type




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Port #1 Parity


RTU - NONE

ASCII - EVEN or ODD


Port #1 Baud Rate


Baudrate is defined as number of bits per second. The available selections are 1200, 2400, 4800, or 9600.

Port #1 RTS Delay

This function allows for a modem or radio delay time before transmission. The Smart Flow Computer will

turn the RTS line high before transmission for the entered time delay period.

Port #2 Baud Rate


Port #2 Modbus Type

Note: This parameter must be set the same for both the PC and the Smart Flow Computer for communication to occur.


Port #2 Parity

RTU - NONE

ASCII - EVEN or ODD


Select 0=RTS,1=Printer

RTS line has dual function selection : either RTS for driving request to send or transmit to serial printer.

To use serial printer interface for printing reports, ie. batch, daily, and interval Connect the serial printer to

RTS and common return, and select 1 for printer.

Port 2 RTS Delay

This function allows modem delay time before transmission. The Smart Flow Computer will turn the RTS

line high before transmission for the entered time delay period.

Printer Baudrate


Printer Number of Nulls

This function is used because no hand shaking with the printer is available and data can become garbled as

the printer’s buffer is filled. The Smart Flow Computer will send nulls at the end of each line to allow time

for the carriage to return. Printers with large buffers do not require additional nulls. If data is still being

garbled, try reducing the baud rate to 1200.

Meter Micro Motion ID

Enter the ‘Micro Motion ID’ for the Serial Peripheral Interface.


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Dial

Use the cursor arrow keys to move the cursor to the desired phone number and press <ENTER>. Dial’s

display indicates the owner of each phone number according to the Phone Book.

Dial cannot add new phone numbers; it can only dial numbers that have previously been entered in the

Phone Book.

Example: T,9,1800-530-5539 instructs the dialer to use tone dialing, pause, dial 9 for an outside line,

pause, then dial the number. See Phone Book for more information.

Phone Book Phone Book lists all the phone numbers with the phone’s owner New numbers can be added to the list.

<Arrow Keys> Select Number to Modify or Delete.

<A> Add new entry to phonebook.

<ALT><D> Delete selected entry.

<M> or <ENTER> Modify selected entry.

<Esc> Exit and save changes.

Phone Book Edit Type name, press <TAB>, and type phone number. Press <ENTER> to save, <Esc> to leave entry

unchanged.

In the phone number the following codes may be used:

<0-9> Dial digit

<P> Change to pulse dialing

<T> Change to tone dialing

<Comma> Pause

Example: T,9,1800-530-5539 instructs the dialer to use tone dialing, pause, dial 9 for an outside line,

pause, then dial the number.


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Modem Setup

<Modem Dial Prefix> Enter the string sent to the modem before the phone number.

Normally either "ATDT" (dial tone) or "ATDP" (dial pulse)

<Modem Dial Suffix> Enter the string sent to the modem after the phone number.

Normally just "^M" (CR)

<Modem Hangup String> Enter the string sent to the modem to hang-up the phone.

See your modem manual for other characters.

Hang-up Phone Press <ENTER> to send the Modem Hang-up string (Defined in Modem Setup) to the modem.

Note : Hand shake and error checking should be turned off. Commands to turn off the hand shake vary between modems. Check your modem manual. Typical command - AT&K0, AT&Y0.


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DIAG

Read Single Flow Computer Communication Setup Press <F2> and the configuration

program will attempt to communicate

with a single Smart Flow Computer at

different baud rates and formats.

Failure to communicate can occur

because of a communication wiring

problem, wrong PC port selection,

communication parameter mismatch

between PC and Flow Computer

(Modbus type, parity, baud rate, etc.) or lack of power

to the Smart Flow Computer. To use this feature, the

user must insure that only one Flow Computer is

connected to the PC. More than one Smart Flow

Computer in the loop will cause data collisions and unintelligible responses.

Diagnostic Data

Diagnostic Data shows real-time, live data. Use it to monitor switch outputs, status inputs, analog

inputs and outputs, analog frequency, failure codes and so forth. To control the switch outputs manually

use the <F8> function key, press the SPACE BAR to change activity, and use <ENTER> key to move to

next switch.

Turbine Diagnos Turbine Diagnostic Data The DFM Flow Computer is able to determine conditions of the

turbine beyond 1956 level A Security level. This is performed by detecting each blade and each revolution

with 2 mhtz clock. Conditions affecting repeatability are detected. Other conditions such as missing

blades, bent blade, deteriorating pickup coil are also detected.


Date: 7/10/2012

Smart Flow Computer Configuration Diagram

Meter Run configuration for the current configuration file . Live data are displayed above the transmitters’

icons. Response of the various metering devices is indicated in either standard US or metric units, per the

chart below.

1. Standard

US Units Metric Units

Flow Rate (Mass) MLb KG

DP Inches H2O column Millibars

Pressure PSIG Bars

Temperature °F °C


Date: 7/10/2012

PROVER The SFC332 is a dual meter run bi-directional flow computer for the measurement of liquid products and

can also be used to prove a meter. To prove a meter, prove and meter data need to be configured. Enter a

temperature or pressure override value if no live input is used. Prover operation will not work with the

wrong prover controller chip-333 (a single detector switch), or chip-331 (dual detector switches)

If “Master Meter Proving” is configured, the master meter uses densitometer frequency (frequency input#3)

as input and it does not use prover controller chip.

Prove Request Enter the meter number to prove and then enter the prove sequence type. Single run sequence is one run

one way in uni-directional prover and round trip in bi-directional. Sequence will be a sequence of run to

achieve repeatability and meter factor.

Prover Temperature Override When there is no live prover temperature connected to the flow computer, user can enter override value to

be used in the proving calculations, or use the meter temperature.

Prover Pressure Override When there is no live prover pressure connected to the flow computer, user can enter override value to be

used in the proving calculations, or use the meter pressure.

Prover Gravity Override Prover gravity override will be used for liquid corrections for both meter and prover. Gravity override is

not used for batch correction, but only in the proving calculations.

Prover Shaft Temperature Override The shaft temperature override is used in piston type provers. The temperature for the shaft is normally the

ambient temperature.

CTL or CPL Override Enter the override value, the proving meter temperature and pressure correction will default to the override

value. Zero in the data entry indicates use calculated value.

Prove Data

PROVER REPORT NUMBER

The number that will appear in the proving report.

Prover Serial Number

The serial number of the prover that will appear in the proving report.

PROVER MODEL

The prover model that will appear in the proving report.

Prover Size

The size of the prover in inches.


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PROVER TYPE

0 = Ballistic type prover with piston action.

1 = Reduced type prover uni-directional with total pulse count less than 10,000.

2 = Reduced volume bi-directional with less than 10,000 pulses in each direction.

All the above will use the double chronometry method (pulse interpolation).

3 = Uni-directional big volume prover with pulse count over 10,000 counts

4 = Bi-directional large volume prover with pulse count in each direction exceeding 10,000 in

each direction

5 = Smith ballistic type prover with piston action.

6 = Master Meter Proving. (Master meter use densitometer frequency as input.)

PROVE RUN COUNTS

Enter prove run counts if master meter proving is configured. The flow computer will use the master meter

pulse counts to constitute one run.

DETECTOR SWITCH

Provers are always fitted with dual detector switches. Because of wiring considerations, many times both

detectors are paralleled together. Select single detector, when both detectors are paralleled together. Select

dual detector, when two isolated signals are used. Prover operation will not work with the wrong prover

controller chip.

333 chip is our most common prover controller chip. It uses a single detector switch. It is normal operation

is for Active Low switches commonly found in Piston SVPs like Calibron and Brooks. It also supports

Active High switches (sometimes called Reverse Polarity detector switch).

331 chip is generally used for Ball provers with dual detector switches like most traditional prover

controllers, one switch for start and one to stop. It also supports Active High single detector provers.

Single Detector Delay

When single detector is used. Hysteresis time is required to insure proper debounce time. 100 milliseconds

is sufficient in most cases.

DETECTOR MOUNTING

When piston type prover is selected, the detector switches distance will change with temperature. For

ballistic provers, the user must select "on calibration section mounting". Pipe provers are normally "off

calibration section mounting".

Prove Seal

When prover seal signal is not available. The option for requiring prove ready signal is waived.

NUMBER OF PROVE RUNS TO AVERAGE

Numbers 1-10 are for the consecutive runs to achieve good meter factor and pulse deviation within set

limit. After the number of prove runs to average is achieved within the pulse deviation limit, then the prove

runs will stop.


Date: 7/10/2012

Number of Total Runs

Numbers 1-20 are the total number of allowable runs to achieve repeatability. The Smart Flow Computer

will attempt to achieve consecutive runs within the repeatability limit.

UPSTREAM S IGNAL POLARITY

The upstream signal polarity signals high or low is ready to launch signal. The logic polarity of the piston

upstream can be programmed as low or high to indicate ready to launch.

RUN OUTPUT S IGNAL POLARITY

When using ballistic provers, a signal is required to start prover, or bring the piston to launch position.

Coefficient of Expansion on Displacer Shaft E-7 (Piston Prover)

This is the coefficient of thermal expansion of the prover piston shaft

mild carbon

62.0 10-7

/F 304 stainless 96.0 10

-7/F

316 stainless

88.3 10-7

/F 7–14 pH stainless

60.0 10-7

/F

Area Thermal Coefficient E-7 (Piston Prover)

This is the coefficient of expansion for prover wall

mild carbon

62.0 10-7


-7/F

316 stainless

88.3 10-7


60.0 10-7

/F

PROVER BASE TEMPERATURE

The temperature in which the prover volume was established. All steel correction factors will be based on

base temperature.

PROVER BASE PRESSURE

The prover pressure correction factors will be based on the reference calibration pressure. The modulus of

elasticity combined with the live pressure are used to calculate wall expansion due to pressure.

Pre- travel in Volume

After the second detector switch is tripped. The Smart Flow Computer allows for certain delay period

proportional to time between prover run first and second detector switch. To allow for the prove ball to

stabilize, after the time expires, the launch sequence will be re-initiated.

Prove Abort Time Out in Seconds

If the prove run was not achieved in the set time, then the prove will be aborted. The reason for this

function is to accommodate the possibility the second detector switch was not triggered for one reason or

another, or the proving was launched from the wrong direction.

PROVER VOLUME

The prover volume in barrels at reference conditions per water draw.


Date: 7/10/2012

PROVER D IAMETER

The diameter of the prover in inches.

PROVER WALL THICKNESS

The thickness of prover wall in inches. assuming single wall prover.

Modulus of Elast icity E+07

The elasticity coefficient of prover wall material.

Coefficient of Cubical Expansion E-7

mild carbon

62.0 10-7


-7/F

316 stainless

88.3 10-7


60.0 10-7

/F

PROVER TEMPERATURE SAMPLE PERIOD

The prover temperature should be stable before proving. This would indicate that the prover and the fluid

through the prover has similar temperatures. The sample period configured is a command to the Smart

Flow Computer to sample the prover temperature every so many minutes and compares the temperature to

the previous sample.

Prover Temperature Allowable Change in Deg.F

Each time the prover temperature is sampled and compared to the previous sample. The deviation should

not exceed the set limit. Once the prover temperature is stable the Smart Flow Computer will give the

command to initiate a prove.

Prover and Meter Temperature Deviat ion

This will set the limit between the meter and prover temperature. If the difference between the meter and

prover temperature is above the set limit the prove will be aborted

Flowrate Change per Sample Period

The maximum flowrate fluctuation acceptable before initiating a prove. The temperature sample checking

period is also used.

PULSE DEVIAT ION

The pulse deviation limit is for setting the repeatability of runs. The Smart Flow Computer will try to

achieve consecutive runs within the programmed limits.

Pulse Deviation %Highest of Counts Lowest of Counts

Counts

Lowest of 100


Date: 7/10/2012

METER FACTOR DEVIAT ION

To implement proved meter factor, the deviation must be within this limits.

Meter Factor Deviation %Proved Meter Factor Previous Meter Factor

Previous Meter Factor

100

IMPLEMENT METER FACTOR AUTOMATICALLY

Enter '1' to automatically implement the new meter factor. The new meter factor will apply to the current

batch and will be used for that product until next prove.

Use Meter Temperature 1=Yes

If there is no prover temperature mounted on the prover, assign the meter temperature to be used for prover

corrections.

Use Meter Pressure 1=Yes

If there is no prover pressure mounted on the prover, assign the meter pressure to be used for prover

corrections.

Prover Pressure Assignment

The Smart Flow Computer provides 4 analog inputs. In order for the Smart Flow Computer to read the live

input, the input must be properly assigned and properly wired.

PROVER PRESSURE AT 4MA

0= Not Used 3= Analog#3

1= Analog#1 4= Analog#4

2= Analog#2 5= Analog#5 (if analog #5/#6 is configured)

6= Analog#6 (if analog #5/#6 is configured)

Enter the 4mA value for the transducer.

PROVER PRESSURE AT 20MA


PROVER PRESSURE LO /H I L IMIT

Enter the low and high limits. When live value exceeds high limit or less than low limit, a alarm log will be

generated.

PROVER PRESSURE MAINTENANCE VALUE

The value to be used when the transmitter fails, or while calibrating. For calibration, set fail code to 1 while

calibrating.

PROVER PRESSURE FAIL CODE

Fail Code 0: always use the live value even if the transmitter failed.

Fail Code 1: always use the maintenance value

Fail Code 2: use maintenance value if transmitter failed. i.e. 4-20mA is above 21.75 or below

3.25)


Date: 7/10/2012

Prover Temperature Transducer 0=Single,1=Dual

Inlet or outlet temperature transmitters are accepted. Inlet is used in forward direction and outlet in the

reverse direction.

Prover Temperature Assignment

The Smart Flow Computer provides 4 analog inputs. In order for the Smart Flow Computer to read the live

input, the input must be properly assigned and properly wired.

0= Not Used 3= Analog#3 6= RTD/Analog#6

1= Analog#1 4= Analog#4

2= Analog#2 5= RTD/Analog Input #5

PROVER TEMPERATURE AT 4MA


PROVER TEMPERATURE AT 20MA


PROVER TEMPERATURE LO /H I L IMIT


generated.

PROVER TEMPERATURE MAINTENANCE VALUE


calibrating.

PROVER TEMPERATURE FAIL CODE




3.25)


Date: 7/10/2012

Prover Diagram Live run data flow diagram for the proving sequence, pulse counts valve sequencing, prover temperature

and prover pressure. meter temperature and pressure.

Previous Prove Report Up to 16 previous proves can be stored and retrieve at any time. The prove reports are not associated with

certain product files but are in chronological order.

Single Prove Report The previous single prove run report.

Prove Abort Report The previous prove abort report.


Date: 7/10/2012

METER

Set Up

METER BANK

Single or two meters run configuration per individual Smart Flow Computer. Enter '1', if two meters are

connected to the flow computer.

DUAL PULSE SECURITY

Prompted only if single meter is selected. The Smart Flow Computer allows up to two turbine pulse inputs.

Therefore dual pulse security will not allow the Smart Flow Computer to have more than one meter per

computer. The dual pulse security function will detect missing or extra pulses that occur on Channel A but

not Channel B, or vise versa. Error Pulses are detected and parity alarm is activated.

S INGLE OR DUAL STREAMS

Single stream can be single or dual meter bank. Dual streams allow independent products on each stream

simultaneously.

STATION TOTAL

Station total can add meter one and two, subtract meter one from meter two, or just ignore this feature by

selecting none.

B I-D IRECTIONAL

This feature allows a status input to give direction for meter one and two, just meter one, meter two, or the

use of the flow computer phase angle feature. The phase angle require dual pickups, therefore this feature

is only available with single meter setup only. The phase angle feature relies on high precision quadrature

decoder that gives quick and precise direction detection. Bi-directional totalizers will totalize accordingly.

COMMON PARAMETERS

This feature will allow the Flow Computer to use the transmitters on meter one to substitute and

compensate for meter two transmitters and higher range flow.

DENSITY TYPE

If live density is connected to the meter, user must enter the density type. Raw density frequency or a 4-

20mA input can be selected. This density will be used to calculate mass flow and net flow. Density

Type Densitometer

Type 0 None

Type 1 4–20 mA

Density 4–20 mA Type

Type 0 Specific Gravity 4-20mA

Type 1 API Gravity 4-20mA

Type 2 Density Signal 4-20mA in GM/CC

Type 2 UGC

Type 3 Sarasota

Type 4 Solatron

Type 5 UGC2

DENSITY 4-20MA TYPE

Note that this type of input requires the user to choose a subtype, as indicated in the table above.

USE METER TEMPERATURE AS DENSITY TEMPERATURE

To allow the meter temperature to calculate the effect of temperature on the densitometer. Make sure the

meter and density temperature are similar to avoid measurement errors.

USE METER PRESSURE AS DENSITY PRESSURE

This feature allows the user to assign the meter pressure to calculate the effect of pressure on the

densitometer. Take caution and make sure the pressure is very similar on the meter and densitometer to

avoid measurement errors.


Date: 7/10/2012

METER DATA

METER ID

Up to 8 characters. This function will serve as Meter Tag.

FLOW CUTOFF FREQUENCY

The Smart Flow Computer will quit totalizing, when frequency is below the set limit. This feature is to

reduce noise effect when the meter is down for period of time. The totalizer will stop totalizing when the

frequency is below the cut off limit.

GROSS FLOWRATE DECIMAL

Flow rate indication will carry the programmed decimal positions.

SELECT MASS PULSE (0=NO ,1=YES )

Flow rate indication will carry the programmed decimal positions.

K FACTOR

K Factor is the number of pulses per unit volume, i.e. 1000 pulses/barrel. The tag on the meter would

normally indicate the K Factor.

GROSS FLOWRATE LOW /H IGH L IMIT

The high/low flow rate alarm is activated, when gross flowrate exceeds or is below the set limit. The alarm

will be documented with time, date, and totalizer.

RETROACTIVE METER FACTOR

If zero is selected, the meter factor will not apply to the entire batch. It will only apply from the time the

new meter factor is entered. Retroactive in the other hand will apply to the entire batch and the entire batch

is re-calculated, using the new meter factor.

UNIT OF MEASUREMENT

Select desired units 0=BBL, 1=GAL,2=Litter,3=M3. User must insures that K Factor value selected is for

the designated unit of measurement. If K factor was selected as 1000, then the units of measurement must

reflect 1000 pulses per the unit volume selected.


Date: 7/10/2012

TURBINE D IAGNOS

The DFM Flow Computer is able to determine conditions of the turbine beyond 1956 level A Security

level. This is performed by detecting each blade and each revolution with 2 mhtz clock. Conditions

affecting repeatability are detected. Other conditions such as missing blades, bent blade, deteriorating

pickup coil are also detected.

NUMBER OF BLADES

Number of blades or buttons are required in order to compare the same blade to itself on each revolution.

Minimum Flowrate Threshold

Enter the minimum threshold for the beginning of the diagnostic.

Maximum Flowrate Threshold

Enter the maximum flowrate threshold for the diagnostic. It represents the maximum operating flowrate.

Revolution Error %

Revolution error represents a filter jitter in the flow profile.

Blade Error %

Blade error represents the maximum gap error in the machining of the turbine

Prof ile Error %

Profile error is the general rotational characteristic of the turbine.

Sensit ive Factor

The DFM Flow Computer updates diagnostic errors before an alarm occurs.

Diagnost ic Update

The DFM Flow Computer updates diagnostic data every one up to ten minutes.


Date: 7/10/2012

PRODUCT DATA

PRODUCT NAME

Up to 16 characters.

TABLE SELECTION

0= 5A/6A 5= 24A 10= 24C

1= 6A 6= 23B/24B 11= 6C

2= 5B/6B 7= 24B 12= API2565-Propylene

3= 6B 8= OLD23/24 13= API2565-Ethylene

4= 23A/24A 9= OLD24 14= ASTM1550-Butadiene

Table A is for Crude, the Table B is for refined products, the Table C is for special products - butadiene,

toluene. OLD Tables are used in for LPG and NGLs.

Crude oil, natural gasoline, drip gasoline JP4 use 6A,24A if density is known, and 5A/6A,23A/24A if live

densitometer is used. Gasoline, naphthalene, jet fuel, aviation fuel, kerosene, diesel, heating oil, furnace oil

use 5B/6B,23B/24B when live density is used. 6B,24B when no live density is used. Benzene, toluene,

styrene, ortho-xylene, and meta-xylene, acetone use 6C/24C.

GRAVITY /DENSITY @60

The gravity at 60 will be prompted only if the table selected, density at reference condition is known. (Even

table is selected). The gravity at 60 is used to calculate the volume correction factor.

ALPHA T E-6

The Alpha T will be prompted only if table 6C or 24C is selected. Enter Alpha T value , the number

entered will be divided by 10-6

.

Example : Entered Value 335 (Actual value 0.000335)

Product Meter Factor/Specific Gravity Enter the meter factor for each product. This will be the default value used at the beginning of each new

batch. Changing the value during the batch will not affect the meter factor for the current batch. To

change current batch meter factor, use the "Meter Factor Override" entry. Changing the meter factor in the

product meter factor file only applies the next time this product is selected.

Flowing specific gravity will determine which product is running, the specific gravity has to maintain in the

product SG range for at least 5 seconds before a product shift occurs. If batch is set to manual, the ‘Flow

Computer’ will compare specific gravity and use the product nearest specific gravity value, when end batch

command is required.

Linear Factor Enter the different correction factors for the meter for the different flow rates. The Smart Flow Computer

will perform linear interpolation. Please note that even though using this feature enhances the

measurement accuracy and rangability, performing an audit trail on a linearized meter factor is very

difficult.


Date: 7/10/2012

OTHER PARAMETERS

DAY START HOUR (0-23)

Day start hour is used for batch operation. If daily batch is selected, the batch will end at day start hour, all

batch totalizers and flow weighted values are reset.

COMPANY NAME

Up to 20 characters. The company name appears in the reports.

METER LOCATION

Up to 20 characters. Meter location will appear in the reports.

FLOW RATE SELECTION

The flow rate will be based on daily basis, hourly, or minute.

FLOW RATE AVERAGE SECOND

Flow rate averaged 1-10 is for fluctuating flow rate conditions. This number is used to perform averaging

on the current flow rate by adding it to the previous seconds flow rate, and then display an averaged

smoothed number. Only low resolution pulse meter requires this function.

Note: In case of low pulse resolution, i.e. 1 pulse/BBL, use 99. Flowrates go to zero when no pulse occurs for 40 seconds.

OLD TABLE GRAVITY UNIT

If old table 23/24 is selected, and gravity units are required in API units

D ISABLE ALARMS

When the alarm function is disabled, alarms will not be logged. Alarms are also not logged if turbine

frequency is below cut of limit.

PRINT INTERVALS IN M INUTES

When the second port of Smart Flow Computer is configured as printer port, then a snapshot report can be

printed at any minute combination. (i.e. every five minutes, every hour, or every ten hours).

GM/CC CONVERSION FACTOR

This factor is used to reference the density to density of water (i.e. .999012) to establish specific gravity.

WEIGHT OF H2O IN VAC @60 DEG .F

The weight of one barrel of water under vacuum conditions. (i.e. 350.1616 Lb/barrel)

ATMOSPHERIC PRESSURE

Local pressure or contracted atmospheric pressure. (i.e. 14.73 psi)


Date: 7/10/2012

RUN SWITCHING

Run switching is used to switch from tube one to tube two, when flow rate reaches certain limits. The

Smart Flow Computer has one active output that can be dedicated to this function. The time delay allows

for some delay in switching.

Note: if Run Switching is being used, then the meter should be configured for a single stream (see Set Up under Meter).

RUN SWITCH H IGH SET POINT

When this flow rate value is exceeded and after the delay timer expires, the switch output will activate.

This output normally opens meter run two. The Smart Flow Computer provides open collector type output

that requires external power.

RUN SWITCH LOW SET POINT

When the flow rate drops below this value and stays below it until the delay timer expires, the output

switch will be turned off to shut meter two.

PULSE OUTPUT AND PULSE OUTPUT W IDTH

Pulse Output is used to activate a sampler or external totalizer. The number selected will be pulses per unit

volume or per unit mass. If 0.1 pulse is selected, the one pulse will be given every 10 unit volumes has

passed through the meter.

Pulse Output Width is the duration, in milliseconds, of one complete pulse cycle (where each cycle is the

pulse plus a wait period, in a 50/50 ratio). For example: if POW = 500 msec, the Smart Flow Computer at

most can produce one pulse each second regardless of the pulse per unit volume selected (500 msec pulse +

500 msec wait). If POW = 10 msec the Smart Flow Computer can produce up to 50 pulses per second.

The Smart Flow Computer’s maximum pulse output is 125 pulses/sec. The Pulse Output in combination

with the Pulse Output Width should be set so that this number is not exceeded.


Date: 7/10/2012

BATCH PARAMETERS Meter | Batch Parameters

DAY START HOUR (0-23)

Day start hour is used for batch operation. If daily batch is selected, the batch will end at day start hour.

All batch totalizers and flow weighted values are reset.

BATCH TYPE 0=If daily batch selected, the batch will end at the day start hour.

1=On demand type will end the batch, when the Smart Flow Computer is requested to end the batch manually.

2=Weekly based batch type will end batch at day start hour on Monday.

3=Flow based batch type will end batch when flow drops below cut off frequency.

4=Manual batch end with automatic product selection.

5=Automatic batch end when density change to a new level and holds for 5 seconds.

To use 4 or 5, batch scheduling has to be disabled.

SELECT 0=MONDAY

Select the day of the week to end batch (0=Monday)

ENABLE BATCH SCHEDULE

If batch schedule is enabled, the Smart Flow Computer will use product schedule to determine which

product to be used in the next batch.

MONTH END BATCH 1=YES

Enter ‘1’ to end batch at the end of the month.

D ISABLE BATCH PRESET

Disable batch preset is to eliminate the warning and alarms associated with batch presets. Batch Preset does

not end batch, it will provide switch output and warning indications.

T ICKET NUMBER

This number will increment by one at the end of batch.

BATCH PRESET VOLUME

Batch Preset warns the operator the batch has reached the preset limit.

BATCH PRESET WARNING VOLUME

Batch Preset warning indicates that batch has reached the preset warning limit.

NEXT BATCH PRODUCT NUMBER

Enter the product number for the next batch.

Batch Scheduling

Up to sixteen different products can be scheduled in sequence. When the flow computer receive end batch

command, it will move the scheduled products one step up, and the product at the top of the schedule list

will be used for the batch. The batch schedule can be altered at any time.

Date and Time

The PC software will show the current date and time from the PC. Press F3 to download that date and time

to the flow computer. Press F2 to upload the date and time from the flow computer.

End Batch The batch will end if requested through this menu. The current batch totalizer and flow weighted data will

reset to zero. Non-resettable totalizers are not affected by the batch resetting.


Date: 7/10/2012

Current Batch Preset Enter the value to override the current batch preset or batch preset warning volume

Overrides:

METER FACTOR OVERRIDE

Enter Meter Factor to override the current batch meter factor. This meter factor is used only for the current

batch. If permanent modifications to the meter factor are needed, change the meter factor in the meter

factor file.

GRAVITY OVERRIDE

Enter Gravity Override to replace current gravity. The gravity override is a non-retroactive gravity and will

not override the product file gravity. It only applies to the current running batch.

BS&W OVERRIDE

Enter the BS&W override for the current batch(none retroactive).

ALPHA T E-6 OVERRIDE

Enter Alpha T Override to the batch. It will not effect the Alpha T value in the product file. Alpha T is the

thermal expansion coefficient for the selected product. The flow computer divides by 1000000.

Example : 0.000355 = 355 / 1000000

METER TEMPERATURE OVERRIDE

This value is entered when no live temperature is available, or different value from live value should be

used.

METER PRESSURE OVERRIDE

Pressure override can be used when no live pressure transmitter is connected to the Smart Flow Computer.

Security Code Several levels of security codes have been selected to fit different levels of responsibility. Up to six

alphanumeric code can be used for each entry. If the security code is not used, then there will not be any

security code prompt in the menu.


Date: 7/10/2012

INPUT/OUTPUT

Transducer Input Assignment

TEMPERATURE RESOLUTION

The resolution is used for calibrations and indication only but does not effect calculations. Maximum

resolution is 0.01ºF. Calculations use a rounded 0.1ºF.

PRESSURE RESOLUTION

The resolution is used for calibrations and display only and is not use in the calculations. Maximum

resolution is 0.1 psig.

SPARE RESOLUTION

The resolution is used for calibrations and display only.

USE RTD 5/6 FOR ANALOG INPUTS 5/6

The ‘Flow Computer’ can be configured as either ‘4 Analog and 2 RTD Inputs’ or ‘6 Analog Inputs’. (For

version SFC 3.16, PC 3.07 and higher).

Enter ‘1’ to use ‘6 Analog Inputs’.

TRANSDUCER INPUT ASSIGNMENT

The Smart Flow Computer provides 4 analog inputs, 4 status input, 5 switch outputs, one density frequency

input, two turbine inputs, and two 4 wire RTD inputs (or 2 extra analog inputs). In order for the Smart

Flow Computer to read the live input, the input must be properly assigned and properly wired.

0= Not Used 4= Analog#4 7 = Dens.Freq (Not Selectable)

1= Analog#1 5= RTD/Analog#5 10 = Multi. Variable Module #1 2= Analog#2 6= RTD/Analog#6 11 = Multi. Variable Module #2

3= Analog#3 12 = Meter#1 Micro Motion

13 = Meter#2 Micro Motion

SPARE ASSIGNMENT

Spare input is used for display and alarm purpose only. It is not used in the calculation process. To read

spare input value, use the diagnostic screen.

4MA


20MA


LO /H I L IMIT


generated.


Date: 7/10/2012

MAINTENANCE VALUE


calibrating.

FAIL CODE




3.25)

DENSITY PERIOD LOW /H IGH L IMITS

Density Period is the time period in micro-second. The densitometer fails if the density period exceeds the

density period low or high limits. If the densitometer fails and density fail code is set to 2, the maintenance

value will be used.

Transducer Tag ID Up to 8 alphanumeric ID number. The transmitters are referred to according to the TAG ID. All alarms

are labeled according to TAG ID.

Calibration

See details in chapter 1.


Date: 7/10/2012

The following PID data entries are for version sfc.3.16, pc.3.07 and higher

PID Tuning

FLOW CONTROLLER GAIN

Enter the flow controller gain. (Allowable range 0-10)

FLOW CONTROLLER RESET

Enter the flow controller reset per minutes (Allowable range 0-10)

PRESSURE CONTROLLER GAIN

Enter the pressure controller gain. (Allowable range 0-10)

PRESSURE CONTROLLER RESET

Enter the pressure controller reset per minutes (Allowable range 0-10)

PID Configuration

USE FLOW LOOP

Enter ‘1’ if flow loop is used or configured in the PID control.

FLOW LOOP MAXIMUM FLOW RATE

Enter maximum flow rate threshold for the PID. It represents the maximum operating flow rate.

FLOW SET POINT

Enter the flow rate set point.

FLOW ACTING – FORWARD OR REVERSE

Enter ‘0’ if valve closes when flow drops.

Enter ‘1’ if valve open when flow drops.

USE PRESSURE LOOP

Enter ‘1’ if pressure loop is used or configured in the PID control.

PRESSURE MAXIMUM

Enter maximum pressure threshold for the PID. It represents the maximum operating pressure.

PRESSURE SET POINT

Enter the pressure set point.

PRESSURE ACTING – FORWARD OR REVERSE

Enter ‘0’ if valve closes when pressure drops.

Enter ‘1’ if valve open when pressure drops.

PID- Operating It displays PID output percentage. Press F8 to change setups. After entering the new data, press F3 to

download new data and start PID loop. Press F10 to switch between meter 1 and meter 2.


Date: 7/10/2012

Status Input Assignment I/O | Status Input Assignment

User can select any one of status input and assign it to input point.

Assignment Comments

1 End Meter#1 Batch End the batch for Meter #1 and reset batch totalizer

2 End Meter#2 Batch End the batch for Meter #2 and reset batch totalizer

3 End Meter#1/#2 Batch End the batch for Meter#1 and #2; reset both batch totalizers

4 Alarm Acknowledge Reset the previous occurred alarms output bit

5 Flow Direction "Off"= forward and "ON"= reverse. For bi-directional meters

6 Display Freeze Set to "ON" to halt scrolling and allow for continuous monitoring

7 Display Toggle The display will scroll as the user toggle the status

8 N/A

9 Prover Ready (High) /

Upstream Polarity

10 Request Prove Meter #1

11 Request Prover Meter #2

12 Request Trial Prove Meter1

13 Request Trial Prove Meter2

14 Product ID Bit 0 Product ID Bits: Before ending batch, user can use status bits to select

next product. These bits are read immediately at batch end.

See the following table to specify a product.

15 Product ID Bit 1

16 Product ID Bit 2

17 Dialog Scroll

18

Dialog Select

To select and change some parameters without lap-top or PC.

To use dialog interface, status input select and scroll must be assigned.

Both statuses must be maintained high for 5 seconds for the SFC to

resume dialog interface.

Meter factor, gravity, and next product ID can be changed through this

function.

19

Print Request Step 1: set port 2 modbus type to 1 (printer type)

Step 2: When this status is activated, the Smart Flow Computer will

send the "Request Report" to the printer via the serial port #2.


Date: 7/10/2012

*PRODUCT ID B ITS

Product Bit 2

Product Bit 1

Product Bit 0

Product Number

0 0 1 = 1

0 1 0 = 2

0 1 1 = 3

1 0 0 = 4

1 0 1 = 5

1 1 0 = 6

1 1 1 = 7

Examples: Assign Status Input #1 5

Assign Status Input #2 14



User is using status input #1 to monitor the flow direction of a bi-directional meter, and is using the

remaining three inputs to monitor the product ID.


Date: 7/10/2012

Switch Output Assignment I/O | Switch Output Assignment

The Smart Flow Computer switch outputs are open collector type and require external D.C power.

Assignment 1-15 are for pulse output. Assignment in the "Other Parameters" menu are ON/OFF type

outputs. Switch 1 and 2 can be pulse or contact type output, switch 3,4,5 are only contact type outputs.

Pulse output/unit value entry is in other parameters assignment.

ASSIGNMENTS - PULSE OUTPUTS

Meter 1 Meter 2 Station

IV 1 6 11

ISV 2 7 12

GSV 3 8 13

NSV 4 9 14

Mass 5 10 15


Date: 7/10/2012

ASSIGNMENTS - CONTACT TYPE OUTPUTS

Meter No: 1 2 Meter-Independent Parameters

Batch Ended (5 sec) 16 19 Day Ended (5 seconds) 22

Batch Preset Warn. 17 20 Dens. Period Low 53

Batch Preset 18 21 Dens. Period High 54

Meter Down 23 26 Temperature Out of Range 55

IV Low 24 27 Gravity Out of Range 56

IV High 25 28 Active Alarms 57

Temperature Low 29 41 Occurred Alarms 58

Temperature High 30 42 Status Input #1 63

Pressure Low 31 43 Run Switch 64

Pressure High 32 44 Prove Meter 1/2 65

Density Low 33 45 Prover Launch Forward 68

Density High 34 46 Prover Launch Reverse 69

Dens.Temp Low 35 47 Prover Launch Fwd/Rev 70

Dens.Temp High 36 48 Prover in Progress 71

DP Low 37 49 Compact Prover Run 72

DP High 38 50 Prove Complete 73

BS&W Low 39 51 Prove Abort 74

BS&W High 40 52 Product Bit* 0 75

Direction – Forward 59 61 Product Bit* 1 76

Direction – Reverse 60 62 Product Bit* 2 77

Prove Meter 66 67 Remote Control 78

Watch Dog 79

Turbine #1 Failed 80

Turbine #2 Failed 81

*PRODUCT ID B ITS

Product Bit 2

Product Bit 1

Product Bit 0

Product Number

0 0 1 = 1

0 1 0 = 2

0 1 1 = 3

1 0 0 = 4

1 0 1 = 5

1 1 0 = 6

1 1 1 = 7


Date: 7/10/2012

Analog Output Assignment 4-20mA selection must be proportional and within the range of the selected parameter. The 4-20mA signal

is 12 bits.

ASSIGNMENTS :

Meter 1 Meter 2 Station

IV 1 6 11

ISV 2 7 12

GSV 3 8 13

NSV 4 9 14

Mass 5 10 15

Meter 1 Meter2 Meter-Independent Parameters

Temperature 16 22 Spare #1 36

Pressure 17 23 Spare #2 37

Density 18 24 Remote Control* 38

Density Temp 19 25 Meter #1 PID 39

Density Pressure 20 26 Meter #2 PID 40

BS&W 21 27

API 28 32

API @60°F 29 33

Specific Gravity 30 34

Spec. Gravity@60°F 31 35

*Note: Remote control output can be controlled through the modbus

communication link.


Date: 7/10/2012

Flow Computer Display Assignment Display assignment select up to 17 assignments. The Smart Flow Computer will scroll through them at the

assigned delay time. Active alarm will automatically prompt on the screen if alarm conditions exists. To

read active alarms, use the diagnostic screen.

Assignment

4 Digit Selection, where 1

st Digit: 0: Forward 1: Reverse

2nd

Digit: 1: Meter#1 2: Meter#2 3: Station 3

rd and 4

th Digit: Selection (see table below)

Flowrate Batch Total Cumulative Total

Previous Daily

Previous Batch

IV 01 06 11 16 21

ISV 02 07 12 17 22

GSV 03 08 13 18 23

NSV 04 09 14 19 24

Mass 05 10 15 20 25

OTHER ASSIGNMENTS

BS&W 46 Specific Gravity 52

Temperature 47 Specific Gravity @60°F 53

Pressure 48 API 54

Density 49 API @60°F 55

Density Temperature 50 Spare #1/#2 60

Density Pressure 51 Time/Date 73

Density Period 56 Alarms 74

Uncorrected Density 57 Prover Mode 76

Density Frequency 58 Prover Temperature 77

Product 59 Prover Pressure 78

Examples:

0116 Display Meter #1 Forward Previous Daily IV Total

0106 Display Meter #1 Forward Batch IV Total

1106 Display Meter #1 Reverse Batch IV Total

1210 Display Meter #2 Reverse Batch Mass Total

0147 Display Meter #1 Temperature

0248 Display Meter #2 Pressure


Date: 7/10/2012

Modbus Shift Reassigns Modbus address registers on one Smart Flow Computer to variables for easy polling and

convenience. Use Modbus Shift to collect values in scattered Modbus registers into a consecutive order.

The Smart Flow Computer will repeat the assigned variables into the selected locations.

Note: some Modbus registers are 2 byte/16 bit, and some are 4 byte/32 bit. Register size incompatibility

could cause rejection to certain address assignments. Refer to the manual for more details and a listing of

the Modbus Address Table Registers.

Example: you want to read the current status of switches #1 and #2 (addresses 2617 and 2618) and the

Forward and Reverse Daily Gross Total for Meter #1 ( addresses 3173 and 3189). Make assignments such

as:

3082=2617

3083=2618

3819=3173

3821=3189


Date: 7/10/2012

REPORTS

Current Data - Snapshot Totalizer Updates This report consists of two sections. The upper section is primarily the non-changing parameters, the

bottom section is the dynamic. Press any key to move from one section of the report to the other. Press

<F8> to pause, then press <F5> to print, or enter the file name and press <F6> to capture the snapshot data.

Previous Batch Data Up to 50 previous batches are stored in the Smart Flow Computer. Select number of previous batches to be

displayed, printed, or captured.

Previous Hourly Data Up to 50 previous hourly data are stored in the Flow Computer. Enter starting hour and date, the Smart

Flow Computer will go backward from that selected time and date. Current hour cannot be selected. Press

<F4> to display, then press <F5> to print, or enter the file name and press <F6> to capture the Previous

Hourly Report.

Previous Daily Data Enter start date, and the Smart Flow Computer will move backward from the entered data and time. Up to

50 previous daily reports can be retrieved. Current day data cannot be retrieved. Press <F4> to display,

press <F5> to print, or enter the file name and press <F6> to capture the previous daily report.

Previous Alarm Data Up to 100 previous alarm data can be retrieved. Starting from the most recent to the oldest. Press <F4> to

display, press <F5> to print, or enter the file name and press <F6> to capture the previous alarm

report.


Date: 7/10/2012

Audit Trail Report The audit trail report shows changed configuration parameters that could influence the calculated numbers.

The Smart Flow Computer provides up to 100 event logs (100 pairs of new and old parameters; some zero

parameters cannot be logged). One purpose for audit trail is to backtrack calculation errors that result from

mistakes by the operator of the flow computer. Press <F4> to display, press <F5> to print, or enter the file

name and press <F6> to capture the "Audit Trail Report".

Build User Report One screen can be built or edited with this menu. Any text can be used. Modbus register must follow the

"^" sign in order for the program to retrieve the address location.

View User Report To monitor the "build user report". user reports can be printed through the PC parallel port.

Formatted Ticket Report The Smart Flow Computer allow the user to make personal ticket report. This ticket report is just for

display and printing purposes. To make this report, user must use "Last Daily Data Area" in the Modbus

registers (3431-3703).

Example: DYNAMIC FLUID BATCH REPORT

METER 1 PRODUCT SELECTION ^3437

METER 1 MASS TOTAL ^3449

Results - The report will look as follows: DYNAMIC FLUID BATCH REPORT

METER 1 PRODUCT SELECTION 3

METER 1 MASS TOTAL 34563. 2

Ticket Report

Select: 0=Standard Report

1=Format Batch Report Standard is the default batch report format that is programmed in the Smart Flow Computer. Format is

according to the formatted batch report. The Smart Flow Computer allows the user to re-calculate any of

the previous 50 batches. The recalculation does not alter the stored data in the Smart Flow Computer. It is

only for printing purposes.

Capture Fi le Name

Capture that file under specified name.

Override values

If the values are left unchanged, the Smart Flow Computer will use the values stored in the historical bank.

Otherwise, it will use the values entered. (Any number other than -99.99).

Auto Data Retrieval This function is made to replace printers and use a PC to poll the configured units on time basis (Hourly or

Daily). All parameters polled will be stored in the configured file name. Each unit ID will have an

individual file name. The PC or laptop must be on at the time it has to get the data, and the user must

activate that function by pressing <F3> and leaving the PC on. The data format can be either standard or

user defined format. This function is to eliminate the need for paper and make the process more

environmentally friendly. Echo to the local printer can be enabled where reports will be stored on hard

drive and printed to a parallel printer.


Date: 7/10/2012

WIRING

See the wiring diagrams in the Wiring section of Chapter 1, “Quick Start”.

To print wiring diagram, you have to run your Smart Flow

Computer software in Windows, then copy the entire screen onto

the Clipboard.

1. Type win and press <ENTER> (run window).

2. Point to MDOS Prompt and click.

3. Type "A:", and press <ENTER>.

4. Type "SFC332” and press <ENTER>.

5. Use arrow keys to move to Wiring and then to

the desired diagram.

6. Press <ALT>+ <ENTER>, then press <ALT>

+SPACEBAR to open Control menu for the

application.

7. From the Control menu, choose Edit, and then

choose Mark. A flashing rectangular cursor

appears at the upper left corner of the window.

8. Move the cursor to the first character you want to

select.

9. Mark the information you want to copy, and press <ENTER> to transfer the selected

information onto the Clipboard.

10. Start an application (Microsoft Word), Place the insertion point at the place you want

the information from the Clipboard to appear. From the application's Edit menu,

choose Paste.


Date: 7/10/2012

PRINT

Print "Help" File Turn on parallel printer, point the cursor to Help, press <ENTER>, and then

press < to print Help file.

Print Modbus Registers Turn on parallel printer, point the cursor to Modbus Reg, press <ENTER>,

and then press <F5> to print Modbus registers.

Print Schematic Turn on parallel printer, point the cursor to the Schematic, press <ENTER>, and then press <F5> to

print schematic (Terminal Board Wiring only).

Print Calibration Data Calibration data are programmed parameters in the data file. To print, turn on parallel printer, point the

cursor to the Calib.Data, press <ENTER>, and then press <F5>.

Print Files

The user can print the files that were captured. Turn on parallel printer, point the cursor to the desired file,

and then press <ENTER>.


Date: 7/10/2012

CHAPTER 3: Flow Equations

FLOWRATES

Mass Flowrate (MASS) Mass flow rate is calculated differently depending on whether live density data is or is not available. Both

equations give results in Lb/Hr.

10001

100099901201

WaterWeight of SG-BSW)%(LMFCPLCTL IV

WaterWeight of

.

Density-BSW)%(LMF IV

MASS

:density live No

MASS

:applied is density live If

eraturerence tempty at refe API Graviwhere API

temp. reference atdensity Product .API

f Water Density o .

temp. reference at expansion of Correction K K

T - T

) (liquid on effect etemperaturfor Correction

FactorMeter Factor ionLinearizat MF LF

:Where

T

T

TT

ReferenceActualT

TTTTe

5131

5141

ASTM D1250

))8.0(1(-

210

CTL

LMF

)%1(

3600

BSWLMFCPLCTLIV

LMFCPLCTLIV

CPLCTLIV

L)(Pulses/BBFactor K Nominal

es/sec)Total(Puls

(BBL/Hr)NSV - VolumeStandard Net

(BBL/Hr)GSV - VolumeStandard Gross

(BBL/Hr)ISV - VolumeStandard Indicated

(BBL/Hr)IV - VolumeIndicated


Date: 7/10/2012

Pe is calculated from the equations developed by Dr.R.W. Hankinson and published as

GPA Technical Publication No.15, unless the override value is being used.

Temperature Range: -50 F to 140 F.

Relative Density Range: 0.49 to 0.676 For F:

Use API Chapter 11.2.1 for liquids 0-90 API

Use API Chapter 11.2.2 for Hydrocarbons

Temperature Range: -50 F to 140 F

Relative Density: 0.350-0.637 K0 and K1 in the above equations are physical constants from the API Manual and are given in the table

below for various product types. However, for products between the jet group and gasoline use constants A

and B in the following equation:

Table Product

Type API

Gravity Relative Density

K0 K1

6A,23A Crude Oil 0-100 .6110 to 1.0760 341.0957 0.0

6B,23B Fuel Oil 0-137 .5270 to 1.0760 103.8720 0.2701

6B,23B Jet Group 37.1-47.9 .7890 to .8395 330.3010 0.0

6B,23B Gasoline 52.1-85 .6535 to .7705 192.4571 0.2438

6B,23B Between Jet and Gasoline

48-52 .7710 to .7885 A =

-0.00186840

B =

1489.0670

factorility Compressib F

pressure mEquilibriu P

PSIG in pressure Flowing P

liquid onility compressibfor Correction ) -F(P-P

e

e

1

1CPL

2T

TB

A


Date: 7/10/2012

PROVE EQUATION

Note:

Additional Information refer to “API Chapter 4 and Chapter 12” that describe full terms and rules for meter

proving.

Volume MeterCorrected

Volume Prover Corrected

CPLMCTLMVolume Meter

Factor K

Counts Total

CTLPCPLPCPSPCTSPBPV

TDVOL

BPV

BBLPulses

c)(Pulses/se Total

FactorMeter Prove

VolumeMeter Corrected

VolumeMeter

VolumeProver Corrected

3600

3600/

:Flowrate IV Prove

:Prover Compact

:ProverPipe

provea duringprover at Pressure Avg. P whenCPL

PressureMeter of effect thefor CorrectionCPLM

provea duringmeter at Temp. Avg.T whenCTL

eTemperaturMeter ofFactor Correction VolumeCTLM

provea duringprover at Pressure Avg. P whenCPL

PressureProver of effect thefor CorrectionCPLP

provea duringprover at Temp. Avg.T whenCTL

eTemperaturProver of effect thefor CorrectionCTLP

PSIG 0 and F60 @ VolumeProver BaseBPV

Where

Actual

Actual

:


Date: 7/10/2012

shaft.displacer on expansion of tcoefficien thermalLinear G

chamber.prover for expansion of tcoefficien thermalArea G

etemperatur Base T

chamberprover of eTemperatur T

TTGCTSP

:Prover Pipe

)T(TG)T(TG CTSP

ON - SectionnCalibratio MountingDetector :Prover Compact

TTGCTSP

OFF - SectionnCalibratio MountingDetector :Prover Compact

etemperatur of effect thefor Correction

l

a

b

p

bpa

bplbpa

bpa

)(1

]1[]1[

)(1

CTSP

prover of thickness Wall WT

materialprover for elasticity of Modulus E

prover ofdiameter Internal ID

Pressure Base P

prover of pressure operating Internal P

WT E

P ID CPSP :Prover Pipe

WT E

)P - (P ID CPSP :Prover Compact

pressure of effect thefor Correction

b

b

1

1

CPSP


Date: 7/10/2012

DENSITY EQUATIONS

Sarasota Density GM/CC Sarasota density is calculated using the frequency signal produced by a Sarasota densitometer, and applying

temperature and pressure corrections as shown below

PSIG in pressure nCalibratio P

ds/PSIGmicrosecon in tcoefficien Pressure P


Fds/microsecon in tcoefficien eTemperatur T

dsmicrosecon in constant nCalibratio T

F e,temperatur Flowing T

ds.microsecon in period noscillatioer densitomet The t

(GM/CC) emass/volum constant, nCalibratio A D

Factor CorrectionDensity DCF

T )P - (P P )T - (T T T

:Where

T

) K(t-T

T

)(t-TD DCF

cal

coef

coef

0

0

0calcoefcalcoef 0p

p

p

p

p

0

0

0

00

2

12Density Corrected


Date: 7/10/2012

UGC Density GM/CC UGC density is calculated using the frequency signal produced by a UGC densitometer, and applying


Fds/microsecon in tcoefficien eTemperatur T


tCoefficien eTemperatur K

Offset Pressure P

Constant Pressure K



ds.microsecon in period noscillatioer densitomet The t

Constants nCalibratio K ,K ,K

: Where

t Kt K Kd

d]) T-TK d) [K(P P DCF

cal

t

0

210

cal(t -

2210

60 10 Density Corrected


Date: 7/10/2012

UGC Density 2 GM/CC UGC density is calculated using the frequency signal produced by a UGC densitometer, and applying


Constant Pressure KP2

Constant Pressure KP1


nCalibratio eTemperatur T

Constant eTemperatur KT2

Constant eTemperatur T1 K



ds.microsecon in period noscillatio erdensitomet The t

Constants nCalibratio K ,K ,K

: Where

txtKK Kd

dxKPKP Px) dx KTKT TcT dDCF

C

210

]*)21[(0

)]21(21()([Density Corrected


Date: 7/10/2012

Solartron Density GM/CC Solartron density is calculated using the frequency signal produced by a Solartron densitometer, and

applying temperature and pressure corrections as shown below.

Density at 68°F and 0 PSIG

Temperature Corrected Density

Temperature and Pressure Corrected Density

Additional Equation for Velocity of Sound Effects The following equation can provide more accurate measurement for LPG products in the density range of

0.300 D 0.550 (D is in gm/cc).

onby Solartr SuppliedConstants nCalibratio K,K,K

dsmicrosecon in Period nOscillatioer Densitomet t Where

t Kt KKD

210

2210

Fre in TemperatuWhere T

)(T- K )(T-K DDT

68]681[ 1918

nby Solarto SuppliedConstants nCalibratio , K K, KK

PKKK

PK KK

PSIG in Pressure P

:Where

P KP) K DL(DP

BABA

BA

BA

2121,2020

212121

202020

21201

range. this outside K Let

KDPKDPD

r

jrvos

0.0

)( 3


Date: 7/10/2012

Propylene Density Density at flowing Temperature and pressure is calculated using API Chapter 11.3.3.2 (API 2565)

Temperature Range 20–165 F

Pressure Range Saturation–1600 PSIA

Ethylene Density Ethylene density is calculated using API Chapter 11.3.3.2

Temperature Range 65–167 F

Pressure Range 200–2100 PSIA

Dynamic Flow Computers SFC332 Liquid Pulse Manual Modbus Data — 4-1

Date: 7/10/2012

CHAPTER 4: MODBUS DATA

MODBUS PROTOCOL

TRANSMISSION MODE

ASCII RTU

DATA BITS 7 8

START BITS 1 1

PARITY EVEN, ODD NONE

STOP BITS 1 1

ERROR CHECKING LRC CRC

BAUD RATE 1200-9600 1200-9600

ASCII FRAMING Framing is accomplished by using colon (:) character indicating the beginning of frame and carriage (CR),

line feed (LF) for the end of frame

ASCII MESSAGE FORMAT ADDRESS FUNCTION DATA ERR\CHECK

: 2 CHAR 2 CHAR Nx2 CHAR 2 CHAR CR LF

8 BITS 16 BITS 16 BITS Nx16 BITS 16 BITS 8 BITS 8 BITS

RTU FRAMING Frame synchronization is done by time basis only. The Smart Flow Computer allows 3.5 characters time

without new characters coming in before proceeding to process the message and resetting the buffer.

RTU MESSAGE FORMAT ADDRESS FUNCTION DATA CRC

8 BITS 8 BITS Nx8 BITS 16 BITS


Date: 7/10/2012

FUNCTION CODE To inform the slave device of what function to perform

FUNCTION CODE

ACTION

01

03 Read Strings or Multiple 16 Bits

16 Write Strings or Multiple 16 Bits

ERROR CHECK

LRC MODE

The LRC check is transmitted as two ASCII hexadecimal characters. First, the message has to be stripped

of the: LF, CR, and then converted the HEX ASCII to Binary. Add the Binary bits and then two's

complement the result.

CRC MODE

The entire message is considered in the CRC mode. Most significant bit is transmitted first. The message is

pre-multiplied by 16. The integer quotient digits are ignored and the 16-bit remainder is appended to the

message as the two CRC check bytes. The resulting message including the CRC, when divided by the

same polynomial (X16+X15+X2+1) at the receiver, which will give zero remainder if no error, has

occurred.

EXCEPTION RESPONSE Exception response comes from the slave if it finds errors in communication. The slave responds to the

master echoing the slave address, function code (with high bit set), exception code and error check. To

indicate that the response is notification of an error, the high order bit of the function code is set to 1.

EXCEPTION CODE DESCRIPTION

01 Illegal Function

02 Illegal Data Address

03 Illegal Data Value

BROADCAST COMMAND All units listen to Unit ID Zero, and no one will respond when the write function is broadcasted.


Date: 7/10/2012

MODBUS EXAMPLES

FUNCTION CODE 03 (Read Single or Multiple Register Points)

RTU MODE - READ ADDRESS 3076

ADDR FUNC CODE

STARTING POINT # OF POINTS CRC CHECK

HI LO HI LO

01 03 0C 04 00 01 C6 9B

RESPONSE

ADDR FUNC CODE

BYTE COUNTS

DATA CRC CHECK

HI LO

01 03 02 00 01 79 84

Write Address 3076

ADDR FUNC CODE

START POINT

# OF POINTS

BYTE COUNTS

DATA CRC CHECK

HI LO HI LO HI LO

01 10 0C 04 00 01 02 00 01 AA 14

Response

ADDR FUNC CODE

START ADDR

# OF POINTS

CRC CHECK

C 10 0C 04 01 43 58

ASCII MODE - READ ADDRESS 3076

ADDR FUNC CODE

STARTING POINT # OF POINTS LRC CHECK

HI LO HI LO

: 30 31 30 33 30 43 30 43 30 30 30 31 45 42 CR LF

RESPONSE

ADDR FUNC CODE

BYTE COUNT

DATA LRC CHECK

HI LO

: 30 31 30 33 30 32 30 30 30 31 46 39 CR LF

Dynamic Flow Computers SFC332 Liquid Pulse Manual Modbus Data – 4-4

MODBUS ADDRESS TABLE – 16 BITS ADDRESS DESCRIPTION DECIMAL READ/WRITE

Date: 7/10/2012

2534 FC Display Delay (1-4) 0 Inferred Read/Write 2535 FC Assignment #1 0 Inferred Read/Write 2536 FC Assignment #2 0 Inferred Read/Write 2537 FC Assignment #3 0 Inferred Read/Write 2538 FC Assignment #4 0 Inferred Read/Write 2539 FC Assignment #5 0 Inferred Read/Write 2540 FC Assignment #6 0 Inferred Read/Write 2541 FC Assignment #7 0 Inferred Read/Write 2542 FC Assignment #8 0 Inferred Read/Write 2543 FC Assignment #9 0 Inferred Read/Write 2544 FC Assignment #10 0 Inferred Read/Write 2545 FC Assignment #11 0 Inferred Read/Write 2546 FC Assignment #12 0 Inferred Read/Write 2547 FC Assignment #13 0 Inferred Read/Write 2548 FC Assignment #14 0 Inferred Read/Write 2549 FC Assignment #15 0 Inferred Read/Write 2550 FC Assignment #16 0 Inferred Read/Write 2551 FC ID 0 Inferred Read/Write 2552 reserved 2553 Port 1 Modbus Type (0=RTU,1=ASCII) 0 Inferred Read/Write 2554 Port 1 Parity(0=None,1=Odd,2=Even) 0 Inferred Read/Write 2555 Port 1 Baud Rate(0=1200,1=2400,3=4800,4=9600) 2556 reserved 2557 Port 1 RTS Delay in Milliseconds 0 Inferred Read/Write 2558-2559 reserved 2560 Port 2 Type (0=Modbus, 1=Printer) 0 Inferred Read/Write 2561 Port 2 Modbus Type (0=RTU,1=ASCII) 0 Inferred Read/Write 2562 Port 2 Parity(0=None,1=Odd,2=Even) 0 Inferred Read/Write 2563 Port 2 Baud Rate(0=1200,1=2400,3=4800,4=9600) 2564 Printer Baudrate(0=1200,1=2400,3=4800,4-9600) 2565 Port 2 RTS Delay 0 Inferred Read/Write 2566 Port 2 Number of Nulls 0 Inferred Read/Write 2567 Port 2 Printer Priority 0 Inferred Read/Write 2568 Flow Direction Selection 0 Inferred Read/Write 2569 Meter Bank 0=One Meter,1=Two Meters 0 Inferred Read/Write 2570 Dual Pulse Security 0=No,1=Yes 0 Inferred Read/Write 2571 Select 0=Single, 1=Dual Streams 0 Inferred Read/Write 2572 Station Total 0=None,1=Add,2=Sub 0 Inferred Read/Write 2573 Common BS&W 1=Yes 0 Inferred Read/Write 2574 Common Temperature 1=Yes 0 Inferred Read/Write 2575 Common Pressure 1=Yes 0 Inferred Read/Write 2576 Density#1 0=None,1=4-20mA,2=S,3=U,3=S 0 Inferred Read/Write 2577 Density#1 4-20mA 0=SG,1=API,2=Density 0 Inferred Read/Write 2578 Use Meter Temp as Dens.Temp#1 0=N,1=Y 0 Inferred Read/Write 2579 Use Meter Pres as Dens.Pres#1 0=N,1=Y 0 Inferred Read/Write 2580 Common Density 1=Yes 0 Inferred Read/Write 2581 Density#2 0=None,1=4-20mA,2=S,3=U,3=S 0 Inferred Read/Write



Date: 7/10/2012

2582 Density#2 4-20mA 0=SG,1=API,2=Density 0 Inferred Read/Write 2583 Use Meter Temp#2 as Dens.Temp 1=Yes 0 Inferred Read/Write 2584 Use Meter Press#2 as Dens.Press 1=Yes 0 Inferred Read/Write 2585-2589 Reserved 2590 Meter #1 Select Mass Pulses(1=Yes) 0 Inferred Read/Write 2591 Meter #2 Select Mass Pulses(1=Yes) 0 Inferred Read/Write 2592 Select 0=Monday,1=Tu.,2=W.. 0 Inferred Read/Write 2593 Month End Batch(1=Yes) 0 Inferred Read/Write 2594 Gravity Unit 0 Inferred Read/Write 2595 Day Start Hour (0-23) 0 Inferred Read/Write 2596-2605 Company Name 40 Chars Read/Write 2606 Disable Alarms ? (0=No, 1=Yes) 0 Inferred Read/Write 2607 Print Interval in Minutes (0-1440) 0 Inferred Read/Write 2608 Run Switch Delay 0 Inferred Read/Write 2609 Pulse Width 0 Inferred Read/Write 2610 Batch Type (0-5) 0 Inferred Read/Write 2611 Disable Batch Preset (0=No,1=Yes) 0 Inferred Read/Write 2612 Meter #1 Next Batch Product ID 0 Inferred Read/Write 2613 Meter #2 Next Batch Product ID 0 Inferred Read/Write 2614 Enable Batch Schedule(1=Yes) 0 Inferred Read/Write 2615 Status Input #1 Status (0=OFF,1=ON) 0 Inferred Read 2616 Status Input #2 Status (0=OFF,1=ON) 0 Inferred Read 2617 Status Input #3 Status (0=OFF,1=ON) 0 Inferred Read 2618 Status Input #4 Status (0=OFF,1=ON) 0 Inferred Read 2619 Switch Output #1 (0=OFF,1=ON) 0 Inferred Read/Write 2620 Switch Output #2 (0=OFF,1=ON) 0 Inferred Read/Write 2621 Switch Output #3 (0=OFF,1=ON) 0 Inferred Read/Write 2622 Switch Output #4 (0=OFF,1=ON) 0 Inferred Read/Write 2623 Switch Output #5 (0=OFF,1=ON) 0 Inferred Read/Write 2624-2633 Meter Location 40 Chars. Read/Write 2634-2637 Meter #1 ID 8 Chars. Read/Write 2638 Meter #1 Flow Cut Off Freq. (0-99) 0 Inferred Read/Write 2639 Meter#1 0,1,2 Inferred* 0,1,2 0 Inferred Read/Write 2640 Meter#1 Retroactive M.F 0 Inferred Read/Write 2641 Meter#1 Volume Units 0=BBL, 1=GAL 0 Inferred Read/Write 2642-2645 Meter #2 ID 2646 Meter #2 Flow Cut Off Freq. (0-99) 0 Inferred Read/Write 2647 Meter#2 0,1,2 Inferred* 0,1,2 0 Inferred Read/Write 2648 Meter#2 Retroactive M.F 0 Inferred Read/Write 2649 Meter#2 Volume Units 0=BBL, 1=GAL 0 Inferred Read/Write 2650-2657 Product #1 Name 16 Chars. Read/Write 2658 Product #1 API Table Select 0 Inferred Read/Write 2659-2666 Product #2 Name 16 Chars. Read/Write 2667 Product #2 API Table Select 0 Inferred Read/Write 2668-2675 Product #3 Name 16 Chars. Read/Write 2676 Product #3 API Table Select 0 Inferred Read/Write 2677-2684 Product #4 Name 16 Chars. Read/Write 2685 Product #4 API Table Select 0 Inferred Read/Write 2686-2693 Product #5 Name 16 Chars Read/Write



Date: 7/10/2012

2694 Product #5 API Table Select 0 Inferred Read/Write 2695-2702 Product #6 Name 16 Chars. Read/Write 2703 Product #6 API Table Select 0 Inferred Read/Write 2704-2711 Product #7 Name 16 Chars. Read/Write 2712 Product #7 API Table Select 0 Inferred Read/Write 2713-2720 Product #8 Name 16 Chars. Read/Write 2721 Product #8 API Table Select 0 Inferred Read/Write 2722-2729 Product #9 Name 16 Chars. Read/Write 2730 Product #9 API Table Select 0 Inferred Read/Write 2731-2738 Product 10 Name 16 Chars. Read/Write 2739 Product 10 API Table Select 0 Inferred Read/Write 2740-2747 Product 11 Name 16 Chars. Read/Write 2748 Product 11 API Table Select 0 Inferred Read/Write 2749-2756 Product 12 Name 16 Chars. Read/Write 2757 Product 12 API Table Select 0 Inferred Read/Write 2758-2765 Product 13 Name 16 Chars. Read/Write 2766 Product 13 API Table Select 0 Inferred Read/Write 2767-2774 Product 14 Name 16 Chars. Read/Write 2775 Product 14 API Table Select 0 Inferred Read/Write 2776-2783 Product 15 Name 16 Chars. Read/Write 2784 Product 15 API Table Select 0 Inferred Read/Write 2785-2792 Product 16 Name 16 Chars. Read/Write 2793 Product 16 API Table Select 0 Inferred Read/Write 2794 Temperature Resolution 0 Inferred Read/Write 2795 Pressure Resolution 0 Inferred Read/Write 2796 Spare 1 Resolution 0 Inferred Read/Write 2797 Spare 1 Resolution 0 Inferred Read/Write 2798 Meter #1 BS&W Assignment 0 Inferred Read/Write 2799 Meter #1 Temperature Assignment 0 Inferred Read/Write 2800 Meter #1 Pressure Assignment 0 Inferred Read/Write 2801 Meter #1 Density Assignment 0 Inferred Read/Write 2802 Meter #1 Density Temp. Assignment 0 Inferred Read/Write 2803 Meter #1 Density Press. Assignment 0 Inferred Read/Write 2804 Meter #2 BS&W Assignment 0 Inferred Read/Write 2805 Meter #2 Temperature Assignment 0 Inferred Read/Write 2806 Meter #2 Pressure Assignment 0 Inferred Read/Write 2807 Meter #2 Density Assignment 0 Inferred Read/Write 2808 Meter #2 Density Temp. Assignment 0 Inferred Read/Write 2809 Meter #2 Density Press. Assignment 0 Inferred Read/Write 2810 Spare #1 Assignment 0 Inferred Read/Write 2811 Spare #2 Assignment 0 Inferred Read/Write 2812 Meter #1 BS&W Fail Code 0 Inferred Read/Write 2813 Meter #1 Temperature Fail Code 0 Inferred Read/Write 2814 Meter #1 Pressure Fail Code 0 Inferred Read/Write 2815 Meter #1 Density/Gravity Fail Code 0 Inferred Read/Write 2816 Meter #1 Density Temp Fail Code 0 Inferred Read/Write 2817 Meter #1 Density Pressure Fail Code 0 Inferred Read/Write 2818 Meter #2 BS&W Fail Code 0 Inferred Read/Write 2819 Meter #2 Temperature Fail Code 0 Inferred Read/Write



Date: 7/10/2012

2820 Meter #2 Pressure Fail Code 0 Inferred Read/Write 2821 Meter #2 Density/Gravity Fail Code 0 Inferred Read/Write 2822 Meter #2 Density Temp Fail Code 0 Inferred Read/Write 2823 Meter #2 Density Pressure Fail Code 0 Inferred Read/Write 2824 Spare #1 Failure Code 0 Inferred Read/Write 2825 Spare #2 Failure Code 0 Inferred Read/Write 2826 Switch Output #1 Assign 0 Inferred Read/Write 2827 Switch Output #2 Assign 0 Inferred Read/Write 2828 Status Input #1 Assign 0 Inferred Read/Write 2829 Analog Output #1 Assign 0 Inferred Read/Write 2830 Analog Output #2 Assign 0 Inferred Read/Write 2831 Flowrate Display (0=HR,1=Min,2=DAY) 0 Inferred Read/Write 2832 Flow Average Second (1-10) 0 Inferred Read/Write 2833 Prover Pressure Failure Code 0 Inferred Read/Write 2834 Prover Temperature Failure Code 0 Inferred Read/Write 2835 Prover Left Temperature Failure Code 0 Inferred Read/Write 2836 Prover Right Temperature Failure Code 0 Inferred Read/Write 2837 Prover Transducer Type (0=Single,1=Dual) 0 Inferred Read/Write 2838 Prover Seal 0 Inferred Read/Write 2839 Prover Piston Signal 0 Inferred Read/Write 2840 Use Meter Press as Prover Press (1=Yes) 0 Inferred Read/Write 2841-2844 Analog Input #1 TAG ID 8 Char. Read/Write 2845-2848 Analog Input #2 TAG ID 8 Char. Read/Write 2849-2852 Analog Input #3 TAG ID 8 Char. Read/Write 2853-2856 Analog Input #4 TAG ID 8 Char. Read/Write 2857-2860 RTD #1 TAG ID 8 Char. Read/Write 2861-2864 RTD #2 TAG ID 8 Char Read/Write 2865-2868 Densitometer TAG ID 8 Char Read/Write 2869-2872 Analog Output #1 TAG ID 8 Char Read/Write 2873-2876 Analog Output #2 TAG ID 8 Char Read/Write 2877 Prover Single Detect Delay 0 Inerred Read/Write 2878 Prover Detector Mount Type 0 Inferred Read/Write 2879 Prover Detector Switch Type 0 Inferred Read/Write 2880 Prover Type 0 Inferred Read/Write 2881 Number of Average Prove Run 0 Inferred Read/Write 2882 Number of Total Prove Run 0 Inferred Read/Write 2883 Signal Polarity 0 Inferred Read/Write 2884 Prover Temperature Sample Periiod 0 Inferred Read/Write 2886 Use Meter Temp as Prover Temp (1=Yes) 0 Inferred Read/Write 2887 Prover Abort Time Period 0 Inferred Read/Write 2888 Prover Pressure Assignment 0 Inferred Read/Write 2889 Prover Temperature Assignment 0 Inferred Read/Write 2890 Prover Left Temperature Assignment 0 Inferred Read/Write 2891 Prover Right Temperature Assignment 0 Inferred Read/Write 2892 Change Meter Factor Automatically 0 Inferred Read/Write 2893-2896 Prover Serial Number Char Read/Write 2897-2900 Prover Model Char Read/Write



Date: 7/10/2012

2901-2916 Meter #1 Batch Schedule 0 Inferred Read/Write 2917-2932 Meter #2 Batch Schedule 0 Inferred Read/Write 2933 Switch Output #1 Assign 0 Inferred Read/Write 2934 Switch Output #2 Assign 0 Inferred Read/Write 2935 Switch Output #3 Assign 0 Inferred Read/Write 2936 Switch Output #4 Assign 0 Inferred Read/Write 2937 Switch Output #5 Assign 0 Inferred Read/Write 2938 Status Input #1 Assign 0 Inferred Read/Write 2939 Status Input #2 Assign 0 Inferred Read/Write 2940 Status Input #3 Assign 0 Inferred Read/Write 2941 Status Input #4 Assign 0 Inferred Read/Write 2942-2946 Weight of H2O 9 Chars Read/Write 2947 Reset Meter #1 Profile 0 Inferred Read/Write 2948 Reset Meter #2 Profile 0 Inferred Read/Write 2949 Meter#1 Turbine Diagnose 0 Inferred Read/Write 2950 Meter#1 Turbine Diagnose-No.of Blades 0 Inferred Read/Write 2951 Meter#1 Turbine Diagnose-Updates 0 Inferred Read/Write 2952-2960 Reserved 2961-2964 Multivar#1 SpareTag ID 8 Chars. Read/Write 2965-2968 Multivar#1 Pressure Tag ID 8 Chars. Read/Write 2969-2972 Multivar#1 Temperature Tag ID 8 Chars. Read/Write 2973-2976 Multivar#2 SpareTag ID 8 Chars. Read/Write 2977-2980 Multivar#2 Pressure Tag ID 8 Chars. Read/Write 2981-2984 Multivar#2 Temperature Tag ID 8 Chars. Read/Write 2985 Rserved 2986 Prover Shaft Temperature Fail Code 0 Inferred Read/Write 2987 Prover Shaft Temperature Assignment 0 Inferred Read/Write 2988 Meter#2 Turbine Diagnose 0 Inferred Read/Write 2989 Meter#2 Turbine Diagnose-No.of Blades 0 Inferred Read/Write 2990 Meter#2 Turbine Diagnose-Updates 0 Inferred Read/Write



Date: 7/10/2012

3001 Version Number 2 Inferred Read 3002 End Meter #1 Batch 0 Inferred Read/Write 3003 End Meter #2 Batch 0 Inferred Read/Write 3004 Meter #1 Frequency 0 Inferred Read 3005 Meter #2 Frequency 0 Inferred Read 3006 Meter #1 Product Used 0 Inferred Read 3007 Meter #1 Table Used 0 Inferred Read 3008-3011 Meter #1 ID 8 Chars Read 3012 Meter #2 Product Used 0 Inferred Read 3013 Meter #2 Table Used 0 Inferred Read 3014-3017 Meter #2 ID 8 Chars Read 3018 Prove Meter #1 (0=No,1=Single,2=Complete) 0 Inferred Read 3019 Prove Meter #2 (0=No,1=Single,2=Complete) 0 Inferred Read 3020-3024 Spare 3025 Last Prove Report Request 0 Inferred Read/Write 3026 Last Daily Report Request 0 Inferred Read/Write Daily Data Area in Location 3431-3753 3027 Last Batch Report Request 0 Inferred Read/Write Last Batch Data Area in Location 3431-3753 3028 Reserved 3029 Last Hourly Report Request 0 Inferred Read/Write 3030 Last Alarm Report Request 0 Inferred Read/Write 3031 Last Audit Report Request 0 Inferred Read/Write

Scaled Data Area

3032 Meter #1 IV Flowrate 0 Inferred Read 3033 Meter #1 ISV Flowrate 0 Inferred Read 3034 Meter #1 GSV Flowrate 0 Inferred Read 3035 Meter #1 NSV Flowrate 0 Inferred Read 3036 Meter #1 MASS Flowrate 0 Inferred Read 3037 Meter #1 Forward Batch IV 0 Inferred Read 3038 Meter #1 Forward Batch ISV 0 Inferred Read 3039 Meter #1 Forward Batch GSV 0 Inferred Read 3040 Meter #1 Forward Batch NSV 0 Inferred Read 3041 Meter #1 Forward Batch MASS 0 Inferred Read 3042 Meter #1 Reverse Batch IV 0 Inferred Read 3043 Meter #1 Reverse Batch ISV 0 Inferred Read 3044 Meter #1 Reverse Batch GSV 0 Inferred Read 3045 Meter #1 Reverse Batch NSV 0 Inferred Read 3046 Meter #1 Reverse Batch MASS 0 Inferred Read



Date: 7/10/2012

3047 Meter #2 IV Flowrate 0 Inferred Read 3048 Meter #2 ISV Flowrate 0 Inferred Read 3049 Meter #2 GSV Flowrate 0 Inferred Read 3050 Meter #2 NSV Flowrate 0 Inferred Read 3051 Meter #2 MASS Flowrate 0 Inferred Read ` 3052 Meter #2 Forward Batch IV 0 Inferred Read 3053 Meter #2 Forward Batch ISV 0 Inferred Read 3054 Meter #2 Forward Batch GSV 0 Inferred Read 3055 Meter #2 Forward Batch NSV 0 Inferred Read 3056 Meter #2 Forward Batch MASS 0 Inferred Read 3057 Meter #1 Reverse Batch IV 0 Inferred Read 3058 Meter #1 Reverse Batch ISV 0 Inferred Read 3059 Meter #1 Reverse Batch GSV 0 Inferred Read 3060 Meter #1 Reverse Batch NSV 0 Inferred Read 3061 Meter #1 Reverse Batch MASS 0 Inferred Read 3062 Spare #1 Data 0 Inferred Read 3063 Spare #2 Data 0 Inferred Read 3064 Meter #1 BSW 0 Inferred Read 3065 Meter #1 Temperature 0 Inferred Read 3066 Meter #1 Pressure 0 Inferred Read 3067 Meter #1 Density 0 Inferred Read 3068 Meter #1 Density Temperature 0 Inferred Read 3069 Meter #1 Density Pressure 0 Inferred Read 3070 Meter #2 BSW 0 Inferred Read 3071 Meter #2 Temperature 0 Inferred Read 3072 Meter #2 Pressure 0 Inferred Read 3073 Meter #2 Density 0 Inferred Read 3074 Meter #2 Density Temperature 0 Inferred Read 3075 Meter #2 Density Pressure 0 Inferred Read

SCALED DATA AREA ENDS

3082-3121 Modbus Shift 2 Bytes Data Area 0 Inferred Read 3122 Prove Meter #1 0 Inferred Read/Write 3123 Prove Meter #2 0 Inferred Read/Write 3124 Reserved 3125 Analog Output #1 (Remote Control Range0-4095)0 Inferred Read/Write 3126 Analog Output #2 (Remote Control Range0-4095)0 Inferred Read/Write 3127 Reserved 0 Inferred Read 3128 Start Proveing Meter 0 Inferred Read/Write

Modbus 16-Bit Address Table Ends

Dynamic Flow Computers SFC332 Liquid Pulsed Manual Modbus Data – 4-11

Date: 7/10/2012

MODBUS ADDRESS TABLE - 32 BITS ADDRESS DESCRIPTION DECIMAL READ/WRITE *Note: no of decimal position is contengined on the resolution setting.

Flow Resolution (meter#1- 2639, meter#2 – 2647)

Temperature Resolution (2794)

Pressure Reslution (2795) 3131 Meter #1 IV Flowrate 0,1,2 Inferred* Read 3133 Meter #1 ISV Flowrate 0,1,2 Inferred* Read 3135 Meter #1 GSV Flowrate 0,1,2 Inferred* Read 3137 Meter #1 NSV Flowrate 0,1,2 Inferred* Read 3139 Meter #1 MASS Flowrate 1,2,3 Inferred* Read 3141 Meter #1 Temperature 0,1,2 Inferred* Read 3143 Meter #1 Pressure 0,1 Inferred* Read 3145 Meter #1 Density 4 Inferred Read 3147 Meter #1 Density Temperature 0,1,2 Inferred* Read 3149 Meter #1 Density Pressure 0,1 Inferred* Read 3151 Meter #1 API 1 Inferred Read 3153 Meter #1 API@60 1 Inferred Read 3155 Meter #1 SG 4 Inferred Read 3157 Meter #1 SG@60 4 Inferred Read 3159 Meter #1 CTL 4 Inferred Read 3161 Meter #1 CPL 4 Inferred Read 3163 Meter #1 Linear Meter Factor 4 Inferred Read 3165 Meter #1 EQUIL 3 Inferred Read 3167 Meter #1 BS&W 2 Inferred Read 3169 Meter #1 Forward Batch IV Total 0,1,2 Inferred* Read 3171 Meter #1 Forward Batch ISV Total 0,1,2 Inferred* Read 3173 Meter #1 Forward Batch GSV Total 0,1,2 Inferred* Read 3175 Meter #1 Forward Batch NSV Total 0,1,2 Inferred* Read 3177 Meter #1 Forward Batch MASS Total 1,2,3 Inferred* Read 3179 Meter #1 Forward Opening IV Total 0,1,2 Inferred* Read 3181 Meter #1 Forward Opening ISV Total 0,1,2 Inferred* Read 3183 Meter #1 Forward Opening GSV Total 0,1,2 Inferred* Read 3185 Meter #1 Forward Opening NSV Total 0,1,2 Inferred* Read 3187 Meter #1 Forward Opening MASS Total 1,2,3 Inferred* Read 3189 Meter #1 Reverse Batch IV Total 0,1,2 Inferred* Read 3191 Meter #1 Reverse Batch ISV Total 0,1,2 Inferred* Read 3193 Meter #1 Reverse Batch GSV Total 0,1,2 Inferred* Read 3195 Meter #1 Reverse Batch NSV Total 0,1,2 Inferred* Read 3197 Meter #1 Reverse Batch MASS Total 1,2,3 Inferred* Read 3199 Meter #1 Reverse Opening IV Total 0,1,2 Inferred* Read 3201 Meter #1 Reverse Opening ISV Total 0,1,2 Inferred* Read 3203 Meter #1 Reverse Opening GSV Total 0,1,2 Inferred* Read 3205 Meter #1 Reverse Opening NSV Total 0,1,2 Inferred* Read 3207 Meter #1 Reverse Opening MASS Total 1,2,3 Inferred* Read



Date: 7/10/2012

*Note: no of decimal position is contengined on the resolution setting.



Pressure Reslution (2795) 3209 Meter #1 Batch Number 0 Inferred Read 3211 Meter #1 Batch Start Date 0 Inferred Read 3213 Meter #1 Batch Start Time 0 Inferred Read 3215-3225 Spare 3227 Meter #2 IV. Flowrate 0,1,2 Inferred* Read 3229 Meter #2 ISV Flowrate 0,1,2 Inferred* Read 3231 Meter #2 GSV Flowrate 0,1,2 Inferred* Read 3233 Meter #2 NSV Flowrate 0,1,2 Inferred* Read 3235 Meter #2 MASS Flowrate 1,2,3 Inferred* Read 3237 Meter #2 Temperature 0,1,2 Inferred* Read 3239 Meter #2 Pressure 0,1 Inferred* Read 3241 Meter #2 Density 4 Inferred Read 3243 Meter #2 Density Temperature 0,1,2 Inferred* Read 3245 Meter #2 Density Pressure 0,1 Inferred* Read 3247 Meter #2 API 1 Inferred Read 3249 Meter #2 API@60 1 Inferred Read 3251 Meter #2 SG 4 Inferred Read 3253 Meter #2 SG@60 4 Inferred Read 3255 Meter #2 CTL 4 Inferred Read 3257 Meter #2 CPL 4 Inferred Read 3259 Meter #2 LMF 4 Inferred Read 3261 Meter #2 EQUIL 3 Inferred Read 3263 Meter #2 BSW 2 Inferred Read 3265 Meter #2 Forward Batch IV Total 0,1,2 Inferred* Read 3267 Meter #2 Forward Batch ISV Total 0,1,2 Inferred* Read 3269 Meter #2 Forward Batch GSV Total 0,1,2 Inferred* Read 3271 Meter #2 Forward Batch NSV Total low Resolution Read 3273 Meter #2 Forward Batch MASS Total 1,2,3 Inferred* Read 3275 Meter #2 Forward Opening IV Total 0,1,2 Inferred* Read 3277 Meter #2 Forward Opening ISV Total 0,1,2 Inferred* Read 3279 Meter #2 Forward Opening GSV Total 0,1,2 Inferred* Read 3281 Meter #2 Forward Opening NSV Total 0,1,2 Inferred* Read 3283 Meter #2 Forward Opening MASS Total 1,2,3 Inferred* Read 3285 Meter #2 Reverse Batch IV Total 0,1,2 Inferred* Read 3287 Meter #2 Reverse Batch ISV Total 0,1,2 Inferred* Read 3289 Meter #2 Reverse Batch GSV Total 0,1,2 Inferred* Read 3291 Meter #2 Reverse Batch NSV Total 0,1,2 Inferred* Read 3293 Meter #2 Reverse Batch MASS Total 1,2,3 Inferred* Read 3295 Meter #2 Reverse Opening IV Total 0,1,2 Inferred* Read 3297 Meter #2 Reverse Opening ISV Total 0,1,2 Inferred* Read 3299 Meter #2 Reverse Opening GSV Total 0,1,2 Inferred* Read 3301 Meter #2 Reverse Opening NSV Total 0,1,2 Inferred* Read 3303 Meter #2 Reverse Opening MASS Total 1,2,3 Inferred* Read



Date: 7/10/2012




Pressure Reslution (2795) 3305 Meter #2 Batch Number 0 Inferred Read 3307 Meter #2 Batch Start Date 0 Inferred Read 3309 Meter #2 Batch Start Time 0 Inferred Read 3311-3321 Spare 3323 Station IV. Flowrate 0,1,2 Inferred* Read 3325 Station ISV Flowrate 0,1,2 Inferred* Read 3327 Station GSV Flowrate 0,1,2 Inferred* Read 3329 Station NSV Flowrate 0,1,2 Inferred* Read 3331 Station MASS Flowrate 1,2,3 Inferred* Read 3333 Station Forward Batch IV Total 0,1,2 Inferred* Read 3335 Station Forward Batch ISV Total 0,1,2 Inferred* Read 3337 Station Forward Batch GSV Total 0,1,2 Inferred* Read 3339 Station Forward Batch NSV Total 0,1,2 Inferred* Read 3341 Station Forward Batch MASS Total 1,2,3 Inferred* Read 3343 Station Forward Open IV Total 0,1,2 Inferred* Read 3345 Station Forward Open ISV Total 0,1,2 Inferred* Read 3347 Station Forward Open GSV Total 0,1,2 Inferred* Read 3349 Station Forward Open NSV Total 0,1,2 Inferred* Read 3351 Station Forward Open MASS Total 1,2,3 Inferred* Read 3353 Station Reverse Batch IV Total 0,1,2 Inferred* Read 3355 Station Reverse Batch ISV Total 0,1,2 Inferred* Read 3357 Station Reverse Batch GSV Total 0,1,2 Inferred* Read 3359 Station Reverse Batch NSV Total 0,1,2 Inferred* Read 3361 Station Reverse Batch MASS Total 1,2,3 Inferred* Read 3363 Station Reverse Open IV Total 0,1,2 Inferred* Read 3365 Station Reverse Open ISV 0,1,2 Inferred* Read 3367 Station Reverse Open GSV 0,1,2 Inferred* Read 3369 Station Reverse Open NSV 0,1,2 Inferred* Read 3371 Station Reverse Open MASS 1,2,3 Inferred* Read 3373 Spare #1 0,1,2,3,4 Inferred* Read 3375 Spare #2 0,1,2,3,4 Inferred* Read 3377 Analog Output #1 Output % 2 Inferred Read 3379 Analog Output #2 Output % 2 Inferred Read



Date: 7/10/2012

3381 Meter #1 Uncorrected Density 4 Inferred Read 3383 Meter #2 Uncorrected Density 4 Inferred Read 3385-3403 Spare 3405 Prover Pressure 1 Inferred Read 3407 Prover Temperature 2 Inferred Read 3409 Prover Right Temperature 2 Inferred Read 3411 Prover Left Temperature 2 Inferred Read 3413 Prover Shaft Temperature 2 Inferred Read 3415-3423 Spare



Date: 7/10/2012

Last Batch/Daily Data Area

LAST DAILY REPORT

3026 = Last Daily Report Request (16 bits) Set last daily report request to 1

LAST BATCH REPORT

3027 = Last Batch Request Set last batch request to 1. (1=Latest, 50=Oldest)

3425 Meter #1 Turbine Diagnose- Rev. Error % 2 Inferred Read 3427 Meter #1 Turbine Diagnose- Blade Error % 2 Inferred Read 3429 Meter #1 Turbine Diagnose- Profie Error % 2 Inferred Read 3431 Batch Type/Disp/Bank/Station Flag 0 Inferred Read 3433 Meter #1 Table Used 0 Inferred Read 3435 Meter #2 Table Used 0 Inferred Read 3437 Meter #1 Product No 0 Inferred Read 3439 Meter #2 Product No 0 Inferred Read 3441 Meter #1 Opening Forward IV Total 1 Inferred Read 3443 Meter #1 Opening Forward ISV Total 1 Inferred Read 3445 Meter #1 Opening Forward GSV Total 1 Inferred Read 3447 Meter #1 Opening Forward NSV Total 1 Inferred Read 3449 Meter #1 Opening Forward MASS Total 2 Inferred Read 3451 Meter #1 Forward Batch IV Total 1 Inferred Read 3453 Meter #1 Forward Batch ISV Total 1 Inferred Read 3455 Meter #1 Forward Batch GSV Total 1 Inferred Read 3457 Meter #1 Forward Batch NSV Total 1 Inferred Read 3459 Meter #1 Forward Batch MASS Total 2 Inferred Read 3461 Meter #1 Forward FWA Temperature 2 Inferred Read 3463 Meter #1 Forward FWA Pressure 1 Inferred Read 3465 Meter #1 Forward FWA Density 4 Inferred Read 3467 Meter #1 Forward FWA Density Temp 2 Inferred Read 3469 Meter #1 Forward FWA Density Pressure 1 Inferred Read 3471 Meter #1 Forward FWA API/SG 1 or 4 Inferred Read 3473 Meter #1 Forward FWA API/SG60 1 or 4 Inferred Read 3475 Meter #1 Forward FWA CTL 4 Inferred Read 3477 Meter #1 Forward FWA CPL 4 Inferred Read 3479 Meter #1 Forward FWA LMF 4 Inferred Read 3481 Meter #1 Forward FWA EQUIL 3 Inferred Read 3483 Meter #1 Forward FWA BS&W 2 Inferred Read 3485-3487 Spare 3489 Meter #1 Opening Reverse IV Total 1 Inferred Read 3491 Meter #1 Opening Reverse ISV Total 1 Inferred Read 3493 Meter #1 Opening Reverse GSV Total 1 Inferred Read 3495 Meter #1 Opening Reverse NSV Total 1 Inferred Read 3497 Meter #1 Opening Reverse MASS Total 2 Inferred Read



Date: 7/10/2012

3499 Meter #1 Reverse Batch IV Total 1 Inferred Read 3501 Meter #1 Reverse Batch ISV Total 1 Inferred Read 3503 Meter #1 Reverse Batch GSV Total 1 Inferred Read 3505 Meter #1 Reverse Batch NSV Total 1 Inferred Read 3507 Meter #1 Reverse Batch MASS Total 2 Inferred Read 3509 Meter #1 Reverse FWA Temperature 2 Inferred Read 3511 Meter #1 Reverse FWA Pressure 1 Inferred Read 3513 Meter #1 Reverse FWA Density 4 Inferred Read 3515 Meter #1 Reverse FWA Density Temp 2 Inferred Read 3517 Meter #1 Reverse FWA Density Pressure 1 Inferred Read 3519 Meter #1 Reverse FWA API/SG 1 or 4 Inferred Read 3521 Meter #1 Reverse FWA API/SG@60 1 or 4 Inferred Read 3523 Meter #1 Reverse FWA CTL 4 Inferred Read 3525 Meter #1 Reverse FWA CPL 4 Inferred Read 3527 Meter #1 Reverse FWA LMF 4 Inferred Read 3529 Meter #1 Reverse FWA EQUIL. 3 Inferred Read 3531 Meter #1 Reverse FWA BSW 2 Inferred Read 3533 Reserved 3535 Meter #1 Forward FWA CTL (V.3.25 & above) 5 Inferred Read 3537 Meter #1 Batch Number 0 Inferred Read 3539 Meter #1 Batch Start Date 0 Inferred Read 3541 Meter #1 Batch Start Time 0 Inferred Read 3543 Meter #1 Batch End Date 0 Inferred Read 3545 Meter #1 Batch End Time 0 Inferred Read 3547 Meter #1 Product Name 16 Char Read 3555 Meter #1 ID 8 Char Read 3559 Meter #1 K Factor 2 Inferred Read 3561 Meter #1 Forward Meter Factor 4 Inferred Read 3563 Meter #1 Reverse Meter Factor 4 Inferred Read 3565 Meter #1 Dens.Corr.Factor 5 Inferred Read 3567 Meter #1 Unit 0 Inferred Read 3569 Meter #1 Reverse FWA CTL (V.3.25 & above) 5 Inferred Read 3571 Meter #2 Opening Forward IV Total 1 Inferred Read 3573 Meter #2 Opening Forward ISV Total 1 Inferred Read 3575 Meter #2 Opening Forward GSV Total 1 Inferred Read 3577 Meter #2 Opening Forward NSV Total 1 Inferred Read 3579 Meter #2 Opening Forward MASS Total 2 Inferred Read 3581 Meter #2 Forward Batch IV Total 1 Inferred Read 3583 Meter #2 Forward Batch ISV Total 1 Inferred Read 3585 Meter #2 Forward Batch GSV Total 1 Inferred Read 3587 Meter #2 Forward Batch NSV Total 1 Inferred Read 3589 Meter #2 Forward Batch MASS Total 2 Inferred Read 3591 Meter #2 Forward FWA Temperature 2 Inferred Read 3593 Meter #2 Forward FWA Pressure 1 Inferred Read 3595 Meter #2 Forward FWA Density 4 Inferred Read 3597 Meter #2 Forward FWA Density Temp 2 Inferred Read 3599 Meter #2 Forward FWA Density Press 1 Inferred Read



Date: 7/10/2012

3601 Meter #2 Forward FWA API/SG 1 or 4 Inferred Read 3603 Meter #2 Forward FWA API/SG60 1 or 4 Inferred Read 3605 Meter #2 Forward FWA CTL 4 Inferred Read 3607 Meter #2 Forward FWA CPL 4 Inferred Read 3609 Meter #2 Forward FWA LMF 4 Inferred Read 3611 Meter #2 Forward FWA EQUIL. 3 Inferred Read 3613 Meter #2 Forward FWA BSW 2 Inferred Read 3615-3617 Spare 3619 Meter #2 Opening Reverse IV Total 1 Inferred Read 3621 Meter #2 Opening Reverse ISV Total 1 Inferred Read 3623 Meter #2 Opening Reverse GSV Total 1 Inferred Read 3625 Meter #2 Opening Reverse NSV Total 1 Inferred Read 3627 Meter #2 Opening Reverse MASS Total 2 Inferred Read 3629 Meter #2 Reverse Batch IV Total 1 Inferred Read 3631 Meter #2 Reverse Batch ISV Total 1 Inferred Read 3633 Meter #2 Reverse Batch GSV Total 1 Inferred Read 3635 Meter #2 Reverse Batch NSV Total 1 Inferred Read 3637 Meter #2 Reverse Batch MASS Total 2 Inferred Read 3639 Meter #2 Reverse FWA Temperature 2 Inferred Read 3641 Meter #2 Reverse FWA Pressure 1 Inferred Read 3643 Meter #2 Reverse FWA Density 4 Inferred Read 3645 Meter #2 Reverse FWA Density Temp 2 Inferred Read 3647 Meter #2 Reverse FWA Density Press 1 Inferred Read 3649 Meter #2 Reverse FWA API/SG 1 or 4 Inferred Read 3651 Meter #2 Reverse FWA API/SG@60 1 or 4 Inferred Read 3653 Meter #2 Reverse FWA CTL 4 Inferred Read 3655 Meter #2 Reverse FWA CPL 4 Inferred Read 3657 Meter #2 Reverse FWA LMF 4 Inferred Read 3659 Meter #2 Reverse FWA EQUIL. 3 Inferred Read 3661 Meter #2 Reverse FWA BSW 2 Inferred Read 3663 Reserved 3665 Meter #2 Forward FWA CTL (V.3.25 & above) 5 Inferred Read 3667 Meter #2 Batch Number 0 Inferred Read 3669 Meter #2 Batch Start Date 0 Inferred Read 3671 Meter#2 Batch Start Time 0 Inferred Read 3673 Meter #2 Batch End Date 0 Inferred Read 3675 Meter #2 Batch End Time 0 Inferred Read 3677 Meter #2 Product Name 16 Char Read 3685 Meter #2 ID 8 Char Read 3689 Meter #2 K Factor 2 Inferred Read 3691 Meter #2 Forward Meter Factor 4 Inferred Read 3693 Meter #2 Reverse Meter Factor 4 Inferred Read 3695 Meter #2 Dens.Corr.Factor 5 Inferred Read 3697 Meter #2 Unit 0 Inferred Read 3699 Meter #2 Reverse FWA CTL (V.3.25 & above) 5 Inferred Read 3701 Meter #2 Gravity Unit 0 Inferred Read



Date: 7/10/2012

3703 Meter #2 Turbine Diagnose- Rev. Error % 2 Inferred Read 3705 Meter #2 Turbine Diagnose- Blade Error % 2 Inferred Read 3707 Meter #2 Turbine Diagnose- Profie Error % 2 Inferred Read 3709 Spare 3711 Station Opening Forward IV Total 1 Inferred Read 3713 Station Opening Forward ISV Total 1 Inferred Read 3715 Station Opening Forward GSV Total 1 Inferred Read 3717 Station Opening Forward NSV Total 1 Inferred Read 3719 Station Opening Forward MASS Total 2 Inferred Read 3721 Station Forward Batch IV 1 Inferred Read 3723 Station Forward Batch ISV 1 Inferred Read 3725 Station Forward Batch GSV 1 Inferred Read 3727 Station Forward Batch NSV 1 Inferred Read 3729 Station Forward Batch MASS 2 Inferred Read 3731 Station Opening Reverse IV Total 1 Inferred Read 3733 Station Opening Reverse ISV Total 1 Inferred Read 3735 Station Opening Reverse GSV Total 1 Inferred Read 3737 Station Opening Reverse NSV Total 1 Inferred Read 3739 Station Opening Reverse MASS Total 2 Inferred Read 3741 Station Reverse Batch IV 1 Inferred Read 3743 Station Reverse Batch ISV 1 Inferred Read 3745 Station Reverse Batch GSV 1 Inferred Read 3747 Station Reverse Batch NSV 1 Inferred Read 3749 Station Reverse Batch MASS 2 Inferred Read 3751 Spare #1 4 Inferred Read 3753 Spare #2 4 Inferred Read

LAST BATCH /DAILY DATA AREA ENDS



Date: 7/10/2012

3755 Prover API Gravity Override 1 Inferred Read/Write 3757 Prover SG Gravity Override 4 Inferred Read/Write 3759 Prover Density Override 4 Inferred Read/Write 3761 Prover Shaft Temperature Override 2 Inferred Read/Write 3763 Prover Temperature Override 2 Inferred Read/Write 3765 Prover Pressure Override 1 Inferred Read/Write 3767-3789 Reserved 3791 Meter #1 BS&W Override 2 Inferred Read/Write 3793 Meter #2 BS&W Override 2 Inferred Read/Write 3795 Meter #1 Forward M.F. Override 4 Inferred Read/Write 3797 Meter #1 Reverse M.F. Override 4 Inferred Read/Write 3799 Meter #1 Gravity Override 1 or 4 Inferred Read/Write 3801 Meter #1 Alpha T E-6 Override 1 Inferred Read/Write 3803 Meter #2 Forward M.F. Override 4 Inferred Read/Write 3805 Meter #2 Reverse M.F. Override 4 Inferred Read/Write 3807 Meter #2 Gravity Override 1 or 4 Inferred Read/Write 3809 Meter #2 Alpha T E-6 Override 1 Inferred Read/Write

3811 Equilibrium Pressure Override #1 3 Inferred Read/Write 3813 Equilibrium Pressure Override #2 3 Inferred Read/Write 3815 Request Start Date 0 Inferred Read/Write 3817 Spare 3819-3997 Modbus Shift Data Area Read 3999 Spare 4001-4149 Reserved 4151 Meter #1 Densitometer Period 3 Inferred Read 4153 Meter #2 Densitometer Period 3 Inferred Read 4155 Yesterday’s Meter #1 Forward IV Total 1 Inferred Read 4157 Yesterday’s Meter #1 Forward ISV Total 1 Inferred Read 4159 Yesterday’s Meter #1 Forward GSV Total 1 Inferred Read 4161 Yesterday’s Meter #1 Forward NSV Total 1 Inferred Read 4163 Yesterday’s Meter #1 Forward MASS Total 2 Inferred Read 4165 Yesterday’s Meter #2 Forward IV Total 1 Inferred Read 4167 Yesterday’s Meter #2 Forward ISV Total 1 Inferred Read 4169 Yesterday’s Meter #2 Forward GSV Total 1 Inferred Read 4171 Yesterday’s Meter #2 Forward NSV Total 1 Inferred Read 4173 Yesterday’s Meter #2 Forward MASS Total 2 Inferred Read 4175 Yesterday’s StationMeter #1 Forward IV Total 1 Inferred Read 4177 Yesterday’s Station Forward ISV Total 1 Inferred Read 4179 Yesterday’s Station Forward GSV Total 1 Inferred Read 4181 Yesterday’s Station Forward NSV Total 1 Inferred Read 4183 Yesterday’s Station Forward MASS Total 2 Inferred Read 4185-4199 Spare



Date: 7/10/2012

4201 Date (MMDDYY) 0 Inferred Read/Write 4203 Time (HHMMSS) 0 Inferred Read/Write 4205 Meter #1 K Factor 2 Inferred Read/Write 4207 Meter #1 Low Limit 0,1,2 Inferred* Read/Write 4209 Meter #1 High Limit 0,1,2 Inferred* Read/Write 4211 Meter #1 Batch Number 0 Inferred Read/Write 4213 Meter #1 Next Batch Preset Volume 0,1,2 Inferred* Read/Write 4215 Meter #1 Next Batch Preset Warning 0,1,2 Inferred* Read/Write 4217 Meter #1 Preset Volume 0,1,2 Inferred* Read/Write 4219 Meter #1 Preset Warning Volume 0,1,2 Inferred* Read/Write

4221 Meter #2 K Factor 2 Inferred Read/Write 4223 Meter #2 Low Limit 0,1,2 Inferred* Read/Write 4225 Meter #2 High Limit 0,1,2 Inferred* Read/Write 4227 Meter #2 Batch Number 0 Inferred Read/Write 4229 Meter #2 Next Batch Preset Volume 0,1,2 Inferred* Read/Write 4231 Meter #2 Next Batch Preset Warning 0,1,2 Inferred* Read/Write 4233 Meter #2 Preset Volume 0,1,2 Inferred* Read/Write 4235 Meter #2 Preset Warning Volume 0,1,2 Inferred* Read/Write 4237 Batch End Start Date 0 Inferred Read/Write 4239-4240 Spare 4241 Product #1 API Gravity Override 1 Inferred Read/Write 4243 Product #1 Specific Gravity Override 4 Inferred Read/Write 4245 Product #1 Density Override 4 Inferred Read/Write 4247 Product #1 Alpha T E-6 1 Inferred Read/Write 4249 Product #2 API Gravity Override 1 Inferred Read/Write 4251 Product #2 Specific Gravity Override 4 Inferred Read/Write 4253 Product #2 Density Override 4 Inferred Read/Write 4255 Product #2 Alpha T E-6 1 Inferred Read/Write 4257 Product #3 API Gravity Override 1 Inferred Read/Write 4259 Product #3 Specific Gravity Override 4 Inferred Read/Write 4261 Product #3 Density Override 4 Inferred Read/Write 4263 Product #3 Alpha T E-6 1 Inferred Read/Write 4265 Product #4 API Gravity Override 1 Inferred Read/Write 4267 Product #4 Specific Gravity Override 4 Inferred Read/Write 4269 Product #4 Density Override 4 Inferred Read/Write 4271 Product #4 Alpha T E-6 1 Inferred Read/Write 4273 Product #5 API Gravity Override 1 Inferred Read/Write 4275 Product #5 Specific Gravity Override 4 Inferred Read/Write 4277 Product #5 Density Override 4 Inferred Read/Write 4279 Product #5 Alpha T E-6 1 Inferred Read/Write 4281 Product #6 API Gravity Override 1 Inferred Read/Write 4283 Product #6 Specific Gravity Override 4 Inferred Read/Write 4285 Product #6 Density Override 4 Inferred Read/Write 4287 Product #6 Alpha T E-6 1 Inferred Read/Write



Date: 7/10/2012

4289 Product #7 API Gravity Override 1 Inferred Read/Write 4291 Product #7 Specific Gravity Override 4 Inferred Read/Write 4293 Product #7 Density Override 4 Inferred Read/Write 4295 Product #7 Alpha T E-6 1 Inferred Read/Write 4297 Product #8 API Gravity Override 1 Inferred Read/Write 4299 Product #8 Specific Gravity Override 4 Inferred Read/Write 4301 Product #8 Density Override 4 Inferred Read/Write 4303 Product #8 Alpha T E-6 1 Inferred Read/Write 4305 Product #9 API Gravity Override 1 Inferred Read/Write 4307 Product #9 Specific Gravity Override 4 Inferred Read/Write 4309 Product #9 Density Override 4 Inferred Read/Write 4311 Product #9 Alpha T E-6 1 Inferred Read/Write 4313 Product #10 API Gravity Override 1 Inferred Read/Write 4315 Product #10 Specific Gravity Override 4 Inferred Read/Write 4317 Product #10 Density Override 4 Inferred Read/Write 4319 Product #10 Alpha T E-6 1 Inferred Read/Write 4321 Product #11 API Gravity Override 1 Inferred Read/Write 4323 Product #11 Specific Gravity Override 4 Inferred Read/Write 4325 Product #11 Density Override 4 Inferred Read/Write 4327 Product #11 Alpha T E-6 1 Inferred Read/Write 4329 Product #12 API Gravity Override 1 Inferred Read/Write 4331 Product #12 Specific Gravity Override 4 Inferred Read/Write 4333 Product #12 Density Override 4 Inferred Read/Write 4335 Product #12 Alpha T E-6 1 Inferred Read/Write 4337 Product #13 API Gravity Override 1 Inferred Read/Write 4339 Product #13 Specific Gravity Override 4 Inferred Read/Write 4341 Product #13 Density Override 4 Inferred Read/Write 4343 Product #13 Alpha T E-6 1 Inferred Read/Write 4345 Product #14 API Gravity Override 1 Inferred Read/Write 4347 Product #14 Specific Gravity Override 4 Inferred Read/Write 4349 Product #14 Density Override 4 Inferred Read/Write 4351 Product #14 Alpha T E-6 1 Inferred Read/Write 4353 Product #15 API Gravity Override 1 Inferred Read/Write 4355 Product #15 Specific Gravity Override 4 Inferred Read/Write 4357 Product #15 Density Override 4 Inferred Read/Write 4359 Product #15 Alpha T E-6 1 Inferred Read/Write 4361 Product #16 API Gravity Override 1 Inferred Read/Write 4363 Product #16 Specific Gravity Override 4 Inferred Read/Write 4365 Product #16 Density Override 4 Inferred Read/Write 4367 Product #16 Alpha T E-6 1 Inferred Read/Write 4369 Meter #1 Forward Direction Thres. #1 2 Inferred Read/Write 4371 Meter #1 Forward Direction Thres. #2 2 Inferred Read/Write 4373 Meter #1 Forward Direction Thres. #3 2 Inferred Read/Write 4375 Meter #1 Forward Direction Thres. #4 2 Inferred Read/Write 4377 Meter #1 Forward Direction L.F.#1 4 Inferred Read/Write 4379 Meter #1 Forward Direction L.F.#2 4 Inferred Read/Write 4381 Meter #1 Forward Direction L.F.#3 4 Inferred Read/Write 4383 Meter #1 Forward Direction L.F.#4 4 Inferred Read/Write



Date: 7/10/2012

4385 Meter #1 Reverse Direction Thres. #1 2 Inferred Read/Write 4387 Meter #1 Reverse Direction Thres. #2 2 Inferred Read/Write 4389 Meter #1 Reverse Direction Thres. #3 2 Inferred Read/Write 4391 Meter #1 Reverse Direction Thres. #4 2 Inferred Read/Write 4393 Meter #1 Reverse Direction L.F. #1 4 Inferred Read/Write 4395 Meter #1 Reverse Direction L.F. #2 4 Inferred Read/Write 4397 Meter #1 Reverse Direction L.F. #3 4 Inferred Read/Write 4399 Meter #1 Reverse Direction L.F. #4 4 Inferred Read/Write 4401 Meter #2 Forward Direction Thres. #1 2 Inferred Read/Write 4403 Meter #2 Forward Direction Thres. #2 2 Inferred Read/Write 4405 Meter #2 Forward Direction Thres. #3 2 Inferred Read/Write 4407 Meter #2 Forward Direction Thres. #4 2 Inferred Read/Write 4409 Meter #2 Forward Direction L.F. #1 4 Inferred Read/Write 4411 Meter #2 Forward Direction L.F. #2 4 Inferred Read/Write 4413 Meter #2 Forward Direction L.F. #3 4 Inferred Read/Write 4415 Meter #2 Forward Direction L.F. #4 4 Inferred Read/Write 4417 Meter #2 Reverse Direction Thres. #1 2 Inferred Read/Write 4419 Meter #2 Reverse Direction Thres. #2 2 Inferred Read/Write 4421 Meter #2 Reverse Direction Thres. #3 2 Inferred Read/Write 4423 Meter #2 Reverse Direction Thres. #4 2 Inferred Read/Write 4425 Meter #2 Reverse Direction L.F. #1 4 Inferred Read/Write 4427 Meter #2 Reverse Direction L.F. #2 4 Inferred Read/Write 4329 Meter #2 Reverse Direction L.F. #3 4 Inferred Read/Write 4331 Meter #2 Reverse Direction L.F. #4 4 Inferred Read/Write 4433 Product #1 Meter #1 Forward M.F 4 Inferred Read/Write 4435 Product #1 Meter #1 Reverse M.F 4 Inferred Read/Write 4437 Product #1 Meter #2 Forward M.F 4 Inferred Read/Write 4439 Product #1 Meter #2 Reverse M.F 4 Inferred Read/Write 4441 Product #2 Meter #1 Forward M.F 4 Inferred Read/Write 4443 Product #2 Meter #1 Reverse M.F 4 Inferred Read/Write 4445 Product #2 Meter #2 Forward M.F 4 Inferred Read/Write 4447 Product #2 Meter #2 Reverse M.F 4 Inferred Read/Write 4449 Product #3 Meter #1 Forward M.F 4 Inferred Read/Write 4451 Product #3 Meter #1 Reverse M.F 4 Inferred Read/Write 4453 Product #3 Meter #2 Forward M.F 4 Inferred Read/Write 4455 Product #3 Meter #2 Reverse M.F 4 Inferred Read/Write 4457 Product #4 Meter #1 Forward M.F 4 Inferred Read/Write 4459 Product #4 Meter #1 Reverse M.F 4 Inferred Read/Write 4461 Product #4 Meter #2 Forward M.F 4 Inferred Read/Write 4463 Product #4 Meter #2 Reverse M.F 4 Inferred Read/Write 4465 Product #5 Meter #1 Forward M.F 4 Inferred Read/Write 4467 Product #5 Meter #1 Reverse M.F 4 Inferred Read/Write 4469 Product #5 Meter #2 Forward M.F 4 Inferred Read/Write 4471 Product #5 Meter #2 Reverse M.F 4 Inferred Read/Write



Date: 7/10/2012

4473 Product #6 Meter #1 Forward M.F 4 Inferred Read/Write 4475 Product #6 Meter #1 Reverse M.F 4 Inferred Read/Write 4477 Product #6 Meter #2 Forward M.F 4 Inferred Read/Write 4479 Product #6 Meter #2 Reverse M.F 4 Inferred Read/Write 4481 Product #7 Meter #1 Forward M.F 4 Inferred Read/Write 4483 Product #7 Meter #1 Reverse M.F 4 Inferred Read/Write 4485 Product #7 Meter #2 Forward M.F 4 Inferred Read/Write 4487 Product #7 Meter #2 Reverse M.F 4 Inferred Read/Write 4489 Product #8 Meter #1 Forward M.F 4 Inferred Read/Write 4491 Product #8 Meter #1 Reverse M.F 4 Inferred Read/Write 4493 Product #8 Meter #2 Forward M.F 4 Inferred Read/Write 4495 Product #8 Meter #2 Reverse M.F 4 Inferred Read/Write 4497 Product #9 Meter #1 Forward M.F 4 Inferred Read/Write 4499 Product #9 Meter #1 Reverse M.F 4 Inferred Read/Write 4501 Product #9 Meter #2 Forward M.F 4 Inferred Read/Write 4503 Product #9 Meter #2 Reverse M.F 4 Inferred Read/Write 4505 Product #10 Meter #1 Forward M.F 4 Inferred Read/Write 4507 Product #10 Meter #1 Reverse M.F 4 Inferred Read/Write 4509 Product #10 Meter #2 Forward M.F 4 Inferred Read/Write 4511 Product #10 Meter #2 Reverse M.F 4 Inferred Read/Write 4513 Product #11 Meter #1 Forward M.F 4 Inferred Read/Write 4515 Product #11 Meter #1 Reverse M.F 4 Inferred Read/Write 4517 Product #11 Meter #2 Forward M.F 4 Inferred Read/Write 4519 Product #11 Meter #2 Reverse M.F 4 Inferred Read/Write 4521 Product #12 Meter #1 Forward M.F 4 Inferred Read/Write 4523 Product #12 Meter #1 Reverse M.F 4 Inferred Read/Write 4525 Product #12 Meter #2 Forward M.F 4 Inferred Read/Write 4527 Product #12 Meter #2 Reverse M.F 4 Inferred Read/Write 4529 Product #13 Meter #1 Forward M.F 4 Inferred Read/Write 4531 Product #13 Meter #1 Reverse M.F 4 Inferred Read/Write 4533 Product #13 Meter #2 Forward M.F 4 Inferred Read/Write 4535 Product #13 Meter #2 Reverse M.F 4 Inferred Read/Write 4537 Product #14 Meter #1 Forward M.F 4 Inferred Read/Write 4539 Product #14 Meter #1 Reverse M.F 4 Inferred Read/Write 4541 Product #14 Meter #2 Forward M.F 4 Inferred Read/Write 4543 Product #14 Meter #2 Reverse M.F 4 Inferred Read/Write 4545 Product #15 Meter #1 Forward M.F 4 Inferred Read/Write 4547 Product #15 Meter #1 Reverse M.F 4 Inferred Read/Write 4549 Product #15 Meter #2 Forward M.F 4 Inferred Read/Write 4551 Product #15 Meter #2 Reverse M.F 4 Inferred Read/Write 4553 Product #16 Meter #1 Forward M.F 4 Inferred Read/Write 4555 Product #16 Meter #1 Reverse M.F 4 Inferred Read/Write 4557 Product #16 Meter #2 Forward M.F 4 Inferred Read/Write 4559 Product #16 Meter #2 Reverse M.F 4 Inferred Read/Write

4561 Coeff of Shaft Temperature E-7 1 Inferred Read/Write 4563 Area Thermal Coefficient E-7 1 Inferred Read/Write 4565 Prover Base Temperature 2 Inferred Read/Write 4567 Prover Base Pressure 3 Inferred Read/Write



Date: 7/10/2012

4569 Coeff. of Cubical Expansion E-7 1 Inferred Read/Write 4571 Prover and Meter Temperature Deviation 2 Inferred Read/Write 4573 Pulse Deviation 2 Inferred Read/Write 4575 Pre-Travel in Volume 5 Inferred Read/Write 4577 Prove Volume 5 Inferred Read/Write 4579 Prover Diameter 3 Inferred Read/Write 4581 Prover Wall Thickness 4 Inferred Read/Write 4583 Modulus of Elasticity 1 Inferred Read/Write 4585 Prove Report Number 0 Inferred Read/Write 4587 Prove Meter Factor Deviation 2 Inferred Read/Write 4589 Flowrate Change Per Sample Period 2 Inferred Read/Write 4591 Prover Temperature Sample Period 2 Inferred Read/Write 4593 Prover Size 2 Inferred Read/Write 4595 Prove Meter CTL Override 5 Inferred Read/Write 4597 Prove Meter CPL Override 5 Inferred Read/Write 4599 Prove Run Counts 0 Inferred Read/Write 4601 Master Meter Prove K Factor 2 Inferred Read/Write 4603-4623 Reserved 4625 Meter #1 Temperature Override 2 Inferred Read/Write 4627 Meter #2 Temperature Override 2 Inferred Read/Write 4629 Meter #1 Pressure Override 1 Inferred Read/Write 4631 Meter #2 Pressure Override 1 Inferred Read/Write 4633-4655 Reserved 4657 Meter #1 BS&W @4mA 2 Inferred Read/Write 4659 Meter #1 BS&W @20mA 2 Inferred Read/Write 4661 Meter #1 BS&W Lo-Limit 2 Inferred Read/Write 4663 Meter #1 BS&W Hi-Limit 2 Inferred Read/Write 4665 Meter #1 BS&W Maintenance 2 Inferred Read/Write 4667 Meter #1 Temperature @4mA 0,1,2 Inferred* Read/Write 4669 Meter #1 Temperature @20mA 0,1,2 Inferred* Read/Write 4671 Meter #1 Temperature Lo-Limit 0,1,2 Inferred* Read/Write 4673 Meter #1 Temperature Hi-Limit 0,1,2 Inferred* Read/Write 4675 Meter #1 Temperature Maintenance 0,1,2 Inferred* Read/Write

4677 Meter #1 Pressure @4mA 0,1 Inferred* Read/Write 4679 Meter #1 Pressure @20mA 0,1 Inferred* Read/Write 4681 Meter #1 Pressure Lo-Limit 0,1 Inferred* Read/Write 4683 Meter #1 Pressure Hi-Limit 0,1 Inferred* Read/Write 4685 Meter #1Pressure Maintenance 0,1 Inferred* Read/Write

4687 Meter #1 Density/Gravity @4mA 4 or 1 Inferred Read/Write 4689 Meter #1 Density/Gravity @20mA 4 or 1 Inferred Read/Write 4691 Meter #1 Density/Gravity Lo-Limit 4 or 1 Inferred Read/Write 4693 Meter #1 Density/Gravity Hi-Limit 4 or 1 Inferred Read/Write 4695 Meter #1 Density/Gravity Maintenance 4 or 1 Inferred Read/Write



Date: 7/10/2012

4697 Meter #1 Density Temp. @4mA 0,1,2 Inferred* Read/Write 4699 Meter #1 Density Temp. @20mA 0,1,2 Inferred* Read/Write 4701 Meter #1 Density Temp. Lo-Limit 0,1,2 Inferred* Read/Write 4703 Meter #1 Density Temp. Hi-Limit 0,1,2 Inferred* Read/Write 4705 Meter #1 Density Temp. Maintenance 0,1,2 Inferred* Read/Write 4707 Meter #1 Density Press. @4mA 0,1 Inferred* Read/Write 4709 Meter #1 Density Press. @20mA 0,1 Inferred* Read/Write 4711 Meter #1 Density Press. Lo-Limit 0,1 Inferred* Read/Write 4713 Meter #1 Density Press. Hi-Limit 0,1 Inferred* Read/Write 4715 Meter #1 Density Press. Maintenance 0,1 Inferred* Read/Write

4717 Meter #1 Dens.Correction Factor 5 Inferred Read/Write 4719 Meter #1 Dens.Period Low Limit 3 Inferred Read/Write 4721 Meter #1 Dens.Period High Limit 3 Inferred Read/Write 4723-4726 Spare 4727 Meter #2 BS&W @4mA 2 Inferred Read/Write 4729 Meter #2 BS&W @20mA 2 Inferred Read/Write 4731 Meter #2 BS&W Lo-Limit 2 Inferred Read/Write 4733 Meter #2 BS&W Hi-Limit 2 Inferred Read/Write 4735 Meter #2 BS&W Maintenance 2 Inferred Read/Write 4737 Meter #2 Temperature @4mA 0,1,2 Inferred* Read/Write 4739 Meter #2 Temperature @20mA 0,1,2 Inferred* Read/Write 4741 Meter #2 Temperature Lo-Limit 0,1,2 Inferred* Read/Write 4743 Meter #2 Temperature Hi-Limit 0,1,2 Inferred* Read/Write 4745 Meter #2 Temperature Maintenance 0,1,2 Inferred* Read/Write

4747 Meter #2 Pressure @4mA 0,1 Inferred* Read/Write 4749 Meter #2 Pressure @20mA 0,1 Inferred* Read/Write 4751 Meter #2 Pressure Lo-Limit 0,1 Inferred* Read/Write 4753 Meter #2 Pressure Hi-Limit 0,1 Inferred* Read/Write 4755 Meter #2 Pressure Maintenance 0,1 Inferred* Read/Write

4757 Meter #2 Density/Gravity @4mA 4 or 1 Inferred Read/Write 4759 Meter #2 Density/Gravity @20mA 4 or 1 Inferred Read/Write 4761 Meter #2 Density/Gravity Lo-Limit 4 or 1 Inferred Read/Write 4763 Meter #2 Density/Gravity Hi-Limit 4 or 1 Inferred Read/Write 4765 Meter #2 Density/Gravity Maintenance 4 or 1 Inferred Read/Write

4767 Meter #2 Density Temp. @4mA 0,1,2 Inferred* Read/Write 4769 Meter #2 Density Temp. @20mA 0,1,2 Inferred* Read/Write 4771 Meter #2 Density Temp. Lo-Limit 0,1,2 Inferred* Read/Write 4773 Meter #2 Density Temp. Hi-Limit 0,1,2 Inferred* Read/Write 4775 Meter #2 Density Temp. Maintenance 0,1,2 Inferred* Read/Write



Date: 7/10/2012

4777 Meter #2 Density Press. @4mA 0,1 Inferred* Read/Write 4779 Meter #2 Density Press. @20mA 0,1 Inferred* Read/Write 4781 Meter #2 Density Press. Lo-Limit 0,1 Inferred* Read/Write 4783 Meter #2 Density Press. Hi-Limit 0,1 Inferred* Read/Write 4785 Meter #2 Density Press. Maintenance 0,1 Inferred* Read/Write

4787 Meter #2 Dens.Correction Factor 5 Inferred Read/Write 4789 Meter #2 Dens.Period Low Limit 3 Inferred Read/Write 4791 Meter #2 Dens.Period High Limit 3 Inferred Read/Write 4793-4796 Spare 4797 Spare#1 @4mA 0,1,2,3,4* Inferred Read/Write 4799 Spare#1 @20mA 0,1,2,3,4* Inferred Read/Write 4801 Spare#1 Lo-Limit 0,1,2,3,4* Inferred Read/Write 4803 Spare#1 Hi-Limit 0,1,2,3,4* Inferred Read/Write 4805 Spare#1 Maintenance 0,1,2,3,4* Inferred Read/Write 4807 Spare#2 @4mA 0,1,2,3,4* Inferred Read/Write 4809 Spare#2 @20mA 0,1,2,3,4* Inferred Read/Write 4811 Spare#2 Lo-Limit 0,1,2,3,4* Inferred Read/Write 4813 Spare#2 Hi-Limit 0,1,2,3,4* Inferred Read/Write 4815 Spare#2 Maintenance 0,1,2,3,4* Inferred Read/Write 4817 GM/CC Conversion Factor 6 Inferred Read/Write 4819 Spare 4821 Reference Density 4 Inferred Read/Write 4823 Run Switch Low Set Point 2 Inferred Read/Write 4825 Run Switch High Set Point 2 Inferred Read/Write 4827 Atmospheric Pressure PSIA 3 Inferred Read/Write 4829 Pulse Output Volume #1 Pulses/Unit 3 Inferred Read/Write 4831 Pulse Output Volume #2 Pulses/Unit 3 Inferred Read/Write 4833 Analog Output #1 at 4 mA 4835 Analog Output #1 at 20 mA 4837 Analog Output #2 at 4 mA 4839 Analog Output #2 at 20 mA 4841 Prover Pressure. @4mA 1 Inferred. Read/Write 4843 Prover Pressure. @20mA 1 Inferred. Read/Write 4845 Prover Pressure. Lo-Limit 1 Inferred Read/Write 4847 Prover Pressure. Hi-Limit 1 Inferred. Read/Write 4849 Prover Pressure. Maintenance 1 Inferred. Read/Write 4851 Prover Temperature. @4mA 2 Inferred. Read/Write 4853 Prover Temperature. @20mA 2 Inferred. Read/Write 4855 Prover Temperature. Lo-Limit 2 Inferred Read/Write 4857 Prover Temperature. Hi-Limit 2 Inferred. Read/Write 4859 Prover Temperature. Maintenance 2 Inferred. Read/Write



Date: 7/10/2012

4861 Prover Left Temperature. @4mA 2 Inferred. Read/Write 4863 Prover Left Temperature. @20mA 2 Inferred. Read/Write 4865 Prover Left Temperature. Lo-Limit 2 Inferred Read/Write 4867 Prover Left Temperature. Hi-Limit 2 Inferred. Read/Write 4869 Prover Left Temperature. Maintenance 2 Inferred. Read/Write 4871 Prover Right Temperature. @4mA 2 Inferred. Read/Write 4873 Prover Right Temperature. @20mA 2 Inferred. Read/Write 4875 Prover Right Temperature. Lo-Limit 2 Inferred Read/Write 4877 Prover Right Temperature. Hi-Limit 2 Inferred. Read/Write 4879 Prover Right Temperature. Maintenance 2 Inferred. Read/Write 4881 Prover Shaft Temperature. @4mA 2 Inferred. Read/Write 4883 Prover Shaft Temperature. @20mA 2 Inferred. Read/Write 4885 Prover Shaft Temperature. Lo-Limit 2 Inferred Read/Write 4887 Prover Shaft Temperature. Hi-Limit 2 Inferred. Read/Write 4889 Prover Shaft Temperature. Maintenance 2 Inferred. Read/Write 4891 Meter#1 Turbine Diagnos-Min.Flow 1 Inferred Read/Write 4893 Meter#1 Turbine Diagnos-Max.Flow 1 Inferred Read/Write 4895 Meter#1 Turbine Diagnos-Rev.Error % 2 Inferred Read/Write 4897 Meter#1 Turbine Diagnos-Blade Error % 2 Inferred Read/Write 4899 Meter#1 Turbine Diagnos-Profile Error % 2 Inferred Read/Write 4901 Meter#1 Turbine Diagnos-Sensitive Period 0 Inferred Read/Write 4903-4905 Spare 4907 Meter#2 Turbine Diagnos-Min.Flow 1 Inferred Read/Write 4909 Meter#2 Turbine Diagnos-Max.Flow 1 Inferred Read/Write 4911 Meter#2 Turbine Diagnos-Rev.Error % 2 Inferred Read/Write 4913 Meter#2 Turbine Diagnos-Blade Error % 2 Inferred Read/Write 4915 Meter#2 Turbine Diagnos-Profile Error % 2 Inferred Read/Write 4917 Meter#2 Turbine Diagnos-Sensitive Period 0 Inferred Read/Write

4919-4927 Spare 4929 Turbine Diag–M1 Profile-Zone#1 Rev.Err% 2 Inferred Read 4931 Turbine Diag–M1 Profile-Zone#1 Blade Err% 2 Inferred Read 4933 Turbine Diag–M1 Profile-Zone#1 Profile Err% 2 Inferred Read 4935 Turbine Diag–M1 Profile-Zone#2 Rev.Err% 2 Inferred Read 4937 Turbine Diag–M1 Profile-Zone#2 Blade Err% 2 Inferred Read 4939 Turbine Diag–M1 Profile-Zone#2 Profile Err% 2 Inferred Read 4941 Turbine Diag–M1 Profile-Zone#3 Rev.Err% 2 Inferred Read 4943 Turbine Diag–M1 Profile-Zone#3 Blade Err% 2 Inferred Read 4945 Turbine Diag–M1 Profile-Zone#3 Profile Err% 2 Inferred Read



Date: 7/10/2012

4947 Turbine Diag–M2 Profile-Zone#1 Rev.Err% 2 Inferred Read 4949 Turbine Diag–M2 Profile-Zone#1 Blade Err% 2 Inferred Read 4951 Turbine Diag–M2 Profile-Zone#1 Profile Err% 2 Inferred Read 4947 Turbine Diag–M2 Profile-Zone#2 Rev.Err% 2 Inferred Read 4949 Turbine Diag–M2 Profile-Zone#2 Blade Err% 2 Inferred Read 4951 Turbine Diag–M2 Profile-Zone#2 Profile Err% 2 Inferred Read 4947 Turbine Diag–M2 Profile-Zone#3 Rev.Err% 2 Inferred Read 4949 Turbine Diag–M2 Profile-Zone#3 Blade Err% 2 Inferred Read 4951 Turbine Diag–M2 Profile-Zone#3 Profile Err% 2 Inferred Read 4953 Turbine Diag–M1 Current Data- Rev.Error% 2 Inferred Read 4955 Turbine Diag–M1 Current Data- Blade Error% 2 Inferred Read 4957 Turbine Diag–M1 Current Data- rofile Error% 2 Inferred Read 4959 Turbine Diag–M2 Current Data- Rev.Error% 2 Inferred Read 4961 Turbine Diag–M2 Current Data- Blade Error% 2 Inferred Read 4963 Turbine Diag–M2 Current Data- rofile Error% 2 Inferred Read 4965-5011 Reserved 5013 Product #1 Flowing Specific Gravity 4 Inferred Read/Write 5015 Product #2 Flowing Specific Gravity 4 Inferred Read/Write 5017 Product #3 Flowing Specific Gravity 4 Inferred Read/Write 5019 Product #4 Flowing Specific Gravity 4 Inferred Read/Write 5021 Product #5 Flowing Specific Gravity 4 Inferred Read/Write 5023 Product #6 Flowing Specific Gravity 4 Inferred Read/Write 5025 Product #7 Flowing Specific Gravity 4 Inferred Read/Write 5027 Product #8 Flowing Specific Gravity 4 Inferred Read/Write 5029 Product #9 Flowing Specific Gravity 4 Inferred Read/Write 5031 Product 10 Flowing Specific Gravity 4 Inferred Read/Write 5033 Product 11 Flowing Specific Gravity 4 Inferred Read/Write 5035 Product 12 Flowing Specific Gravity 4 Inferred Read/Write 5037 Product 13 Flowing Specific Gravity 4 Inferred Read/Write 5039 Product 14 Flowing Specific Gravity 4 Inferred Read/Write 5041 Product 15 Flowing Specific Gravity 4 Inferred Read/Write 5043 Product 16 Flowing Specific Gravity 4 Inferred Read/Write



Date: 7/10/2012

Last Prove Data Area

6001 No of Good Run 0 Inferred Read 6003 Date 0 Inferred Read 6005 Time 0 Inferred Read 6007 Prove Report Number 0 Inferred Read 6009-6011 Prove Model Number 8 Chars. Read 6013-6015 Prove Meter ID 8 Chars. Read 6017-6019 Prove Serial Number 8 Chars. Read 6021-6027 Prove Product Name 16 Chars. Read 6029 Prove Product Table 0 Inferred Read 6031 Prover Size 2 Inferred Read 6033 Prover Diameter 3 Inferred Read 6035 Prover Elasticity E+7 1 Inferred Read 6037 Prover Coeff.of Shaft E-7 1 Inferred Read 6039 Area Coeff 1 Inferred Read 6041 Wall Thickness in Inches 4 Inferred Read 6043 Cubic Expansion 1 Inferred Read 6045 Equilibrium Pressure 3 Inferred Read 6047 Cum.IV Total 0 Inferred Read 6049 Averaged Prove Counts 0 Inferred Read 6051 Averaged Meter Temperature 2 Inferred Read 6053 Averaged Prove Temperature 2 Inferred Read 6055 Averaged Meter Pressure 1 Inferred Read 6057 Averaged Prove Pressure 1 Inferred Read 6059 Averaged Gravity 4 Inferred Read 6061 Averaged IV Flowrate 1 Inferred Read 6063 Averaged Interpolated Counts 3 Inferred Read 6065 Averaged TFMP 5 Inferred Read 6067 Averaged TDVOL 5 Inferred Read 6069 Prove Base Volume 5 Inferred Read 6071 Prove CTSP 5 Inferred Read 6073 Prove CPSP 5 Inferred Read 6075 Prove CTLP 5 Inferred Read 6077 Prove CPLP 4 Inferred Read 6079 Prove Corrected Prove Volume 5 Inferred Read 6081 Prove Averaged Interpolated Counts 3 Inferred Read 6083 Prove Meter Volume 5 Inferred Read 6085 Prove K Factor 2 Inferred Read 6087 Prove CTLM 5 Inferred Read 6089 Prove CPLM 4 Inferred Read 6091 Prove Corrected Meter Volume 5 Inferred Read 6093 Prove Meter Factor 4 Inferred Read 6095 Prove Actual K Factor 2 Inferred Read 6097 Prove Pulse Deviation 2 Inferred Read 6099 Prove Meter Factor Deviation 2 Inferred Read



Date: 7/10/2012

6101 Reserved 6103 Change Meter Factor Flag 0 Inferred Read 6105 Last Prove Data 1 – Date 0 Inferred Read 6107 Last Prove Data 1 – Time 0 Inferred Read 6109 Last Prove Data 1 – Temperature 2 Inferred Read 6111 Last Prove Data 1 – Pressure 1 Inferred Read 6113 Last Prove Data 1 – Gravity 4 Inferred Read 6115 Last Prove Data 1 – IV Flowrate 1 Inferred Read 6117 Last Prove Data 1 – Meter Factor 4 Inferred Read 6119 Last Prove Data 2 – Date 0 Inferred Read 6121 Last Prove Data 2 – Time 0 Inferred Read 6123 Last Prove Data 2 – Temperature 2 Inferred Read 6125 Last Prove Data 2 – Pressure 1 Inferred Read 6127 Last Prove Data 2 – Gravity 4 Inferred Read 6129 Last Prove Data 2 – IV Flowrate 1 Inferred Read 6131 Last Prove Data 2 – Meter Factor 4 Inferred Read 6133 Last Prove Data 3 – Date 0 Inferred Read 6135 Last Prove Data 3 – Time 0 Inferred Read 6137 Last Prove Data 3 – Temperature 2 Inferred Read 6139 Last Prove Data 3 – Pressure 1 Inferred Read 6141 Last Prove Data 3 – Gravity 4 Inferred Read 6143 Last Prove Data 3 – IV Flowrate 1 Inferred Read 6145 Last Prove Data 3 – Meter Factor 4 Inferred Read 6147 Prove Run #1 Counts 0 Inferred Read 6149 Prove Run #1 Total Counts 0 Inferred Read 6151 Prove Run #1 Interpolated Counts 3 Inferred Read 6153 Prove Run #1 TFMP 5 Inferred Read 6155 Prove Run #1 TDVOL 5 Inferred Read 6157 Prove Run #1 Meter Temperature 2 Inferred Read 6159 Prove Run #1 Prover Temperature 2 Inferred Read 6161 Prove Run #1 Meter Pressure 1 Inferred Read 6163 Prove Run #1 Prover Pressure 1 Inferred Read 6165 Prove Run #1 Gravity 4 Inferred Read 6167 Prove Run #1 IV Flowrate 1 Inferred Read 6169 Prove Run #2 Counts 0 Inferred Read 6171 Prove Run #2 Total Counts 0 Inferred Read 6173 Prove Run #2 Interpolated Counts 3 Inferred Read 6175 Prove Run #2 TFMP 5 Inferred Read 6177 Prove Run #2 TDVOL 5 Inferred Read 6179 Prove Run #2 Meter Temperature 2 Inferred Read 6181 Prove Run #2 Prover Temperature 2 Inferred Read 6183 Prove Run #2 Meter Pressure 1 Inferred Read 6185 Prove Run #2 Prover Pressure 1 Inferred Read 6187 Prove Run #2 Gravity 4 Inferred Read



Date: 7/10/2012

6189 Prove Run #2 IV Flowrate 1 Inferred Read 6191 Prove Run #3 Counts 0 Inferred Read 6193 Prove Run #3 Total Counts 0 Inferred Read 6195 Prove Run #3 Interpolated Counts 3 Inferred Read 6197 Prove Run #3 TFMP 5 Inferred Read 6199 Prove Run #3 TDVOL 5 Inferred Read 6201 Prove Run #3 Meter Temperature 2 Inferred Read 6203 Prove Run #3 Prover Temperature 2 Inferred Read 6205 Prove Run #3 Meter Pressure 1 Inferred Read 6207 Prove Run #3 Prover Pressure 1 Inferred Read 6209 Prove Run #3 Gravity 4 Inferred Read 6211 Prove Run #3 IV Flowrate 1 Inferred Read 6213 Prove Run #4 Counts 0 Inferred Read 6215 Prove Run #4 Total Counts 0 Inferred Read 6217 Prove Run #4 Interpolated Counts 3 Inferred Read 6219 Prove Run #4 TFMP 5 Inferred Read 6221 Prove Run #4 TDVOL 5 Inferred Read 6223 Prove Run #4 Meter Temperature 2 Inferred Read 6225 Prove Run #4 Prover Temperature 2 Inferred Read 6227 Prove Run #4 Meter Pressure 1 Inferred Read 6229 Prove Run #4 Prover Pressure 1 Inferred Read 6231 Prove Run #4 Gravity 4 Inferred Read 6233 Prove Run #4 IV Flowrate 1 Inferred Read 6235 Prove Run #5 Counts 0 Inferred Read 6237 Prove Run #5 Total Counts 0 Inferred Read 6239 Prove Run #5 Interpolated Counts 3 Inferred Read 6241 Prove Run #5 TFMP 5 Inferred Read 6243 Prove Run #5 TDVOL 5 Inferred Read 6245 Prove Run #5 Meter Temperature 2 Inferred Read 6247 Prove Run #5 Prover Temperature 2 Inferred Read 6249 Prove Run #5 Meter Pressure 1 Inferred Read 6251 Prove Run #5 Prover Pressure 1 Inferred Read 6253 Prove Run #5 Gravity 4 Inferred Read 6255 Prove Run #5 IV Flowrate 1 Inferred Read 6257 Prove Run #6 Counts 0 Inferred Read 6259 Prove Run #6 Total Counts 0 Inferred Read 6261 Prove Run #6 Interpolated Counts 3 Inferred Read 6263 Prove Run #6 TFMP 5 Inferred Read 6265 Prove Run #6 TDVOL 5 Inferred Read 6267 Prove Run #6 Meter Temperature 2 Inferred Read 6269 Prove Run #6 Prover Temperature 2 Inferred Read 6271 Prove Run #6 Meter Pressure 1 Inferred Read 6273 Prove Run #6 Prover Pressure 1 Inferred Read 6275 Prove Run #6 Gravity 4 Inferred Read 6277 Prove Run #6 IV Flowrate 1 Inferred Read



Date: 7/10/2012

6279 Prove Run #7 Counts 0 Inferred Read 6281 Prove Run #7 Total Counts 0 Inferred Read 6283 Prove Run #7 Interpolated Counts 3 Inferred Read 6285 Prove Run #7 TFMP 5 Inferred Read 6287 Prove Run #7 TDVOL 5 Inferred Read 6289 Prove Run #7 Meter Temperature 2 Inferred Read 6291 Prove Run #7 Prover Temperature 2 Inferred Read 6293 Prove Run #7 Meter Pressure 1 Inferred Read 6295 Prove Run #7 Prover Pressure 1 Inferred Read 6297 Prove Run #7 Gravity 4 Inferred Read 6299 Prove Run #7 IV Flowrate 1 Inferred Read 6301 Prove Run #8 Counts 0 Inferred Read 6303 Prove Run #8 Total Counts 0 Inferred Read 6305 Prove Run #8 Interpolated Counts 3 Inferred Read 6307 Prove Run #8 TFMP 5 Inferred Read 6309 Prove Run #8 TDVOL 5 Inferred Read 6311 Prove Run #8 Meter Temperature 2 Inferred Read 6313 Prove Run #8 Prover Temperature 2 Inferred Read 6315 Prove Run #8 Meter Pressure 1 Inferred Read 6317 Prove Run #8 Prover Pressure 1 Inferred Read 6319 Prove Run #8 Gravity 4 Inferred Read 6321 Prove Run #8 IV Flowrate 1 Inferred Read 6323 Prove Run #9 Counts 0 Inferred Read 6325 Prove Run #9 Total Counts 0 Inferred Read 6327 Prove Run #9 Interpolated Counts 3 Inferred Read 6329 Prove Run #9 TFMP 5 Inferred Read 6331 Prove Run #9 TDVOL 5 Inferred Read 6333 Prove Run #9 Meter Temperature 2 Inferred Read 6335 Prove Run #9 Prover Temperature 2 Inferred Read 6337 Prove Run #9 Meter Pressure 1 Inferred Read 6339 Prove Run #9 Prover Pressure 1 Inferred Read 6341 Prove Run #9 Gravity 4 Inferred Read 6343 Prove Run #9 IV Flowrate 1 Inferred Read 6345 Prove Run #10 Counts 0 Inferred Read 6347 Prove Run #10 Total Counts 0 Inferred Read 6349 Prove Run #10 Interpolated Counts 3 Inferred Read 6351 Prove Run #10 TFMP 5 Inferred Read 6353 Prove Run #10 TDVOL 5 Inferred Read 6355 Prove Run #10 Meter Temperature 2 Inferred Read 6357 Prove Run #10 Prover Temperature 2 Inferred Read 6359 Prove Run #10 Meter Pressure 1 Inferred Read 6361 Prove Run #10 Prover Pressure 1 Inferred Read 6363 Prove Run #10 Gravity 4 Inferred Read 6365 Prove Run #10 IV Flowrate 1 Inferred Read

End of Last Prove Data Area



Date: 7/10/2012

Current Prove Data Area

6381 Prove Run #1 Counts 0 Inferred Read 6383 Prove Run #1 Total Counts 0 Inferred Read 6385 Prove Run #2 Counts 0 Inferred Read 6387 Prove Run #2 Total Counts 0 Inferred Read 6389 Prove Run #3 Counts 0 Inferred Read 6391 Prove Run #3 Total Counts 0 Inferred Read 6393 Prove Run #4 Counts 0 Inferred Read 6395 Prove Run #4 Total Counts 0 Inferred Read 6397 Prove Run #5 Counts 0 Inferred Read 6399 Prove Run #5 Total Counts 0 Inferred Read 6401 Current Prove Run Counts 0 Inferred Read 6403 Current Prove Run Total Counts 0 Inferred Read 6405 Prover Temperature 2 Inferred Read 6407 Prover Pressure 1 Inferred Read 6409 Meter Temperature 2 Inferred Read 6411 Meter Pressure 1 Inferred Read 6413 Prove Status 0 Inferred Read 01 00 00 00 – Prove Meter #1 or Prove Meter #2

02 00 00 00 – Prove Meter #1

04 00 00 00 – Prove Meter #2

08 00 00 00 – Launch Forward 20 00 00 00 – Launch Ball

10 00 00 00 – Launch Reverse 80 00 00 00 – Compact Proving in Progress

40 00 00 00 – Proving in Progress 00 02 00 00 – Prove Aborted

00 01 00 00 – Prove Completed 00 00 00 00 – Prove not in Progress

Combination Examples:

43 00 00 00 – Meter#1 Proving in Progress 6b 00 00 00 – Meter #1 Launch ball Forward

45 00 00 00 – Meter#2 Proving in Progress 6d 00 00 00 – Meter #2 Launch ball Forward

6415 Prove Run Number 0 Inferred Read 6417 Prove Run #6 Counts 0 Inferred Read 6419 Prove Run #6 Total Counts 0 Inferred Read 6421 Prove Run #7 Counts 0 Inferred Read 6423 Prove Run #7 Total Counts 0 Inferred Read 6425 Prove Run #8 Counts 0 Inferred Read 6427 Prove Run #8 Total Counts 0 Inferred Read 6429 Prove Run #9 Counts 0 Inferred Read 6431 Prove Run #9 Total Counts 0 Inferred Read 6433 Prove Run #10 Counts 0 Inferred Read 6435 Prove Run #10 Total Counts 0 Inferred Read

End of Current Prove Data Area



Date: 7/10/2012

Last Single Prove Report Data Area

6451 Date 0 Inferred Read 6453 Time 0 Inferred Read 6455-6457 Prove Model Number 8 Chars. Read 6459-6461 Prove Meter ID 8 Chars. Read 6463-6465 Prove Serial Number 8 Chars. Read 6467-6473 Prove Product Name 16 Chars. Read 6475 Prove Product Table 0 Inferred Read 6477 Prover Size 2 Inferred Read 6479 Prover Diameter 3 Inferred Read 6481 Prover Elasticity E+7 1 Inferred Read 6483 Prover Coeff.of Shaft E-7 1 Inferred Read 6485 Area Coeff 1 Inferred Read 6487 Wall Thickness in Inches 4 Inferred Read 6489 Cubic Expansion 1 Inferred Read 6491 Cum.IV Total 0 Inferred Read 6493 Counts 0 Inferred Read 6495 Total Counts 0 Inferred Read 6497 Interpolated Counts 3 Inferred Read 6499 TFMP 5 Inferred Read 6501 TDVOL 5 Inferred Read 6503 Meter Temperature 2 Inferred Read 6505 Prover Temperature 2 Inferred Read 6507 Meter Pressure 1 Inferred Read 6509 Prover Pressure 1 Inferred Read 6511 Gravity 4 Inferred Read 6513 IV Flowrate 1 Inferred Read 6515 Prover Type 0 Inferred Read

End of Last Single Prove Report Data Area



Date: 7/10/2012

Last Abort Prove Report Data Area

6551 No of Good Run 0 Inferred Read 6553 Date 0 Inferred Read 6555 Time 0 Inferred Read 6557-6559 Prove Meter ID 8 Chars. Read 6561-6567 Prove Product Name 16 Chars. Read 6569 Prove Product Table 0 Inferred Read 6571 Prove Run #1 Counts 0 Inferred Read 6573 Prove Run #1 Total Counts 0 Inferred Read 6575 Prove Run #1 Interpolated Counts 3 Inferred Read 6577 Prove Run #1 TFMP 5 Inferred Read 6579 Prove Run #1 TDVOL 5 Inferred Read 6581 Prove Run #1 Meter Temperature 2 Inferred Read 6583 Prove Run #1 Prover Temperature 2 Inferred Read 6585 Prove Run #1 Meter Pressure 1 Inferred Read 6587 Prove Run #1 Prover Pressure 1 Inferred Read 6589 Prove Run #1 Gravity 4 Inferred Read 6591 Prove Run #1 IV Flowrate 1 Inferred Read 6593 Prove Run #2 Counts 0 Inferred Read 6595 Prove Run #2 Total Counts 0 Inferred Read 6597 Prove Run #2 Interpolated Counts 3 Inferred Read 6599 Prove Run #2 TFMP 5 Inferred Read 6601 Prove Run #2 TDVOL 5 Inferred Read 6603 Prove Run #2 Meter Temperature 2 Inferred Read 6605 Prove Run #2 Prover Temperature 2 Inferred Read 6607 Prove Run #2 Meter Pressure 1 Inferred Read 6609 Prove Run #2 Prover Pressure 1 Inferred Read 6611 Prove Run #2 Gravity 4 Inferred Read 6613 Prove Run #2 IV Flowrate 1 Inferred Read 6615 Prove Run #3 Counts 0 Inferred Read 6617 Prove Run #3 Total Counts 0 Inferred Read 6619 Prove Run #3 Interpolated Counts 3 Inferred Read 6621 Prove Run #3 TFMP 5 Inferred Read 6623 Prove Run #3 TDVOL 5 Inferred Read 6625 Prove Run #3 Meter Temperature 2 Inferred Read 6627 Prove Run #3 Prover Temperature 2 Inferred Read 6629 Prove Run #3 Meter Pressure 1 Inferred Read 6631 Prove Run #3 Prover Pressure 1 Inferred Read 6633 Prove Run #3 Gravity 4 Inferred Read 6635 Prove Run #3 IV Flowrate 1 Inferred Read 6637 Prove Run #4 Counts 0 Inferred Read 6639 Prove Run #4 Total Counts 0 Inferred Read 6641 Prove Run #4 Interpolated Counts 3 Inferred Read



Date: 7/10/2012

6643 Prove Run #4 TFMP 5 Inferred Read 6645 Prove Run #4 TDVOL 5 Inferred Read 6647 Prove Run #4 Meter Temperature 2 Inferred Read 6649 Prove Run #4 Prover Temperature 2 Inferred Read 6651 Prove Run #4 Meter Pressure 1 Inferred Read 6653 Prove Run #4 Prover Pressure 1 Inferred Read 6655 Prove Run #4 Gravity 4 Inferred Read 6657 Prove Run #4 IV Flowrate 1 Inferred Read 6659 Prove Run #5 Counts 0 Inferred Read 6661 Prove Run #5 Total Counts 0 Inferred Read 6663 Prove Run #5 Interpolated Counts 3 Inferred Read 6665 Prove Run #5 TFMP 5 Inferred Read 6667 Prove Run #5 TDVOL 5 Inferred Read 6669 Prove Run #5 Meter Temperature 2 Inferred Read 6671 Prove Run #5 Prover Temperature 2 Inferred Read 6673 Prove Run #5 Meter Pressure 1 Inferred Read 6675 Prove Run #5 Prover Pressure 1 Inferred Read 6677 Prove Run #5 Gravity 4 Inferred Read 6679 Prove Run #5 IV Flowrate 1 Inferred Read 6681 Prove Run #6 Counts 0 Inferred Read 6683 Prove Run #6 Total Counts 0 Inferred Read 6685 Prove Run #6 Interpolated Counts 3 Inferred Read 6687 Prove Run #6 TFMP 5 Inferred Read 6689 Prove Run #6 TDVOL 5 Inferred Read 6691 Prove Run #6 Meter Temperature 2 Inferred Read 6693 Prove Run #6 Prover Temperature 2 Inferred Read 6695 Prove Run #6 Meter Pressure 1 Inferred Read 6697 Prove Run #6 Prover Pressure 1 Inferred Read 6699 Prove Run #6 Gravity 4 Inferred Read 6701 Prove Run #6 IV Flowrate 1 Inferred Read 6703 Prove Run #7 Counts 0 Inferred Read 6705 Prove Run #7 Total Counts 0 Inferred Read 6707 Prove Run #7 Interpolated Counts 3 Inferred Read 6709 Prove Run #7 TFMP 5 Inferred Read 6711 Prove Run #7 TDVOL 5 Inferred Read 6713 Prove Run #7 Meter Temperature 2 Inferred Read 6715 Prove Run #7 Prover Temperature 2 Inferred Read 6717 Prove Run #7 Meter Pressure 1 Inferred Read 6719 Prove Run #7 Prover Pressure 1 Inferred Read 6721 Prove Run #7 Gravity 4 Inferred Read 6723 Prove Run #7 IV Flowrate 1 Inferred Read 6725 Prove Run #8 Counts 0 Inferred Read 6727 Prove Run #8 Total Counts 0 Inferred Read 6729 Prove Run #8 Interpolated Counts 3 Inferred Read 6731 Prove Run #8 TFMP 5 Inferred Read 6733 Prove Run #8 TDVOL 5 Inferred Read



Date: 7/10/2012

6735 Prove Run #8 Meter Temperature 2 Inferred Read 6737 Prove Run #8 Prover Temperature 2 Inferred Read 6739 Prove Run #8 Meter Pressure 1 Inferred Read 6741 Prove Run #8 Prover Pressure 1 Inferred Read 6743 Prove Run #8 Gravity 4 Inferred Read 6745 Prove Run #8 IV Flowrate 1 Inferred Read 6747 Prove Run #9 Counts 0 Inferred Read 6749 Prove Run #9 Total Counts 0 Inferred Read 6751 Prove Run #9 Interpolated Counts 3 Inferred Read 6753 Prove Run #9 TFMP 5 Inferred Read 6755 Prove Run #9 TDVOL 5 Inferred Read 6757 Prove Run #9 Meter Temperature 2 Inferred Read 6759 Prove Run #9 Prover Temperature 2 Inferred Read 6761 Prove Run #9 Meter Pressure 1 Inferred Read 6763 Prove Run #9 Prover Pressure 1 Inferred Read 6765 Prove Run #9 Gravity 4 Inferred Read 6767 Prove Run #9 IV Flowrate 1 Inferred Read 6769 Prove Run #10 Counts 0 Inferred Read 6771 Prove Run #10 Total Counts 0 Inferred Read 6773 Prove Run #10 Interpolated Counts 3 Inferred Read 6775 Prove Run #10 TFMP 5 Inferred Read 6777 Prove Run #10 TDVOL 5 Inferred Read 6779 Prove Run #10 Meter Temperature 2 Inferred Read 6781 Prove Run #10 Prover Temperature 2 Inferred Read 6783 Prove Run #10 Meter Pressure 1 Inferred Read 6785 Prove Run #10 Prover Pressure 1 Inferred Read 6787 Prove Run #10 Gravity 4 Inferred Read 6789 Prove Run #10 IV Flowrate 1 Inferred Read 6791 Prove Abort Flag 0 Inferred Read 11 – prove was in progress. 12 – deviation between prover and meter temperature 13 – not ready 14 – pulse deviation out of limit 15 – time out

End of Last Prove Abort Data Area



Date: 7/10/2012

The following registers (6801-68010) are only good for version sfc3.16,fc 3.07 and higher)

6801 Meter#1 PID Output % 2 Inferred Read/Write 6803 Meter#1 PID Flow 2 Inferred Read/Write 6805 Meter#1 PID Flow Set Point 2 Inferred Read/Write 6807 Meter#1 PID Flow Controller Gain 2 Inferred Read/Write 6809 Meter#1 PID Flow Controller Reset(M 2 Inferred Read/Write 6811 Meter#1 PID Pressure Maximum 2 Inferred Read/Write 6813 Meter#1 PID Pres.Set Point 2 Inferred Read/Write 6815 Meter#1 PID Pres.Controller Gain 2 Inferred Read/Write 6817 Meter#1 PID Pres.Controller Reset(M.) 2 Inferred Read/Write 6819 Meter#1 PID Minimum Output % 2 Inferred Read/Write 6821 Meter#1 PID Maximum Output % 2 Inferred Read/Write 6823 Meter#2 PID Output % 2 Inferred Read/Write 6825 Meter#2 PID Flow Maximum 2 Inferred Read/Write 6827 Meter#2 PID Flow Set Point 2 Inferred Read/Write 6829 Meter#2 PID Flow Controller Gain 2 Inferred Read/Write 6831 Meter#2 PID Flow Controller Reset(M.) 2 Inferred Read/Write 6833 Meter#2 PID Pressure Maximum 2 Inferred Read/Write 6835 Meter#2 PID Pres.Set Point 2 Inferred Read/Write 6837 Meter#2 PID Pres.Controller Gain 2 Inferred Read/Write 6839 Meter#2 PID Pres.Controller Reset(M.) 2 Inferred Read/Write 6841 Meter#2 PID Minimum Output % 2 Inferred Read/Write 6843 Meter#2 PID Maximum Output % 2 Inferred Read/Write

6845 Meter#1 PID Auto/Manual 0 Inferred Read/Write 6847 Meter#1 PID Flow Loop Used (1=Yes) 0 Inferred Read/Write 6849 Meter#1 PID Flow Direct/Reverse Act 0 Inferred Read/Write 6851 Meter#1 PID Pressure Loop Used (1=Yes) 0 Inferred Read/Write 6853 Meter#1 PID Pressure Direct/Reverse Act 0 Inferred Read/Write 6855 Meter#1 PID Flow Loop in Service 0 Inferred Read/Write 6857 Meter#1 PID Pressure Loop in Service 0 Inferred Read/Write 6859 Meter#1 PID 0=Low,1=High Signal 0 Inferred Read/Write 6861 Meter#1 PID Flow Base 0=Gross,1=Net,2=Mass 0 Inferred Read/Write 6863 Meter#2 PID Auto/Manual 0 Inferred Read/Write 6865 Meter#2 PID Flow Loop Used (1=Yes) 0 Inferred Read/Write 6867 Meter#2 PID Flow Direct/Reverse Act 0 Inferred Read/Write 6869 Meter#2 PID Pres.Loop Used (1=Yes) 0 Inferred Read/Write 6871 Meter#2 PID Pres.Direct/Reverse Act 0 Inferred Read/Write 6873 Meter#2 PID Flow Loop in Service 0 Inferred Read/Write 6875 Meter#2 PID Pres.Loop in Service 0 Inferred Read/Write 6877 Meter#2 PID 0=Low,1=High Signal 0 Inferred Read/Write 6879 Meter#2 PID Flow Base 0=Gross,1=Net,2=Mass 0 Inferred Read/Write



Date: 7/10/2012

LAST HOURLY DATA AREA

3029 = Last Hourly Report Request (16 bits) 8001-8009 Spare 8011 Meter #1 Frequency 0 Inferred Read 8013 Meter #1 Flow Flag/Flow Dir 0 Inferred Read 8015 Spare 8017 Meter #1 Forward Batch IV 1 Inferred Read 8019 Meter #1 Forward Batch ISV 1 Inferred Read 8021 Meter #1 Forward Batch GSV 1 Inferred Read 8023 Meter #1 Forward Batch NSV 1 Inferred Read 8025 Meter #1 Forward Batch Mass 2 Inferred Read 8027 Meter #1 Forward FWA Temperature 2 Inferred Read 8029 Meter #1 Forward FWA Pressure 1 Inferred Read 8031 Meter #1 Forward FWA SG/API 1 or 4 Inferred Read 8033 Meter #1 Forward FWA SG60/API60 1 or 4 Inferred Read 8035 Meter #1 Forward FWA CTL 4 Inferred Read 8037 Meter #1 Forward FWA CPL 4 Inferred Read 8039 Meter #1 Forward FWA Linear M.F. 4 Inferred Read 8041 Meter #1 Forward FWA BS&W 2 Inferred Read 8043 Meter #1 Forward FWA Equil Pressure 3 Inferred Read 8045 Meter #1 Forward FWA Dens.Temperature 2 Inferred Read 8047 Meter #1 Forward FWA Dens.Pressure 1 Inferred Read 8049 Meter #1 Forward FWA Density 4 Inferred Read 8051 Meter #1 IV Flowrate 1 Inferred Read 8053 Meter #1 ISV Flowrate 1 Inferred Read 8055 Meter #1 GSV Flowrate 1 Inferred Read 8057 Meter #1 NSV Flowrate 1 Inferred Read 8059 Meter #1 Mass Flowrate 2 Inferred Read 8061 Meter #1 Temperature 2 Inferred Read 8063 Meter #1 Pressure 1 Inferred Read 8065 Meter #1 SG/API 1 or 4 Inferred Read 8067 Meter #1 SG60/API60 1 or 4 Inferred Read 8069 Meter #1 CTL 4 Inferred Read 8071 Meter #1 CPL 4 Inferred Read 8073 Meter #1 Linear Meter Factor (F/R) 4 Inferred Read 8075 Meter #1 BS&W 2 Inferred Read 8077 Meter #1 Equilibrium Pressure 3 Inferred Read 8079 Meter #1 Densitometer Temperature 2 Inferred Read 8081 Meter #1 Densitometer Pressure 1 Inferred Read 8083 Meter #1 Density 4 Inferred Read 8085 Meter #1 Reverse Batch IV 1 Inferred Read 8087 Meter #1 Reverse Batch ISV 1 Inferred Read 8089 Meter #1 Reverse Batch GSV 1 Inferred Read 8091 Meter #1 Reverse Batch NSV 1 Inferred Read 8093 Meter #1 Reverse Batch Mass 2 Inferred Read



Date: 7/10/2012

8095 Meter #1 Reverse FWA Temperature 2 Inferred Read 8097 Meter #1 Reverse FWA Pressure 1 Inferred Read 8099 Meter #1 Reverse FWA SG/API 1 or 4 Inferred Read 8101 Meter #1 Reverse FWA SG60/API60 1 or 4 Inferred Read 8103 Meter #1 Reverse FWA CTL 4 Inferred Read 8105 Meter #1 Reverse FWA CPL 4 Inferred Read 8107 Meter #1 Reverse FWA Linar M.F. 4 Inferred Read 8009 Meter #1 Reverse FWA BS&W 2 Inferred Read 8111 Meter #1 Reverse FWA Equil Pressure 3 Inferred Read 8113 Meter #1 Reverse FWA Dens.Temperature 2 Inferred Read 8115 Meter #1 Reverse FWA Dens.Pressure 1 Inferred Read 8117 Meter #1 Reverse FWA Density 4 Inferred Read 8119 Meter #1 Table used 0 Inferred Read 8121 Meter #1 Unit of Measurement 0 Inferred Read 8123 Meter #1 Gravity Unit 0 Inferred Read 8125 Meter #1 Forward FWA CTL (V.3.25 & Above) 5 Inferred Read 8127 Meter #1 Forward FWA CPL (V.3.25 & Above) 5 Inferred Read 8129 Meter #1 CTL (V.3.25 & Above) 5 Inferred Read 8131 Meter #1 Reverse Cum, IV 1 Inferred Read 8133 Meter #1 Reverse Cum. ISV 1 Inferred Read 8135 Meter #1 Reverse Cum. GSV 1 Inferred Read 8137 Meter #1 Reverse Cum. NSV 1 Inferred Read 8139 Meter #1 Reverse Cum. Mass 2 Inferred Read 8141 Meter #1 Forward Cum. IV 1 Inferred Read 8143 Meter #1 Forward Cum. ISV 1 Inferred Read 8145 Meter #1 Forward Cum. GSV 1 Inferred Read 8147 Meter #1 Forward Cum. NSV 1 Inferred Read 8149 Meter #1 Forward Cum. Mass 2 Inferred Read 8151 Meter #1 Table Used 0 Inferred Read 8153 Meter #1 Batch Number 0 Inferred Read 8155 Meter #1 Batch Start Date 0 Inferred Read 8157 Meter #1 Batch Start Time 0 Inferred Read 8159 Meter #1 Batch End Date 0 Inferred Read 8161 Meter #1 Batch End Time 0 Inferred Read 8163 Meter #1 Product Used 0 Inferred Read 8165 Meter #1 Unit of Measurement 0 Inferred Read 8167-8173 Meter #1 Product ID 16 Chars. Read 8175-8177 Meter #1 ID 8 Chars. Read 8179 Meter #1 K Factor 2 Inferred Read 8181 Meter #1 Density Correction Factor 5 Inferred Read 8183 Meter #1 Flow Direction Selection 0 Inferred Read 8185 Meter #1 Forward Meter Factor 4 Inferred Read 8187 Meter #1 Reverse Meter Factor 4 Inferred Read 8189 Meter #1 Density 4 Inferred Read 8191 Meter #1 Densitometer Temperature 2 Inferred Read 8193 Meter #1 Densitometer Pressure 1 Inferred Read 8195 Meter #1 Turbine Diag.-Rev.Error% 2 Inferred Read 8197 Meter #1 Turbine Diag.-Blade Error% 2 Inferred Read 8199 Meter #1 Turbine Diag.-Profile Error% 2 Inferred Read



Date: 7/10/2012

8201-8209 Spare 8211 Meter #2 Frequency 0 Inferred Read 8213 Meter #2 Flow Flag/Flow Dir 0 Inferred Read 8215 Spare 8217 Meter #2 Forward Batch IV 1 Inferred Read 8219 Meter #2 Forward Batch ISV 1 Inferred Read 8221 Meter #2 Forward Batch GSV 1 Inferred Read 8223 Meter #2 Forward Batch NSV 1 Inferred Read 8225 Meter #2 Forward Batch Mass 2 Inferred Read 8227 Meter #2 Forward FWA Temperature 2 Inferred Read 8229 Meter #2 Forward FWA Pressure 1 Inferred Read 8231 Meter #2 Forward FWA SG/API 1 or 4 Inferred Read 8233 Meter #2 Forward FWA SG60/API60 1 or 4 Inferred Read 8235 Meter #2 Forward FWA CTL 4 Inferred Read 8237 Meter #2 Forward FWA CPL 4 Inferred Read 8239 Meter #2 Forward FWA Linear M.F. 4 Inferred Read 8241 Meter #2 Forward FWA BS&W 2 Inferred Read 8243 Meter #2 Forward FWA Equil Pressure 3 Inferred Read 8245 Meter #2 Forward FWA Dens.Temperature 2 Inferred Read 8247 Meter #2 Forward FWA Dens.Pressure 1 Inferred Read 8249 Meter #2 Forward FWA Density 4 Inferred Read 8251 Meter #2 IV Flowrate 1 Inferred Read 8253 Meter #2 ISV Flowrate 1 Inferred Read 8255 Meter #2 GSV Flowrate 1 Inferred Read 8257 Meter #2 NSV Flowrate 1 Inferred Read 8259 Meter #2 Mass Flowrate 2 Inferred Read 8261 Meter #2 Temperature 2 Inferred Read 8263 Meter #2 Pressure 1 Inferred Read 8265 Meter #2 SG/API 1 or 4 Inferred Read 8267 Meter #2 SG60/API60 1 or 4 Inferred Read 8269 Meter #2 CTL 4 Inferred Read 8271 Meter #2 CPL 4 Inferred Read 8273 Meter #2 Linear Meter Factor (F/R) 4 Inferred Read 8275 Meter #2 BS&W 2 Inferred Read 8277 Meter #2 Equilibrium Pressure 3 Inferred Read 8279 Meter #2 Densitometer Temperature 2 Inferred Read 8281 Meter #2 Densitometer Pressure 1 Inferred Read 8283 Meter #2 Density 4 Inferred Read 8285 Meter #2 Reverse Batch IV 1 Inferred Read 8287 Meter #2 Reverse Batch ISV 1 Inferred Read 8289 Meter #2 Reverse Batch GSV 1 Inferred Read 8291 Meter #2 Reverse Batch NSV 1 Inferred Read 8293 Meter #2 Reverse Batch Mass 2 Inferred Read 8295 Meter #2 Reverse FWA Temperature 2 Inferred Read 8297 Meter #2 Reverse FWA Pressure 1 Inferred Read 8299 Meter #2 Reverse FWA SG/API 1 or 4 Inferred Read 8201 Meter #2 Reverse FWA SG60/API60 1 or 4 Inferred Read 8203 Meter #2 Reverse FWA CTL 4 Inferred Read 8205 Meter #2 Reverse FWA CPL 4 Inferred Read



Date: 7/10/2012

8207 Meter #2 Reverse FWA Linear M.F. 4 Inferred Read 8209 Meter #2 Reverse FWA BS&W 2 Inferred Read 8311 Meter #2 Reverse FWA Equil Pressure 3 Inferred Read 8313 Meter #2 Reverse FWA Dens.Temperature 2 Inferred Read 8315 Meter #2 Reverse FWA Dens.Pressure 1 Inferred Read 8317 Meter #2 Reverse FWA Density 4 Inferred Read 8319 Meter #2 Table used 0 Inferred Read 8321 Meter #2 Unit of Measurement 0 Inferred Read 8323 Meter #2 Gravity Unit 0 Inferred Read 8325 Meter #2 Forward FWA CTL (V.3.25 & Above) 5 Inferred Read 8327 Meter #2 Forward FWA CPL (V.3.25 & Above) 5 Inferred Read 8329 Meter #2 CTL (V.3.25 & Above) 5 Inferred Read 8331 Meter #2 Reverse Cum. IV 1 Inferred Read 8333 Meter #2 Reverse Cum. ISV 1 Inferred Read 8335 Meter #2 Reverse Cum. GSV 1 Inferred Read 8337 Meter #2 Reverse Cum. NSV 1 Inferred Read 8339 Meter #2 Reverse Cum. Mass 2 Inferred Read 8341 Meter #2 Forward Cum.IV 1 Inferred Read 8343 Meter #2 Forward Cum. ISV 1 Inferred Read 8345 Meter #2 Forward Cum. GSV 1 Inferred Read 8347 Meter #2 Forward Cum. NSV 1 Inferred Read 8349 Meter #2 Forward Cum. Mass 2 Inferred Read 8351 Meter #2 Table Used 0 Inferred Read 8353 Meter #2 Batch Number 0 Inferred Read 8355 Meter #2 Batch Start Date 0 Inferred Read 8357 Meter #2 Batch Start Time 0 Inferred Read 8359 Meter #2 Batch End Date 0 Inferred Read 8361 Meter #2 Batch End Time 0 Inferred Read 8363 Meter #2 Product Used 0 Inferred Read 8365 Meter #2 Unit of Measurement 0 Inferred Read 8367-8373 Meter #2 Product ID 16 Chars. Read 8375-8377 Meter #2 ID 8 Chars. Read 8379 Meter #2 K Factor 2 Inferred Read 8381 Meter #2 Density Correction Factor 5 Inferred Read 8383 Meter #2 Flow Direction Selection 0 Inferred Read 8385 Meter #2 Forward Meter Factor 4 Inferred Read 8387 Meter #2 Reverse Meter Factor 4 Inferred Read 8389 Meter #2 Density 4 Inferred Read 8391 Meter #2 Densitometer Temperature 0,1,2 Inferred* Read 8393 Meter #2 Densitometer Pressure 0,1 Inferred* Read 8395 Meter #2 Turbine Diag.-Rev.Error% 2 Inferred Read 8397 Meter #2 Turbine Diag.-Blade Error% 2 Inferred Read 8399 Meter #2 Turbine Diag.-Profile Error% 2 Inferred Read

LAST HOURLY DATA AREA ENDS



Date: 7/10/2012




Pressure Reslution (2795)

CURRENT DATA AREA

9001 Meter #1 Frequency 0 Inferred Read 9003 Meter #1 Flow Flag/Flow Dir 0 Inferred Read 9005 Meter #1 Alarm Status 0 Inferred Read Flow Direction B0-B3 : 1:Reverse, 0:Forward Flow Flag B4-B7 : 1:Meter#1 Bi-Dir,2:Meter#2 Bi-Dir,3:Meter#1/#2 Bi-Dir 9007 Meter #1 Forward Batch IV 0,1,2 Inferred* Read 9009 Meter #1 Forward Batch ISV 0,1,2 Inferred* Read 9011 Meter #1 Forward Batch GSV 0,1,2 Inferred* Read 9013 Meter #1 Forward Batch NSV 0,1,2 Inferred* Read 9015 Meter #1 Forward Batch Mass 1,2,3 Inferred* Read

9017 Meter #1 Forward FWA Temperature 0,1,2 Inferred* Read 9019 Meter #1 Forward FWA Pressure 0,1 Inferred* Read 9021 Meter #1 Forward FWA SG/API 1 or 4 Inferred Read 9023 Meter #1 Forward FWA SG60/API60 1 or 4 Inferred Read 9025 Meter #1 Forward FWA CTL 4 Inferred Read 9027 Meter #1 Forward FWA CPL 4 Inferred Read 9029 Meter #1 Forward FWA Linear M.F. 4 Inferred Read 9031 Meter #1 Forward FWA BS&W 2 Inferred Read 9033 Meter #1 Forward FWA Equil Pressure 3 Inferred Read 9035 Meter #1 Forward FWA Dens.Temperature 0,1,2 Inferred* Read 9037 Meter #1 Forward FWA Dens.Pressure 0,1 Inferred* Read 9039 Meter #1 Forward FWA Density 4 Inferred Read 9041 Meter #1 IV Flowrate 0,1,2 Inferred* Read 9043 Meter #1 ISV Flowrate 0,1,2 Inferred* Read 9045 Meter #1 GSV Flowrate 0,1,2 Inferred* Read 9047 Meter #1 NSV Flowrate 0,1,2 Inferred* Read 9049 Meter #1 Mass Flowrate 1,2,3 Inferred* Read 9051 Meter #1 Temperature 0,1,2 Inferred* Read 9053 Meter #1 Pressure 0,1 Inferred* Read 9055 Meter #1 SG/API 1 or 4 Inferred Read 9057 Meter #1 SG60/API60 1 or 4 Inferred Read 9059 Meter #1 CTL 4 Inferred Read 9061 Meter #1 CPL 4 Inferred Read 9063 Meter #1 Linear Meter Factor (F/R) 4 Inferred Read 9065 Meter #1 BS&W 2 Inferred Read 9067 Meter #1 Equilibrium Pressure 3 Inferred Read 9069 Meter #1 Densitometer Temperature 0,1,2 Inferred* Read 9071 Meter #1 Densitometer Pressure 0,1 Inferred* Read 9073 Meter #1 Density 4 Inferred Read 9075 Meter #1 Reverse Batch IV 0,1,2 Inferred* Read 9077 Meter #1 Reverse Batch ISV 0,1,2 Inferred* Read 9079 Meter #1 Reverse Batch GSV 0,1,2 Inferred* Read 9081 Meter #1 Reverse Batch NSV 0,1,2 Inferred* Read



Date: 7/10/2012




Pressure Reslution (2795) 9083 Meter #1 Reverse Batch Mass 1,2,3 Inferred* Read 9085 Meter #1 Reverse FWA Temperature 0,1,2 Inferred* Read 9087 Meter #1 Reverse FWA Pressure 0,1 Inferred* Read 9089 Meter #1 Reverse FWA SG/API 1 or 4 Inferred Read 9091 Meter #1 Reverse FWA SG60/API60 1 or 4 Inferred Read 9093 Meter #1 Reverse FWA CTL 4 Inferred Read 9095 Meter #1 Reverse FWA CPL 4 Inferred Read 9097 Meter #1 Reverse FWA Linar M.F. 4 Inferred Read 9099 Meter #1 Reverse FWA BS&W 2 Inferred Read 9101 Meter #1 Reverse FWA Equil Pressure 3 Inferred Read 9103 Meter #1 Reverse FWA Dens.Temperature 0,1,2 Inferred* Read 9105 Meter #1 Reverse FWA Dens.Pressure 0,1 Inferred* Read 9107 Meter #1 Reverse FWA Density 4 Inferred Read 9109 Meter #1 Table used 0 Inferred Read 9111 Meter #1 Unit of Measurement 0 Inferred Read 9113 Meter #1 Gravity Unit 0 Inferred Read 9115 Meter #1 Forward FWA CTL (V.3.25 & Above) 5 Inferred Read 9117 Meter #1 Forward FWA CPL (V.3.25 & Above) 5 Inferred Read 9119 Meter #1 CTL (V.3.25 & Above) 5 Inferred Read 9121 Meter #1 Reverse Cum. IV 0,1,2 Inferred* Read 9123 Meter #1 Reverse Cum. ISV 0,1,2 Inferred* Read 9125 Meter #1 Reverse Cum. GSV 0,1,2 Inferred* Read 9127 Meter #1 Reverse Cum. NSV 0,1,2 Inferred* Read 9129 Meter #1 Reverse Cum. Mass 1,2,3 Inferred* Read 9131 Meter #1 Forward Cum. IV 0,1,2 Inferred* Read 9133 Meter #1 Forward Cum. ISV 0,1,2 Inferred* Read 9135 Meter #1 Forward Cum. GSV 0,1,2 Inferred* Read 9137 Meter #1 Forward Cum. NSV 0,1,2 Inferred* Read 9139 Meter #1 Forward Cum. Mass 1,2,3 Inferred* Read 9141 Meter #1 Table Used 0 Inferred Read 9143 Meter #1 Batch Number 0 Inferred Read 9145 Meter #1 Batch Start Date 0 Inferred Read 9147 Meter #1 Batch Start Time 0 Inferred Read 9149 Meter #1 Batch End Date 0 Inferred Read 9151 Meter #1 Batch End Time 0 Inferred Read 9153 Meter #1 Product Used 0 Inferred Read 9155 Meter #1 Unit of Measurement 0 Inferred Read 9157-9164 Meter #1 Product ID 16 Chars. Read 9165-9168 Meter #1 ID 8 Chars. Read 9169 Meter #1 K Factor 2 Inferred Read 9171 Meter #1 Density Correction Factor 5 Inferred Read 9173 Meter #1 Flow Direction Selection 0 Inferred Read 9175 Meter #1 Forward Meter Factor 4 Inferred Read 9177 Meter #1 Reverse Meter Factor 4 Inferred Read 9179 Meter #1 Density 4 Inferred Read



Date: 7/10/2012

9181 Meter #1 Densitometer Temperature 0,1,2 Inferred* Read 9183 Meter #1 Densitometer Pressure 0,1 Inferred* Read 9185 Meter #1 Turbine Diag.-Rev.Error% 2 Inferred Read 9187 Meter #1 Turbine Diag.-Blade Error% 2 Inferred Read 9189 Meter #1 Turbine Diag.-Profile Error% 2 Inferred Read 9191-9199 Spare 9201 Meter #2 Frequency 0 Inferred Read 9203 Meter #2 Flow Flag/Flow Dir 0 Inferred Read 9205 Meter #2 Alarm Status 0 Inferred Read Flow Direction B0-B3 : 1:Reverse, 0:Forward Flow Flag B4-B7 : 1:Meter#1 Bi-Dir,2:Meter#2 Bi-Dir,3:Meter#1/#2 Bi-Dir 9207 Meter #2 Forward Batch IV 0,1,2 Inferred* Read 9209 Meter #2 Forward Batch ISV 0,1,2 Inferred* Read 9211 Meter #2 Forward Batch GSV 0,1,2 Inferred* Read 9213 Meter #2 Forward Batch NSV 0,1,2 Inferred* Read 9215 Meter #2 Forward Batch Mass 1,2,3 Inferred* Read 9217 Meter #2 Forward FWA Temperature Temp.Resol Read 9219 Meter #2 Forward FWA Pressure 0,1 Inferred* Read 9221 Meter #2 Forward FWA SG/API 1 or 4 Inferred Read 9223 Meter #2 Forward FWA SG60/API60 1 or 4 Inferred Read 9225 Meter #2 Forward FWA CTL 4 Inferred Read 9227 Meter #2 Forward FWA CPL 4 Inferred Read 9229 Meter #2 Forward FWA Linear M.F. 4 Inferred Read 9231 Meter #2 Forward FWA BS&W 2 Inferred Read 9233 Meter #2 Forward FWA Equil Pressure 3 Inferred Read 9235 Meter #2 Forward FWA Dens.Temperature 0,1,2 Inferred* Read 9237 Meter #2 Forward FWA Dens.Pressure 0,1 Inferred* Read 9239 Meter #2 Forward FWA Density 4 Inferred Read 9241 Meter #2 IV Flowrate 0,1,2 Inferred* Read 9243 Meter #2 ISV Flowrate 0,1,2 Inferred* Read 9245 Meter #2 GSV Flowrate 0,1,2 Inferred* Read 9247 Meter #2 NSV Flowrate 0,1,2 Inferred* Read 9249 Meter #2 Mass Flowrate Flow Resol. + 1 Read 9251 Meter #2 Temperature 0,1,2 Inferred* Read 9253 Meter #2 Pressure 0,1 Inferred* Read 9255 Meter #2 SG/API 1 or 4 Inferred Read 9257 Meter #2 SG60/API60 1 or 4 Inferred Read 9259 Meter #2 CTL 4 Inferred Read 9261 Meter #2 CPL 4 Inferred Read 9263 Meter #2 Linear Meter Factor (F/R) 4 Inferred Read 9265 Meter #2 BS&W 2 Inferred Read 9267 Meter #2 Equilibrium Pressure 3 Inferred Read 9269 Meter #2 Densitometer Temperature 0,1,2 Inferred* Read 9271 Meter #2 Densitometer Pressure 0,1 Inferred* Read 9273 Meter #2 Density 4 Inferred Read 9275 Meter #2 Reverse Batch IV 0,1,2 Inferred* Read 9277 Meter #2 Reverse Batch ISV 0,1,2 Inferred* Read 9279 Meter #2 Reverse Batch GSV 0,1,2 Inferred* Read 9281 Meter #2 Reverse Batch NSV 0,1,2 Inferred* Read 9283 Meter #2 Reverse Batch Mass 1,2,3 Inferred* Read



Date: 7/10/2012

9285 Meter #2 Reverse FWA Temperature 0,1,2 Inferred* Read 9287 Meter #2 Reverse FWA Pressure 0,1 Inferred* Read 9289 Meter #2 Reverse FWA SG/API 1 or 4 Inferred Read 9291 Meter #2 Reverse FWA SG60/API60 1 or 4 Inferred Read 9293 Meter #2 Reverse FWA CTL 4 Inferred Read 9295 Meter #2 Reverse FWA CPL 4 Inferred Read 9297 Meter #2 Reverse FWA Linar M.F. 4 Inferred Read 9299 Meter #2 Reverse FWA BS&W 2 Inferred Read 9301 Meter #2 Reverse FWA Equil Pressure 3 Inferred Read 9303 Meter #2 Reverse FWA Dens.Temperature 0,1,2 Inferred* Read 9305 Meter #2 Reverse FWA Dens.Pressure 0,1 Inferred* Read 9307 Meter #2 Reverse FWA Density 4 Inferred Read 9309 Meter #2 Table used 0 Inferred Read 9311 Meter #2 Unit of Measurement 0 Inferred Read 9313 Meter #2 Gravity Unit 0 Inferred Read 9315 Meter #2 Forward FWA CTL (V.3.25 & Above) 5 Inferred Read 9317 Meter #2 Forward FWA CPL (V.3.25 & Above) 5 Inferred Read 9319 Meter #2 CTL (V.3.25 & Above) 5 Inferred Read 9321 Meter #2 Reverse Cum. IV 0,1,2 Inferred* Read 9323 Meter #2 Reverse Cum. ISV 0,1,2 Inferred* Read 9325 Meter #2 Reverse Cum. GSV 0,1,2 Inferred* Read 9327 Meter #2 Reverse Cum. NSV 0,1,2 Inferred* Read 9329 Meter #2 Reverse Cum. Mass 1,2,3 Inferred* Read 9331 Meter #2 Forward Cum. IV 0,1,2 Inferred* Read 9333 Meter #2 Forward Cum. ISV 0,1,2 Inferred* Read 9335 Meter #2 Forward Cum. GSV 0,1,2 Inferred* Read 9337 Meter #2 Forward Cum. NSV 0,1,2 Inferred* Read 9339 Meter #2 Forward Cum. Mass 1,2,3 Inferred* Read 9341 Meter #2 Table Used 0 Inferred Read 9343 Meter #2 Batch Number 0 Inferred Read 9345 Meter #2 Batch Start Date 0 Inferred Read 9347 Meter #2 Batch Start Time 0 Inferred Read 9349 Meter #2 Batch End Date 0 Inferred Read 9351 Meter #2 Batch End Time 0 Inferred Read 9353 Meter #2 Product Used 0 Inferred Read 9355 Meter #2 Unit of Measurement 0 Inferred Read 9357-9364 Meter #2 Product ID 16 Chars. Read 9365-9368 Meter #2 ID 8 Chars. Read 9369 Meter #2 K Factor 2 Inferred Read 9371 Meter #2 Density Correction Factor 5 Inferred Read 9373 Meter #2 Flow Direction Selection 0 Inferred Read 9375 Meter #2 Forward Meter Factor 4 Inferred Read 9377 Meter #2 Reverse Meter Factor 4 Inferred Read 9379 Meter #2 Density 4 Inferred Read 9381 Meter #2 Densitometer Temperature 0,1,2 Inferred* Read 9383 Meter #2 Densitometer Pressure 0,1 Inferred* Read 9385 Meter #2 Turbine Diag.-Rev.Error% 2 Inferred Read 9387 Meter #2 Turbine Diag.-Blade Error% 2 Inferred Read 9389 Meter #2 Turbine Diag.-Profile Error% 2 Inferred Read



Date: 7/10/2012

Alarms and Status Codes Previous Alarm Data Area- Set last alarm status request (3030) to 1.

4001 last alarm date mmddyy 4003 last alarm time hhmmss 4005 last alarm flag = (ID x 106) + (CODE x 104) + (ACODE x 102) + STATUS 4007 last alarm meter #1 batch total 4009 last alarm meter #2 batch total

ID CODE ACODE STATUS

ID

0 Analog Input #1 6 Analog Output #1

1 Analog Input #2 7 Analog Output #2

2 Analog Input #3 8 Densitometer

3 Analog Input #4 9 Densitometer

4 RTD #1 11 Meter #1

5 RTD #2 12 Meter #2

CODE

1 IV (Indicated Volume) 6 Batch Preset

2 Specific Gravity Out of Range 7 Down

3 Temperature Out of Range 8 Start

4 ALPHA T Out of Range 9 API Out of Range

5 Batch Preset Warning Note that CODE = 10 is not used.

ACODE

Given in one hexadecimal byte (HEX 00):

in binary 00000000 bit 76543210

bit 6 = : 0 1 meter configuration

1 2 meters configuration

bit 4 = : 0 Meter #1 Flow in Forward Direction

1 Meter #2 Flow in Reverse Direction



STATUS

0 ID = 9: FAILED OK

ID = 6 OR 7: OVERRANGE OK

If (ID 9,6,7) Then STATUS - OK

1 HI

2 LO

4 FAILED

5 OVERRANGE


Date: 7/10/2012

Previous Audit Data Area: Set last audit data request (3031) to 1.

8501 Last Audit Date mmddyy 8503 Last Audit Time hhmmss 8505 Old Value 8507 New Value 8509 Meter #1 Batch Total (Meter #1 0,1,2 Inferred* Inferred) 8511 Meter #2 Batch Total (Meter #2 0,1,2 Inferred* Inferred) 8513 Code Flag

Code Flag

Config Code No. Audit Code Old/New Value Decimal Inferred

Config Code

in binary 00000000 bit 76543210

bit 6 = : 0 1 meter configuration

1 2 meters configuration





NO.

1 Meter #1 31 BS&W Me

ter #

1

Tag

ID

2 Meter #2 33 Temperature

11 Product #1

Pro

du

ct ID

35 Pressure

12 Product #2 37 Density

13 Product #3 39 Density Temperature

14 Product #4 41 Density Pressure

15 Product #5 32 BS&W Me

ter #

2

16 Product #6 34 Temperature

17 Product #7 36 Pressure

18 Product #8 38 Density

19 Product #9 40 Density Temperature

20 Product #10 42 Density Pressure

21 Product #11 43 Spare #1

22 Product #12 44 Spare #2

23 Product #13 45 Analog Output #1

24 Product #14 46 Analog Output #2

25 Product #15

26 Product #16


Date: 7/10/2012

Audit Codes

1 BS&W

Ov

errid

es

44 Density Temp. @ 4 mA Den

s.T

Tra

ns.In

pu

t As

sig

nm

en

ts

2 Meter Factor-Forward 45 Density Temp. @ 20 mA

3 Meter Factor-Reverse 46 Maintenance Value

4 Gravity 47 Density Press. @ 4 mA Den

s.P

5 Alpha T 48 Density Press. @ 20 mA

6 Equilibrium Pressure 49 Maintenance Value

8 API 50 Spare #1 @ 4 mA Sp

are1

9 Specific Gravity 51 Spare #1 @ 20 mA

10 Density 52 Maintenance Value

11 Alpha T E-6 53 Spare #2 @ 4 mA Sp

are2

7 K Factor 54 Spare #2 @ 20 mA

12 Threshold #1

Fo

rwa

rd

Me

ter L

ine

ar F

ac

tor C

orre

ctio

ns

55 Maintenance Value

13 Threshold #2 56 Analog Output Limit @ 4 mA

14 Threshold #3 57 Analog Output Limit @ 20 mA

15 Threshold #4 58 Density Correction Factor

16 Linear Factor #1 59 GM/CC Conversion Factor

17 Linear Factor #2 60 Weight of H2O

18 Linear Factor #3 61 Atmospheric Pressure, PSIA

19 Linear Factor #4 62 Pulse Output #1 Volume

20 Threshold #1 R

ev

ers

e

63 Pulse Output #2 Volume

21 Threshold #2 150 Common Temperature

22 Threshold #3 151 Common Pressure

23 Threshold #4 152 Common BS&W

24 Linear Factor #1 153 Station Type

25 Linear Factor #2 154 Densitometer Type

26 Linear Factor #3 155 Density Unit

27 Linear Factor #4 156 Use Meter Temp. as Dens.Temp.

28 Meter #1 Fwd. Meter Factor 157 Use Meter Press. as Dens.Press.

29 Meter #1 Rev. Meter Factor 158 Day Start Hour

30 Meter #2 Fwd. Meter Factor 159 Disable Alarms

31 Meter #2 Rev. Meter Factor 160 Batch Type

32 BS&W @ 4 mA BS

&W

Tra

ns. In

pu

t As

sig

nm

en

ts

161 Flow Cut-Off

33 BS&W @ 20 mA 162 0,1,2 Inferred*

34 Maintenance Value 163 Retroactive Meter Factor

35 Temp. @ 4 mA Tem

p

36 Temp. @ 20 mA


38 Pressure @ 4 mA Press.

39 Pressure @ 20 mA


41 Density/Gravity @ 4 mA Den

sity

42 Density/Gravity @20mA



Date: 7/10/2012

164 BS&W Assignment

Inp

ut

Ass

ign

me

nts

172 BS&W Fail Code

Fail C

od

es

165 Temperature Assign. 173 Temperature Fail Code

166 Pressure Assignment 174 Pressure Fail Code

167 Densitometer Assign. 175 Densitometer Fail Code

168 Density Temp. Assign. 176 Density Temp. Fail Code

169 Density Press. Assign. 177 Density Press. Fail Code

170 Spare #1 Assignment 178 Spare #1 Fail Code

171 Spare #2 Assignment 179 Spare #2 Fail Code

180 ***SEE NOTE

NOTE: When Audit Code = 180, then the following Modbus Addresses store the parameters indicated.

8501 System Start Date

8503 System Start Time

8505 System Failed Date

8507 System Failed Time

8509 Not Used

8511 Not Used


Date: 7/10/2012

CURRENT ALARM STATUS 4 Bytes in Hex - FF FF FF FF

METER#1: MODBUS ADDRESS 9497

METER#2: MODBUS ADDRESS 9499

The Current Alarm Status is a 4-byte string that resides at Modbus address 9497 for Meter #1 and

Modbus address 9499 for Meter #2. The alarm status codes are the same for both meters.

00 00 00 01 IV Flowrate High

00 00 00 02 IV Flowrate Low

00 00 00 04 Temperature Assignment High

00 00 00 08 Temperature Assignment Low

00 00 00 10 Pressure Assignment High

00 00 00 20 Pressure Assignment Low

00 00 00 40 Gravity/Density Assignment High

00 00 00 80 Gravity/Density Assignment Low

00 00 01 00 Dens.Temperature Assignment High

00 00 02 00 Dens.Temperature Assignment Low

00 00 04 00 Dens.Pressure Assignment High

00 00 08 00 Dens.Pressure Assignment Low

00 00 10 00 Densitometer Failed

00 00 20 00 Densitometer Failed

00 00 40 00 BS&W Assignment High

00 00 80 00 BS&W Assignment Low

01 00 00 00 Down

02 00 00 00 SG Out of Range

04 00 00 00 Temperature Out of Range

08 00 00 00 Alpha T Out of Range

10 00 00 00 Batch Preset Warning

20 00 00 00 Batch Preset

40 00 00 00 API Out of Range

OTHER ALARMS (MODBUS ADDRESS 9495)

4 Bytes in Hex - FF FF FF FF

00 00 00 01 Analog Output #1 Overrange

00 00 00 02 Analog Output #2 Overrange

00 00 00 04 Spare #1 Assignment High

00 00 00 08 Spare #1 Assignment Low

00 00 00 40 Spare #2 Assignment High

00 00 00 80 Spare #2 Assignment Low

CURRENT ALARMS STATUS SECTION ENDS


Date: 7/10/2012

Snapshot Report

UNIT NO ^2107 DATE ^9149 TIME ^9151

COMPANY NAME ^2021 METER LOCATION ^2031

METER#1 ID ^9165 METER#2 ID ^9365

BATCH NO. ^9143 ^9343

PRODUCT NAME/NO ^9157/^9153 ^9357/^9353

TABLE ^9141 ^9341

K FACTOR/UNITS ^9169/^9155 ^9369/9355

DENS.CORR.FACTOR ^9171 ^9371

DENSITY ^9179 ^9379

DENS.DEG.F ^9181 ^9381

DENS.PSIG ^9183 ^9383

REV.ERR % ^9185 BLADE ^9187 REV ERR % ^9385 BLADE ^9387

PROFILE ERR % ^9189 PROFILE ERR % ^9389

M.F. FORWARD ^9175 REVERSE ^9177 FORWARD ^9375 REVERSE ^9377

BATCH OPENING DATE ^9145 ^9345

TIME ^9147 ^9347

CUM.TOTAL FORWARD REVERSE FORWARD REVERSE

IV ^9131 ^9121 ^9331 ^9321

ISV ^9133 ^9123 ^9333 ^9323

GSV ^9135 ^9125 ^9335 ^9325

NSV ^9137 ^9127 ^9337 ^9327

MASS ^9139 ^9129 ^9339 ^9329

FLOWRATE

FREQENCY ^9001 FREQUENCY ^9201 STATION

I.V. ^9041 ^9241 ^9411

ISV. ^9043 ^9243 ^9413

GSV. ^9045 ^9245 ^9415

NSV. ^9047 ^9247 ^9417

MASS ^9049 ^9249 ^9419

TOTAL M1.FORWARD M1.REVERSE M2.FORWARD M2.REVERSE ST.FORWARD ST.REVERSE

IV. ^9007 ^9075 ^9207 ^9275 ^9421 ^9441

ISV. ^9009 ^9077 ^9209 ^9277 ^9423 ^9443

GSV. ^9011 ^9079 ^9211 ^9279 ^9425 ^9445

NSV. ^9013 ^9081 ^9213 ^9281 ^9427 ^9447

MASS ^9015 ^9083 ^9215 ^9283 ^9429 ^9449

INSTANT F.FWA R.FWA INSTANT F.FWA R.FWA

DEG.F ^9051 ^9017 ^9085 ^9251 ^9217 ^9285

PSIG ^9053 ^9019 ^9087 ^9253 ^9219 ^9287

API/SG ^9055 ^9021 ^9089 ^9255 ^9221 ^9289

API/SG60 ^9057 ^9023 ^9091 ^9257 ^9223 ^9291

EQ.PRES ^9067 ^9033 ^9101 ^9267 ^9233 ^9301

BS&W % ^9065 ^9031 ^9099 ^9265 ^9231 ^9299

LMF ^9063 ^9029 ^9097 ^9263 ^9229 ^9297

CTL ^9059 ^9025 ^9093 ^9259 ^9225 ^9293

CPL ^9061 ^9027 ^9095 ^9261 ^9227 ^9295


Date: 7/10/2012

3027 = Last Batch Request Set last batch request to 1. (1=Latest, 50=Oldest)

Previous Batch Report

DATE ^3543 TIME ^3545

BATCH START DATE ^3539 TIME ^T3541 DATE ^3669 TIME ^T3671

COMPANY NAME ^2021

METER LOCATION ^2031

UNIT NO ^2107 METER ID ^2041 METER ID ^2045

BATCH NO. ^3537 ^3667

PRODUCT NAME/NO ^3547 (^3437) ^3677 (^3439)

TABLE ^3433 ^3435

K FACTOR/UNITS ^3559/^3567 ^3689 /^3697


OPENING FORWARD REVERSE FORWARD REVERSE FORWARD REVERSE

IV ^3441 ^3489 ^3571 ^3619 ^3711 ^3731

ISV ^3443 ^3491 ^3573 ^3621 ^3713 ^3733

GSV ^3445 ^3493 ^3575 ^3623 ^3715 ^3735

NSV ^3447 ^3495 ^3577 ^3625 ^3717 ^3737

MASS ^3449 ^3497 ^3579 ^3627 ^3719 ^3739

BATCH TOTAL

IV ^3451 ^3499 ^3581 ^3629 ^3721 ^3741

ISV ^3453 ^3501 ^3583 ^3631 ^3723 ^3743

GSV ^3455 ^3503 ^3585 ^3633 ^3725 ^3745

NSV ^3457 ^3505 ^3587 ^3635 ^3727 ^3747

MASS ^3459 ^3507 ^3589 ^3637 ^3729 ^3749

BATCH FLOW WEIGHTED AVERAGE

FORWARD REVERSE FORWARD REVERSE

TEMP DEG.F ^3461 ^3509 ^3591 ^3639

PRESS PSIG ^3463 ^3511 ^3593 ^3641

DENSITY ^3465 ^3513 ^3595 ^3643

DENS.DEG.F ^3467 ^3515 ^3597 ^3645

DENS.PSIG ^3469 ^3517 ^3599 ^3647

API/SG ^3471 ^3519 ^3601 ^3649

API/SG60 ^3473 ^3521 ^3603 ^3651

EQ.PRES ^3481 ^3529 ^3611 ^3659

BS&W % ^3483 ^3531 ^3613 ^3661

LMF ^3479 ^3527 ^3609 ^3657

CTL ^3475 ^3523 ^3605 ^3653

CPL ^3477 ^3525 ^3607 ^3655

REV.ERR% ^3485 ^3615

BLADE ERR% ^3487 ^3617

PROFILE ERR% ^3533 ^3663


Date: 7/10/2012

3026 = Last Day Request Set last batch request to 1. (1=Latest, 50=Oldest)

Previous Daily Report

DATE ^3543 TIME ^3545

BATCH START DATE ^3539 TIME ^T3541 DATE ^3669 TIME ^T3671

COMPANY NAME ^2021

METER LOCATION ^2031

UNIT NO ^2107 METER ID ^2041 METER ID ^2045

BATCH NO. ^3537 ^3667

PRODUCT NAME/NO ^3547 (^3437) ^3677 (^3439)

TABLE ^3433 ^3435

K FACTOR/UNITS ^3559/^3567 ^3689 /^3697


OPENING FORWARD REVERSE FORWARD REVERSE FORWARD REVERSE

IV ^3441 ^3489 ^3571 ^3619 ^3711 ^3731

ISV ^3443 ^3491 ^3573 ^3621 ^3713 ^3733

GSV ^3445 ^3493 ^3575 ^3623 ^3715 ^3735

NSV ^3447 ^3495 ^3577 ^3625 ^3717 ^3737

MASS ^3449 ^3497 ^3579 ^3627 ^3719 ^3739

BATCH TOTAL

IV ^3451 ^3499 ^3581 ^3629 ^3721 ^3741

ISV ^3453 ^3501 ^3583 ^3631 ^3723 ^3743

GSV ^3455 ^3503 ^3585 ^3633 ^3725 ^3745

NSV ^3457 ^3505 ^3587 ^3635 ^3727 ^3747

MASS ^3459 ^3507 ^3589 ^3637 ^3729 ^3749

BATCH FLOW WEIGHTED AVERAGE

FORWARD REVERSE FORWARD REVERSE

TEMP DEG.F ^3461 ^3509 ^3591 ^3639

PRESS PSIG ^3463 ^3511 ^3593 ^3641

DENSITY ^3465 ^3513 ^3595 ^3643

DENS.DEG.F ^3467 ^3515 ^3597 ^3645

DENS.PSIG ^3469 ^3517 ^3599 ^3647

API/SG ^3471 ^3519 ^3601 ^3649

API/SG60 ^3473 ^3521 ^3603 ^3651

EQ.PRES ^3481 ^3529 ^3611 ^3659

BS&W % ^3483 ^3531 ^3613 ^3661

LMF ^3479 ^3527 ^3609 ^3657

CTL ^3475 ^3523 ^3605 ^3653

CPL ^3477 ^3525 ^3607 ^3655

REV.ERR% ^3485 ^3615

BLADE ERR% ^3487 ^3617

PROFILE ERR% ^3533 ^3663


Date: 7/10/2012

Hourly Report

3029 = Last Hour Request Set last hour request to 1. (1=Latest, 50=Oldest)

UNIT NO ^2107 DATE ^8159 TIME ^8161

COMPANY NAME ^2021 METER LOCATION ^2031

METER#1 ID ^8175 METER#2 ID ^8375

BATCH NO. ^8153 ^8353

PRODUCT NAME/NO ^8167/^8163 ^8367/^8363

TABLE ^8151 ^8351

K FACTOR/UNITS ^8179/^8165 ^8379/8365


DENSITY ^8189 ^8389

DENS.DEG.F ^8191 ^8391

DENS.PSIG ^8193 ^8393

REV.ERR % ^8195 BLADE ^8197 REV ERR % ^8395 BLADE ^8397

PROFILE ERR % ^8199 PROFILE ERR % ^8399

M.F. FORWARD ^8185 REVERSE ^8187 FORWARD ^8385 REVERSE ^8387

BATCH OPENING DATE ^8155 ^8355

TIME ^8157 ^8357

CUM.TOTAL FORWARD REVERSE FORWARD REVERSE

IV ^8141 ^8131 ^8341 ^8331

ISV ^8143 ^8133 ^8343 ^8333

GSV ^8145 ^8135 ^8345 ^8335

NSV ^8147 ^8137 ^8347 ^8337

MASS ^8149 ^8139 ^8349 ^8339

FLOWRATE METER #1 METER#2 STATION

I.V. ^8051 ^8251 ^8421

ISV. ^8053 ^8253 ^8423

GSV. ^8055 ^8255 ^8425

NSV. ^8057 ^8257 ^8427

MASS ^8059 ^8259 ^8429

TOTAL M1.FORWARD M1.REVERSE M2.FORWARD M2.REVERSE ST.FORWARD ST.REVERSE

IV. ^8017 ^8085 ^8217 ^8285 ^8431 ^8451

ISV. ^8019 ^8087 ^8219 ^8287 ^8433 ^8453

GSV. ^8021 ^8089 ^8221 ^8289 ^8435 ^8455

NSV. ^8023 ^8091 ^8223 ^8291 ^8437 ^8457

MASS ^8025 ^8093 ^8225 ^8293 ^8439 ^8459

INSTANT F.FWA R.FWA INSTANT F.FWA R.FWA

DEG.F ^8061 ^8027 ^8095 ^8261 ^8227 ^8295

PSIG ^8063 ^8029 ^8097 ^8263 ^8229 ^8297

API/SG ^8065 ^8031 ^8099 ^8265 ^8231 ^8299

API/SG60 ^8067 ^8033 ^8101 ^8267 ^8233 ^8301

EQ.PRES ^8077 ^8043 ^8111 ^8277 ^8243 ^8311

BS&W % ^8075 ^8041 ^8109 ^8275 ^8241 ^8309

LMF ^8073 ^8039 ^8107 ^8273 ^8239 ^8307

CTL ^8069 ^8035 ^8103 ^8269 ^8235 ^8303

CPL ^8071 ^8037 ^8105 ^8271 ^8237 ^8305

Documents

SFC332 OPERATORS MANUAL - Prover · PDF fileSFC332 OPERATORS MANUAL Smart Flow Computer Liquid Pulse Version 12603 Southwest Freeway, Suite 320 ... Wiring of Calibron Prover: