Anfomatic Instruction Manual Rev 8.1

ANFOMATIC INSTRUCTION MANUAL DOC: G.04/02PAGE: 1 OF 25REV: 8

ANFOMATIC

INSTRUCTION MANUAL

INSTALLATION AND COMMISSIONING


INDEX

1.0 INTRODUCTION1.1 General System Description1.2 Safety Precautions

2.0 MATERIALS AND EQUIPMENT2.1 Electrical2.1.1 Power Control Unit2.1.2 Electric Cable2.1.3 Junction Box2.2 Alloy Anodes

3.0 INSTALLATION INSTRUCTIONS3.1 Power Control Unit3.2 Connecting Cables/Junction Boxes3.3 Anode/Cofferdam/Flange3.4 Anode Replacement Procedure

4.0 COMMISSIONING

5.0 OPERATION & DISPLAYS

6.0 MAINTENANCE

7.0 SPECIFIC VESSEL DETAILS

8.0 LOG DATA SHEET

9.0 NOTES

10.0 SPARE PARTS LIST

11.0 DRAWING SCHEDULE


1.0 INTRODUCTION

1.1 General System Description

Principle of Operation.

Marine fouling and biological fouling commonly occur in seawater circulation systems. This involves the establishment of marine plants and animals, and bacterial growths. These fouling organisms enter the system in microscopic and macroscopic form, e.g. larvae and spats, settle and develop into adult forms wherever favourable environmental conditions exist.

Hard fouling by mussels, barnacles etc. most commonly occurs in seawater circuits and can result in interference in flow conditions, blockage and increased corrosion. Traditional chemical methods of water treatment to prevent fouling are now less favoured particularly, for example, chlorination. Chlorine accelerates corrosion rates, usually by causing pitting attack on steel, is environmentally unacceptable and treatment requires continuous monitoring and control.

The Anfomatic System.

The Anfomatic system employs a variation of the well-established impressed current cathodic protection principle. Direct current applied to the copper anode(s) releases a controlled quantity of copper ions into the system to create an environment in which primary forms of marine life do not grow.

Current applied to the aluminium anodes releases a ‘floc’, a precipitate of aluminium hydroxide which can help reduce corrosion rates on ferrous components in the seawater system by modifying the ferrous oxides formed and film deposition. Ferrous anodes in the system are designed to help with corrosion reduction in non-ferrous materials.

The Anfomatic system is automatic, requires minimal maintenance and is environmentally friendly. Mussels and similar marine life which are the primary cause of blockage in marine sea water cooling systems are not killed by the Cupric ions given off by the Anfomatic anodes. The environment created is hostile without being fatal and prevents the microscopic embryos from attaching to pipeline walls, settling or developing. A further benefit of the Anfomatic system is that potable water distillation plants can be operated without interruption.

Anode functions are as follows:

WW - Cuproline: Anti-foulingWW - Aloline: Reduction in corrosion of steel materials.WW - Ferroline: Reduction in corrosion of copper based materials.

1.2 General Safety Precautions for Electrical Equipment


The following is given as a guideline only and the operators own safety rules and regulations should be followed at all times.

Non-energised Equipment

1. Isolate the supply, carry out the “Tag Out” system drill or equivalent as specified by the operators own safety procedures.

2. Obtain an approved voltage tester and check it against a known good power supply. Test the equipment circuits across all lines and between each line and earth to ensure that it has been isolated from its power supply before you touch it. Check the tester again after use.

3. Ensure that any capacitors associated with the equipment are fully discharged, fitting shorting straps if necessary.

Energised Equipment

Work on ‘live’ equipment is only to be carried out if there is no alternative. Personnel involved must be briefed on the precautions.

1. Do not take risks.

2. Wear electrically insulated gloves if practicable or work with one hand if possible, keeping the other away from live circuits and components.

3. Use insulated tools if practicable taking particular care that tools do not cause short circuits.

4. Stand on rubber insulating mats. Avoid leaning on adjacent bulkheads of equipment.

5. Wear insulating footwear. Certain types of footwear contain conducting material and are not electrically safe.

6. Be aware of the voltages that are or can be present.

7. Do not rely on interlocks or other safety devices and unless it is essential, do not render interlocks or safety devices inoperative.

8. Do not work alone. Make sure your assistant knows the electric shock procedure, also where and how to isolate the power supply in an emergency.


2.0 MATERIALS AND EQUIPMENT

2.1 Electrical

2.1.1 Power Control Units

2.1.2 Electric Cable

2.1.3 Junction Box

2.1.1 Controller Power Units.

The Mk IV modular control unit is a variable voltage, constant current unit designed for single-phase input power supplies of between 90v to 260v or 350 to 450v AC at 50-60Hz and is available in two cabinet sizes. The smaller cabinet (AM1528) can accommodate between one and five control modules with the larger cabinet (AM1529) being able to accommodate between six and ten. Each two-channel control module is rated at a maximum 65-Watts power output with each output channel having a maximum output of 3.5 amps DC at 12 volts.Refer to drawings AM1528 & AM1529

The Mk V non-modular control unit is a variable voltage, constant current unit designed for single-phase input power supplies of between 90v to 260v AC at 50-60Hz. Each four-channel unit is rated at a maximum 130-Watts power output with each output channel having a maximum output of 3.5 amps DC at 12 volts. This model is intended for use where available space is at a premium.Refer to drawing AM1521

The Mk VI non-modular control unit is a variable voltage, constant current unit designed for single-phase input power supplies of between 90v to 260v AC at 50-60Hz. Each two-channel unit is rated at a maximum 65-Watts power output with each output channel having a maximum output of 3.5 amps DC at 12 volts. This model is intended for use on small vessels or for installation in remote locations with feedback to a master control via a CAN network.Refer to drawing AM1522


2.1.2 Cable

(a) Input

All input cables and shrouds are of shipyard supply. Fittings, terminations, glands, etc are also usually of shipyard supply. The AC supply cable size is rated according to the maximum DC output of the power unit. Usually, a very small conductor size is adequate but for physical and electrical reasons, it is preferable to use a larger cable conductor size than the nominal current capacity needed. Cable insulation, armouring and sleeving is dictated by ship classification requirements.

Input cable size of minimum cross-section 4 sq. mm per conductor is recommended.

e.g. 3 X 4 sq. mm PVC/PVC/SWA/PVC

(b) D.C. Output

The positive DC output from each channel is connected to a corresponding anode (positive output) and the common negative to each sea chest, strainer or reaction vessel in which the anodes are installed respectively (negative return) via an intermediate junction box.

Single core, 6mm2 cable is generally adequate for DC distribution to the anodes without any significant voltage drop or alternatively multi-core cables may be used. For convenience many systems utilise 3 core cable per module output with two positive to anti-fouling and corrosion mitigation anodes respectively and one negative to the sea chest (see Drawing No. AM 1164).

An armoured ship wiring cable for DC supply is recommended (e.g. EPR/CSP/GSW/CSP) unless cable tray or conduit is used for distribution. In such cases cables with acceptable insulation and sleeving alone can be adequate (e.g. EPR/CSP or XLPE/PVC/PVC). Cable voltage rating is not significant since units operate well below 18 volts DC with the maximum output of the power unit rated at 12 volts except in specialist applications.

(c) Earthing

An insulated earthing cable with a recommended minimum 6 mm2 , single core should be connected from the earth connection on the power unit housing to a suitable external earth point.


2.1.3 Junction Boxes (Optional Supply)

An intermediate junction box facilitates separation of individual anodes from the supply thus avoiding interference with the rest of the system during inspection or anode replacement.

Junction boxes should be intrinsically safe or have an IP rating to client specification. Corrpro Companies Europe supplies polymer enclosures rated to IP65 for two, four and six anode arrangements in each sea chest.Refer to Drawings AM1513, AM1514 & AM1515.

2.2 Alloy Anodes

A typical anode assembly, complete with cofferdam and mounting flange is shown in drawing No. AM1500. The anode can be separated from the cofferdam and flange as shown in drawing AM1503

Anode size and material type is indicated by an alphanumeric code identifying the model, material & dimensions of each anode.

Typical examples of minimum anode material required for anti-fouling are given below for various flow rates at 2, 3 and 5 year dry docking cycles.

Flow Rate (m3/Hr) 2 years 3 years 5 years

100 6.6 Kg 9.9 Kg 16.4 Kg200 13.2 Kg 19.8 Kg 32.9 Kg300 19.7 Kg 29.6 Kg 49.3 Kg400 26.3 Kg 39.5 Kg 65.8 Kg500 32.9 Kg 49.3 Kg 82.2 Kg600 39.5 Kg 59.2 Kg 98.6 Kg700 46.0 Kg 69.0 Kg 115.1 Kg800 52.6 Kg 78.9 Kg 131.5 Kg900 59.2 Kg 88.8 Kg 147.9 Kg1000 65.8 Kg 98.6 Kg 164.4 Kg


3.0 INSTALLATION INSTRUCTIONS

3.1 Installation of the Power Control Unit

3.2 Connecting Cables & Junction Boxes

3.3 Anodes, Cofferdams & Flanges

3.1 Power Control Unit

The control panel should be located as near as possible to a suitable AC power supply and the anode locations in order to minimise the DC cable length and voltage drop.

The control panel location should meet the following requirements:

(a) Max. ambient temperature of 50 deg. C. (Unit rated to 55 deg. C).

(b) Adequate space around unit to assist ventilation.

(c) Approx. head height to facilitate ease of reading display, current adjustment in operation or servicing.

(d) Be easily accessible.

(e) Be in a safe, non-hazardous environment

(f) Bulkhead mounted or secured to a suitable base

3.2 Cable Connections - Power Control Unit, Junction Box & Anodes

Input AC cable connection points and earthing cable connections are clearly marked inside the power control unit. Positive output terminals for connection to the anodes and a common negative cable connection are clearly marked inside the unit. If a power failure relay is installed, connections will be clearly marked.

Refer to drawings:

Mark IV Unit: 2 to 10 output channels: AM1528-1Mark IV Unit: 12 to 20 output channels: AM1529-1Mark V Unit: AM1521-1Mark VI Unit: AM1522-1

The DC supply cable to the anodes should be connected to the intermediate junction box provided. This is supplied complete with gland inputs and connection terminals.

Refer to drawings:AM 1513, AM1514, AM1515 (polymer enclosures types 1 to 3)


3.3 Anodes, Cofferdams and Flanges

Where possible, anodes should be installed in the position specifically shown or advised for each vessel.

The anodes are installed in the selected compartments, usually sea chests, injection strainers, crossover channels or specially designed reaction vessels.

(a) The agreed positions for the apertures for the cofferdam entry points should be clearly marked and burnt or cut out taking precautions to protect surrounding equipment with heat resistant blankets etc. A stand-by fire extinguisher and fire sentry should be provided.

(b) The mating flange to receive the anode and cofferdam flange should be welded in position with continuous welds on both inside and outside joints and inspected by the relevant certifying authority at the time of installation.

(c) To provide a connection point for the negative return, a screw or suitable alternative connection can be welded onto the sea chest mounted flange or to any other convenient location in direct and continuous electrical contact with the sea chest or hull to obtain a zero resistance connection.

(d) All weld scales should be removed and any damaged paint work reinstated.

(e) Lift cofferdam at flange using 2 x eyebolts supplied.

Carefully lift the anode & cofferdam assembly and lower the anode into the sea chest or strainer. Ensure that the cofferdam flange lines up correctly with the mating flange welded to the hull and making sure that the rubber gasket is in the correct position. Evenly tighten down the anode cofferdam flange nuts taking care not to exceed the maximum rating of 244 Nm.

(THE PROCESS IS REPEATED FOR ALL ANODES)

Note: All threaded sections of nuts, bolts and the cofferdam lid must be lightly coated with marine lubricant.

(f) Remove the eyebolts and store for further use.

(g) Make the negative cable connection onto the welded flange. AFTER making this connection, the stud and nut assembly should be completely covered with a light coating of Marine Lubricant.


(h) Secure anode cables and negative single cable together and take back for connection in the junction box.

Anode Type Cofferdam Colour Cable Colour

WW Cuproline Blue RedWW Aloline Silver Grey BlackWW Ferroline Black Black

Note: Cable colour scheme is indicative only and refers only to Corrpro Companies (Europe) Ltd. standard supply cable. Where client specified cable is supplied it may not be possible to match this colour scheme.

(i) When vessel is afloat, carry out leakage tests by checking for ingress of water into the cofferdam.

3.4 Anode Replacement Procedure

Power to the anodes must be switched off before carrying out the following procedure. Vessel must be in dry dock or the sea chest completely sealed off to prevent ingress of water.

(a) Loosen cable gland located on top of the cofferdam lid.

(b) Unscrew cofferdam lid and slide along the cable until the lid is clear of the cofferdam.

(c) Disconnect the cable from the anode support stud. Secure cable and lid safely.

(d) Secure two (2) lifting eyes to cofferdam flange assembly.

(e) Remove the eight (8) cofferdam flange securing nuts.

(f) Carefully lift out the anode/cofferdam assembly.

(g) Remove the lock nut and main securing nut from the support stud. Carefully remove all accompanying washers.

(h) The cofferdam can now be separated from the anode.

(i) Ensure that the cofferdam is clean and then fit to the new replacement assembly.

(j) Replace washers in correct sequence and secure cofferdam with nuts supplied. The main securing nut should set to a minimum torque of 100 lbs./ft.


(k) Using a suitable test meter ensure that the anode is electrically isolated from the cofferdam mounting.

(l) Locate complete assembly in the sea chest and secure with the eight (8) cofferdam flange nuts. Ensure gasket is in position and tighten down evenly.

(m) Connect anode positive cable, re-fit lid and tighten cable gland.

A specific data sheet for each vessel stating anode sizes, locations and operating conditions is provided (Section 7.0). This data sheet is for completion on board by the vessel’s engineers after installation and testing of the equipment has been carried out. All anodes are designed with a +20% margin allowing for overrun and higher current settings if required.


4.0 COMMISSIONING AND FAULT FINDING

4.1 Commissioning

(ONLY TO BE CARRIED OUT WHEN THE VESSEL IS AFLOAT)

a) Check all cable connections at power control unit, terminal box and anodes.

b) Identify each positive output and relevant anode, and record the same.

c) Switch on AC supply and then the panel on/off switch.

e) Adjust output to the recommended current values on each anode.

4.2 Fault Finding

FAULT PROBABLE CAUSE REMEDIAL ACTIONLCD display on one module fails to illuminate.

Faulty module. Exchange module with another that is known to be working. If fault remains on original module, return to manufacturer for replacement

Anode current reduces to zero output and a warning symbol ∆ appears.

1. Break in electrical circuit with anode.

Check continuity of circuit Repair as necessary.

2. Anode Consumed Replace as necessary

LCD displays on all modules fail to illuminate. Power on LED remains illuminated.

Blown control fuse. Check internal fuses and replace as necessary.

LCD displays on all modules fail to illuminate. Power on LED fails to illuminate.

1. Blown power supply fuse. Check internal fuses and replace as necessary.

2. Power supply failure. Check power supply.

Bio-fouling growing in sea water cooling system.

Incorrect current output settings.

Check settings and adjust as necessary.


5.0 OPERATION & DISPLAYS

Each Mk IV plug-in module controls two individual output channels. The Mk V and VI models have a fixed number of output channels with displays configured in the same way as the modular units.

The new style Power Module has a new look front plate that comprises of a graphic LCD display and four control buttons. The buttons function left to right as follows:

Function : Symbol

“Cancel” or “Exit Menu” “Up” or “Increase” “Down'” or “Decrease” “OK” or “Enter”

The Main Screen.

On initial power up the LCD will display the manufacturers logo for a period of 4 seconds, or until any function button is pressed. The display will then default to the main indicator screen, which shows actual current on both output channels with channel 1 at the top and channel 2 below.

To the right of the current digits there is an indicator icon which in normal condition shows the anode material identifier. This identifier can be set to show “Cu” for Cuproline, “Al” for Aluminium or “Fe” for Ferrous on either channel. A fourth option exists should only one output channel be required to operate on a module and selecting “BLANK” for either channel from the anode identification menu will remove the output reading from the main display.

The Set Current screen.

From the main screen pressing the “ENTER” button allows the user to set the desired anode currents. At the first press of the “ENTER” button the word “SET” will appear next to channel 1, and the user can use the “UP” and “DOWN” buttons to increase or decrease the desired value. If a button is held down it will accelerate the increase or decrease count.

If no other button is pressed for 4 minutes or the “CANCEL” button is pressed next the display will return to the main screen.

Pressing the “ENTER” button a second time will result in the word “SET” appearing next to channel 2. The desired current can then set for channel 2 in the same way as for channel 1

Pressing “ENTER” again will advance to the status menu.

The Status menu screen.


This screen will display a menu of three items, “OPTIONS”, “HOUR COUNTS” and “VOLTAGES”. The module software version is also displayed in the bottom right corner of the screen.

The user can move through the menu using the “UP” and “DOWN” buttons to highlight each menu item and then press “ENTER” to select the function.

Pressing “CANCEL” or not pressing a button for 4 minutes will return to the main screen.

The Options menu

The Options menu shows a further five items to allow the user to set the shutdown current percentage, material identifier and shutdown input.

In each of the Shutdown screens the “UP and “DOWN” buttons can be used to set the percentage of the normal current that should flow when the module shutdown input is connected to ground or the manual shutdown is selected. Pressing “ENTER” is required to confirm changes. “CANCEL” will discard the changes and return to the Options menu.

In each of the Anode ID screens the “UP” and “DOWN” buttons can be used to select the anode material from one of “Cu” for Copper, “Al” for Aluminium, “Fe” for Ferrous or “BLANK” for no display. Pressing “OK” is required to confirm changes. “CANCEL” will discard the changes and return to the Options menu.

In the Shutdown Input screen the “UP” and “DOWN” buttons can both be used to toggle the shutdown input between “SIGNAL” and “MANUAL” to select either the volt-free contact signal input or manual shutdown control.

The Hour Count screen

The hour counters show four items. All are accurate to 1/10th hour (6 minutes).

Line 1: shows the total number of anode run hours since the last reset.Line 2: shows channel 1 total Ampere hours since the last reset.Line 3: shows channel 2 total Ampere hours since the last reset.Line 4: shows the total module hours run since manufacture and can not be reset.

When the anodes are replaced the user can enter this screen and pressing both the “UP” and “DOWN” buttons simultaneously will reset the anode counters. Pressing “CANCEL” will return to the Status menu.


The Voltages screen

This screen shows anode voltages, the module internal temperature and the total power consumption for that module. Voltages are accurate to 0.1V, the module temperature is accurate to 5C and the power is in watts.

Pressing “CANCEL” will return to the Status menu.

Shutdown Operation

Each module can be set to respond to either manual control or a remote input signal.

If “Manual” shutdown mode is selected then the “UP” and “DOWN” buttons can be used to go between normal operation (UP) and shutdown mode (DOWN).

If “Signal” shutdown mode is selected then the module will only respond to an external input signal such as “pump running/pump stopped”. In this mode “UP” and “DOWN” for selecting between normal running and shutdown are disabled

The selected setting is stored even if power to the module is removed.

Abnormal Condition

In abnormal condition a warning symbol is “∆” displayed. This warning icon will show if the set output current on a channel cannot be maintained or if the total power consumption for the module exceeds the maximum safe value rated at 57W per module.

If the power limit is exceeded for more than 8 seconds the warning icon will appear next to both channels, and the module will reduce the output current for each channel to 35% of the set value. The module will stay at a reduced output for a period of 4 minutes, or until “CANCEL” is pressed. The module will then attempt to return to 100% of the set current value. If the power limit is exceeded again it will cycle in this way until the problem is removed.

Remote CAN control

Each module has a CAN bus network interface brought out to the backplane connector enabling monitoring and control through another linked anti-fouling unit, a remote terminal or even PC interface. The module transmits data onto the bus every second, giving information on each anode current, voltage, power and temperature. The module can also be commanded to output a specific current which overrides but does not alter, the module stored set current.

6.0 MAINTENANCE


The maintenance requirement for the Anfomatic system is minimal. The system operates at constant current output and does not therefore require adjustment unless the operational requirements specifically require regular adjustments to be made.

A weekly recording of current outputs on each anode is recommended for which a log sheet is provided as enclosed.

This provides a record of the system's operation, an indication of any changes in function and a reminder when anode replacements are scheduled.

A complete loss of current on any anode should be investigated by checking all cable connections, power panel fuses or by interchanging modules.

Regular electrical maintenance should be carried out according to the operators own procedures and planned maintenance system.

Anodes should be replaced at the end of their designed life span or during each dry docking of the vessel according the procedure laid down in the manual.


7.0 SPECIFIC VESSEL DETAILS

(To be completed on board at time of commissioning by appointed engineer)

PROJECT REFERENCE NUMBER

VESSEL NAME

INSTALLATION DETAILS

POWER CONTROL UNIT

AC INPUT CABLE

PANEL EARTH CABLE

JUNCTION BOX

POSITIVE ANODE CABLE

NEGATIVE CABLE

ANODE LOCATIONDIAMETER/SIZE CURRENT SETTINGS

7.0 SPECIFIC VESSEL DETAILS.....Cont.


PROJECT REFERENCE NUMBER

VESSEL NAME

INSTALLATION DETAILS

INSTALLATION DATE/LOCATION

OPERATION PERIOD

ORDER DATE FOR REPLACEMENT ANODES

OTHER RELEVANT INFORMATION / ENGINEERS COMMENTS


8.0 LOG DATA SHEET

See over.


Anfomatic System Log

Adam Street, Bowesfield LaneStockton on Tees, Cleveland. TS18 3HQTelephone (01642) 614106 (8 lines)Telex 587388Fax (01642) 614100

Vessel Ship Owner Month CPU Serial Number

Anode Amperage Reading Anode Location

Week 1 Week 2 Week 3 Week 4 Week 5

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

"A Commitment to Excellence"

CorrproCompaniesEurope Limited


9.0 NOTES


9.0 NOTES…..Cont.


10.0 SPARE PARTS LIST

ITEM: Part. No.

Power Unit:

Power Unit Complete State CPU serial No.

CPU Step Down Transformer AN-CPU(TR1)Module Transformer. AN-CPU(TR2)Plug in Module. AN-CPU(M)Power Failure Relay Kit AN-CPU(PFA)Door Key AN-CPU(K)3 Amp Fuse AN-CPU(F3)5 Amp Fuse AN-CPU(F5)Indicator Lamp Bulb AN-CPU(IL)

Anode Installation Mountings (AM 1500):

Cofferdam AN/CD-1500Cofferdam Lid AN/CD(L)-STDMounting Boss AN/CD(MB)-STDMounting Boss Gasket AN/G-MB“O” Ring Seal AN/G-OXM.16 Galvanised Stud AN/ST(MB)-M16M.16 Galvanised Nut AN/NF-M16M.16 Galvanised Washer AN/WF-M16Cable Gland M.16 entry AN/CG-M16

Anode Installation Mountings (AM 1211/1):

Cofferdam AN/CD-SBCofferdam Lid AN/CD(L)-SBMounting Boss AN/CD(MB)-SB Mounting Boss Gasket AN/G-MB(SB)“O” Ring Seal AN/G-OXM.12 Galvanised Stud AN/ST(MB)-M12M.12 Galvanised Nut AN/NF-M12M.12 Galvanised Washer AN/WF-M12Cable Gland M.16 entry AN/CG-M16


Anode Installation Cables:

Positive Anti-fouling Anode Supply Cable (5 meter) CXP006RPositive Anti-corrosion Anode Supply Cable (5 meter) CXP006B

The Following Items supplied as part of complete or replacement anode assemblies:

Heat Shrink Sleeve AM1500/4Nitrile Gasket AM1500/6Rigid PVC Washer AM1500/7Rigid Sleeve AM1500/8Phenolic Resin Washer AM1500/9Galvanised Washer AM1500/11Galvanised Full Nut AM1500/12Galvanised Lock Nut AM1500/136mm2 X M.8 Brass Terminal AM1500/14High Tensile Support Stud AM1500/23Galvanised Spring Washer AM1500/24M.8 Brass Screw & washer AM1500/25

Replacement Anodes:

State either three letter identifier code (e.g. AM1501-SJT) or anode dimensions & material.


11.0 DRAWING SCHEDULE

1. AM 1366 Typical Installation

2. AM 1164 Anfomatic General Arrangement

3. AM 1528 Modular Controller Power Unit Mk IV (2-10 channels)

4. AM 1529 Modular Controller Power Unit Mk IV (12-20 channels)

5. AM 1521 Modular Controller Power Unit Mk V (4 channels)

6. AM 1522 Controller Power Unit Mk VI (2 channels)

7. AM 1528-1 Modular CPU Terminal Connections (Mk IV units only, 2-10 channel)

8. AM 1529-1 Modular CPU Terminal Connections (Mk IV units only, 12-20 channel)

9. AM 1521-1 Non-Modular CPU Anode Connections (Mk V unit)

10. AM 1522-1 Non-Modular CPU Anode Connections (Mk VI unit)

11. AM 1500 Anode General Assembly.

12. AM 1501 Anode General Arrangement

13. AM 1211-1 General Arrangement (75mm dia. and smaller)

14. AM 1513 Junction Box Detail Type 1 (2 Anodes)



17. AM1376-1 Plug In Module General Assembly

AM 1503 Replacement Anode – Electrode Detail (General).

Documents

Anfomatic Instruction Manual Rev 8.1