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Wind Turbine Design and Implementation Final Design Report
Team Members: Pranav Boda Fairman Campbell Jennifer Long MIlki Wakweya Advisor & Client: Dr. Venkataramana Ajjarapu DISCLAIMER: This document was developed as a part of the requirements of an electrical and computer engineering course at Iowa State University, Ames, Iowa. This document does not constitute a professional engineering design or a professional land surveying document. Although the information is intended to be accurate, the associated students, faculty, and Iowa State University make no claims, promises, or guarantees about the accuracy, completeness, quality, or adequacy of the information. The user of this document shall ensure that any such use does not violate any laws with regard to professional licensing and certification requirements. This use includes any work resulting from this student-prepared document that is required to be under the responsible charge of a licensed engineer or surveyor. This document is copyrighted by the students who produced this document and the associated faculty advisors. No part may be reproduced without the written permission of the senior design course coordinator.
12/11/2009
2
Table of Contents Pg.
1. Introduction 4
1.1 Executive Summary and Problem Statement 4
1.2 Proposed Solution 4
1.3 System Description 4
1.4 Operating Environment 5
1.5 Intended User and Uses 5
1.6 Risks 5
1.7 Market & Literature Survey 6
2. Design 7
2.1 System Requirements 7
2.1.1 Functional Requirements 7
2.1.2 Non- Functional Requirements 7
2.2 Concept Sketch 8
2.3 System Block Diagram 9
2.4 Component Design 9
2.4.1 Air-X Turbine 9
2.4.2 Outback Inverter 10
2.4.3 Battery Bank 10
2.4.4 Sensing Circuits 12
2.5 Interface 13
3. Implementation and Testing 17
3.1 Turbine, Battery and Inverter 17
3.2 Sensing Circuits 18
3.3 Interface 18
3
3.4 Sensors and Interface 18
3.5 Entire System 18
4. Deliverables 19
5. Financial Details 19
5.1 Earned Value Analysis 19
5.2 Material Cost 20
5.3 Financial Report 21
6. Work Breakdown 22
7. Lessons Learned and Conclusions 23
Appendix 24
4
1. Introduction
1.1 Executive Summary and Problem Statement
In 2008, President Geoffrey introduced the Live green program, which called for environmentally
conscious living. In light of this initiative, it was decided to actively assemble a wind turbine that would
supply power to Coover hall and reduce our carbon footprint.
The goal of our project is to install and implement a wind turbine system into the Coover Hall grid. The
project also includes making the necessary circuits to make the power generated by the turbine gird
compatible. In addition to this, we will measure various parameters and display them via a visual
interface developed by us. The purpose of the project s is to make a functional system which has
practical value and also educational value.
1.2 Proposed Solution
In response to the goal of the project we decided to make this project an on-going project. The system is
designed to produce 1200 watts when all phases are completed but during our phase, the output will be
400 watts. The turbine is an AIR X permanent magnate generator. The inverter is an OUTBACK grid tie
inverter with a capacity of 2500VA. Our design is focused on sensing and outputting values from the
circuits and the interface created by our team.
1.3 System Description
The Air-X wind turbine has a permanent magnetic alternator that converts wind energy into mechanical
motion. The generator then converts mechanical motion into electrical power. The alternator provides
variable frequency and variable AC power, after this it will go into a rectifier that will convert it to DC
power of approximately 24V. After the turbine, there will be a fuse that protects the turbine if the
current is too high, and after it went through the fuse there should be a switch that turn on and off.
Once it goes through fuse and switch, it will go through the battery bank. The battery bank consists of
two 12V batteries in series. On the output of the battery bank is the input of the inverter. The inverter
will take a 24V DC voltage and convert it to AC 120V at a frequency of 60Hz. Then, the power from the
inverter goes into the solid-state relay. The capacity sensor is on the output of the batteries and
measures the voltage across the battery, and goes to the control input on the solid-state relay. When
the voltage across the battery drops below 23VDC, it will send a signal to the relay to disconnect the
inverter from the load. The solid-state relay acts like a switch, and has a DC control input from 5.5V-
10V. After the solid-state relay, the AC power is fed directly to the Coover Hall grid or to an
independent load. There will be a current sensor and voltage sensor on the output of the turbine. After
the inverter, there will be a current transformer, and it will go into the AC current sensor. We used an
independent load like an induction motor that is located in a power lab, or we will connect it to AC load
5
Coover power grid. In the appendix, is a detailed diagram of our system. The AC current, DC voltage,
and DC current are all measured, and are inputs to the NI DAQ 6008. The NI DAQ 6008 then goes to the
LabView interface.
1.4 Operating Environment
The turbine will be mounted above Coover Hall. It will be subjected to all the elements of Iowa's
weather. The extremes of Iowa's weather are ice, wind, rain, heat, and lightning. The turbine itself
should be able to withstand all of Iowa's weather but the inverter and battery bank will need to be in a
controlled environment. The battery bank in particular will need a specific temperature range to be
most effective. This is why both the inverter and battery bank will be placed indoors.
1.5 Intended Users and Uses
The turbine will be mounted on the Coover Hall roof. The turbine will service Coover Halls electrical grid
and will be used by Iowa State Electrical and Computer Engineering faculty and students. The turbine
can be used for research within the university along with undergraduate students for class work. Using
the LabView interface users can view the power generated in the past. This design will also serve as a
useful educational tool and will enhance one’s learning experience.
1.6 Risks & Solutions
1. The tower mounted can’t withstand the high wind speed
a. Tower will be mounted by professional
2. Battery bank suffers complete discharge
a. Inverter has a charger to prevent total discharge
b. Capacity sensor will disconnect inverter from the load when batteries get too low
3. Battery bank suffers overcharge
a. Turbine has controller that will not allow overcharging
4. LabView interface gets outdated and not sufficient
5. Will not have the turbine mounted on the roof for IRP
a. Build stand in Coover 1102, and use drill to power turbine
6. Components won’t be installed in time
6
a. Assemble mock setup in Coover 1102
7. Will not be able to hook up to Coover Hall power grid
a. Create a load dump or alternate load to test design on
8. LabView interface gets outdated and insufficient
a. Update the interface and excel file. Expand its function
1.7 Market and Literature Survey
In today’s world, the need for alternative, environmentally friendly energy generation has never been
greater. The Department of Energy (DOE) has set plans and taken the initiative to have wind energy
account for 20% of total energy generation or 300GW by capacity in the United States by 2030. This
would cause a huge increase in demand for more efficient wind turbine designs to maximize energy
generation while minimizing losses.
7
2. Design
The focus of the project was to erect the turbine and design sensing that would output values from the
system along with a safe work environment for those working with the system.
2.1 System Requirements
The system comprises of Functional and Non-functional requirements that were to be met in this
project. These requirements are listed below.
2.1.1 Functional Requirements
1. Produce 400 watts of electrical energy to the Coover Grid at 120 volts with a 60 Hz frequency
2. Convert turbine DC voltage to useable AC voltage
3. Sensing circuits read DC and AC voltages and currents
4. Sensing circuits send information to display on a computer using LabView
5. Protect batteries from total discharge
6. Turbine is mounted high enough to receive non turbulent wind
2.1.2 Non-Functional Requirements
1. All wiring and electrical work complies with university and state electrical codes and regulations
2. Battery bank is in controlled temperature and stable environment
3. Tower mounting complies with building standards
4. Turbine is mounted high enough to allow maintenance to walk under turbine
8
2.2 Concept Sketch
Fig-1
9
2.3 System Block Diagram
Fig-2
2.4 Component Design
The system comprised of purchased and designed components. The component design is comprised of
the Air X turbine, Outback Inverter, Battery Bank, and sensing circuits.
2.4.1 Air X Turbine
The Turbine we chose to purchase is the AIR X from Southwest power. The picture of the turbine can be seen in the Appendix. The reason we chose this particular turbine was a combination of cost and functionality. The turbine itself cost $700 and produces 400W, at peak power at 28 MPH of wind speed. The power curve can be seen in the Appendix. It produces this power by using a permanent magnet alternator. The power from this alternator is converted from AC to DC with inverter inside the turbine housing. The turbine can output 12 or 24 VDC. We will have the turbine output 24V due to the high current that is produced at 12 VDC. For the functionality side we chose the AIR X because of its control of generator in the turbine. The control will stop the turbine when the wind speed is too great. The Rotor Diameter of the turbine is 46 inches. The start up speed is 7 MPH. The total weight of the turbine including blades is 13 lbs. The diagram of the dimensions of the turbine can be seen in the Appendix. The control will also shut down the turbine when the battery bank is at full charge, protecting the batteries from overcharge. We plan to mount the turbine to the side of Coover to eliminate a major tower design and to increase ease of construction. The wire coming down the side of Coover Hall will be 10-AWG wire. The turbine requires batteries to work properly. If there is no load attached to the
10
turbine, then the positive and negative leads on the turbine must be shorted together. If attached with no load, it can cause permanent damage.
We began our search looking at three different turbines. We decided the Air X was the best turbine because it offered the best cost to benefit ratio. The benefits of this turbine are that it is light, relatively small, and controls mechanical failure due to high winds. The cons for this turbine are that it does not come with any type of tower set up as well as an inverter circuit with a display interface. Below is a table for the different turbines that we looked at using. In the appendix, there is a power curve for the turbine, and an exploded view of the Air X Turbine. In the appendix the dimensions of the turbine are given. There is also a picture of the Air X Turbine.
Turbine Watts Display Interface
Inverter Controller Turbine Type Cost
Whisper 1000 900 W Yes (optional) Included Speed/ Battery Protection
Permanent Magnate
$ 2100
AIR X 400 W NO Not Included
Speed/ Battery Protection
Permanent Magnate
$700
Wind Max 500 W NO Not Included
Speed Permanent Magnate
$500
2.4.2 Outback Inverter
For our project we are using a Outback GTFX2524 inverter. This inverter is capable of taking 2500VA of
input and converting it to 120VAC at 60 Hz. The inverter inputs a nominal DC voltage of 24 VDC with a
range of 21.0 to 34 VDC. The idle power that inverter will take is 20 Watts. The inverter has an efficiency
of 92 percent at 25 Celsius. Continuous AC RMS output is 20.8 amps AC with a peak of 70 amps AC. The
inverter has an AC overload capability of 6000 VA. It’s sealed with a weight of 56 lbs. and is 13 x 8.25 x
16.5". A picture of the Outback GTFX2524 can be seen in the appendix.
2.4.3 Battery Bank
The battery will supply a power to the inverter and to the control system. Also, battery has to be fully
charged at all time and the battery bank is expandable so that we can add more batteries to it in the
future. For this project we are using flooded lead acid battery.
For this project we are using 24volt battery, we bought two 12 volt flooded lead acid batteries and we
are connecting them in series to make it 24 volt.
11
Flooded Lead Acid Battery: Wet Lead Acid or flooded lead-acid batteries are the most commonly used
batteries to store electrical power.
Battery (24volt battery)
Type: Flooded Lead acid Battery
Two 12 Volt Batteries
200 Ah
Fig-3
12
2.4.4 Sensing Circuits
DC Current Sensor
The DC current from the turbine is measured by using a DC current transducer. The current transducer is made by LEM. It is rated at ±70A. This sensor will measure the current after the fuse. The sensor will output a current of50mA when the input current is 50A. The current transducer has a 1:1000
conversion ratio. On the output of the DC current sensor, there is a 100Ω, 1/4W resistor. The current
sensor has and ±15V rail is needed for the sensor to run. The voltage is measured across the resistor, and is then connected to the NI DAQ 6008, and then displayed on the interface. This sensor has low power consumption, and can handle up to 8-gauge wire. The high current never has to touch the board, so large traces are not necessary. In the appendix, there is a copy of the specifications of the LEM component.
DC Voltage Sensor
The DC voltage sensor measures the voltage coming out of the turbine. The input should be approximately 24VDC. The DC voltage sensor consists of two resistors in series. It divides the voltage from 24VDC to 5VDC. The resistor values are 100kΩ, and 390kΩ. The resistors are ¼W resistors. The voltage is measured in parallel with the output of the turbine. The power loss is less than 50mW. The output voltage is measured across the 100kΩ resistor.
AC Current Sensor
After the inverter, there is a current transformer. The purpose of the current sensing circuit is to determine the AC current of the system. The current transformer steps down the current from 10A to 20mA. The circuit is used to ensure that the current limit of the NI DAQ 6008 is not exceeded. The current sensing circuit takes the output from the current transformer, and rectifies the signal into DC. The rectified DC is then filtered by the low-pass filter. Then the signal is amplified with an inverting op-amp.
The current transformer has a 1:500 conversion ratio. The Foster Transformer Company manufactures it. It has a rated current input of 0.1A-30A. The voltage output is 100mV/A. On the output of the current transformer, we added a 50Ω resistor. We wanted to obtain a 5VAC to go to our current sensing circuit. In the appendix, there are the data specifications of the Foster Transformer.
The current sensing circuit consists of a full-wave precision rectifier circuit. The precision rectifier consists of two op-amps, two diodes, and six resistors. The precision rectifier converts the AC input into a DC output. The output of the rectifier has quite a bit of ripple, so it needs to be filtered. Next, there is a low-pass filter. The low-pass filter consists of a 10kΩ resistor, and a 22μF capacitor. After the low-pass filter, the voltage is only 3.2V, and the NI DAQ 6008 has an input range from 0-5V. To boost the
voltage up to 5V, there is an inverting op-amp circuit. The op-amps have rails of ±15V. In the appendix, there is the circuit diagram of the current sensing circuit.
13
Capacity Sensor
After the battery bank, a voltage divider steps down the battery voltage between zero and five volts. A Schmitt trigger compares the voltage. When the battery voltage drops below 22.5VDC, the output of the Schmitt trigger goes low. The output of the Schmitt trigger goes high again when the battery voltage is above 24VDC. The output goes into the control input of the solid-state relay. The solid-state relay is a switch that connects the inverter to the load. The circuit is used to ensure that the batteries are not depleted too far. If the batteries become too discharged, it can cause irreversible damage to the batteries. In the appendix, there is the circuit diagram for the capacity sensor, and the data sheet for the solid-state relay.
A Schmitt trigger is a comparator circuit that incorporates positive feedback. When the negative input is higher 23VDC, the output is high; when the input is below 22.5VDC, the output is low; when the input is between the two, the output retains its value. The comparator we are using is the LM311. The Schmitt trigger’s VCC of +15V, and –VCC =0V.
Electrol manufactures the solid-state relay. The solid-state relay needs a heat sink to dissipate the heat, so the metal box will be the heat sink. The solid-state relay has a 10A, 230VAC rating. The DC control input for the relay is from 5.5V-10V. In our system, the control input is 7.4VDC. The relay should only see a 9.8VDC or 0VDC. To connect the relay to the system, it has quick connected clips on top of the relay. Below is a picture of the relay.
Fig-4 http://cgi.ebay.com/ws/eBayISAPI.dll?ViewItem&item=310060201690&rvr_id=&crlp=1_263602_263622&UA=WXF%3F&GUID=70a2d5b11250a0e2027063c0ffaad080&itemid=310060201690&ff4=263602_263622
2.5 Interface
The interface used in the project was developed using LabView through a NI 6008 data acquisition
device (DAQ). The DAQ takes its inputs from the sensors. The DAQ then connects to a computer or
laptop via a USB. The interface developed will display real time values of the chosen parameters by
reading them continuously. These values are then automatically stored in a spreadsheet for future
14
reference. Below are screenshots of both the system block diagram as well as the front panel of the
interface.
Fig-5
As we can see due to the size of the block diagram, it was necessary to break it up into multiple
screenshots in order to include the entire diagram. In the first screenshot above, we are taking an input
via the task created (pranav_task), which goes through the DAQ start and the while which is then
connected to the DAQ READ.vi function. This tool reads in the values inputted via the NI 6008 USB
control. Once the samples itself are read in through the different channels, it is upto us to sort through
them and display our chosen values. This was accomplished using an index array. Using this array we
were able to read in multiple channels in one task. The first array displays the battery voltage in three
forms: numeric indicator, numeric meter and as a waveform plotted against time. The second array
outputs a DC voltage which is then converted to a DC current. This DC current is then displayed in the
formats as before. The third array displays the output DC voltage in the three formats specified above.
The final array outputs a voltage which depending the turns ratio is converted to a an AC current which
is again displayed as before. In addition to these measurements we also calculated the instantaneous
power by simply using a multiplication function from the functions palette and multiplying the DC
voltage and the DC current.
15
Fig-6
Now that we have our various voltages , currents and power calculated and displayed, we move on to
writing these values to a spreadsheet. The figure above shows us two of the three while loops created in
order to efficiently and accurately display the values in a spreadsheet. Each loop displays a date/time
stamp to keep track of the different power generation values throughout any given day. Note that at the
top left side of the screenshot we used a file dialog to specify the selected path.
16
Fig-7
Below is a sample of our output displayed in the spreadsheet mentioned. As we can see the date/time
stamp is displayed in addition to the output power.
Fig-8
17
Also included below is the front panel of our project which would be what the user would view when
running the program. Each of the parameters is displayed in the three forms.( numeric indicator,
numeric meter and as a waveform plotted against time).
Fig-9
3. Implementation and Testing
3.1 Turbine, Battery, and Inverter
Turbine & Batteries
To test the turbine and batteries, we connected them together, and attached a drill to the rotor of the turbine. The blades were taken off for protection when using the drill. Then, a torque was applied at different RPM’s to determine the output power. We measured the current and voltage, and then multiplied the two outputs together to get the instantaneous power. We used a 1000-RPM drill, and it produced only 40W. When the turbine is running, the blades are hard to see.
We tested the batteries by hooking it up to a load or the wall outlet to make sure it discharged. The batteries were then attached to any power supply to make sure it charges. We used a voltmeter to test the actual voltage of the battery.
We tested the Outback inverter by hooking the battery bank to the input of the inverter, and attached a single-phase AC motor as the load. Then we measured the voltage of the system to ensure that the DC is fully converted into AC. Then the load was increased to ensure that the batteries would supply the increased load.
18
3.2 Sensing Circuits
Sensors To test the sensors, we used power supplies as inputs, and used an oscilloscope to measure the outputs. Then the outputs were verified to ensure that the sensors were accurately working. When soldering the circuits to the board, a multimeter was used to check connectivity of each line. The output of the DC current sensor was between 0-5 volts depending on the amount of current passing through the circuit. The output of the DC voltage sensor is around 5VDC. The output of the AC current transformer is between 1.1A-1.5A. The output of the current sensing circuit was 30mV. The oscilloscope output readings of the sensors are shown in the appendix. Capacity Sensing Circuit & Relay To test the battery capacity circuit, a LED was used as the output to verify that the capacity of the batteries is being read properly. When connected to the solid-state relay, the control input was varied to ensure that the control input goes on/off. The output of the capacity sensor will remain high until the battery voltage drops below 23V. The capacity sensor will remain low until the battery voltage rises above 24V. The relay should only see a 9.8VDC or 0VDC. Then, we verified that the comparator circuit would break the power going to the load. When soldering the circuits, a multimeter was used to check connectivity of each line. The oscilloscope readings of the capacity sensor are shown in the appendix. 3.3 Interface
While testing the interface, we used the LabView compiler to verify our design. We also tested and
verified our results using DC and AC power supplies in the labs. To ensure that the system as a whole
runs smoothly, we used and tested the interface in conjunction with the turbine and sensing circuits and
eliminated any glitches and minor errors.
3.4 Sensors & Interface To test the sensor together, attach all the control components to a power supply to ensure that there is no interference with each other. Then a 24VDC, 8A supply was used to test the DC sensors and comparator circuit. In addition, a 120VAC, 5A supply was used to test the AC sensors. To test the sensors and the LabView interface together, they are connected through the NI DAQ 6008. Then the program was started, and each output was verified. 3.5 Entire System
To test the entire system, we connected the turbine, battery bank, inverter, sensors, and LabView
interface together. Then, a drill was applied to the rotor of the turbine, and the interface was
monitored to ensure that all the sensors were reading the values correctly. The drill speed was
increased and checked that the DC power went up accordingly. The LED on the capacity circuit was
monitored to ensure that the relay will disconnect the load from the inverter when the battery voltage
becomes too low.
19
4. Deliverables
These are the project deliverables:
AirX turbine capable of producing 400 Watts
Outback inverter capable of converting 2500VA of DC to AC
Sensing circuitry that can sense DC and AC voltage and current
LabView interface which takes its inputs from the sensors
LabView data is stored in an Excel spreadsheet for future reference
5. Financial Details
5.1 Earned Value Analysis
T-2
Team Member Semester-1 Earned
value
Semester-2 Earned
value
Total Earned value
Pranav Boda $15*89 $15*57.50 $2200
Fairman Campbell $15*85 $15*76.50 $2422
Jennifer Long $15*87 $15*79.50 $2460
Milki Wakweya $15*80 $15*44.50 $1867.50
20
5.2 Material Cost
Fig-10
21
5.3 Financial Report
Fig-11
22
6. Work Breakdown
Schedule (Semester 1)
Fig-12
Schedule (Semester 2)
Fig-13
23
7. Lessons Learned and Conclusions
The first lesson we learned in this project was the fact we needed to decide on a plan at the beginning
and stick with it. There was far too much indecision to make this as productive as it needed to be. Funds
for this project needed to procured more quickly and this was a major setback. The group needed to
have a full scale plan for no funding. Once funding was procured the project costs were not assessed
correctly and we were found to be vastly under budget. In conclusion, this project had a very large
upside that will be seen in later continuations. The group as a whole preformed well given the situations
and was able to produce something that can be built on in the future.
24
APPENDIX
Fig-14
Turbine Dimensions
25
Fig-15
Exploded View of Air X Turbine
Fig-16
Fig-17
http://www.tande.com.tw/rn-wg-manual/airxland-manual.pdf
26
Air X Turbine
Fig-18
27
Outback Inverter
Fig-19
28
Entire System Testing
Fig-20
29
Sensor Circuit Diagram
Fig-21
Sensor Testing Oscilloscope Outputs DC Voltage Sensor
Fig-22
R9
10k
0
R2
10k
0
R4
20k
V2
20
0
V3
20
U6
uA741
3
2
74
6
1
5+
-
V+
V-
OUT
OS1
OS2
0
U4
uA741
3
2
74
6
1
5+
-
V+
V-
OUT
OS1
OS2
0
R1
10k
R11
30k
0
V4
20
R3
20kV1
20
D17
D1N914
0
U3
uA741
3
2
74
6
1
5+
-
V+
V-
OUT
OS1
OS2
0
0
V5
20Vdc
C1
22u
D18
D1N914
R5
10k
0
0
V12
FREQ = 60VAMPL = 5
VOFF = 0
V6
20Vdc
R8
10k
0
R10
390k
R7
100k
V7
24Vdc
V1
0Vdc
V215Vdc
V63.67VDC
U1
LM311
OUT7
+2
-3
G1
V+
8
V-4
B/S6B
5
0
0
R1
10k
R2
2.2k
0
0
R3
1k
0
0
0
R4
300
R5
1k
V7
22
R6
1k
R7
1k
0
V
AC
Current
Sensor
Battery
Capacity
Circuit DC
Voltage
Sensor
30
DC Current Sensor
Fig-23
AC Current Sensor (After Rectifer)
Fig-24
31
AC Current Sensor (Output)
Fig-25
Capacity Sensor
Fig-26
32
LEM 55-p DC Current Sensor
Fig-27
33
NI 6008 USB
Fig-28
Specifications:
8 analog inputs (12-bit, 10 kS/s)
2 analog outputs (12-bit, 150 S/s); 12 digital I/O; 32-bit counter
Bus-powered for high mobility; built-in signal connectivity
OEM version available
Compatible with LabVIEW, LabWindows/CVI, and Measurement Studio for Visual Studio .NET
NI-DAQmx driver software and NI LabVIEW SignalExpress LE interactive data-logging software
34
Foster Transformer: Current Transformer Data Sheet
Fig-29
35
List of Figures and Tables Figures: Fig-1 Pg: 8 Fig-2 Pg: 9 Fig-3 Pg: 10 Fig-4 Pg: 11 Fig-5 Pg: 13 Fig-6 Pg: 14 Fig-7 Pg: 15 Fig-8 Pg: 16 Fig-9 Pg: 16 Fig-10 Pg: 17 Fig-11 Pg: 20 Fig-12 Pg: 21 Fig-13 Pg: 22 Fig-14 Pg: 22 Fig-15 Pg: 24 Fig-16 Pg: 24 Fig-17 Pg: 25 Fig-18 Pg: 25 Fig-19 Pg: 26 Fig-20 Pg: 27 Fig-21 Pg: 28 Fig-22 Pg: 29 Fig-23 Pg: 29 Fig-24 Pg: 30 Fig-25 Pg: 30 Fig-26 Pg: 31 Fig-27 Pg: 31 Fig-28 Pg: 33 Fig-29 Pg: 34 Tables: T-1 T-2