DESIGN OF A CONTROLLABLE 
RESISTOR LOAD BANK 
Master of Science Dissertation 
P. H . K. H . P U H U L W E L L A 
Department of Electrical Engineering 
University of Moratuwa, Sri Lanka 
April 2011 
( 3 
^ L I B R A R Y 
UliVERSITV Of MORATUWA. SRI LANK 
. . MORATUWA 
DESIGN OF A CONTROLLABLE 
RESISTOR LOAD BANK 
A dissertation submitted to the 
Department of Electrical Engineering, University of Moratuwa 
In partial fulfilment of the requirements for the 
Degree of Master of Science 
by 
P. H . K. H . P U H U L W E L L A 
Supervised by: Dr. J. P. Karunadasa 
University of Moratuwa 
III III 111 I HI1 
100849 
Department of Electrical Engineering 
University of Moratuwa, Sri Lanka 
April 2011 
Declaration 
The work submitted in this dissertation is the result of my own investigation, 
except where otherwise stated. 
It has not already been accepted for any degree, and is also not being concurrently 
submitted for any other degree. 
P. H. K. H. Puhulwella 
Date: / ? ? / ) . 
We/I endorse the declaration by the candidate. 
Dr. J. P. Karunadasa 
Abbreviations 
Colombo Dockyard Public Limited Company 
Uninterrupted Power Supply 
New Construction Project / Normally Closed Contact 
Normally Open Contact 
Lloyds Register/ Indian Register of shipping 
Main Switch Board 
c 
Table of Contents 
Declaration iii 
Abbreviations iv 
Table of Contents v 
Abstract viii 
Acknowledgement ix 
List of Figures x 
List of Tables xi 
Chapter 1 1 
1 Introduction 1 
1.1 Types of Load Banks 1 
1.1.1 Resistive Load Bank 1 
1.1.2 Reactive Load Bank 2 
1.2 Application of Load Banks 2 
1.3 Load Testing Procedure at Colombo Dockyard PLC 3 
1.3.1 Standard Load Testing Requirement 3 
"* 1.3.2 Liquid Rheostat (Salt Water Rheostat) 4 
1.3.3 Load Testing Procedure with Salt Water Rheostat 5 
1.3.4 Drawbacks of a Salt Water Rheostat 5 
1.3.5 Operational issues inherent to Colombo Dockyard 6 
1.4 Objectives 6 
1.5 Scope of the Project 7 
Chapter 2 8 
2 Modern Load Banks 8 
2.1 Load bank Details 8 
2.2 Basic Components of a Dry Type Load Bank 9 
2.2.1 Resistors / Power Resistors 9 
2.2.2 Types of Resistors based on the Construction 10 
2.2.3 Power Wire Wound Resistors 10 
2.2.3.1 Ayrton-Perry Winding 12 
2.2.4 Effect of Temperature Variations on Resistance 13 
Chapter 3 15 
3 Load Controlling Techniques 15 
3.1 Linearly Switching 15 
3.2 Binary Switching 15 
3.3 Linearly Switching with Binary Tailing 15 
3.4 Linearly Switching with PWM Tailing 16 
3.5 Application of Power Controllers in Automatic Load Controlling 16 
3.5.1 Operation of the Automatic Load Controller 17 
« 
V 
3.6 Automatic Load Controlling Model 18 
Chapter 4 22 
4 Fan Cooled Resistive Load Bank Design Proposal 22 
4.1 Capacity Selection 22 
4.2 Load Bank Ratings 23 
4.3 Size and the enclosure 23 
4.4 Size and Resistor Composition Limitations 23 
4.5 Resistor Composition and Arrangement 25 
4.6 Resistor De-rating Curve and the Ambient Temperature 26 
4.7 Resistor Arrangement 27 
4.8 Cooling System 28 
4.8.1 Airflow Formula for Thermal Design 28 
4.8.2 Blower Specifications for the 60kW Unit 29 
4.8.3 Blower Specifications for the 30kW Unit 29 
4.8.4 Blower Specifications for the 15kW Unit 30 
4.8.5 Blower Specifications for the 6kw Unit 30 
4.9 Blower Composition 30 
4.10 Contactor Selection 31 
4.11 Power Circuit 32 
4.12 Control System 34 
4.12.1 The Operational Modes 34 
4.12.2 Normal Operation 38 
4.12.3 Master Load Switch Operation (Up to 50% of Full Load) 38 
4.12.4 Master Load Switch Operation (Up to 50% of Full Load and then from 50% to 100%) 
39 
4.13 Protection Features 39 
4.13.1 Emergency Stop 39 
4.13.2 Load Step Interlock 40 
4.13.3 Ventilation Interlock 40 
4.13.4 Mode Interlock 40 
4.13.5 Endurance Changeover 40 
4.14 Control Indications 41 
4.14.1 Source Indication 41 
4.14.2 Mode Indication and Mode Standby Indication 41 
4.14.3 Resistor Unit Indication 41 
4.15 Bill of Material (BOM) for the Design 42 
Chapter 5 44 
5 Cost analysis on the Liquid Rheostat Load Testing at CDPLC - Case Study of NC210 
Passenger Vessel 44 
5.1 Vessel Generator Specifications 44 
5.1.1 Test Types and Durations 44 
5.2 Generator Loading and Energy Generation during the Tests 45 
5.3 Major Cost Components 45 
5.3.1 Fuel Cost Calculation 45 
5.3.2 Man Hour Cost Calculation : 47 -
5.3.3 Water Cost Calculation :-. f. 48 
5.3.4 Cost Composition 48 
5.4 Cost Saving for the Proposed Resistor Type Load Bank 49 
5.4.1 Pay Back Period for a New Dry Type Load Bank 49 
Conclusion 50 
References 54 
Annexure-1: Pilot Project 55 
Annexure-2: Quotations 56 
vii 
Abstract 
This research is focused on designing a controllable, dry type resistor load bank for 
load testing purpose and developing a model to simulate the load controlling 
techniques in modern load banks. 
A literature review was carried out on the types of load banks and their applications. 
The operation and the drawbacks of the liquid type load bank, which is commonly 
used in industry, are discussed by studying the generator load testing procedure at 
Colombo Dockyard PLC (CDPLC). This addresses the practical difficulties, 
operational issues and limitations encountered in the generator load testing procedure. 
A study has been done on the main components in a modern dry type load bank, 
including the selection method of power resistors and their special construction 
features. The variation of resistance values with the temperature is discussed in detail. 
Different load controlling techniques available in modern load banks are discussed 
and a MATLAB Simulink Model is developed to simulate the automatic load 
controlling with the variation of temperature in a linearly switched load bank with 
PWM tailing. 
A detail design proposal of a dry type load bank, from the capacity selection to design 
stage, including ratings, resistor composition, arrangement, resistor selection, cooling 
design, power circuit design, control safety and indication designs is given 
considering the requirement of generator load testing at CDPLC. A Bill of Material is 
given for the major components used in the implementation stage. An economic 
analysis on the proposed load bank was done in comparison with the present load 
testing procedure by conducting a case study with actual test data and major cost 
components obtained from a recently completed ship building project at CDPLC. 
The advantages and the economical aspects of the design proposal were discussed 
presenting the limitations and further improvement opportunities. 
viii 
Acknowledgement 
At the very beginning, I would like to thank specially, my supervisor, Head of the 
Department of Electrical Engineering, Dr. J. P. Karunadasa, for his valuable 
suggestions and guidance provided throughout the project in spite of his busy 
schedules. 
I offer my sincerest gratitude to Dr. Narendra de Silva, Engineering, Research and 
Development Manager of Lanka Electricity Company, for encouraging and guiding 
me on further improvements. 
I am specially thankful to the other members of the academic staff of the Department 
of Electrical Engineering, for their valuable suggestions and comments. I wish to 
thank the staff in the Department of Electrical Engineering and in the Post Graduate 
Office of the Faculty of Engineering of University of Moratuwa for their excellent 
cooperation. 
I am indebt to the Special Project Manager, Mr. Shantha Rathnayaka and Assistant 
Production Manager, Mr. D.A.P. Senasinghe and all my colleagues at Colombo 
Dockyard PLC for their excellent support. 
Finally, I am very much thankful to my family for their understanding and motivation 
given throughout this project to make it a success. 
ix 
List of Figures 
Figure 1.1 : Liquid Rheostat Load Bank used in Colombo Dockyard 4 
Figure 2.1 : Power Wire Wound Resistor 11 
Figure 2.2 : Power Wire Wound Resistor Windings 12 
Figure 3.1- Load bank with an Automatic Power Controller 17 
Figure 3.2 - Model for Automatic Load Controlling 18 
Figure 3.3 - Model for Automatic Load Controlling 19 
Figure 3.4- Automatic Load Controlling with PWM Controlled Power Element 20 
Figure 3.5 - Automatic Load Controlling with Additional Switching ON of Power Elements 20 
Figure 4.1 : Silicon Coated Wire-Wound Power Resistor with mounting fixture 24 
Figure 4.2 : Silicon Coated Wire-Wound Power Resistor with mounting fixture (MF Power Resistor 
Ltd, http://www.mf-powerresistor.com) 25 
Figure 4.3 : Resistor De-rating Curve for Silicon Coated Wire-Wound Power Resistor with mounting 
fixture (MF Power Resistor Ltd, http://www.mf-powerresistor.com) 26 
Figure 4.4 : Resistor Unit 27 
Figure 4.5 : Power Resistor Arrangement 28 
Figure 4.6 : Airflow Formula - Thermal Design 29 
Figure 4.7 : Load Bank Power Circuit 33 
Figure 4.8 : Control Circuit Page -1 35 
Figure 4.9 : Control Circuit Page -2 36 
Figure 4.10: Control Circuit Page -3 37 
Figure 5.1 : Load Test Cost Composition 48 
x 
List of Tables 
Table 4.1: New Construction Projects Details -CDPLC 
Table 4.2: Resistor Composition 
Table 4.3 : Blower Composition 
Table 4.4: Resistor Unit Currents 
Table 4.5: Resistor Unit Contactor Composition 
Table 4.6: Blower Contactor Composition 
Table 4.7: Bill of Material for the Load Bank 
Table 5.1: Generator Specifications -NC210 
Table 5.2: Test Types and Durations 
Table 5.3: Test Types and Durations for the Fuel Cost 
Table 5.4: Test-A Energy Consumption 
Table 5.5: Test-B Energy Consumption 
Table 5.6: Test-C Energy Consumption 
Table 5.7: Diesel Cost Calculation