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Transcript of RENEWABLE ENERGY (SOLAR POWER) MINI PROTOTYPE PLANT...
RENEWABLE ENERGY (SOLAR POWER) MINI
PROTOTYPE PLANT WITH SCADA SYSTEM
Muhammad Nashriq bin Mohd Haris
BEKP
MAY 2010
“ I hereby declare that I have read through this report entitle “Renewable Energy (Solar
Power) Mini Prototype Plant with SCADA System” and found that it has comply the
partial fulfillment for awarding the degree of Bachelor of Electrical Engineering (Industrial
Power)”
Signature : .......................................................
Supervisor’s Name : MR. MASLAN BIN ZAINON
Date : 12th
MAY 2010
RENEWABLE ENERGY (SOLAR POWER) MINI PROTOTYPE PLANT WITH
SCADA SYSTEM
MUHAMMAD NASHRIQ BIN MOHD HARIS
A report submitted in partial fulfillment of the requirements for the degree of
Electrical Engineering (Industrial Power)
Faculty of Electrical Engineering
UNIVERSITI TEKNIKAL MALAYSIA MELAKA
2010
I declare that this report entitle “Renewable Energy (Solar Power) Mini Prototype Plant
with SCADA System” is the result of my own research except as cited in the references.
The report has not been accepted for any degree and is not concurrently submitted in
candidature of any other degree.
Signature : ...........................................................
Name : MUHAMMAD NASHRIQ BIN MOHD HARIS
Date : 12th
MAY 2010
To my beloved mother and father
ii
ACKNOWLEDGEMENT
First and foremost, I would like to express my thankfulness and gratitude to Allah
S.W.T who has given me inspiration and strength for me to complete this progress report.
Besides, I wish to express my sincere appreciation to my supervisor, Mr. Maslan
bin Zainon, for give me a lot of encouragement, guidance critics and support to accomplish
this progress report. I also would like to show my appreciation to all my lectures and
technical staffs that have taught me with strong theories especially in electrical subjects to
fulfil the requirement of this project.
Furthermore, I would like to thank my friends and fellow classmates for sharing
and discussing knowledge and ideas to give me the inspiration in completed this report.
Their supports, opinions, and advises will be not forgotten. Not forget to technicians in
UTeM that have spent their time to explain and help me in this project.
Finally I want to express my sincere appreciation to my beloved family who giving
me full of support and encouragement to finish this report.
iii
ABSTRACT
This project is focusing on the designing and constructing an attractive prototype
solar power plant for teaching and learning kit. The aim of this project is to give people
especially student the overview of operations of solar power plant in generating electricity
in attractive way. Through this approach, people will be more interested to learn about the
operation of solar power plant and at the same time this renewable energy can be
implemented widely in this country. This prototype will be implemented with Supervisory
Control and Data Acquisition (SCADA) system to monitor and control the solar prototype
plant. User or operator can observe the actual operation of solar power plant in graphical
method through the PC. DC and AC load switching is implemented through SCADA
system. In this project, programmable logic controller (PLC) will be used to interface
between hardware parts and software parts. Solar prototype plant is basically consisting of
solar photovoltaic panel, charge controller, rechargeable battery, power inverter, SCADA
software and PLC.
iv
ABSTRAK
Projek ini tertumpu kepada rekaan dan penghasilan sebuah janakuasa solar
prototaip sebagai bahan pengajaran dan pembelajaran. Matlamad projek ini adalah untuk
memberikan masyarakat terutamanya para pelajar mengenai gambaran operasi sebuah
janakuasa solar dalam cara yang lebih menarik dan berkesan. Melalui pendekatan ini,
mereka akan lebih berminat untuk mempelajari mengenai operasi janakuasa solar di
samping dapat memperluaskan penggunaan tenaga solar di negara ini. Prototaip ini akan
menggunakan system SCADA untuk memantau dan mengawal sistem prototaip ini.
Pengguna atau pemerhati dapat memerhati sistem sebenar janakuasa solar dalam bentuk
grafik melalui komputer. Penyambung dan pemutus litar bagi beban DC dan AC telah
diaplikasikan di dalam sistem SCADA. Dalam projek ini, PLC akan bertindak sebagai
medium penghubung antara bahagian perkakasan dan bahagian perisian. Prototaip
janakuasa solar ini secara asasnya mengandungi panel solar PV, pengawal caj, bateri cas
semula, penyongsang kuasa, perisian SCADA dan PLC.
v
TABLE OF CONTENTS
CHAPTER TITLE PAGE
ACKOWLDGEMENT ii
ABSTRACT iii
ABSTRAK iv
TABLE OF CONTENTS v
LIST OF TABLES viii
LIST OF FIGURES ix
LIST OF ABBREVIATION xi
LIST OF APPENDICES xii
1 INTRODUCTION 1
1.1 Overview of Project Background 1
1.2 Problem Statement 2
1.3 Project Objectives 2
1.4 Project Scope 3
1.5 Project Outline 3
2 LITERATURE REVIEW AND 4
THEORETICAL BACKGROUND
2.1 Solar Module Monitoring Expert 4
System for PV System Model Design
2.2 5 kW Grid Connected Photovoltaic 8
2.3 Grid Connected and Building 9
Integrated Photovoltaic: Application
Status & Prospect for Malaysia
2.4 Conclusion on Literature Review 10
2.5 Theoretical Background 11
vi
CHAPTER TITLE PAGE
2.5.1 Solar Photovoltaic Panel 11
2.5.2 Charge Controller Circuit 13
2.5.3 Power Inverter 17
2.5.4 Programmable Logic Controller 18
2.5.4 Supervisory Control and Data 19
Acquisition System (SCADA)
3 PROJECT METHODOLOGY 20
3.1 Overview 20
3.2 Project Planning 20
3.3 Project Flowchart 23
3.4 Phase 1 24
3.5 Phase 2 25
3.6 Phase 3 27
3.7 Phase 4 31
3.7.1 CX-Designer 33
4 PROJECT RESULT AND DISCUSSION 35
4.1 Overview 35
4.2 Analysis of PV Module 35
4.3 Simulation 39
4.3.1 Charge Controller Simulation 39
4.3.2 Power Inverter Simulation 40
4.4 Hardware 41
4.4.1 Charge Controller Hardware 41
4.4.2 Power Inverter Hardware 45
4.5 Software 46
4.5.1 CX-Designer 46
4.5.2 CX-Programmer 47
4.6 Solar Power Mini Prototype Plant with 49
SCADA System
vii
CHAPTER TITLE PAGE
5 CONCLUSION AND RECOMMENDATION 51
5.1 Conclusion 51
5.2 Recommendation 52
REFERENCES 53
APPENDICES 54
viii
LIST OF TABLE
TABLE TITLE PAGE
2.1 Specification of PV Module 4
3.1 Project Planning Schedule 20
4.1 Effect of PV Orientation Angle on Output PV Module 35
4.2 Effect of Time on Output PV Module 37
4.3 Input and Output Voltage for Charge Controller 44
ix
LIST OF FIGURES
FIGURE TITLE PAGE
2.1 Sample Data of Solar Radiation for a Week 5
2.2 Sample Data of Ambient Temperature for a Week 5
2.3 System’s Block Diagram 7
2.4 Microsystem Architecture 7
2.5 Block Diagram of Typical PV Utility Grid Interconnection 8
2.6 Silicon Semiconductor Structure 12
2.7 NPN Junction 12
2.8 Semiconductor Depletion Region Formations 13
2.9 10A Charge Controller Circuit Diagram 14
2.10 1A Charge Controller Circuit Diagram 15
2.11 12V dc to 240V ac Inverter Circuit Diagram 18
3.1 Flow of Project Execution 21
3.2 Flow of Project Execution (continued) 22
3.3 Project Flow Graph 23
3.4 Project Flow Graph (continued) 24
3.5 10A Charge Controller Simulation Circuit 26
3.6 Power Inverter Simulation Circuit 26
3.7 PCB Design for Charge Controller Circuit 27
3.8 PCB Design for Power Inverter Circuit 28
3.9 Steps in PCB Etching Process 28
3.10 Charge Controller Circuit on PCB 29
3.11 Power Inverter Circuit on PCB 29
3.12 Soldering the Components 30
3.13 Charge Controller Circuit 30
3.14 Inverter Circuit 30
3.15 1A Charge Controller Circuit 31
3.16 Software Implementation 32
x
FIGURE TITLE PAGE
3.17 Project Property Setting 33
3.18 System Setting Window 34
4.1 Graph Effect of PV Orientation Angle on Output Power 36
PV Module
4.2 Graph Effect of Time on Output PV Module 38
4.3. Voltage Output Simulation For Charge Controller 39
4.4 Current Output Simulation For Charge Controller 39
4.5 Voltage And Current Output Simulation of Power Inverter 40
4.6 10A Charge Controller Hardware 41
4.7 1A Charge Controller Hardware 43
4.8 Power Inverter Hardware 45
4.9 DC Load Switch Button On 46
4.10 DC Load Switch Button Off 47
4.11 Ladder Diagram (DC Load Off) 48
4.12 Ladder Diagram (DC Load On) 48
4.13 Overall View Solar Power Mini Prototype Plant 49
4.14 DC Load (Motor) On 49
4.15 AC Load (Lamp) On 49
4.16 Connecting Hardware to CJ1G PLC 50
4.17 Control DC Load Switching Through PC 50
xi
LIST OF ABBREVIATION
PV - Photovoltaic
C - Capacitor
R - Resistor
D - Diode
Q - Transistor
T - Transformer
V - Voltage
I - Current
LED - Light Emitting Diode
GUI - Graphical User Interface
MPPT - Maximum Power Point Tracker
AC - Alternating Current
DC - Direct Current
PLC - Programmable Logic Controller
SCADA - Supervisory control and data acquisition
I/O - Input/ Output
RTU - Remote Terminal Unit
FYP - Final Year Project
UTeM - Universiti Teknikal Malaysia Melaka
xii
LIST OF APPENDICES
APPENDIX TITLE PAGE
A Gantt Chart 55
B B1: 12V dc, 10A Charge Controller Circuit 57
B2: 12V dc, 1A Charge Controller Circuit 58
B3: Power Inverter Circuit 59
C Datasheet of Components 60
CHAPTER 1
INTRODUCTION
This chapter will discuss the background of solar renewable energy and solar power
plant, the aims and specified objectives of the project, project scope and problem
statements. The project outline is also listed at the end of this chapter.
1.1 Project Background
In today's climate of growing energy needs and increasing environmental concern,
alternatives to the use of non-renewable and polluting fossil fuels have to be investigated.
One such alternative is solar energy. Nowadays, solar applications are widely use in
developed country such as United State and most of country in Europe. In Malaysia, solar
energy has opportunity to develop since this country has high sun radiation and this
condition can be used to convert solar energy into electricity. With proper study about the
operations of solar power plant, electricity can be generated by solar energy as a back up to
the ordinary or non-renewable source of energy such as diesel, steam and coal power plant.
An attractive approach need to be exposed especially to students. With certain approach
that is attracting and interesting, students will be more interested to learn and understand
the operations of solar power plant. This project will focus on the design and development
of a prototype of solar power plant system. This prototype will be implemented with
Supervisory Control and Data Acquisition (SCADA) system and Programmable Logic
Controller (PLC) to monitor and control solar prototype power plant in graphical. This
method can gives more attractive to students in learn about the solar power plant
operations.
2
1.2 Problem Statement
Solar energy is a part of a widely recognized renewable energy sources. The solar
energy source is free of cost and clean energy whereby environmental impacts are
negligible. In tropical countries like Malaysia, potential in solar energy is developing but
still has not been implemented widely especially in teaching and learning applications.
This problem is due to lack of knowledge among people and students especially in
operation of solar power plants. At the same time people are not aware about the
importance of solar energy in future.
Most of students will prefer to something attractive rather than just theory and
formulae. Solar prototype plant for educational can be implemented with SCADA system
which will attracts student to learn and understand the operations of solar power plant. All
systems need to be monitored and controlled to make sure the system is running steadily.
Same with solar power plant system itself. The system need to be stabilized in order to
prevent any interruption that will cause to many problems such as unstable power supply
and power cut out. These problems can be overcomed with proper monitoring and
controlling system.
1.3 Project Objective:
The objectives of this project are:
to analyze and understand the operations of solar power plant system.
to design and develop power plant prototype for teaching and learning based on solar
energy.
to design SCADA system and control (on/off) DC load in solar power plant system.
to explore solar renewable energy as an alternative to support electricity generations.
3
1.4 Project Scope:
In order to achieve the objective of the project, there are several scope has been
specified.
The scope of this project includes:
This prototype power plant is for teaching and learning kit.
12V, 2.4Watt Solar PV Panel.
Charge controller rating current up to 1A.
Rechargeable battery 12V, 1.2Ah.
Power Inverter (12Vdc – 240ac)
SCADA software and Programmable Logic Controller (PLC)
1.5 Project Outline
Chapter 1 represents the introduction part, project background, problem statement,
project objectives, project scopes, and project outline. Chapter 2 represents the literature
review part. These parts are including review on related project based on solar charge
controller, inverter, SCADA system, and other component. Chapter 3 represents project
planning and project methodology that will be applied in this project. Chapter 4 represents
result and analysis for this project. Finally Chapter 5 represents the discussion and
conclusion of this project.
4
CHAPTER 2
LITERATURE REVIEW AND THEORETICAL BACKGROUND
2.1 Solar Module Monitoring Expert System for PV System Model Design
For a large number of applications, PV technology is simply the least-cost option. It
is important to determine the correct system size, in terms of both peak output and overall
annual output, in order to ensure acceptable operation at minimum cost.
Parameters require in order to accurately predict the electrical output of the systems:
Influence of solar angle of incidence
Influence of solar spectrum
Temperature coefficient for the open circuit voltage and maximum power voltage
Temperature coefficient for the short circuit current and the maximum power
current
Module operating temperature as a function of ambient temperature, wind velocity
and solar radiation.
To investigate the fundamental characteristics of the PV modules, the long term
measurement is ongoing. Table 2.1 indicates the specification of PV module .used for the
measurements. The modules are set with the slop of 35 to 90 degrees.
Table 2.1: Specification of PV Module.
Max Power 75 W
Short Circuit Current 4.75 A
Open Circuit Voltage 21.4 V
Optimum Operating Current 4.45 A
Optimum Operating Voltage 17 V
5
In addition the environmental factors, such as the irradiation, temperature, humidity
and wind velocity are measured at the same interval by using personal computer based
measurement system. In Figure 2.1 and Figure 2.2, data of ambient temperature and solar
radiation were collected for every half an hour every day
.
Figure 2.1: Sample Data of Solar Radiation for a Week
Figure 2.2: Sample Data of Ambient Temperature for a Week
The earth rotates about its axis every twenty-four hours, therefore any location
faced to the sun about 12 hours a day. Hence, assume that the solar energy available 12
hours per day. In peninsular Malaysia, the average solar insulation is 4.5 kWh per meter
6
square per day. Considering the available solar radiation, module area and angle, these
parameters can derive total solar energy per day as in Equation (1).
Sep = Itotal x S x [sin (α) sin (β) + 1] (1)
Where:
Sep solar energy per day
Itotal is global solar radiation
S is area of PV module
α is duration available for solar energy conversion and varies between 0 o<α <180
o,
15 ° per hour and also is a sun trajectory from the east and west.
β is a degree of PV module's angle, it varies from 0 o of the negative direction of
zenith to 90 °at coordination of north and south, east and west orientation.
The amount of energy produced by a PV device depends not only on available solar
energy but also on how well the device converts sunlight to the electrical energy i.e. the
efficiency of the cell or module used. The conversion efficiency can be measured by the
equation below:
η = ___Pmax____ x 100 (2)
Srad x Area
Where:
Pmax is the maximum output power (kWh)
Srad is the solar radiation intensity (kWh/m2)
Area is the total area of the cell or module (m2)
There are two parts in the system development, hardware and software. In hardware
part, all the data are collected by the microsystem before send to the monitoring pc. The
microsystem of data acquisition as related to photovoltaic systems gives comprehensive
support to the design of a PV system for general users. The system is not only limited to
collecting data but the system also analyze and remedy the performance of PV systems.
7
Figure 2.3: System’s Block Diagram
The microsystem architecture uses a microcontroller to control and monitor the
data acquisition as represented in Figure 2.4. The analog part is composed essentially of
one adaptation and an analog multiplexer allowing the acquisition of many meteorological
parameters and the parameters related to the PV system. The numerical part of
microsystem allows the transfer of data between the analog-to-digital converter (ADC) and
the data bus. The treatment of data is in real time in the microsystem and the transfer of
data to the pc is carried out through a bidirectional serial port using an RS232 protocol.[3]
Figure 2.4: Microsystem Architecture
The data are collected from real weather condition i.e. solar radiation, ambient
temperature and humidity. At the same lime, the data also collected from PV module
where all the output from PV module such voltage, current and power are recorded. These
SENSOR ADAPTATION MUX
ADC µC EEPROM
TO RS232 & PC
8
two major parameters (weather condition and PV module monitoring) will be analyzed by
ES to evaluate the best PV system model for that location.[3]
2.2 5 kW Grid Connected Photovoltaic
Power supply reliability and power quality have become important issues for all
kind of power electronic systems including photovoltaic systems. Interconnecting a
photovoltaic system with utility, it is necessary that the PV system should meet the
harmonic standard and the active power supply requirement. Several utility connected
photovoltaic systems have been proposed. Among these systems, the most common type is
the parallel running PV with bi-directional power flow to provide unity power factor on the
utility line. In this system, an inverter connected to the photovoltaic array supplies the
power to the utility. Photovoltaics (PV) are the direct conversion of sunlight to electricity
by solar cells. When photons of sunlight are absorbed in solar cells, the photons free
electrons from the cell’s atoms, creating a voltage potential.
Figure 2.5 is a block diagram description of a PV utility-interactive system. The
PCS is primarily responsible for converting the DC PV power into utility compatible AC
power and for synchronizing and transferring that Ac power safety into the utility grid. The
DC to AC commutated inverter utilizes the utility voltage as a means of commutation
(turn-off) of transistor or thyristor switching devices.[8]
Figure 2.5: Block Diagram of a Typical PV Utility Grid Interconnection