, Design and Construction of Solar Tracking System for Optimum Solar Panel Positioning

ABSTRACT

This study aims to design a solar tracking system based on microcontroller Arduino using sensors to facilitate optimum solar panel positioning. The system consists of several electronic components such as microcontroller, sensors, batteries, DC motor. The research method used in this experiment is a direct test of the tool. The result of this final product is a microcontroller, based solar tracking system that uses sensors to check for high sun rays. Based on the results of the manufacture, operation and testing of tools. It is known that the working mechanism of microcontroller-based solar tracking system using ultrasonic sensor, works in accordance with expectation and supporting theories.

TABLE OF CONTENT

Title page i

Declaration ii

Certification iii

Dedication iv

Acknowledgement v

Table of content vi

List of Table viii

List of figures ix

Abstract x

CHAPTER 1

INTRODUCTION

1.0 Background 1

1.1 Statement of problems 7

1.2 Objectives 7

1.2.1 Aim 7

1.2.2 General objectives 7

1.3 Significances 8

1.4 Limitations 8

CHAPTER 2

LITERATURE REVIEW

2.1 Thermal application of solar energy 9

2.2 Electrical application of solar energy 11

2.3 Factors affecting the efficiency of solar cells 19

2.4 Types of solar PV modules 20

2.5 Components of PV system 22

2.6 Rays transmission from sun 25

2.7 Solar angles 27

CHAPTER 3

MATERIALS AND METHODS

3.1 Materials 29

3.1.1 DC Motor 29

3.1.2 Light dependent resistor (LDR) 30

3.2 Methodology 33

3.2.1 Theoretical framework 33

3.2.2 Study design 35

3.3 Solar tracking system 36

3.4 Mathematical calculations 42

3.4.1 Solar calculations 42

3.4.2 Torque calculation 44

3.5 Design 45

3.5.1 Mechanical design 45

3.5.2 Electrical design 47

CHAPTER 4

RESULTS AND EVALUATION

4.1 Experiment results 49

4.2 Analysis 52

CHAPTER 5

CONCLUSION AND RECOMMENDATION

5.1 Conclusion 53

5. 2 Recommendation 53

LIST OF TABLE

Table 1: solar Energy production by countries 6

Table 2: Types of concentrator 11

Table 3: Photovoltaic array output for sunny bright day 49

Table 4: LDR output for cloudy day 50

Table 5: LDR output for bright day 51

LIST OF FIGURE

Figure 1: Layers of solar PV module 3

Figure 2: Photoelectric effect in PV cell 12

Figure 3: I-V Curve of solar cells 15

Figure 4: Pictorial form of PV panel 18

Figure 5: Pictorial presentation from solar cell to solar array 19

Figure 6: Types of solar cells 20

Figure 7: Solar design configuration 25

Figure 8: Earth’s energy budget 26

Figure 9: Low speed high torque DC Motor 12V/14RPM 29

Figure 10: RDR characteristics 39

Figure 11: A Light speed dependent resistor 32

Figure 12: Schematic diagram of single-axis solar tractor/ double-axis solar tractor 33

Figure 13: Variation in Trajectory of Sun from winter to summer 34

Figure 14: Sample flow chart of tracking system with component 35

Figure 15: Study design process 36

Figure 16: Power comparism of dual-axis, single-axis and fixed-axis mode 38

Figure 17: Sun path diagram for Dhulikhel 39

Figure 18: Algorism for tracking 41

Figure 19: Mechanical view of solar tracking system 45

Figure 20: Circuit diagram 48

, Design and Construction of Solar Tracking System for Optimum Solar Panel Positioning

Reviews

APA

MLA

Chicago

Share this work