Description
ABSTRACT
This paper demonstrated a step by step process in designing a solar powered charging bag that is capable of charging mobile devices efficiently. A selection of existing products available on the market were reviewed and compared to ascertain the cost, size, and output capabilities. Next, the solar cell types and regulators were compared and their respective merits were also investigated. The charging system was then designed and tested before being integrated with the solar bag. The results clearly showed that the system managed to charge the mobile phone. However, it was found that the excessive power dissipation has caused the linear regulator to generate significant heat.
TABLE OF CONTENTS
TITLE PAGE
APPROVAL PAGE
DEDICATION
ACKNOWELDGEMENT
ABSTRACT
TABLE OF CONTENT
CHAPTER ONE
- INTRODUCTION
- AIM/ OBJECTIVE OF THE PROJECT
- SIGNIFICANCE OF THE PROJECT
- SCOPE OF THE PROJECT
- LIMITATION OF THE PROJECT
- PROJECT ORGANISATION
CHAPTER TWO
LITERATURE REVIEW
2.0 LITERATURE REVIEW
2.1 REVIEW OF THE STUDY
2.2 HISTORICAL BACKGROUND OF POWER BANK
2.3 BACKGROUND SOLAR ENERGY
2.4 HISTORICAL BACKGROUND OF SOLAR CELLS
2.5 THEORY OF SOLAR CELLS
CHAPTER THREE
DESIGN METHODOLOGY
3.0 METHODOLOGY
3.1 SYSTEM BLOCK DIAGRAM
3.2 SYSTEM CIRCUIT DIAGRAM
3.3 COMPONENT LIST
3.4 SYSTEM OPERATION
3.5 CIRCUIT DESCRIPTION
3.6 CONNECTING THE SOLAR PANEL
3.7 CONNECTING THE USB PORT
3.8 DESCRITION OF MAJOR COMPONENTS USED
CHAPTER FOUR
4.0 RESULT ANALYSIS
4.1 CONSTRUCTION PROCEDURE
4.2 SELECTION OF SOLAR CELL
4.3 TESTING OF SYSTEM OPERATION
4.4 ASSEMBLING
4.5 INTEGRATION OF SOLAR CELL
4.6 OBSERVATION
4.7 DIFFICULTIES ENCOUNTERED ON THE SYSTEM
CHAPTER FIVE
- CONCLUSION, RECOMMENDATION AND REFERENCES
- CONCLUSION
- RECOMMENDATION
- REFERENCES
CHAPTER ONE
1.0 INTRODUCTION
Solar is one of the most abundant sources of renewable energy [1–4], with the potential capability of generating enough power to meet the demands of the entire planet. It was calculated theoretically that the amount of sun received on earth for one day has the capability to meet the demand of the world for more than 20 years [5]. Despite the huge potential, solar photovoltaic only provides 1.2% of the world’s electricity [6].
The harnessing of solar energy is still very much ongoing with the advancements in solar technology constantly improving. There are many applications where solar energy is utilized – from the very big application, such as generating electricity for homes and industry from solar fields, to the very small applications like powering the calculators. The possibilities are extensive.
There are a varying number of products already on the market that utilise solar energy for storing and charging devises. The products range in all shapes and sizes from fully integrated to attachable. As with Generally, the power of the solar bag was ranging from 6W to 7W with the output voltage of between 5V and 6V. The bag that come at greater cost tended to have a battery pack incorporated. The addition of this does increase the overall weight as expected.
The purpose of the paper is to develop a different prototype of solar powered charging bag that is capable of charging a mobile devices efficiently. The design would have to meet certain criteria including durability, reliability, practicality and low cost. In order for this to be achieved successfully, research, design, testing and analysis are carried out.
1.1 AIM OF THE PROJECT
The main aim of this work is to build a portable, mobile and light in weight solar pack which is packaged in a bag for the purpose of charging portable rechargeable devices.
1.2 SIGNIFICANCE OF THE PROJECT
- Solar bag is light-weight, hence making it easier to carry.
- Solar bag carry a green energy source for the environment.
- Flexible solar panels also are light and portable, as well as waterproof.
1.3 SCOPE OF THE PROJECT
The solar bag usually contains a flexible monocrystalline solar panel, battery, charge controller, plugs, cords and light bulbs. It provides users with power up to 120 watt-hours/day, capable of powering electronic equipment rated up to 300 W depending on the design.
1.4 APPLICATION OF THE PROJECT
- It can also be utilized in international aid, disaster relief, emergency power and field research.
Solar bag can also power laptops for up to 3 hours.
After an exposure of about six hours, it can power an emergency light for 14 hours.
Solar bag can also be used to power medical equipment and humanitarian relief efforts where power from the utility grid is not available.
These types of bag can also be used to power cameras for use in remote areas.
1.5 LIMITATION OF THE PROJECT
- It can only be recharged with solar energy through solar panel
- The duration of the charged when in used depend on the number of cell used.
- Using solar energy for this device means that charging the power bank during cloudy or raining time becomes a problem.
1.6 PROJECT WORK ORGANISATION
The various stages involved in the development of this project have been properly put into five chapters to enhance comprehensive and concise reading. In this project thesis, the project is organized sequentially as follows:
Chapter one of this work is on the introduction to the study. In this chapter, the background, significance, objective, limitation and scope of the study were discussed.
Chapter two is on literature review of this study. In this chapter, all the literature pertaining to this work was reviewed.
Chapter three is on design methodology. In this chapter all the method involved during the design and construction were discussed.
Chapter four is on testing analysis. All testing that result accurate functionality was analyzed.
Chapter five is on conclusion, recommendation and references.
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