Design and construction a solar powered mobile phone charger
Table Of Contents
- <p> </p><p><b>INTRODUCTION</b></p><p>
- 1.0Background</p><p>
- 1.2Aim and objectives</p><p>
- 1.3Problem statement</p><p>
- 1.4Solution approach</p><p>
- 1.5Scope of study</p><p>
- 1.6Thesis outline</p><p><b>
Chapter TWO
LITERATURE REVIEW
- </b></p><p><b>REVIEW OF LITERATURE</b></p><p>
- 2.0Need for Regulated Supply</p><p>
- 2.1Unregulated D.C. Power Supply</p><p>
- 2.2Regulated Power Supply</p><p>
- 2.3Types of Voltage Regulators</p><p>
- 2.4Zener Diode Voltage Regulator</p><p>
- 2.5Zener Diode as Reference Element</p><p>
- 2.6Transistor series voltage regulator</p><p>
- 2.7Series Feedback Voltage Regulator</p><p><b>
Chapter THREE
RESEARCH METHODOLOGY
- </b></p><p><b>METHODOLOGY</b></p><p>
- 3.1Block Diagram</p><p>
- 3.11The solar panel</p><p>
- 3.12Series Feedback Voltage Regulator (SFVR) Circuitry</p><p>
- 3.13Control Circuitry</p><p>
- 3.14Rechargeable Battery</p><p>
- 3.15Final Regulator</p><p>
- 3.2Principle of operation of the solar powered mobile phone charger</p><p>
- 3.3Determination Component sizes</p><p><b>
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- </b></p><p><b>CONSTRUCTION AND TESTING</b></p><p>
- 4.1Introduction</p><p>
- 4.2Circuit Construction and Selection of component values</p><p>
- 4.21Determination of duration of hours rechargeable battery will last</p><p>
- 4.3Casing Construction</p><p>
- 4.4Assembling of constructed work</p><p><b>
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- </b></p><p>CONCLUSION AND RECOMMENDATION</p><p>Conclusion</p><p><b>REFERENCES</b></p> <br><p></p>
Project Abstract
This research project focuses on the design and construction of a solar-powered mobile phone charger. With the increasing use of mobile phones and the growing concern for sustainable energy sources, the development of a solar-powered charger presents a practical and eco-friendly solution. The project aims to create a portable and efficient charger that utilizes solar energy to power mobile devices. The design process involves selecting appropriate solar panels, batteries, and charging circuits to ensure optimal performance. The charger will be equipped with a photovoltaic panel to convert sunlight into electrical energy, which will then be stored in a rechargeable battery for later use. The construction phase will involve assembling the components in a compact and user-friendly manner, making the charger suitable for outdoor and on-the-go use. To improve the usability of the charger, the design will include features such as multiple charging ports, indicator lights, and a durable casing to protect the internal components. The device will be designed to be lightweight and portable, allowing users to conveniently carry it while traveling or engaging in outdoor activities. By harnessing solar power, the charger not only offers a renewable energy source but also reduces the dependence on traditional electricity grids, making it a sustainable and cost-effective solution. The charger can be utilized in various settings, including camping trips, hiking expeditions, or emergency situations where access to electricity is limited. The project will also explore the feasibility of integrating additional features such as a power bank function or wireless charging capabilities to enhance the charger's utility and appeal to a wider range of users. By incorporating innovative technologies and design elements, the solar-powered mobile phone charger aims to provide a versatile and efficient charging solution for mobile devices. Overall, this research project seeks to address the need for sustainable energy solutions in the mobile technology sector by developing a solar-powered charger that is reliable, portable, and environmentally friendly. The outcome of this project will contribute to the advancement of renewable energy applications and promote the adoption of solar power in everyday devices.
Project Overview
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</p><p><strong>INTRODUCTION</strong></p><p><strong>1.0 Background</strong></p><p>Nigeria as the largest country in Africa with a population of about 148 million is facing the challenge of erratic power supply. This is because not less than 60% of the population has limited or no access to affordable electricity, hence there is need to stem the energy crisis in the nation [1]. Due to the increasing population of Nigeria, there has been a corresponding increase in power demand without a reliable supply to meet such. The short fall in the supply of electricity in this country especially in the rural settlement where there are inadequate or no grid systems necessitates the need to explore renewable source of energy. Ref [2] ascertains that stand-alone photovoltaic (PV) system configuration offer an economical substitute to the costly grid extensions in rural areas in the world. Small scale affordable production of solar energy can be used in the charging of phones as well as lighting in the rural areas.</p><p>Solar power as a renewable energy source, is gaining wide spread acceptance due to the availability of technical know-how and solar resources. Like all other renewable energy sources, it evidently has numerous benefits over nonâ€renewable energy sources, such as coal, oil and nuclear energy etc. as an environmental friendly option of power generation it is nonâ€polluting, reliable and can produce energy anywhere that there is sunlight. Another major advantage is that solar resources are not going to run out anytime soon. When compare with other sources of res, it has some technical and environmental advantages. Solar power is generated using solar panels, which do not require any major mechanical parts, such as wind turbines. these mechanical parts can break down and cause maintenance issues and can also be quite noisy. both of these issues are virtually nonâ€existent with solar panels. also, the solar cells, that connects together to make up the solar panel, can last up to several decades without replacement. However, there is a shortcoming to solar energy production – energy can only be produce when the sunlight is available. to overcome this, usually solar panels are coupled with back up rechargeable batteries, which can store excess power generated during the period of availability and utilize this in providing energy to systems when there is no sunlight. in this way solar power can be used in residential areas especially for charging of phones and provision of light during the night.</p><p>In these systems there is need for voltage regulation of the supply voltage form the solar panel as well as a charging circuit for the rechargeable battery. This is because the solar panel usually produces an output direct current (dc) voltage which is usually more than that needed to charge the phone as well as charge the rechargeable battery. Therefore there is need for voltage regulation.</p><p>For the purpose of this project, the load (phone) to be connected only requires dc input, so dcâ€ac conversion is not needed. Instead, dcâ€dc conversion would be used to provide the correct power to the system from the power generated by the solar panel.</p><p><strong>1.1 Motivation of study</strong></p><p>Following a survey of the duration of electricity power available during the day as well as night in rural areas of Nigeria, there is a need to design a solar-powered cell phone charger that is fabricated locally. This is of primary importance because a large number of cell phone owners or users in the rural areas as well as some urban areas with no or limited access to utility electricity, are forced to pay at least N50 per charge for their cell phone from a commercial outfit using a 750VA petrol driven generator. This adds up to a significant investment over a period of time, especially for a poor rural dweller.</p><p><strong>1.2 Aim and objectives</strong></p><p>The aim of this research is to design and construct a solar powered mobile phone charger. More especially the objectives are:</p><p>1) To design an electric circuit for the purpose of charging through the solar power<strong></strong></p><strong><p>2) To carry out a design calculation so as to ascertain the duration for which the rechargeable battery will charge the mobile phone.<strong></strong></p><strong><p>3) To run a technical test to verify the variation in the input and output of the charger.<strong></strong></p><strong><p><strong>1.3 Problem statement</strong></p><p>As earlier stated the need for rural residents to charge phones during the hours of the day when sunlight is available and the need to cut down the level of carbon emission is a major concern. In order to achieve this a solar powered mobile phone charger will be needed. As against this background, the purpose of this project is to design and construct a cost effective, affordable solar powered mobile phone charger.</p><p><strong>1.4 Solution approach</strong></p><p>The main design of the circuitry of this project is such that it would be implementing the mobile phone charging algorithm to charge the mobile phones at the load.</p><p>To solve this problem, the circuitry is connected to a solar panel with an output voltage of 9V.</p><p>These were the considerations that were taken into account while designing the project:</p><p>· The finished product should not cost more than N10,000 due to economic level of the targeted consumers.</p><p>· The project design is made as simple as possible for easy reproductivity and for easy maintainance.</p><p>· It should be users friendly because of the level of literacy of the targeted consumers</p><p>· The product should be flexible such that it can charge the different cell phone brands available in market.</p><p><strong>1.5 Scope of study</strong></p><p>The scope of this study is limited to the design and construction of solar powered mobile phone charger.<strong></strong></p><strong><p><strong>1.6 Thesis outline</strong></p><p>The rest of this project is as follows: chapter 2 presents a literature review, while in chapter 3 the methodology of the work is highlighted. In chapter 4, the results and its discussion are presented. In chapter 5, conclusion and recommendations is drawn from the results presented in the previous chapter.</p></strong></strong></strong></strong>
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