Design and construction of micro controller time socket outlet
Table Of Contents
Chapter ONE
INTRODUCTION
- 1.1Introduction
- 1.2Background of Study
- 1.3Problem Statement
- 1.4Objective of Study
- 1.5Limitation of Study
- 1.6Scope of Study
- 1.7Significance of Study
- 1.8Structure of the Research
- 1.9Definition of Terms
Chapter TWO
LITERATURE REVIEW
- 2.1Overview of Literature Review
- 2.2Theoretical Framework
- 2.3Historical Development
- 2.4Current Trends in the Field
- 2.5Key Concepts and Definitions
- 2.6Empirical Studies
- 2.7Knowledge Gaps
- 2.8Critique of Existing Literature
- 2.9Theoretical Contributions
- 2.10Summary of Literature Review
Chapter THREE
RESEARCH METHODOLOGY
- 3.1Research Methodology Overview
- 3.2Research Design
- 3.3Data Collection Methods
- 3.4Sampling Techniques
- 3.5Data Analysis Procedures
- 3.6Ethical Considerations
- 3.7Research Limitations
- 3.8Reliability and Validity
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- 4.1Overview of Findings
- 4.2Presentation of Data
- 4.3Analysis and Interpretation
- 4.4Comparison with Research Objectives
- 4.5Discussion of Key Findings
- 4.6Implications of Findings
- 4.7Recommendations for Future Research
- 4.8Practical Applications
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- 5.1Conclusion and Summary of Research
- 5.2Summary of Findings
- 5.3Contributions to Knowledge
- 5.4Practical Implications
- 5.5Recommendations for Practice
- 5.6Suggestions for Further Study
Project Abstract
The design and construction of a microcontroller time socket outlet is a project aimed at creating an intelligent and energy-efficient solution for controlling electrical devices based on time schedules. The system integrates a microcontroller unit with relay modules to enable the automatic switching of connected devices according to pre-set time settings. The project involves the design and development of the hardware components, including the microcontroller unit, relay modules, power supply, and user interface. Additionally, software programming is implemented to facilitate the scheduling and control functionalities. The microcontroller serves as the brain of the system, executing the programmed time schedules and managing the relay modules for device switching. The relay modules act as the interface between the microcontroller and the electrical devices, allowing for safe and efficient control of power supply. A user interface, which can be in the form of a digital display or mobile application, enables users to set and adjust the time schedules according to their preferences. The construction of the microcontroller time socket outlet involves assembling the hardware components into a compact and user-friendly device. Proper insulation and safety measures are implemented to ensure reliable and secure operation. The system is designed to be compatible with a wide range of electrical devices, making it versatile for various applications in homes, offices, and industrial settings. The software programming aspect of the project involves developing a user-friendly interface for setting time schedules, configuring device control options, and monitoring the system status. The programming also includes error handling mechanisms to ensure the system operates smoothly and efficiently. Advanced features such as remote access and connectivity can be incorporated for enhanced functionality and convenience. Overall, the design and construction of a microcontroller time socket outlet offer a practical and efficient solution for automating electrical device control based on time schedules. The integration of hardware components with software programming results in a versatile and user-friendly system that can contribute to energy savings, convenience, and automation in various settings. Further enhancements and customization options can be explored to tailor the system to specific user requirements and preferences.
Project Overview
<p>
</p><p><strong>INTRODUCTION</strong></p><p>As the world becomes concerned with conserving electric power and the fuels that generate electricity, there is a growing need for the conscientious homeowner to keep an eye on and minimize their power usage.</p><p>Vampire or standby power is loosely defined as the “electricalpowerconsumed by appliances while they are switched off (but are designed to draw some power) or in a standby mode. This only</p><p>occurs because some devices claimed to be “s different state from switching off at the pl off at the power point is effective enough to control the vampire power, there is no need to</p><p>disconnect all the devices from the power point [1].</p><p>Some devices utilize vampire power in a useful manner to provide persistence features such as maintaining clock settings between active sessions, convenience features such as powering the necessary hardware to respond to remote controls, and to eliminate long initialization times by keeping the hardware in a semi-powered state. Other devices have no beneficial use of vampire power, such as a powered but disconnected mobile device charger or an uninterruptible power supply (UPS) with no active system connected.</p><p>With advancement of technology, things are becoming simpler and easier for us. Automation is the use of control systems and information technologies to reduce the need for human work in the production of goods and services [2].</p><p>1</p><p>The case of the MICROCONTROLLER TIMER SOCKET OUTLET helps in conserving the vampire power. Electrical and electronic appliances are connected to the socket outlet and</p><p>programmed to be in power for a specific dur way in conserving energy as the device(s) is/are disconnected after the specified duration. It is very</p><p>useful in cases whereby the user has to keep in touch of what he or she had connected earlier and due to the multitasking nature of human beings, we tend to forget what had been connected to attend to other things in the household or wherever we find ourselves.</p><ol><li><strong>AIM AND OBJECTIVES OF THE PROJECT</strong></li></ol><p>The aim of this project is to;</p><p>Design and construct an automatic socket outlet with an operational timer incorporated into it using a microcontroller.</p><p>The objectives of this project are as follows:</p><p>To conserve electrical power domestically.</p><p>To reduce and subsequently prevent electrical hazards in the home front.</p><p>To control the use of electrical power domestically.</p><p>Through conservation and control of electrical power, electricity bills are reduced.</p><ol><li><strong>PROJECT MOTIVATION</strong></li></ol><p>Since the advent of socket outlet manufacturing in developing countries like Nigeria, solution has been found for power conservation or regulation. There is yet to be an effective socket outlet for timing domestic socket outlets. The failure to have an operational timer for the socket outlets has</p><p>2</p><p>caused a lot of electrical hazards. This has claimed lives and properties of many people. The user often forgets to look after what he/she had connected and due to incessant power outages, he/she often forgets to switch off appliances earlier connected to power when leaving his/her home or due to carelessness of the user. Due to this negligence, the connected appliances continue to build up, when power is restored, even after completing their purpose of connection and when it gets beyond control, it damages the appliances. Repeated occurrences of these hazards have led to the loss of valuable things worth millions of naira.</p><p>However, with the help of a timer socket outlet, an effective solution is provided to these problems. An effective control timer for the socket outlet makes it safer and easier to use and also helps to reduce hazard rate. The use of a microcontroller comes to play in this motivation. Every microcontroller has a timer unit inside. A timer is nothing more than a time counting device fabricated inside the microcontroller unit. A wide range of practical applications require a timer in action. For example, we need to turn a motor ON for 5 minutes and then turn it OFF, how will we do that? A timer inside a microcontroller unit aids us in implementing this perfectly.</p><ol><li><strong>METHODOLOGY</strong></li></ol><p>The circuit employs the use of various electrical and electronic components like resistors, capacitors, light emitting diode (LED), switches, piezoelectric buzzer, 13-amp socket outlet, jumper wires, 7-segment display, battery, relay, Vero board and most importantly, the Peripheral Interface Microcontroller 16F877 microcontroller (PIC 16F877).</p><p>The microcontroller is programmed using”softwarethe“MikroC.Itis prog to communicate with all the other components on the board.</p><p>3</p><p>The switches are used to input instructions into the microcontroller. The instructions are basically</p><p>the SET TIME, START, RESET and STOP.</p><ul><li>The SET TIME instructions are displayed on the 7-segment display.</li></ul><ul><li>The START button signifies the beginning of the entire timing process.</li></ul><ul><li>If a wrong time is set in, the RESET button helps to restore it to default.</li></ul><ul><li>The STOP button helps to stop the timing process, this is necessary as there could be a change of mind after the process has started.</li></ul><p>The battery serves as a temporary memory holder. If during the process, there is power outage and the set instruction has not been reached, it will help the circuit start from where it stops when power is restored. For example, a 12,000-litre reservoir fills to the brim in 30minutes, the set instruction will be 30minutes and if there is power outage after the 23rd minute, the battery helps to continue from where it stopped (23rd minute) to the 30th minute. However, a major limitation to this is in the use of a boiling ring, or for the purpose of boiling. If experimentally, pure water boils in exactly 10mins, and power outage occurs in the 7th minute for as long as 30minutes, when power is restored, the water cannot boil in 3minutes again. So this is where the STOP button comes to play.</p><p>The buzzer and the LED serve as audio and visual indicators respectively. They indicate the completion of the timing process. They indicate that the process was completed according to the set instruction. After completion, the circuit automatically shuts the relay off which stops the supply of power to the circuit thereby conserving power.</p>
<br><p></p>