Bicycle Generator

The purpose of this project is to design a power generation system that will utilize the mechanical energy produced by the pedaling of a bicycle to charge the battery. Design is to be implemented on a bicycle mechanically coupled with a permanent magnet DC-generator capable to support 480-500 watts

Project Title

Bicycle Generator

Project Area of Specialization

Electrical/Electronic Engineering

Project Summary

The purpose of this project is to design a power generation system that will utilize the mechanical energy produced by the pedaling of a bicycle to charge the battery. Design is to be implemented on a bicycle mechanically coupled with a permanent magnet DC-generator capable to support 480-500 watts of the system. The pedaling bicycle will rotate the generator producing DC power, which will be an input of a designed push-pull converter to buck the output when the
generated power at the DC-generator is high for charging up of 12 V battery and boost the output when the generator output voltage is less for the charging up of battery. The system includes the development of a battery management system, comprising a microcontroller and simple LCD that will monitor the battery’s voltage, temperature, charging voltages, and currents as well as output voltages of the generator. The edge of this model is that bicycles can be attached and separated from the cycle anytime using a special cycle to generator coupling mechanism. Using this bicycle generator, gym owners, as well as households, can charge up their batteries free of cost while doing exercise.

Project Objectives

Following are the main objectives of our Project Bicycle Generator

1. To design a system capable of producing 480-500watts of power.
2. To analyze and design a DC-DC Push-Pull converter according to the system specification.
3. To design a 3D model for mechanical coupling.
4. To implement a battery monitoring system.

Project Implementation Method

Following are the implementation steps of the Bicycle Generator Project:

1. Mathematical calculation and designing of the push-pull converter
2. Designing of high-frequency transformer for push-pull converter
3. Controller coding of feedback implementation of the push-pull converter
4. DC generator selection according to the system specification
5. 3D modeling of mechanically coupled hardware
6. Microcontroller coding of the battery monitoring system
7. Software implementation of the system
8. Hardware implementation
9. Testing and finetuning of system

Benefits of the Project

Following are the Direct Benefits of the Project:

1. Charge batteries
2. Run electrical devices directly
3. Can be used as an effective backup unit
4. Portable System
5. Free charge up of UPS batter

Following are the Indirect Benefits  of the Project:

1. Keeps you fit and healthy
2. Lower electricity cost
3. Energy source for remote areas

Technical Details of Final Deliverable

The final deliverables will be:
1. Designing a Push-pull converter
2. Designing of a 480–500-watt system
3. Design Mechanical Hardware for coupling
4. Designing of Battery Monitoring System
5. Complete Hardware Design of System

Final Deliverable of the Project

Hardware System

Core Industry

Energy

Other Industries

Manufacturing

Core Technology

Clean Tech

Other Technologies

Others

Sustainable Development Goals

Affordable and Clean Energy

Required Resources

If you need this project, please contact me on contact@adikhanofficial.com