Energy Generation from Waste Material
Submitted by
1.Vaibhav Meshram
2.Tanishq Fulekar
3.Saurabh Bhokre
Guided by
Name of the Guide
Dr. Sanjay Sajjanwar
Asst. Prof. Mechanical Engineering
JIT, Nagpur
Department of Mechanical Engineering
Jhulelal Institute of Technology
Session 2025-26
ABSTRACT
Abstract: In the modern world, the ever-increasing demand for energy, coupled with the growing challenges of waste management, has created a critical need for sustainable and eco-friendly solutions. Rapid urbanization, industrialization, and population growth have led to excessive generation of waste materials and a significant rise in energy consumption. Conventional energy sources such as fossil fuels are not only depleting rapidly but also contributing heavily to environmental pollution and global warming. In this context, the project titled “Energy Generation from Waste Material using Peltier Modules” presents an innovative approach to address both energy scarcity and waste disposal issues simultaneously.
This project is based on the concept of thermoelectric power generation, which involves the direct conversion of heat energy into electrical energy without the use of moving parts. The working principle primarily relies on the Peltier effect, where a voltage is generated across a material when there is a temperature difference between its two sides. The core component used in this system is a Peltier module (thermoelectric generator), a semiconductor device capable of converting thermal gradients into electrical energy.
The experimental setup consists of a combustion chamber, typically constructed using a heat-resistant metal enclosure such as aluminium. In this chamber, various types of waste materials—including paper, dry leaves, cardboard and other combustible waste—are burned to generate heat. This process not only helps in reducing waste volume but also produces a considerable amount of thermal energy that would otherwise be lost to the environment.
The generated heat is directed toward the hot side of the Peltier module, while the cold side is maintained at a lower temperature using cooling techniques such as heat sinks, air cooling fans . The temperature difference between the hot and cold surfaces creates a movement of charge carriers within the semiconductor layers of the module, thereby producing direct current electricity. The magnitude of the generated voltage depends on the temperature gradient, making thermal management a key factor in optimizing system performance.
To enhance the output, multiple Peltier modules can be connected in series to increase voltage and in parallel to increase current. The generated electricity can be stored in rechargeable batteries or directly utilized to power low-energy devices such as LED bulbs.
