Air Pollution Control Project/Inspire Award Winning Project/Electrical Project For Final Year/Diploma Engeering Project For Students
Objective: To mitigate air pollution by capturing vehicle emissions and converting them into usable ink.
Technology Used: Carbon filters integrated into vehicles to capture emitted smoke particles.
Conversion Process: Smoke particles trapped by filters are processed to extract carbon-based materials suitable for ink production.
Original price was: ₹4,999.00.₹3,750.00Current price is: ₹3,750.00.
In the relentless battle against pollution, innovative solutions are indispensable. Imagine a world where every vehicle that traverses our roads not only serves its transportation purpose but also becomes a contributor to environmental sustainability. Introducing our revolutionary project: a pollution mitigation system ingeniously integrated into the very infrastructure of our roads.
In this visionary endeavor, we have conceptualized and implemented a groundbreaking solution to address the rampant issue of vehicular pollution. Our project ingeniously harnesses the emissions expelled by vehicles on roads and transforms them into a resource for positive environmental impact.
At the heart of our innovation lies the Smoke Absorber, strategically positioned along the thoroughfare. Equipped with state-of-the-art IR Sensor modules, this absorber springs into action upon detecting the approach of any vehicle. Triggered by the IR Sensor’s signal, the relay mechanism activates, powering the absorber’s motors to commence its pivotal task.
As vehicles traverse the road, their emissions are swiftly captured and drawn into the Smoke Absorber’s chamber. Here, the pollutants are contained and channeled towards a secondary absorber unit, which directs them through a series of carbon filters. These filters, meticulously designed and implemented, efficiently trap the harmful pollutants while allowing clean air to pass through.
Notably, our pollution mitigation system operates with optimal efficiency and minimal energy consumption. By employing intelligent sensor technology, it remains dormant until a vehicle’s presence activates it, ensuring that energy resources are utilized sparingly and effectively.
The captured pollutants, now securely confined within the carbon filters, undergo a transformative process. Through innovative techniques, these pollutants are converted into a valuable resource: ink. This ink, derived from the very emissions that once polluted our atmosphere, symbolizes our project’s commitment to sustainability and resourcefulness.
Furthermore, our project exemplifies a symbiotic relationship between transportation infrastructure and environmental preservation. By seamlessly integrating pollution mitigation mechanisms into the fabric of our roads, we pave the way for a cleaner, healthier future.
Join us as we embark on this journey towards a greener tomorrow, where every mile traveled contributes not only to progress but also to the restoration of our planet’s precious ecological balance. Together, let us redefine the notion of vehicular impact and pave the way for a sustainable future.
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1. Introduction: In today’s world, the growing concern for environmental sustainability has led to the development of renewable energy solutions. Electric vehicles (EVs) have gained popularity as an eco-friendly alternative to traditional gasoline-powered cars. However, one of the challenges faced by EV owners is the limited range due to battery constraints. To address this issue, we have developed a groundbreaking project – a solar-powered wireless charging system that can provide emergency charging to electric vehicles using a remote-controlled (RC) robotic car.
Welcome to our Smart Inverter Project tutorial! In this video, we’ll show you how to build a DIY inverter that provides an automatic power backup solution for your home. If you’re looking for a continuous power supply during outages, this inverter with battery storage will keep your lights on even when the main power goes out.
This project involves creating a smart inverter circuit that can seamlessly switch from AC power to a 12V DC battery when the electricity supply is interrupted. Not only does it ensure uninterrupted power to your 230V AC appliances, but it also recharges the battery when the main power is available.
In this detailed how-to guide, we cover everything from the basic components needed to the step-by-step assembly and testing of the inverter. Plus, we’ll discuss how this inverter system can be adapted for use in transmission lines, ensuring a reliable power supply to cities from substations, even if the main transmission line fails temporarily.
What You’ll Learn in This Video:
Inverter Basics: Understand how an inverter works and the role of battery storage in providing continuous power.
Step-by-Step Construction: Follow our easy instructions to build your own inverter circuit with a 12V DC battery backup.
Automatic Switching: Learn how the inverter automatically switches to battery power during outages and back to AC power when available.
Practical Applications: Discover how this smart inverter system can be used in transmission lines to maintain city power supply during disruptions.
In this video, I demonstrate how to create a floating house using ACC blocks (Autoclaved Aerated Concrete blocks) and a cardboard house. I built the base of the house with ACC blocks, which are lightweight and float on water. When placed in a water tank, the house’s height automatically rises with the water level, preventing it from sinking. This project shows how real-life houses can be designed to stay afloat during heavy rainfall or floods, offering a solution for disaster management in flood-prone areas. The idea behind this floating house concept is to build homes that automatically adjust their height based on the rising water levels, ensuring that they do not get submerged during extreme weather conditions.
This floating house project is a great idea for those interested in science experiments, civil engineering projects, or innovative disaster management solutions. Whether you’re a student, a science enthusiast, or someone looking for unique school projects, this video will help you understand the concept of a floating house and its potential use in real life. Watch the full video to see how you can make this project at home and learn about flood-resistant house designs.
How It Works: Laser Beam Setup: A laser torch emits a beam that travels across the area by reflecting off three strategically placed mirrors (glasses). This configuration creates a continuous laser barrier around the perimeter of a model house or any area you wish to secure.
LDR Detection: The laser beam ultimately hits an LDR module, which is sensitive to light. As long as the laser beam is unbroken and falls on the LDR, the system remains in a passive state, with no alarm triggered.
Relay and Buzzer Activation: The LDR is connected to a single-channel relay module that controls a 9V buzzer. If the laser beam is interrupted, the LDR detects a change in light intensity, signaling the relay to activate the buzzer. This results in an audible alarm that warns you of the potential intrusion.
Unauthorized Entry Alert: The alarm is designed to activate whenever there is an obstruction in the laser path, such as someone entering the secured area without permission. This feature provides a simple yet effective means of safeguarding your space.
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The Cow Drone Safety system is a cutting-edge technology designed to improve the safety and well-being of cattle on farms. By utilizing drones equipped with advanced sensors and monitoring capabilities, this system aims to revolutionize the way farmers manage their livestock. In this project, we will explore the design, functionality, and potential benefits of the Cow Drone Safety system.
How It Works: Traffic Light Sequence: Our setup uses BC547 transistors to control the traditional red, yellow, and green traffic lights, allowing them to operate in a seamless sequence.
Blue LED Congestion Indicator: The key feature of our system is the blue LED, which lights up to indicate traffic congestion.
IR Sensor Modules: We have installed three IR sensor modules along the road. These sensors detect the presence of vehicles.
Relay Modules: Each IR sensor is connected to a relay module. When all three sensors detect vehicles simultaneously, they activate their respective relays.
Congestion Detection: Once all the relay modules are active, the blue LED lights up, indicating that the road is congested. If any one of the relay modules is inactive, it means there is space on the road, and the blue LED remains off, indicating that traffic is flowing smoothly.
Benefits: This project provides real-time traffic updates, helping drivers make informed decisions and allowing authorities to manage traffic more efficiently.
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Design and Operation: VAWTs typically consist of two or more blades that rotate around a vertical axis. The blades can have different shapes, such as straight, helical, or S-shaped, and are attached to a central shaft. As the wind blows, the blades capture the kinetic energy and convert it into mechanical rotation, which can then be used to generate electricity through a generator or to perform other tasks directly.
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