Abstract
This project presents an advanced Battery Monitoring System (BMS) designed for Electric Vehicles (EVs), offering innovative features tailored for large-scale deployment.
Key features include a voice assistant for audible warnings, integration of the STM32 microcontroller for enhanced performance, precise monitoring of battery temperature and current flow with sensors like DS1820 and ACS712, seamless remote monitoring and management via Arduino IoT Cloud, automatic activation of an air-cooled fan for thermal management, and implementation of safety mechanisms such as automatic voltage cutoff and shutdown in response to excess current or voltage.
Abstract
The "Cylinder Gas Monitoring System Using IoT" is a sophisticated solution designed to enhance the safety and efficiency of managing LPG gas cylinders within residential and commercial settings. This IoT-based system leverages an ESP32 microcontroller to detect LPG gas and smoke, triggering various safety measures and notifications as needed.
Abstract
The Smart Parking System using IoT presents a dynamic solution to the modern urban challenge of efficient parking management. In light of the ever-increasing vehicular population and limited parking resources, this project employs cutting-edge IoT technologies to enhance the parking experience for both vehicle owners and parking operators.
Hello Student,
Welcome to Engineering Projects Hub
We Make All Engineering Project
1) EMBEDDED SYSTEM ASSOCIATE
2) INTERNET OF THINGS(IOT)
3) PYTHON (MACHINE LEARNING, DATA SCIENCE)
4) MATLAB DEVELOPER
5) MECHATRONICS
6) Web Development
The goal of this project is to design and develop a solar panel cleaning robot that can clean solar panels efficiently and effectively. The robot is controlled by an Arduino Uno microcontroller and uses a HC05 Bluetooth module to communicate with a mobile device. The cleaning mechanism consists of a water pump and a cleaning brush that are powered by a 60 RPM gear motor and a L298N motor driver. The robot moves forward and backward with the help of a rack and pinion mechanism connected to the solar panel. The robot is designed to start cleaning when it receives a signal from the mobile device.The project involved designing the hardware and software of the robot. The hardware design included selecting and assembling the components, such as the gear motor, motor driver, and cleaning mechanism. The software design involved writing the code using the Arduino IDE and establishing a Bluetooth connection between the mobile device and the Arduino Uno microcontroller using the HC05 Bluetooth module.
Abstract
In the contemporary healthcare landscape, the need for innovative solutions to streamline Medicine dispensing processes and enhance accessibility is paramount. This project proposes the development of an Automatic UPI-based Medicine Vending Machine using IoT technology to address this need. The system integrates the Unified Payment Interface (UPI) for secure transactions and IoT components such as the ESP32 microcontroller, sensors, GSM module, LCD, and encoder to create a seamless and efficient platform for dispensing Medicines.
The proposed work will involve the assembly of the hardware components, including the Arduino Nano, LDR sensors, servo motors, 3D printed structures, and solar panel. The system will be programmed to detect the position of the sun using the LDR sensors and adjust the position of the solar panel using the servo motors. The voltage sensor will be used to detect the voltage output of the solar panel and display it on the LCD screen.Finally, the performance of the solar tracking system will be evaluated by measuring the efficiency of the solar panel under different lighting conditions with and without the solar tracking system. The results will be analysed to determine the effectiveness of the system in maximising the energy output of the solar panel.Overall, this project aims to develop an efficient solar tracking system using readily available components and technology to optimise the performance of solar panels and promote sustainable energy generation
The system also sends data to the Arduino IOT cloud using IoT technology, including the moisture level and the status of the pump and relay. This data can be analysed and monitored in real-time using a dashboard that displays graphs and charts. The system is highly efficient, and it saves water and improves crop yields. Additional sensors, such as temperature and humidity sensors, can be added to the system for more comprehensive environmental data analysis. Overall, this project demonstrates the power of technology to create innovative solutions for agriculture and environmental sustainability.
Abstract
The Solar Wireless Electric Vehicle Charging System represents a pioneering venture unsustainable transport
tion infrastructure, marrying renewable energy with innovative wireless charging technology. This project harnesses the power of solar energy to wirelessly charge electric vehicles, paving the way for eco-friendly mobility solutions.At its core, the system is controlled by two NodeMCU microcontrollers, orchestrated with Arduino IoT Cloud integration. These microcontrollers oversee the operation of various sensors and components crucial to the charging process. A DC voltage sensor facilitates the monitoring of electrical parameters, ensuring efficient power delivery.
This site was created with the Nicepage