logologo
Contact

HOMEABOUTSERVICESBLOGSBOOKSSHOPCONTACT

+977 9803661701support@nepatronix.orgLokanthali, Bhaktapur

© 2025 NepaTronix all rigths reserved

Play Buzzer with Solar Panel Power(STEAM Education)

  Back To Blogs

To understand and demonstrate the utilization of solar energy to power and play Buzzer.

Project : 15


Play Buzzer with Solar Panel Power

 

Project Aim:

To understand and demonstrate the utilization of solar energy to power and play Buzzer.

 

Components Used:

1.     Solar Panel

2.     Buzzer

3.     Connecting Wires

 

Circuit Diagram:



If you want to post your project ,research or any document related to Ai,Ml,IoT,Robotics then please email us with your image ,details and your project at blog@nepatronix.org


Connection Procedure:

Step 1: Connect the Positive Terminal of the solar panel (Pin 51) to Positive terminal (+Ve) of Buzzer (Pin 54).

Step 2: Connect the Negative Terminal (-Ve) of Buzzer (Pin 53) to the Negative Terminal of the Solar Panel (Pin 52).

Step 3: As sunlight (or any source of light) falls on the solar panel, it generates electrical energy, causing the Buzzer to BEEP.

 

Explanation:

In this project, we're connecting a solar panel with a buzzer in series. The solar panel contains photovoltaic cells that directly convert light energy into electrical energy through the photovoltaic effect. When sunlight falls on the solar panel, it generates electrical voltage, which activates the buzzer to produce a beep sound. This demonstrates how solar energy can be harnessed to power simple devices like a buzzer, showcasing the potential of renewable energy sources like solar power.


If you want to post your project ,research or any document related to Ai,Ml,IoT,Robotics then please email us with your image ,details and your project at blog@nepatronix.org




Total likes : 4

Comments






Read More Blogs!

Carbon Monoxide Reader On Mobile App(IoT project)

The Carbon Monoxide Reader project aims to develop a robot that monitors carbon monoxide (CO) levels and reports the data to a mobile application using the Blynk platform. This integration allows for real-time data visualization and alerts through a WiFi connection, enhancing safety by providing timely notifications of dangerous CO levels. The project leverages components such as the ESP32, a CO sensor, and an LCD for local display, combined with the Blynk app for remote monitoring. This project highlights the practical applications of IoT in environmental monitoring and mobile app interfacing with microcontrollers.


1.5k03

FIRE DETECTION THROUGH ESP32 MOBILE APP (IoT Project in Nepal)

This project is designed to detect fire using an ESP32 microcontroller and a flame sensor. The system monitors the flame sensor's readings and sends data to a mobile app via the Blynk platform. Additionally, it displays the status on an LCD screen. If fire is detected, an alert message is displayed on both the mobile app and the LCD. This project demonstrates how IoT can be leveraged for fire detection and safety systems.


2.8k04

Run Motor Fan from Solar(STEAM Education)

To understand the practical application of solar energy by demonstrating its conversion into electrical energy to power a Motor Fan.


1.7k03

Diode Action in Forward bias(STEAM Education)

To understand the functioning of a diode under forward-biased conditions


1.8k05