e-Newsletter-November 2024

 Department Events

Industrial Visit on 05/11/2024 at Sai Biomass Company, Dindori

On 5th November, the Department of Electrical Engineering organized an insightful industrial visit for TY Div. B students at Sai Biomass Company, Dindori. This visit provided our students an excellent opportunity to bridge the gap between classroom learning and real-world applications. Prof Chetan Gadage and Prof. Pooja Sapkade coordinated this visit seamlessly. The students gained valuable exposure to advanced technologies and industry practices, making it a truly enriching experience.

Industrial Visit to Teknocrat's Control Systems India Pvt. Ltd!

On 26th November 2024, the Department of Electrical Engineering, in collaboration with the Institution's Innovation Council (IIC), organized an insightful Industrial Visit for final-year students to Teknocrat's Control Systems (I) Pvt. Ltd. (Manufacturing Division)

This visit was part of the Advanced Control Systems course, designed to bridge the gap between classroom learning and industry practices. Students had the opportunity to gain first-hand experience with state-of-the-art automation and control technologies, enriching their understanding of real-world applications in industrial automation.

Such industry interactions inspire innovation, critical thinking, and a deeper appreciation of engineering practices. We extend our sincere thanks to Teknocrat's team for their guidance and hospitality, which made this visit a valuable learning experience. Prof. Rupali Ahire and Prof. Chetan Gadge coordinated the visit.

Student Corner

Student Placement

The following students are placed in various multinational companies. Congratulations to all the students!

Placed Students Details (November - 2024)

Sr. No.	Name of the Student	Package	Placement Date
	Gitesh Rajesh Patil	4.5	06/11/2024
2.	Raj Dhanraj Chavhan	4.5	06/11/2024
3.	Ritesh Jyotiram Arote	4.5	06/11/2024
4.	Varun Ravindra Bhadane	2.28	23/11/2024
5.	Shubham Manoj Bhagwat	3.75	23/11/2024
6.	Roshan Sharad Anwat	3.75	23/11/2024

Faculty Corner

Congratulations to Prof. Ganesh Jadhav

Prof. Ganesh Jadhav received the certificate of registration of design from the Patent Office, Government of India for an Electric Scooter Chassis. 

Alumni Success Story: Inspiring the Next Generation!

On 5th November 2024, we welcomed our alumni, Harshal Waghulde, Associate Power System Engineer, and Devang Vyas, Associate Power Systems Analyst (2021-2022 batch) from ABB Global Industries and Services Private Limited, Nashik!
Harshal and Devang visited our campus to conduct internship interviews for our third- and final-year students, sharing their expertise and guidance while opening doors to exciting opportunities. Their presence on campus exemplifies the power of a strong alumni network, as they inspire the next generation to excel and build meaningful careers.

Newspaper Cutting

Student Article

IoT-Based Smart Plant Monitoring System

Guided by:Dr. Saravanan S

Sejal S. Kumbhare SY-B (Electrical) sejalkumbhare02@gmail.com                                                            Divya A. Katkade                                                              SY-B (Electrical) divyakatkade3@gmail.com Abhinav A. Keshewar SY-B(Electrical)         abhinavkeshewar777@gmail.com Abstract The Smart Plant Monitoring System utilizes NodeMCU and various sensors to create an intelligent and automated solution for plant care. This mini project integrates a DHT11 sensor to monitor temperature and humidity, a PIR sensor for detecting movement around the plant, and a soil moisture sensor to assess the hydration levels of the soil. Additionally, a relay module is employed to automate watering based on the moisture readings. Data from these sensors is transmitted wirelessly to a user-friendly mobile application, allowing users to monitor their plants in real-time and receive alerts when specific conditions, such as low moisture or extreme temperature, are detected. The system not only enhances plant health through timely interventions but also encourages sustainable practices by optimizing water usage. This Smart Plant Monitoring System represents a significant step towards modernizing gardening, making it accessible and efficient for enthusiasts of all levels. 1. Introduction The Internet of Things (IoT) has revolutionized how we interact with and monitor the environment around us, enabling the development of innovative and efficient solutions for everyday challenges. One such application is smart plant monitoring systems, which leverage IoT technology to ensure optimal growth conditions for plants while reducing human effort.                                                                                                     This project introduces an IoT-based Smart Plant Monitoring System using the NodeMCU microcontroller, a versatile and cost-effective platform powered by the ESP8266 Wi-Fi module. The system is designed to monitor key environmental parameters such as soil moisture, temperature, humidity, and light intensity, which are crucial for plant health. The real-time data collected by the sensors is transmitted to an IoT platform, enabling users to remotely monitor plant conditions via a smartphone or web interface. In addition to real-time monitoring, the system can be integrated with automated actuators, such as water pumps by ensuring timely irrigation the system not only enhances plant growth but also conserves resources like water.   2. Problem Identification Problems in plant care include resource wastage, labor-intensive monitoring, delayed detection of issues, unpredictable climate impacts, lack of real-time data, inefficiency in large-scale farming, urban space constraints, high costs, scalability challenges, and integration difficulties with existing methods.  3. System Overview The Smart Plant Monitoring System consists of several key components that work together to monitor and manage plant health: A Circuit Diagram of an IoT-based smart plant monitoring system is shown in Fig 1. Microcontroller (NodeMCU): The NodeMCU serves as the central processing unit of the system, featuring Wi-Fi capabilities for remote communication. It collects data from connected sensors and facilitates user interaction through a mobile app or web interface.               Fig 1: Circuit Diagram of IoT-based smart plant monitoring system The Smart Plant Monitoring System consists of several key components that work together to monitor and manage plant health. Microcontroller (NodeMCU): The NodeMCU serves as the central processing unit of the system, featuring Wi-Fi capabilities for remote communication. It collects data from connected sensors and facilitates user interaction through a mobile app or web interface. 1) DHT11 Sensor: This sensor measures the temperature and humidity of the environment. By providing real-time data, it helps users maintain optimal conditions for plant growth, allowing for timely adjustments to watering and ventilation. 2) Soil Moisture Sensor: This sensor gauges the moisture level in the soil, helping to determine when irrigation is necessary. The system can automate watering processes, activating a relay to control a water pump when moisture levels drop below a specified threshold. 3) PIR Motion Sensor: The motion sensor detects any movement near the plants, enhancing security by alerting users to potential disturbances or unauthorized access. This feature is particularly useful in protecting valuable crops. 4) Relay Module: The relay acts as a switch that controls external devices, such as irrigation systems or grow lights. It receives commands from the NodeMCU based on sensor readings, allowing for automated responses to environmental conditions. 5) User Interface: The system includes a user-friendly interface accessible via a mobile app or web dashboard. This interface displays real-time data, allows users to configure settings, and sends notifications regarding plant conditions or security alerts.   4. Working The smart plant monitoring system operates through an integrated combination of hardware and software components that work together to enhance plant care. Initially, various sensors, including the DHT11 for temperature and humidity, the soil moisture sensor for monitoring soil conditions, and the PIR sensor for motion detection, continuously collect data about the environment and plant health. This data is sent to a central microcontroller, typically a Node MCU, which processes the information based on predefined thresholds. For instance, if the soil moisture falls below a certain level, the microcontroller activates a relay module to trigger an irrigation system, ensuring the plants receive adequate water without manual intervention. Additionally, the system connects to a Wi-Fi network, allowing users to monitor real-time data through a mobile application or cloud platform, complete with alerts for critical conditions like low moisture or high temperatures. The PIR sensor enhances security by notifying users of any unauthorized movement. The system can also log historical data, enabling users to analyze trends and make informed decisions about plant care. Overall, the smart plant monitoring system combines automation, remote access, and data analysis to provide a comprehensive solution for effective plant management. 5. The need for a greenhouse monitoring system A smart plant monitoring system ensures efficient resource use, improves plant health, automates care, supports sustainability, and adapts to changing conditions. It uses IoT sensors and AI to monitor soil, water, and environmental factors, reducing labour and costs while enhancing productivity and convenience in farming, gardening, and landscaping.It optimizes resources (water, fertilizers), enhances plant health through real-time monitoring, detects issues early, automates care (irrigation), supports sustainability, adapts to climate changes, reduces costs, increases productivity, and integrates IoT and AI for efficient farming, gardening, and urban greenery management. Fig 2. Evaluation and Presentation of Project 6. Future Scope The future scope of smart plant monitoring systems includes AI-driven predictive analytics, advanced IoT sensors, precision agriculture, climate-resilient solutions, urban farming integration, improved global food security, user-friendly home systems, and data-driven innovations to enhance efficiency, sustainability, and productivity in plant care. 7. Conclusion The smart plant monitoring system represents a significant advancement in agricultural technology, integrating various sensors and IoT capabilities to optimize plant care. By providing real-time data on environmental conditions, automating irrigation, and enhancing security, the system effectively addresses the challenges of modern gardening and farming. Its ability to conserve resources while improving plant health makes it a valuable tool for both hobbyists and commercial growers. Overall, the system enhances productivity, efficiency, and user engagement, paving the way for a smarter approach to plant management.