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PROJECT PPT.pptxhsvsnnhbsnsbsbnnnnsbsbsnb
1.
2. VISVESVARAYA TECHNOLOGICAL UNIVERSITY
BELAGAVI - 590 018
GOVERNMENT ENGINEERING COLLEGE
HUVINA HADAGALI - 583219
DEPARTMENT OF ELECTRONICS AND COMMUNICATION
ENGINEERING
PROJECT PHASE I PRESENTATION
“IOT BASED WIRLESS VEHICLE CHARGING STATION ”
UNDER THE GUIDENCE OF : - MR. MANUKUMAR G B
PRESENTED BY : -
GANESH S G 2GB20EC003
JEEVAN K 2GB20EC006
MADHUKUMAR M 2GB20EC009
THYAGARAJA J 2GB20EC020
3. The transition to Electric Vehicles (EVs) is reshaping the landscape of
transportation and sustainable mobility.
Harnessing the power of the IoT, our charging station facilitates real-time
monitoring, employs data analytics and optimizes the charging process.
The transition to electric vehicles (EVs) plays a pivotal role in mitigating
environmental concerns and reducing dependency on traditional fossil fuels.
In response to this demand, our project introduces an innovative solution an
Internet of Things (IoT)-based wireless vehicle charging system.
4. It offers real-time insights into charging status, tariff rates, and battery State of
Charge (SOC).
To support the widespread adoption of EVs, efficient and user-friendly charging
infrastructure is imperative.
By deploying sensors at the charging stations, real-time data on availability and
usage is continuously collected
5. Develop an IoT based wireless vehicle charging station for
efficient and intelligent EV charging.
Integrate IoT technologies to enable real-time monitoring,
data analytics, and optimization.
Ensure scalability, flexibility, and alignment with smart
city initiatives.
Create a user-friendly interface for real-time information
and remote control.
6. Conducted by P. Paul et al. (2021), an ESP32-based wireless charging
station was developed for electric vehicles:The charging station was
designed to be controlled remotely using an Android application. The
ESP32 module was used to monitor the charging process, collect data, and
provide realtime feedback to the user.
Conducted by D. Mandal et al. (2021), an ESP32-based wireless
charging station was developed for mobile devices:The charging station
was designed to charge multiple devices simultaneously and was equipped
with inductive coils to ensure efficient charging.
Conducted by A. Sharma et al. (2020), an ESP32-based wireless
charging station was developed for electric vehicles:The charging
station was designed to charge the vehicle battery using inductive power
transfer.
7. Conducted by. Li et al. (2020), an ESP32-based wireless charging
station was developed for wearable devices. The charging station was
designed to charge the devices using inductive power transfer.
8.
9. Wireless Power Transfer:
The charging pads or coils use electromagnetic induction to
wirelessly transfer power from the charging station to the
electric vehicle. This process eliminates the need for physical
cables, offering a convenient and efficient charging experience.
Microcontroller Control:
The Arduino microcontroller serves as the central control unit. It
manages the charging process by coordinating the relay for
power control, interpreting data from the current transformer
for real-time monitoring, and interacting with user interfaces
such as the LCD display.
Real-time Monitoring:
The current transformer continuously monitors the electric
current during the charging process. This real-time data is
crucial for ensuring the safety of the charging operation,
preventing overcurrent situations, and optimizing charging
efficiency.
10. Wireless Communication:
The WiFi module facilitates wireless communication,
enabling users to remotely monitor and control the
charging station. This feature allows for convenient
access to charging status and control functions using an
Android device.
User Interface - LCD Display:
The LCD display provides users with real-time feedback
on the charging status. It displays essential information
such as battery level, charging progress, and any relevant
alerts, enhancing the user's understanding of the charging
process
13. Commercial Lots: Provide cost-effective and green charging in business parking
spaces.
Highways: Optimize charging at highway stations based on real-time rates.
Fleet Charging: Improve efficiency in charging for commercial fleets.
Tourist Attractions: Offer optimized charging at popular destinations.
Cost-Efficiency: Minimizes charging costs through real-time tariff analysis.
Remote Control: Enables convenient monitoring and control for user
14. Remote control and monitoring enhance user convenience in initiating and
overseeing the wireless charging process.
Wireless charging technology, such as inductive charging, eliminates the
need for physical cables, offering a streamlined and wear-resistant solution.
IoT integration establishes a smart infrastructure, allowing seamless
communication between charging units, vehicles, and a centralized server.
Energy optimization and real-time data analysis contribute to efficient
power distribution, reducing charging times and promoting sustainable
electric vehicle usage.
15. P. Paul, P. Mohanty, S. S. Mahapatra, and D. K. Pradhan,
"Design of Wireless Charging Station for Electric
Vehicles using ESP32 with IoT-Based Monitoring
System," in 2021 7th International Conference on
Advanced Computing and Communication Systems
(ICACCS), Coimbatore, India, 2021, pp. 57-62, doi:
10.1109/ICACCS52232.2021.9373304
D. Mandal, S. Singh, S. Biswas, S. Roy, S. S. Saha, and S.
K. Ray, "Design and Implementation of a Multi-Device
Wireless Charging Station Using ESP32," in 2021 6th
International Conference on Control, Automation and
Robotics (ICCAR), Nagoya, Japan, 2021, pp. 385-390, doi:
10.1109/ICCAR50762.2021.9428705.
16. A. Sharma, R. A. Mehta, and J. K. Solanki, "Design and
Implementation of Wireless Power Transfer System for
Electric Vehicle Using Inductive Power Transfer Technique,"
in 2020 3rd International Conference on Inventive Research in
Computing Applications (ICIRCA), Coimbatore, India, 2020, pp.
153-157, doi: 10.1109/ICIRCA49224.2020.9126167.
C. Li, Z. Chen, C. Song, and J. Liu, "Design and
Implementation of Wireless Charging System for Wearable
Devices Using Inductive Power Transfer Technology," in 2020
IEEE 4th Information Technology, Networking, Electronic and
Automation Control Conference (ITNEC), Chengdu, China,
2020, pp. 763-767, doi: 10.1109/ITNEC48647.2020.9149563.