International Research Journal of Innovations in Engineering and Technology - IRJIET International Open Access, Monthly, Peer Reviewed, Reputed Journal ISSN (online): 2581-3048

Impact Factor (2025): 6.9

DOI Prefix: 10.47001/IRJIET

Speed and Direction Control of DC Geared Motor Using WiFi Module

Abstract

This study covers the design and implementation of a remote brush direct-current (DC) motor speed control platform that is WiFi-based.[1] The NODE MCU, battery, dummy, chassis, and motor driver circuit(L293D) are the parts that make up the platform. The main processor, NODE MCU, is configured with Linux to provide remote control and speed feedback of the motor within a WiFi environment.[2] This article then uses socket technology to realize the processor's communication with the remote client.[3] The encoder and speed meter record the geared DC speed, which is measured by the speed sensor. This article provides a detailed description of the development process of the networked control platform. The platform's feasibility is verified through experimentation using the findings.

Country : India

1 Dr. Anupama Singh2 Dr. Sawata Deore3 Labhada Khandare4 Sanket Shinde5 Pranav Rane6 Raj Nangare

  1. Assistant Professor, Department of Electrical Engineering, A. C. Patil College of Engineering, Kharghar, India
  2. Head of Department of Electrical Engineering, A. C. Patil College of Engineering, Kharghar, India
  3. UG Student, Department of Electrical Engineering, A. C. Patil College of Engineering, Kharghar, India
  4. UG Student, Department of Electrical Engineering, A. C. Patil College of Engineering, Kharghar, India
  5. UG Student, Department of Electrical Engineering, A. C. Patil College of Engineering, Kharghar, India
  6. UG Student, Department of Electrical Engineering, A. C. Patil College of Engineering, Kharghar, India

IRJIET, Volume 8, Issue 3, March 2024 pp. 358-361

doi.org/10.47001/IRJIET/2024.803055

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References

  1. Lei B, Chen H. Swarm Robots Formation Control Based on Wireless Sensor Network, International Conference on Internet and Distributed Computing Systems. Springer International Publishing, 2016: 458-465.
  2. Papadopoulos G Z, Kritsis K, Gallais A, et al. Performance evaluation methods in ad hoc and wireless sensor networks: a literature study. IEEE Communications Magazine, 2016, 54(1): 122-128.
  3. Du X, Wang J, Ji P, et al. Design and implement of wireless measure and control system for greenhouse, Control Conference, 2011 30th Chinese. IEEE, 2011: 4572-4575.
  4. Guo P, Zhang J, Lv M, et al. Fault detection for wireless network control system with multiple time delay and packet loss, Control Conference, 2014 33rd Chinese. IEEE, 2014: 3012-3017.
  5. Liu G P. Predictive controller design of networked systems with communication delays and data loss. IEEE Transactions on Circuits and Systems II: Express Briefs, 2010, 57(6): 481-485.
  6. Zhang H, Shi Y, Mehr A S. Robust static output feedback control and remote PID design for networked motor systems. IEEE Transactions on Industrial Electronics, 2011, 58(12): 5396-5405.
  7. Zheng R, Cai R, Li M. An on-line active energy flow split strategy for battery-ultra capacitor energized PMSM driving system, Industrial Electronics Society, IECON 2016-42nd Annual Conference of the IEEE. IEEE, 2016: 2694-2701.
  8. Vandorpe J, Vliegen J, Smeets R, et al. Remote FPGA design through DiViDe—European Digital Virtual Design Lab, Field Programmable Logic and Applications, 2013 23rd International Conference on. IEEE, 2013: 1-1.
  9. https://www.theengineeringprojects.com/2017/07/introduction-to-l293d.html
  10. https://embetronicx.com/tutorials/tech_devices/l293d-motor-driver-working/#:~:text=L293D%20H%2Dbridge%20driver%20is,motors%20simultaneously%20in%20any%20direction

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