Infrared (IR) wireless transmission technology has proven to be reliable in electric motor control. The existing control schemes for electric motors require the operator to be at the location of the motors or resort to the use of wired controls. Wired motor controls can fail due to objects falling on them and accidental disconnections. Also, voltage drops in the control wires are wasted in generating heat and increase the cost of electricity tariffs. Further, there is increase in labour cost and installation of wired motor control. Additionally, there are slips, trips and fall hazards associated with control trailing wires. In this research, a wireless control system for a three-phase, 415 V, 50 Hz, squirrel-cage induction motor is designed, simulated and implemented. The issues of voltage drop in control wires is minimised because of the reduced wires involved with this control scheme, thereby improving on the motor efficiency. The transmitter transmits IR signal to the receiver. There is a phototransistor in the receiver that receives the IR signal, amplifies it and decodes it with the help of a microcontroller. The output from the microcontroller is used to regulate auto-transformers to control the three-phase voltage to the motor. The designed system can wirelessly start, stop and change the speeds of induction motor for three successive speed levels. The receiver senses signal from the transmitter within a distance of 9 m. The system is designed to switch the motor into standby mode and then proceed to speeds one, two, three and then finally stop the motor. The developed infrared-based wireless transceiver can be adopted to control a three-phase, 415 V, 50 Hz, squirrel-cage induction motor at remote and inaccessible areas such as water treatment and three-phase separation plants.
| DOI | 10.11648/j.jeee.20200803.13 |
| Published in | Journal of Electrical and Electronic Engineering (Volume 8, Issue 3, June 2020) |
| Page(s) | 92-102 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Infrared Wireless Transmission, Transmitter, Receiver, Induction Motor
| [1] | Hossein-Ali, K. (2015), “Dynamic Analysis of Three-Phase Induction Motor in Dig Silent Power Factory”, MSc Thesis, School of Engineering and Information Technology, Murdoch University, Perth, Australia, pp. 67-77. |
| [2] | Anon. (2012), “Manual Motor Control and Overload Protection”, Electric Motor Control Learning Activity Packet 2, Amatrol Incorporated, Jeffersonville, USA, pp. 6-7. |
| [3] | Anon. (2013a), “Motor Control Solutions”, Data Bulletin, Schneider Electric, Knightdale, New York City, USA, pp. 11-15. |
| [4] | Anon. (2013b), “Scalar (V/F) Control of Three-Phase Induction Motors”, Application Report, Texas Instruments, Dallas, Texas, USA, pp. 3-5. |
| [5] | Kailaswar, S. V. and Keswani, R. A. (2013), “Speed Control of Three-Phase Induction Motor by V/F Method for Batching Motion System”, International Journal of Engineering Research and Applications, Vol. 3, No. 2, pp. 1732-1736. |
| [6] | Sarhan, H. (2014), “Effect of High-Order Harmonics on Efficiency-Optimized Three-Phase Induction Motor Drive System Performance”, International Journal of Enhanced Research in Science Technology and Engineering, Vol. 3, No. 4, pp. 15-20. |
| [7] | Thinga, R., Gupta, S. and Phulambikar, S. P. (2014), “Field Oriented Control of Single-Phase Induction Motor”, International Journal of Emerging Technology and Advanced Engineering, Vol. 4, No. 8, pp. 760-763. |
| [8] | Anon. (2015a), “Grundfos Motor Book”, www.grundfos.com. Accessed: January 13, 2016. |
| [9] | Karim, K. A., Yusoff, N. A. M., Jidin, A., Patkar, F., Firdaus, R. N. and Jamil, M. (2015), “Analysis of Five-Phase Induction Motor with Dynamic Load”, Asian Research Publishing Network Journal of Engineering and Applied Sciences, Vol. 10, No. 20, pp. 9830-9834. |
| [10] | Anon. (2016a), “Wireless Communications”, www.techopedia.com/definition/10062/ wireless-communications. Accessed: February 10, 2016. |
| [11] | Anon. (2016b), “History of Wireless Communications”, www.microwavejournal.com/ articles/24759. Accessed: February 10, 2016. |
| [12] | Jilani, S. A. (2015), “Spectrum Allocation Methods Studying Allocation through Auctions”, Journal of Economics, Business and Management, Vol. 3, No. 7, pp. 742-745. |
| [13] | Anon. (2016c), “Spectrum Allocation in Ghana’’, www.nca.org.gh. Accessed: February 11, 2016. |
| [14] | Deliversky, J., Yaneva-Deliverska, M., Lyapina, M. and Kisselova, A. (2015), “European and International Standards on Medical Devices for Dentistry”, International Medical Association of Bulgaria, Vol. 21. No. 1, pp. 713-717. |
| [15] | Anon. (2013c), “Empowering the Evolution of Technology”, Annual Report, New York, USA, pp. 13-14. |
| [16] | Anon. (2014), “Encouraging the Next Generation of Standards Expects”, World Standards Co-operation Day, Ottawa, Canada, pp. 6-7. |
| [17] | Anon. (2013d), “Performances and Feasibility of mmWave Beam Forming Prototype for 5G Cellular Communications”, Communications Research Team, Samsung Electronics Corporation, pp. 1-29. |
| [18] | Azar, Y., Wong, G. N., Wang, K., Mayzus, R., Schulz, J. K., Zhao, H., Gutierrez, F. Jr., Hwang, D. D. and Rappaport, T. S. (2013), “28 GHz Propagation Measurements for Outdoor Cellular Communications Using Steerable Beam Antennas”, IEEE International Conference on Communications, New York City, USA, pp. 1-2. |
| [19] | Walter, L. O. and Kritzinger, P. S. (2016), “Cellular Networks Past, Present and Future” www.faculty.kfupm.edu.sa/ICS/salah/082/ics343/handouts/mobile/mobileO. Accessed: February 15, 2016. |
| [20] | Banerji, S. (2013), “Upcoming Standards in Wireless Local Area Networks”, Wireless and Mobile Technologies, Vol. 1, No. 1, pp. 1-2. |
| [21] | Anon. (2016d), “Roaming Wireless Local Area Network Diagram”, www.conceptdraw.com/examples/local–area–network-diagram. Accessed: February 15, 2016. |
| [22] | Nathaniel, S., Onwuka, E. N., Adegboyega, A. J. and Suleiman, D. U. (2013), “Networks Integration between Wireless LAN and UMTS Networks”, Journal of Emerging Trends in Computing and Information Sciences, Vol. 4, No. 5, pp. 459-465. |
| [23] | Vadde, A. R. and Bokka, R. (2015), “Integration of Access Technology of Wireless World Wide Web”, Global Journal of Engineering Science and Research Management, Vol. 2, No. 3, pp. 24-30. |
| [24] | Anon. (2016e), “Wireless Installation”, www.innetrex.com/ wireless_install.php. Accessed: February 16, 2016. |
| [25] | Alsamhi, S. H. (2015), “An Intelligent HAP for Broadband Wireless Communications: Developments, QoS and Applications”, International Journal of Electronics and Electrical Engineering, Vol. 3, No. 2, pp. 134-143. |
| [26] | Madhow, U. (2014), Introduction to Communication Systems, University of California, Santa Barbara, USA, pp. 41-42. |
| [27] | Anon. (2016f), “Ad Hoc Wireless Network Diagram”, www.conceptdraw.com/examples/wireless-wlan. Accessed: February 15, 2016. |
| [28] | Fagiri, M. A. O. and Nerma, M. H. M. (2015), “Sequential Paging Technique in the Fourth Generation Communication System”, GE-International Journal of Engineering Research, Vol. 3, No. 4, pp. 64-75. |
| [29] | Anon. (2016g), “Wireless Paging Systems and Urgent Communication Solutions”, www.visiplex.com/products /onsite–paging.html. Accessed: 17, February, 2016. |
| [30] | Anon. (2016h), “Using Both Wired and Wireless Connections”, www.conceptdraw.com/How–To–Guide/using–both–wired–and-wireless connections. Accessed: February 15, 2016. |
| [31] | Vishnudas, C. S. and Sreehari, S. (2015), “Multilevel Inverter Based VFD for Three- Phase Induction Motor”, International Research Journal of Engineering and Technology, Vol. 2, No. 5, pp. 274-278. |
| [32] | Preethi, K., Anil, G. and Vani, E. (2013), “Speed Control of Induction Motor Using Eleven Levels of Multilevel Inverter”, International Journal of Science and Modern Engineering, Vol. 1, No. 5, pp. 15-20. |
| [33] | Snehasish, P., Santanu, N. and Debajyoti, P. (2015), “Adjustable Speed Control of Induction Motor using Variable Frequency Drives”, GE-International Journal of Engineering Research, Vol. 3, No. 4, pp. 13-24. |
| [34] | Madivalappa, B. and Aspalli, M. S. (2013), “Speed Control of Three-Phase Induction Motor by Variable Frequency Drive”, International Journal of Advanced Research in Computer Science and Software Engineering, Vol. 3, No. 12, pp. 411-412. |
| [35] | Zaini, H. G., Metwally, M. K. and Ahmed, M. (2014), “Direct Torque Control of Induction Motor Drive Fed from Hybrid Multilevel Inverter”, International Journal of Electrical and Computer Sciences, Vol. 14, No. 3, pp. 6-11. |
| [36] | Petrovic, I., Jozsa, L. and Baus, Z. (2015), “Use of Fuzzy Logic Systems for Assessment of Primary Faults”, Journal of Electrical Engineering, Vol. 66, No. 5, pp. 257-263. |
| [37] | Husna, V. A. and Kumar, N. M. (2014), “Performance Analysis of Sensorless Based DTC of Induction Motor using Neuro-Fuzzy”, International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering, Vol. 3, No. 2, pp. 602-609. |
| [38] | Sethu, P., Selvaraj, A. and Surendar, S. (2014), “A Wireless Speed Control of AC Drive System”, International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering, Vol. 3, No. 2, pp. 448-456. |
APA Style
Daniel Kumi Owusu, Christian Kwaku Amuzuvi. (2020). Design and Construction of a 3-Phase Induction Motor Wireless Control System. Journal of Electrical and Electronic Engineering, 8(3), 92-102. https://doi.org/10.11648/j.jeee.20200803.13
ACS Style
Daniel Kumi Owusu; Christian Kwaku Amuzuvi. Design and Construction of a 3-Phase Induction Motor Wireless Control System. J. Electr. Electron. Eng. 2020, 8(3), 92-102. doi: 10.11648/j.jeee.20200803.13
AMA Style
Daniel Kumi Owusu, Christian Kwaku Amuzuvi. Design and Construction of a 3-Phase Induction Motor Wireless Control System. J Electr Electron Eng. 2020;8(3):92-102. doi: 10.11648/j.jeee.20200803.13
Share This Article
Twitter
Linked In
Facebook
Copy
Download@article{10.11648/j.jeee.20200803.13,
author = {Daniel Kumi Owusu and Christian Kwaku Amuzuvi},
title = {Design and Construction of a 3-Phase Induction Motor Wireless Control System},
journal = {Journal of Electrical and Electronic Engineering},
volume = {8},
number = {3},
pages = {92-102},
doi = {10.11648/j.jeee.20200803.13},
url = {https://doi.org/10.11648/j.jeee.20200803.13},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.jeee.20200803.13},
abstract = {Infrared (IR) wireless transmission technology has proven to be reliable in electric motor control. The existing control schemes for electric motors require the operator to be at the location of the motors or resort to the use of wired controls. Wired motor controls can fail due to objects falling on them and accidental disconnections. Also, voltage drops in the control wires are wasted in generating heat and increase the cost of electricity tariffs. Further, there is increase in labour cost and installation of wired motor control. Additionally, there are slips, trips and fall hazards associated with control trailing wires. In this research, a wireless control system for a three-phase, 415 V, 50 Hz, squirrel-cage induction motor is designed, simulated and implemented. The issues of voltage drop in control wires is minimised because of the reduced wires involved with this control scheme, thereby improving on the motor efficiency. The transmitter transmits IR signal to the receiver. There is a phototransistor in the receiver that receives the IR signal, amplifies it and decodes it with the help of a microcontroller. The output from the microcontroller is used to regulate auto-transformers to control the three-phase voltage to the motor. The designed system can wirelessly start, stop and change the speeds of induction motor for three successive speed levels. The receiver senses signal from the transmitter within a distance of 9 m. The system is designed to switch the motor into standby mode and then proceed to speeds one, two, three and then finally stop the motor. The developed infrared-based wireless transceiver can be adopted to control a three-phase, 415 V, 50 Hz, squirrel-cage induction motor at remote and inaccessible areas such as water treatment and three-phase separation plants.},
year = {2020}
}
TY - JOUR T1 - Design and Construction of a 3-Phase Induction Motor Wireless Control System AU - Daniel Kumi Owusu AU - Christian Kwaku Amuzuvi Y1 - 2020/07/17 PY - 2020 N1 - https://doi.org/10.11648/j.jeee.20200803.13 DO - 10.11648/j.jeee.20200803.13 T2 - Journal of Electrical and Electronic Engineering JF - Journal of Electrical and Electronic Engineering JO - Journal of Electrical and Electronic Engineering SP - 92 EP - 102 PB - Science Publishing Group SN - 2329-1605 UR - https://doi.org/10.11648/j.jeee.20200803.13 AB - Infrared (IR) wireless transmission technology has proven to be reliable in electric motor control. The existing control schemes for electric motors require the operator to be at the location of the motors or resort to the use of wired controls. Wired motor controls can fail due to objects falling on them and accidental disconnections. Also, voltage drops in the control wires are wasted in generating heat and increase the cost of electricity tariffs. Further, there is increase in labour cost and installation of wired motor control. Additionally, there are slips, trips and fall hazards associated with control trailing wires. In this research, a wireless control system for a three-phase, 415 V, 50 Hz, squirrel-cage induction motor is designed, simulated and implemented. The issues of voltage drop in control wires is minimised because of the reduced wires involved with this control scheme, thereby improving on the motor efficiency. The transmitter transmits IR signal to the receiver. There is a phototransistor in the receiver that receives the IR signal, amplifies it and decodes it with the help of a microcontroller. The output from the microcontroller is used to regulate auto-transformers to control the three-phase voltage to the motor. The designed system can wirelessly start, stop and change the speeds of induction motor for three successive speed levels. The receiver senses signal from the transmitter within a distance of 9 m. The system is designed to switch the motor into standby mode and then proceed to speeds one, two, three and then finally stop the motor. The developed infrared-based wireless transceiver can be adopted to control a three-phase, 415 V, 50 Hz, squirrel-cage induction motor at remote and inaccessible areas such as water treatment and three-phase separation plants. VL - 8 IS - 3 ER -
Information
Email: