Design Modification of Automated Power Window Circuit System for Automobiles Air -Condition.

Authors

  • Joseph Sekyi-Ansah  Department of Mechanical Engineering , Takoradi Technical University, Takoradi, 00233, Ghana.
  • James Kwasi Quaisie  School of Mechanical Engineering, Jiangsu University, Zhenjiang, Jiangsu 212013, China.
  • Isaac Eduyah  Department of Mechanical Engineering , Takoradi Technical University, Takoradi, 00233, Ghana.
  • Mohammed Okoe Alhassan  Department of Mechanical Engineering , Takoradi Technical University, Takoradi, 00233, Ghana.
  • Eric Quansah  Department of Mechanical Engineering , Takoradi Technical University, Takoradi, 00233, Ghana.
  • Esther Kyere Andoh-Acquah  Department of Mechanical Engineering , Takoradi Technical University, Takoradi, 00233, Ghana.

DOI:

https://doi.org/10.32628/IJSRST207474

Keywords:

Air Conditioning; Automobile; Power Window; Circuit; Electromechanical; Vehicle Operation.

Abstract

Air conditioning has become a key component in the automobile industry now, and almost every vehicle manufactured in the 21st century has air conditioning integrated. Most drivers drive with their air conditioning on while some of their windows are not fully closed; this affects the operation of the air conditioning. In addition, if the driver wants to turn on the air conditioning while driving, he or she has to move up the power windows manually after or before he or she turns on the air conditioning, which may affect his or her concentration on the road. The concept of this power window circuit system is to automatically close the windows after a few seconds when the air conditioner is turned on.

References

  1. L. I. Farfan-Cabrera, "Tribology of electric vehicles: A review of critical components, current state and future improvement trends," Tribology International, vol. 138, pp. 473-486, 2019/10/01/ 2019.
  2. R. Crowder, "1 - Electromechanical systems," in Electric Drives and Electromechanical Systems (Second Edition), R. Crowder, Ed., ed: Butterworth-Heinemann, 2020, pp. 1-35.
  3. A. Weckenmann, L.-P. Schmidt, and M. Bookjans, "Collaborative Research Centre 694 "Integration of electronic components into mobile systems"–Motivation and survey," Physics Procedia, vol. 5, pp. 719-726, 2010/01/01/ 2010.
  4. A. Gurubalan, M. P. Maiya, and P. J. Geoghegan, "A comprehensive review of liquid desiccant air conditioning system," Applied Energy, vol. 254, p. 113673, 2019/11/15/ 2019.
  5. Y. Yang, C. Ren, M. Tu, B. Luo, C. Yang, and J. Fu, "Performance analysis for a new hybrid air conditioning system in hot-humid climates by simulation," International Journal of Refrigeration, vol. 117, pp. 328-337, 2020/09/01/ 2020.
  6. Z. Zhang, J. Wang, X. Feng, L. Chang, Y. Chen, and X. Wang, "The solutions to electric vehicle air conditioning systems: A review," Renewable and Sustainable Energy Reviews, vol. 91, pp. 443-463, 2018/08/01/ 2018.
  7. Y. Xie, Z. Liu, J. Liu, K. Li, Y. Zhang, C. Wu, et al., "A Self-learning intelligent passenger vehicle comfort cooling system control strategy," Applied Thermal Engineering, vol. 166, p. 114646, 2020/02/05/ 2020.
  8. J. Christensen and C. Bastien, "Chapter | one - Vehicle Architectures, Structures, and Safety Requirements," in Nonlinear Optimization of Vehicle Safety Structures, J. Christensen and C. Bastien, Eds., ed Oxford: Butterworth-Heinemann, 2016, pp. 1-49.
  9. Z. Wang, M. Wei, F. Peng, H. Liu, C. Guo, and G. Tian, "Experimental evaluation of an integrated electric vehicle AC/HP system operating with R134a and R407C," Applied Thermal Engineering, vol. 100, pp. 1179-1188, 2016/05/05/ 2016.
  10. L. Haupt, M. Schöpf, L. Wederhake, and M. Weibelzahl, "The influence of electric vehicle charging strategies on the sizing of electrical energy storage systems in charging hub microgrids," Applied Energy, vol. 273, p. 115231, 2020/09/01/ 2020.
  11. S. P. Datta and P. K. Das, "Performance of an automotive air conditioning system with the variation of state-of-charge of the storage battery," International Journal of Refrigeration, vol. 75, pp. 104-116, 2017/03/01/ 2017.
  12. W. Li and J. Sun, "Numerical simulation and analysis of transport air conditioning system integrated with a passenger compartment," Applied Thermal Engineering, vol. 50, pp. 37-45, 2013/01/10/ 2013.
  13. M. Khamis Mansour, M. N. Musa, M. N. Wan Hassan, and K. M. Saqr, "Development of novel control strategy for multiple circuit, roof top bus air conditioning system in hot humid countries," Energy Conversion and Management, vol. 49, pp. 1455-1468, 2008/06/01/ 2008.
  14. Z. Ghaddar, K. Ghali, and N. Ghaddar, "Impact of integrating desiccant dehumidification processes to conventional AC system on urban microclimate and energy use in Beirut city," Energy Conversion and Management, vol. 153, pp. 374-390, 2017/12/01/ 2017.
  15. B. C. Ng, I. Z. M. Darus, H. Jamaluddin, and H. M. Kamar, "Application of adaptive neural predictive control for an automotive air conditioning system," Applied Thermal Engineering, vol. 73, pp. 1244-1254, 2014/12/05/ 2014.
  16. K. A. Joudi, A. S. K. Mohammed, and M. K. Aljanabi, "Experimental and computer performance study of an automotive air conditioning system with alternative refrigerants," Energy Conversion and Management, vol. 44, pp. 2959-2976, 2003/11/01/ 2003.

International Journal of Scientific Research in Science and Technology

Downloads

Published

2020-08-30

Issue

Volume 7, Issue 4, July-August-2020

Section

Research Articles

License

Copyright (c) IJSRST

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

How to Cite

[1]
Joseph Sekyi-Ansah, James Kwasi Quaisie, Isaac Eduyah, Mohammed Okoe Alhassan, Eric Quansah, Esther Kyere Andoh-Acquah "Design Modification of Automated Power Window Circuit System for Automobiles Air -Condition." International Journal of Scientific Research in Science and Technology(IJSRST), Online ISSN : 2395-602X, Print ISSN : 2395-6011,Volume 7, Issue 4, pp.264-270, July-August-2020. Available at doi : https://doi.org/10.32628/IJSRST207474