Optimization of temperature measurement on the bus drum brake as a basis for developing brake fault signals

Authors

DOI:

https://doi.org/10.15587/1729-4061.2021.224907

Keywords:

brake fault, traffic accident, brake temperature, temperature measurement, drum brake

Abstract

Brake failure is always possible due to several factors that are difficult to control, such as a slight leak in the brake hose due to an impact or a rat bite. In the latest research, the development of a brake performance detection tool has been started, but how to detect a brake temperature more efficiently on the brakes of large vehicles has not been specified. Given the significant impact of losses due to brake failure and accidents that are still occurring, this research plays an important role. It must be completed immediately so that accident cases can be reduced. The object of this research is where the position of the maximum brake temperature occurs? How to measure brake temperature is more practical? What sensor is optimal in detecting a brake temperature? The research method is carried out in a systematic stage that ends with an experimental method. This study indicates that the maximum temperature is relative to the entire friction area between the canvas and the drum brake. The most efficient sensor placement is in the hole in the drum brake cover so that installation is more practical and the brakes are not disturbed by the sensor’s presence. The optimal sensor is a thermocouple sensor because it is more stable to vibrations and more resistant to mud disturbances than infrared sensors. When using a thermocouple sensor, the temperature detection results must be corrected. The correction factor can be made with the equation y=10.3670+1.3205x–0.0003x2, where y is the actual temperature displayed, and x is the input temperature from the thermocouple sensor’s initial detection. Accurate brake temperature detection results will be developed as a signal for detecting brake faults in real-time to avoid brake failure. Finally, the safety of public transportation can be improved

Author Biographies

Rolan Siregar, Universitas Indonesia, Darma Persada University

Postgraduate Student

Department of Mechanical Engineering

Lecturer

Department of Mechanical Engineering

Mohammad Adhitya, Universitas Indonesia

Doctor Ingenieur Degree, Lecturer

Department of Mechanical Engineering

Danardono A Sumarsono, Universitas Indonesia

Professor, Lecturer

Department of Mechanical Engineering

Nazaruddin Nazaruddin, Universitas Indonesia

Postgraduate Student

Department of Mechanical Engineering

Ghany Heryana, Universitas Indonesia

Postgraduate Student

Department of Mechanical Engineering

Sonki Prasetya, Universitas Indonesia

Postgraduate Student

Department of Mechanical Engineering

Fuad Zainuri, Universitas Indonesia

Postgraduate Student

Department of Mechanical Engineering

References

  1. Suhariyanto (2019). Land Transportation Statistics 2018. BPS-Statistics Indonesia. Jakarta, 84. Available at: https://www.bps.go.id/publication/download.html?nrbvfeve=N2ZkZDMzNzkxMDhiNGE2MGUwNDZmNGM4&xzmn=aHR0cHM6Ly93d3cuYnBzLmdvLmlkL3B1YmxpY2F0aW9uLzIwMTkvMTEvMjcvN2ZkZDMzNzkxMDhiNGE2MGUwNDZmNGM4L3N0YXRpc3Rpay10cmFuc3BvcnRhc2ktLWRhcmF0LS0yMDE4Lmh0bWw%3D&twoadfnoarfeauf=MjAyMS0wMS0yNyAxOTowMDo1Ng%3D%3D
  2. Hasil investigasi KNKT di Ciloto, Bawen, Karangloso dan Kebumen (2017). Jakarta. Available at: http://knkt.dephub.go.id/knkt/ntsc_home/Publication/FGD%2021122017/5.%20Paparan%20Kasubkom%20LLAJ-FGD%20211217%20v%204%20Kecelakaan.pdf
  3. Owusu-Ansah, P., Alhassan, T., Frimpong, A., Agyei Agyemang, A. (2014). Survey of the Causes of Brake Failure in Commercial Mini-buses in Kumasi. Research Journal of Applied Sciences, Engineering and Technology, 7 (23), 4877–4882. doi: https://doi.org/10.19026/rjaset.7.878
  4. Chandra Verma, P., Menapace, L., Bonfanti, A., Ciudin, R., Gialanella, S., Straffelini, G. (2015). Braking pad-disc system: Wear mechanisms and formation of wear fragments. Wear, 322-323, 251–258. doi: https://doi.org/10.1016/j.wear.2014.11.019
  5. Oduro, S. (2012). Brake failure and its effect on road traffic accident in Kumasi Metropolis, Ghana. International Journal of Science and Technology, 1 (9), 448–454. Available at: https://www.researchgate.net/publication/279843241_Brake_Failure_and_its_Effect_on_Road_Traffic_Accident_in_Kumasi_Metropolis_Ghana
  6. Ahmed, I., Sofan, H., Abdelwahed, K., Fatouh, Y., Allam, E. M. (2019). Effect of Changing Drum Brakes Lining Form on the Brake Performance. International Research Journal of Engineering and Technology (IRJET), 06 (02). Available at: https://www.irjet.net/archives/V6/i2/IRJET-V6I201.pdf
  7. Awe, S. A. (2019). Developing Material Requirements for Automotive Brake Disc. Modern Concepts in Material Science, 2 (2). Available at: https://irispublishers.com/mcms/pdf/MCMS.MS.ID.000531.pdf
  8. Hemchi, T. (2008). Thermal stress and Thermal expansion in a brake drum of heavy commercial truck. Universiti Teknologi Petronas. Available at: http://utpedia.utp.edu.my/1001/1/THAWEESAK_HEMCHI.pdf
  9. Yan, M., Xu, J. (2018). Prediction Model for Brake-Drum Temperature of Large Trucks on Consecutive Mountain Downgrade Routes Based on Energy Conservation Law. Mathematical Problems in Engineering, 2018, 1–10. doi: https://doi.org/10.1155/2018/4587673
  10. Stephens, A. (2006). Aerodynamic Cooling of Automotive Disc Brakes. School of Aerospace, Mechanical & Manufacturing Engineering RMIT University, 15–20. Available at: https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.1012.5236&rep=rep1&type=pdf
  11. Neis, P. D., Kruze, G., Ferreira, N. (2010). Relation between the temperature of the disc measured with thermocouple and by thermography using a reduced scale dynamometer. ABCM Symposium Series in Mechatronics, 4, 907–913. Available at: https://abcm.org.br/symposium-series/SSM_Vol4/Section_VII_SENSORS_AND_ACTUATORS/SSM4_VII_16.pdf
  12. Cho, H., Cho, C., Kim, C.-B. (2007). Thermal and Mechanical Performance Analysis in Accordance with Disk Stiffness Changes in Automotive Disk Brake. SAE Technical Paper Series. doi: https://doi.org/10.4271/2007-01-3661
  13. Husaini, M., Krishnan, P., Yaacob, S. (2018). Data Analysis for Braking System in Time Domain for Fault Diagnosis. International Research Journal of Engineering and Technology (IRJET), 05 (08), 348–354. Available at: https://www.irjet.net/archives/V5/i8/IRJET-V5I862.pdf
  14. Jegadeeshwaran, R., Sugumaran, V. (2015). Health monitoring of a hydraulic brake system using nested dichotomy classifier – A machine learning approach. International Journal of Prognostics and Health Management, 6 (1). Available at: https://www.phmsociety.org/sites/phmsociety.org/files/phm_submission/2014/ijphm_15_014.pdf
  15. Jegadeeshwaran, R., Sugumaran, V. (2015). Brake fault diagnosis using Clonal Selection Classification Algorithm (CSCA) – A statistical learning approach. Engineering Science and Technology, an International Journal, 18 (1), 14–23. doi: https://doi.org/10.1016/j.jestch.2014.08.001
  16. Giyarto (2018). Implementasi perangkat sensor suhu tromol mobil tangki di tbbm plumpang. Jakarta.
  17. Air Brake Performance and Wear Test Code Commercial Vehicle Inertia Dynamometer (2006). SAE International. doi: https://doi.org/10.4271/j2115_200608
  18. Surface vehicle recommended practice. SAE International. Available at: https://www.sae.org/standardsdev/tsb/tsb004.pdf
  19. ISO/PAS 12158:2002. Road vehicles – Braking systems – Temperature measuring methods. Available at: https://www.iso.org/standard/33466.html
  20. Adams, F. (2004). Pat. No. US 2005/0212357 A1. Brake monitoring and sensor system for sensing temperature and wear. No. 10/806,686; declareted: 23.03.2004; published: 29.09.2005. Available at: https://patents.google.com/patent/US20050212357A1/en
  21. Ghazaly, N. M., Makrahy, M. (2014). Experimental investigation of drum brake performance for passenger car. International Journal of Mechanical And Production Engineering, 2 (12), 70–73. Available at: http://www.iraj.in/journal/journal_file/journal_pdf/2-100-141760734370-73.pdf
  22. Adhitya, M., Siregar, R., Sumarsono, D. A., Nazaruddin, N., Heryana, G., Prasetyo, S., Zainuri, F. (2020). Experimental analysis in the test rig to detect temperature at the surface disc brake rotor using rubbing thermocouple. Eastern-European Journal of Enterprise Technologies, 2 (5 (104)), 6–11. doi: https://doi.org/10.15587/1729-4061.2020.191949
  23. Day, A. (2014). Braking of Road Vehicles. Butterworth-Heinemann, 488. doi: https://doi.org/10.1016/c2011-0-07386-6

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Published

2021-02-19

How to Cite

Siregar, R., Adhitya, M., Sumarsono, D. A., Nazaruddin, N., Heryana, G. ., Prasetya, S. ., & Zainuri, F. . (2021). Optimization of temperature measurement on the bus drum brake as a basis for developing brake fault signals . Eastern-European Journal of Enterprise Technologies, 1(1 (109), 13–19. https://doi.org/10.15587/1729-4061.2021.224907

Issue

Section

Engineering technological systems