Brake pads most especially in the automotive industry play a vital role in controlling the speed of a moving vehicle or machines in some instances. This can only be achieved through careful formulations of selected materials in the right proportions. However, not all brake pads materials are safe for use in automobile and other industrial applications, due to environmental pollution and other health related factors. Thus, the need to develop materials which are considerably suitable and at the same time energy efficient in nature becomes necessary in order to minimize and reduce further damage to an already damaged environment. Thus, environment friendly and non-toxic materials are gaining popularity, and hence, a priority among researchers and industries. The heralding introduction of environmentally friendly natural fibres to replace asbestos in a control composition with other additives in the production of brake pads proves to be a popularly embraced concept among recent researchers. This paper presents review on mechanical properties, tribological behavior, water absorption capacity, dynamic mechanical analysis, morphological and thermal properties of organic reinforced brake pad composites with respect to the materials used and methods of production employed. Findings of this study show that hybridization, modification, chemical treatment and composition control of constituent materials can improve mechanical, thermal and dynamic mechanical properties as well as reduce wear rate and water absorption property. It can be concluded that many researchers were able to improve the performance of braking systems by introducing environmental and user friendly composite materials that can withstand the test of time.
Published in | Composite Materials (Volume 4, Issue 1) |
DOI | 10.11648/j.cm.20200401.12 |
Page(s) | 8-14 |
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), 2020. Published by Science Publishing Group |
Chemical Treatments, Organic Fibres, Physico-Chemical Properties, Polymer Composites
[1] | Anon. Automotive Brake Repairs Trends and Safety Issues. SciElo Analytics Brasil Website. [Online] May 2, 2004. http://www.sirim.my/amtee/pm/brake.hltm. |
[2] | Norton, R. L.,. Machine Design: An Integrated Approach. [ed.] Ali Gordon. 4th. s. l.: Pearson, 2010. |
[3] | Weintraub, M. Brake Additives Consultant. s. l.: Private Communication, 1998. |
[4] | Blau, P. J.,. Compositions, Functions and Testing of Friction Brake Materials and Their Additives. U.S. Department of Energy, Energy Efficiency and Renewable Energy, Transportation Technologies. Tennessee: Oak Ridge National Laboratory, 2001. pp. 78-80. |
[5] | Performance of Ceramic-Enhanced Phenolic Matrix Brake Lining Materials for Automotive Brake Linings. Hee, K. W., Filip, S. P. 7-12, 2005, Wear, Vol. 259, pp. 1088-1096. |
[6] | Development of Natural Fibre in Non-metallic Brake Friction Material. Efendy, H., Mochamad, W. M., Yusuf, N. B. M. Palembang: s. n., 2010, Seminar Nasional Tahunan Teknik Mesin (SNTTM), Vols. Ke-9, pp. 13-15. |
[7] | Dagwa, I. M. Development of Automobile Disc Brake Pad from Local Materials. Benin: University of Benin, 2005. |
[8] | Bio Fibres and Biocomposites. John, M. J., Thomas, S. 3, 2008, Carbohydrate Polymers, Vol. 71, pp. 343-364. |
[9] | Influence of Chemical Surface Modification on the Properties of Biodegradable Jute Fabrics-Polyester Amide Composite. Mohanty, A. K., Khan, M. A., Hinrichsen, G. 2, 2000, Composites Part A: Applied Science and Manufacturing, Vol. 31, pp. 143-150. |
[10] | Biswal, S., Satapathy, A. Preparation, Properties and Wear Performance Evaluation of Epoxy-Palmyra Fibre Composites. Mechanical Engineering, National Institute of Technology. Rourkela: Wiley Online Library, 2016. |
[11] | Natural Fibre Reinforced Poly (Vinyl Chloride) Composites: A Review. Abdul Khalil, H. P. S., Tehrani, M. A., Davoudpour, Y., Bhat, A. H., Jawaid, M., Hassan, A. 5, 2013, Journal of Reinforced Plastics and Composites, Vol. 32, pp. 330-356. |
[12] | A Review on the Tensile Properties of Natural Fiber Reinforced Polymer Composites. Ku, H., Wang, H., Pattarachaiyakoop, N., Trada, M.. 4, 2011, Composites Part B: Engineering, Vol. 42, pp. 856-873. |
[13] | Natural Fiber Reinforced Polymer Composites in Industrial Applications: Feasibility of Date Palm Fibers for Sustainable Automotive Industry. Al-Oqla, F. M., Sapuan, S. M. 2014, Journal of Cleaner Production, Vol. 66, pp. 347-354. |
[14] | Mechanical Processing of Bast Fibres: The Occurrence of Damage and its Effect on Fibre Structure. H¨anninen, T., Thygesen, A., Mehmood, S., Madsen, B., Hughes, M.. 1, 2012, Industrial Crops and Products, Vol. 39, pp. 7-11. |
[15] | Processing and Characterization of Natural Cellulose Fibers/Thermoset Polymer Composites. Thakur, V. K. & Thakur, M. K. 2014, Carbohydrate Polymers, Vol. 109, pp. 102-117. |
[16] | Biocomposites Reinforced with Natural Fibres. Faruk, O., Bledzki, A. K., Fink, H. P., Sain, M. 11, 2012, Progress in Polymer Science: 2000-2010, Vol. 37, pp. 1552-1596. |
[17] | Influence of Processing and Chemical Treatment of Flax Fibres on their Composites. Van de Weyenberg, I., Ivens, J., De Coster, A., Kino, B., Baetens, E., Verpoest, I.. 9, 2003, Composites Science and Technology, Vol. 63, pp. 1241-1246. |
[18] | Dai, D. & Fan, M. Wood fibres as Reinforcements in Natural Fibre Composites: Structure, Properties, Processing and Applications in Natural Fibre Composites: Materials, Processes and Properties. s. l.: Woodhead Publishing, 2014. pp. 3-65. |
[19] | Chemical Treatments on Plant-Based Natural Fibre Reinforced Polymer Composites: An Overview. Kabir, M. M., Wang, H., Lau, K. T., Cardona, F. 7, 2012, Composite Part B-Engineering, Vol. 43, pp. 2883-2892. |
[20] | Oil Palm Fibre (OPF) and its Composites: A Review. Shinoj, S., Visvanathan, R., Panigrahi, S., Kochubabu, M. 1, 2011, Industrial Crops and Products, Vol. 33, pp. 7-22. |
[21] | Characterization of Chemically and Enzymatically Treated Hemp Fibres Using Atomic Force Microscopy and Spectroscopy. George, M., Mussone, P. G., Abboud, Z. & Bressler, D. C. 2014, Applied Surface Science, Vol. 314, pp. 1019-1025. |
[22] | Possibilities for Improving the Mechanical Properties of Jute/Epoxy Composites by Alkali Treatment of Fibres. Gassan, J. & Bledzki, A. K.. 9, 1999, Composites Science and Technology, Vol. 59, pp. 1303-1309. |
[23] | The Effect of Fiber Treatment on the Mechanical Properties of Unidirectional Sisal-Reinforced Epoxy Composites. Rong, M. Z., Zhang, M. Q., Liu, Y., Yang, G. C., & Zeng, H. M.. 10, 2001, Composites Science and Technology, Vol. 61, pp. 1437-1447. |
[24] | Continuous Natural Fiber Reinforced Thermoplastic Composites by Fiber Surface Modification. Wongsriraksa, P., Togashi, K., Nakai, A. & Hamada, H. 2013, Advances in Mechanical Engineering, Vol. 5, p. Article ID685104. |
[25] | Rice and Einkorn Wheat Husks Reinforced Poly (lactic acid) (PLA) Biocomposites: Effects of Alkaline & Silane Surface Treatments of Husks. Tran, T. P. T., B´en´ezet, J. C. & Bergeret, A.. 2014, Industrial Crops and Products, Vol. 58, pp. 111-124. |
[26] | Effect of Chemical Treatment on Physical, Mechanical and Thermal Properties of Ladies Finger Natural Fiber. Hossain, S. I., Hasan, M., Hasan, M. N. & Hassan, A.. Article ID 824274, 2013, Advances in Materials Science and Engineering, Vol. 2013, p. 6 pages. |
[27] | Natural fiber composites with plant oil-based resin. O’Donnell, A., Dweib, M. A. & Wool, R. P. 9, 2004, Composites Science and Technology, Vol. 64, pp. 1135-1145. |
[28] | Mechanical and Thermomechanical Behaviors of Sizing-Treated Corn Fiber/Polylactide Composites. Luo, H., Xiong, G., Ma, C. et al. 2014, Polymer Testing, Vol. 39, pp. 45-52. |
[29] | Maleated Natural Rubber as a Coupling Agent for Paper Sludge Filled Natural Rubber Composites. Ismail, H., Rusli, A. & Rashid, A. A.. 7, 2005, Polymer Testing, Vol. 24, pp. 856-862. |
[30] | Effect of Surface Treatments on the Electrical Properties of Low-Density Polyethylene Composites Reinforced with Short Sisal Fibers. Paul, A., Joseph, K. & Thomas, S. 1, 1997, Composites Science and Technology, Vol. 57, pp. 67-79. |
[31] | Chemical Modification of Jute Fibers for the Production of Green-Composites. Corrales, F., Vilaseca, F., Llop, M., Giron`es, J., M´endez, J. A. & Mutj`, P.. 3, 2007, Journal of Hazardous Materials, Vol. 144, pp. 730-735. |
[32] | Study of the Interfacial Properties of Natural Fibre Reinforced Polyethylene. Torres, F. G. & Cubillas, M. L. 6, 2005, Polymer Testing, Vol. 24, pp. 694-698. |
[33] | Characterization of Polylactic Acid (PLA)/Kenaf Composite Degradation by Immobilized Mycelia of Pleurotus ostreatus. Hidayat, A. & Tachibana, S.. 2012, International Biodeterioration & Biodegradation, Vol. 71, pp. 50-54. |
[34] | A Method for Determining Reactive Hydroxyl Groups in Natural Fibers: Application to Ramie Fiber and its Modification. He, L., Li, X., Li, W., Yuan, J. & Zhou, H. 2012, Carbohydrate Research, Vol. 348, pp. 95-98. |
[35] | Surface Modification of Cellulose with Triazine Derivative to Improve Printability with Reactive Dyes. Xie, K., Liu, H., & Wang, X. 3, 2009, Carbohydrate Polymers, Vol. 78, pp. 538–542. |
[36] | Investigation on the Surface Properties of Chemically Modified Natural Fibers Using Inverse Gas Chromatography. Cordeiroa, N., Ornelasa, M., Ashorib, A., Sheshmanic, S. & Norouzic, H.. 4, 2012, Carbohydrate Polymers, Vol. 87, pp. 2367-2375. |
[37] | Influence of Various Chemical Treatments on the Composition and Structure of Hemp Fibres. Le Troedec, M., Sedan, D., Peyratout, C., et al.,. 3, 2008, Composites Part A: Applied Science and Manufacturing, Vol. 39, pp. 514-522. |
[38] | Effect of Fibre Surface Treatments on the Essential work of Fracture of HDPE-Continuous Henequen Fibre-Reinforced Composites. May-Pat, A., Valadez-Gonzalez, A., Herrera-Franco, P. J. 6, 2013, Polymer Testing, Vol. 32, pp. 1114-1122. |
[39] | Fiber Surface Treatment and its Effect on Mechanical and Visco-Elastic behaviour of Banana/Epoxy Composite. Venkateshwaran, N., Elaya Perumal, A., Arunsundaranayagam, D. 2013, Materials & Design, Vol. 47, pp. 151-159. |
[40] | Effect of Chemical Modification on Properties of Hybrid Fiber Biocomposites. John, M. J., Francis, B. K., Varughese, T. & Thomas, S. 2, 2008, Composites Part A: Applied Science and Manufacturing, Vol. 39, pp. pp. 352–363. |
[41] | Fabrication of Medium Density Fibreboard from Enzyme Treated Rubber Wood (Hevea brasiliensis) Fibre and Modified Organosolv Lignin. Nasir, M., Gupta, A., Beg, M. D. H., Chua, G. K. & Kumar, A.. 2013, International Journal of Adhesion and Adhesives, Vol. 44, pp. pp. 99–104. |
[42] | Effects of Fiber Treatment on Morphology, Tensile and Thermogravimetric Analysis of Oil Palm Empty Fruit Bunches Fibers. Norul Izani, M. A., Paridah, M. T., Anwar, U. M. K., Mohd Nor, M. Y., H’Ng, P. S.. 1, 2013, Composites Part B: Engineering, Vol. 45, pp. 1251-1257. |
[43] | Effect of Chemical Treatment on Flexural Properties of Natural Fiber Reinforced Polyester Composite. Rokbi, M., Osmani, H., Imad, A. & Benseddiq, N. 2011, Procedia Engineering, Vol. 10, pp. pp. 2092–2097. |
[44] | Performance of Oil Palm Empty Fruit Bunch Fibres Coated with Acrylonitrile Butadiene Styrene. Bateni, F., Ahmad, F., Yahya, A. S. & Azmi, M. 4, 2011, Construction and Building Materials, Vol. 25, pp. pp. 1824 –1829. |
[45] | The Physical, Chemical Properties of Untreated and Chemically Treated Palmyra Palm Leaf Fibres. Thiruchitrambalam, M., Logesh, M., Shanmugam, D. & Muthukumar, S. 2.24, 2018, International Journal of Engineering & Technology, Vol. 7, pp. pp. 582-585. |
[46] | Shanmugam, D. Studies on the Properties of Palmyra Palm Leaf Stalk Fibre (PPLSF) Reinforced Polyester Composite Materials. Tamil Nadu: Anna University, 2014. |
APA Style
Danladi Ozokwere Ayogwu, Ibrahim Saidu Sintali, Mohammed Ahmed Bawa. (2020). A Review on Brake Pad Materials and Methods of Production. Composite Materials, 4(1), 8-14. https://doi.org/10.11648/j.cm.20200401.12
ACS Style
Danladi Ozokwere Ayogwu; Ibrahim Saidu Sintali; Mohammed Ahmed Bawa. A Review on Brake Pad Materials and Methods of Production. Compos. Mater. 2020, 4(1), 8-14. doi: 10.11648/j.cm.20200401.12
@article{10.11648/j.cm.20200401.12, author = {Danladi Ozokwere Ayogwu and Ibrahim Saidu Sintali and Mohammed Ahmed Bawa}, title = {A Review on Brake Pad Materials and Methods of Production}, journal = {Composite Materials}, volume = {4}, number = {1}, pages = {8-14}, doi = {10.11648/j.cm.20200401.12}, url = {https://doi.org/10.11648/j.cm.20200401.12}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.cm.20200401.12}, abstract = {Brake pads most especially in the automotive industry play a vital role in controlling the speed of a moving vehicle or machines in some instances. This can only be achieved through careful formulations of selected materials in the right proportions. However, not all brake pads materials are safe for use in automobile and other industrial applications, due to environmental pollution and other health related factors. Thus, the need to develop materials which are considerably suitable and at the same time energy efficient in nature becomes necessary in order to minimize and reduce further damage to an already damaged environment. Thus, environment friendly and non-toxic materials are gaining popularity, and hence, a priority among researchers and industries. The heralding introduction of environmentally friendly natural fibres to replace asbestos in a control composition with other additives in the production of brake pads proves to be a popularly embraced concept among recent researchers. This paper presents review on mechanical properties, tribological behavior, water absorption capacity, dynamic mechanical analysis, morphological and thermal properties of organic reinforced brake pad composites with respect to the materials used and methods of production employed. Findings of this study show that hybridization, modification, chemical treatment and composition control of constituent materials can improve mechanical, thermal and dynamic mechanical properties as well as reduce wear rate and water absorption property. It can be concluded that many researchers were able to improve the performance of braking systems by introducing environmental and user friendly composite materials that can withstand the test of time.}, year = {2020} }
TY - JOUR T1 - A Review on Brake Pad Materials and Methods of Production AU - Danladi Ozokwere Ayogwu AU - Ibrahim Saidu Sintali AU - Mohammed Ahmed Bawa Y1 - 2020/06/20 PY - 2020 N1 - https://doi.org/10.11648/j.cm.20200401.12 DO - 10.11648/j.cm.20200401.12 T2 - Composite Materials JF - Composite Materials JO - Composite Materials SP - 8 EP - 14 PB - Science Publishing Group SN - 2994-7103 UR - https://doi.org/10.11648/j.cm.20200401.12 AB - Brake pads most especially in the automotive industry play a vital role in controlling the speed of a moving vehicle or machines in some instances. This can only be achieved through careful formulations of selected materials in the right proportions. However, not all brake pads materials are safe for use in automobile and other industrial applications, due to environmental pollution and other health related factors. Thus, the need to develop materials which are considerably suitable and at the same time energy efficient in nature becomes necessary in order to minimize and reduce further damage to an already damaged environment. Thus, environment friendly and non-toxic materials are gaining popularity, and hence, a priority among researchers and industries. The heralding introduction of environmentally friendly natural fibres to replace asbestos in a control composition with other additives in the production of brake pads proves to be a popularly embraced concept among recent researchers. This paper presents review on mechanical properties, tribological behavior, water absorption capacity, dynamic mechanical analysis, morphological and thermal properties of organic reinforced brake pad composites with respect to the materials used and methods of production employed. Findings of this study show that hybridization, modification, chemical treatment and composition control of constituent materials can improve mechanical, thermal and dynamic mechanical properties as well as reduce wear rate and water absorption property. It can be concluded that many researchers were able to improve the performance of braking systems by introducing environmental and user friendly composite materials that can withstand the test of time. VL - 4 IS - 1 ER -