The eco-friendly brake composite has been still an interesting issue in the development of brake friction materials. Wastes of S. Macrophylla (mahogany) fruit skin and coal fly ash are available as organic ingredients of bio-composite brakes. In this research, we investigated the effects of both ingredients on the brake composite properties which were fabricated using hot isostatic pressing at temperature 200 °C and pressure 5 kN for 3 h. The specimens were prepared in some volume fractions of carbon (2 vol% - 12 vol%). As a result, several tested specimens containing mahogany fruit skin carbon revealed maximum Rockwell hardness 69 HRB, wear 2.49x10^-4mm²/kg, and water absorption 2.72 %, while specimens containing coal fly ash showed 78 HRB, 1.1x10^-3mm²/kg, and 3.5 %, respectively. The brake composites containing coal fly ash performed better than ones containing mahogany fruit skin carbon. The hardness and wear of these two types of brake composite friction materials meet the minimum criteria required by SAE, JA661, and are close to the quality of the brake pads of two commercial brake composite materials. Water absorption in the brake lining specimens with mahogany leather carbon showed that the addition of the volume fraction caused an increase in water absorption, while the specimen containing coal fly ash showed that the increase in the carbon volume fraction caused a decrease in water absorption.

Adam, T., Hashim, U., Sutikno. 2012. Simulation of passive fluid driven micromixer for fast reaction assays in nano lab-on-chip domain. Procedia Engineering. 50: 416-425.

Ahlawat, V., Kajal, S., Parinam, A. 2020. Tribo-performance assessment of milled fly ash brake friction composites. Polymer Composites. 41(2): 707-718.

Ahlawat, V., Kajal, S., Parinam, A. 2019. Exploring the suitability of milled fly ash for brake friction composites: characterization and tribo-performance. Material Research Express. 6(4): 045311

Ahmadijokani, F., Alaei, Y., Shojaei, A., Arjmand, M., Yan., N. 2019. Frictional behavior of resin-based brake composites: Effect of carbon fibre reinforcement. Wear. 420–421: 108–115.

Ahmadijokani, F., Shojaei, A., Dordanihaghighi, S., Jafarpour, E., Mohammadi, S., Arjmand, M. 2020. Effects of hybrid carbon-aramid fiber on performance of non-asbestos organic brake friction composites. Wear. 452–453: 203280.

Arvinte, A., Sesay, A.M., Virtanen, V. 2020. Designing carbon reinforced PMMA composites for integrated electrodes as electrochemical detectors in PMMA microchips. Journal of Electroanalytical Chemistry. 876: 114486.

Chen, Y., Shah, N., Huggins, F.E., Huffman, G.P. 2005. Transmission electron microscopy investigation of ultrafine coal fly ash particles. Environmental Science & Technology. 39(4): 1144–1151.

Cong, P., Wang, H., Wu, X., Zhou, G., Liu, X., Li., T. 2012. Braking performance of an organic brake pad based on a chemically modified phenolic resin binder. Journal of Macromolecular Science, Part A. 49: 518–527.

Dadkar, N., Tomar, B.S., Satapathy, B.K. 2009. Evaluation of fly ash-filled and aramid fibre reinforced hybrid polymer matrix composites (PMC) for friction braking applications. Material and Design. 30: 4369–4376.

Dang, A., Li, T., Wang, J., Zhao, T., Xia, Y., Chen, X., Li, H., Tang, C., Xiong, C. 2019. Preparation and mechanical properties of CCF reinforced RBSC braking composite from pre-liquid dispersion. Ceramics International. 45(5): 6528-6534.

Erol, M., Küçükbayrak, S., Ersoy-Meriçboyu, A. 2008. Comparison of the properties of glass, glass ceramic and ceramic materials produced from coal fly ash. Journal of Hazardous Material. 153: 418–425.

Hao, M., Luo, R., Hou, Z., Yang, W., Xiang, Q., Yang, C. 2014. Effect of fiber-types on the braking performances of carbon/carbon composites. Wear. 319: 145–149.

Ilic, M., Cheeseman, C., Sollars, C., Knight, J., 2003. Mineralogy and microstructure of sintered lignite coal fly ash. Fuel. 82: 331–336.

Jeganmohan, S., Sugozu, B., 2020. Usage of powder pinus brutia cone and colemanite combination in brake friction composites as friction modifier. Materials Today: Proceedings. 27(P3): 2072-2075.

Külaots, I., Hurt, R.H., Suuberg, E.M., 2004. Size distribution of unburned carbon in coal fly ash and its implications. Fuel. 83: 223–230.

Madnasri, S., Edi, S.S., Saputra, D.S. 2013. Crystal structures thermal properties of bamboo nanofiber reinforced-composite friction materials of glass and metal wastes. Advance Material Research.789: 49-55.

Maleque, M.A., Atiqah. A. 2013. Development and Characterization of Coir Fibre Reinforced Composite Brake Friction Materials. Arabian Journal for Science and Engineering. 38: 3191–3199.

Prabhu, T.R. 2016. Effect of bimodal size particles reinforcement on the wear, friction and mechanical properties of brake composites. Tribology - Materials, Surfaces & Interfaces. 10(4): 163-171.

Pujari, S., Srikiran, S. 2019. Experimental investigations on wear properties of Palm kernel reinforced composites for brake pad applications. Defence Technology. 15: 295-299.

Shojaei, A., Fahimian, M., Derakhshandeh, B. 2007. Thermally conductive rubber-based composite friction materials for railroad brakes-thermal conduction characteristics. Composites Science and Technology. 67: 2665–2674.

Singaravelu, D.L., Vijay, R., Filip., P. 2019. Influence of various cashew friction dusts on the fade and recovery characteristics of non-asbestos copper-free brake friction composites. Wear. 426–427: 1129–1141.

Singh, T., Tiwari, A., Patnaik, A., Chauhan, R., Ali, S. 2017. Influence of wollastonite shape and amount on tribo-performance of nonasbestos organic brake friction composites. Wear. 386–387: 157–164.

Singh, T., Patnaik, A. 2015. Performance assessment of lapinus-aramid based brake pad hybrid phenolic composites in friction braking. Archives of Civil and Mechanical Engineering. 15: 151-161.

Sugözü, B. 2018. Tribological properties of brake friction materials containing fly ash. Industrial Lubrication and Tribology. 70(5): 902-906.

Sutikno, M., Marwoto, P., Rustad, S. 2010. The Mechanical properties of carbonized coconut char powder-based friction materials. Carbon. 48: 3616-3620.

Sutikno, M., Edi, S.S., Saputra, D.S. 2013. Crystal structures and thermal properties of bamboo nanofiber reinforced-composite friction materials of glass and metal wastes. Advanced Materials Research. 789: 49-55.

Sutikno, Sukiswo, S.E., Dany, S.S. 2012. Sifat mekanik bahan gesek rem komposit diperkuat serat bambu. Jurnal Pendidikan Fisika Indonesia. 8: 83-89.

Wasilewski, P. 2017. Experimental study on the effect of formulation modification on the properties of organic composite railway brake shoe. Wear. 390–391: 283–294.