DEVELOPMENT AND CHARACTERISATION OF PANTOGRAPH SLIDES FOR RAILWAY APPLICATIONS: A SHORT REVIEW
DOI:
https://doi.org/10.11113/jm.v46.486Keywords:
Pantograph slide, carbon-copper composite, graphene reinforcementAbstract
High-speed railways have transformed global transportation, leading to increased economic activity and reduced congestion. Railway development is surging in Asia, encompassing upgrades to existing lines and the construction of new high-speed railways. This article explores the materials, processes, and properties of pantograph slides. A pantograph slide is an important component of top-running rails that enables the transmission of electrical energy from traction substations to moving trains. This review presents the evolution of pantograph slide materials, such as metal slide plates, pure carbon slides, powder metallurgy slides, metal-impregnated slides, and composite slides. The characterisations of pantograph slide properties, such as density, resistivity, hardness, impact, and flexural properties are also reported. This article delves into the utilisation of local materials, particularly carbon derived from palm kernel shells and coconut shells, as well as graphene from petroleum coke, for the development of current collectors. These findings may contribute to the understanding of pantograph slide materials and provide insights into the potential use of sustainable materials in high-speed railway systems.
References
Wu, G., G. Gao, W. Wei, and Z. Yang, The current collection approach of high-speed train—pantograph and catenary system, The Electrical Contact of the Pantograph-Catenary System, 2019: p. 1-16.
Yusoff, I., B.K. Ng, and S.A. Azizan, Towards sustainable transport policy framework: A rail-based transit system in Klang Valley, Malaysia, PLoS One, 2021. 16(3): p. 1–30.
Omar, N.A., R.A. Ghani, S.M. Ramly, N. Aqilah, H. Mohd, and M.A. Nazri, Keretapi Tanah Melayu (KTMB) services: The role of service quality and recovery towards satisfaction and loyalty, Journal of International Business, Economics and Entrepreneurship, 2022. 7(1): p. 79–90.
Isai K.I.A., V. Kadiresan, N. Jayabalan, Z.K.M. Makhbul, M.N.A. Ibrahim, H.S. Ching, V.N. Kanan, and S. Ramalingam, Customer satisfaction and commuter service: An evaluation of intercity Keretapi Tanah Melayu Berhad (KTMB) performance delivery, Malaysian Journal of Social Sciences and Humanities, 2020. 5(5): p. 95–124.
Ma S., E. Xu, Z. Zhu, Q. Liu, S. Yu, J. Liu, H. Zhong, and Y. Jiang, Mechanical and wear performances of aluminum/sintered-carbon composites produced by pressure infiltration for pantograph sliders, Powder Technology, 2018. 326: p. 54–61.
Li Y., J. Huang, M. Wang, J. Liu, C. Wang, H. Zhong, and Y. Jiang, Microstructure and current carrying wear behaviors of copper/sintered–carbon composites for pantograph sliders, Metals and Materials International, 2021. 27(9): p. 3398–3408.
Wang J. and G. Mei, Effect of pantograph’s main structure on the contact quality in high-speed railway, Shock and Vibration, 2021. 2021: p. 1-15.
Fu X., Y. Hu, G. Peng, and J. Tao, Effect of reinforcement content on the density, mechanical and tribological properties of Ti3SiC2/Al2O3 hybrid reinforced copper-matrix pantograph slide, Science and Engineering of Composite Materials, 2017. 24(6): p. 807–815.
Kuznar M., A. Lorenc, and G. Kaczor, Pantograph sliding strips failure — reliability assessment and damage reduction method based on decision tree model, Materials, 2021. 14(5743): p. 1-17.
Shang F., S. Wei, Q. Bin, Y. He, and H. Li, Research status and development trend of pantograph contact strip materials, in MATEC Web of Conference, 2016. 67: p. 06040.
Wu G., K. Dong, Z. Xu, S. Xiao, W. Wei, H. Chen, J. Li, Z. Huang, J. Li, G. Gao, G. Kang, C. Tu, and X. Huang, Pantograph–catenary electrical contact system of high-speed railways: recent progress, challenges, and outlooks, Railway Engineering Science, 2022. 30(4): p. 437–467.
Zuo H., W. Wei, Z. Yang, X. Li, W. Xie, Q. Liao, Y. Xian, J. Ren, G. Gao, and G. Wu, Synchronously improved mechanical strength and electrical conductivity of carbon / copper composites by forming Fe 3 C interlayer at C / Cu interface, Materials Today Communications, 2021. 28: p. 102661.
Huang J., M. Wang, Y. Li, E. Xu, K. Jiang, M. Li, H. Zhong, J. Liu, and Y. Jiang, Effect of flake graphite content on wear between behavior between P/M copper-based pantograph slide and contact wire, Materials Research Express, 2020. 7: p. 76510.
Perumal A.B., R.B. Nambiar, P. Selvam, and E.R. Sadiku, Carbon Fiber Composites, Handbook of Nanomaterials and Nanocomposites for Energy and Environment Applications, 2021: p. 85-115.
Wu G., Y. Zhou, G. Gao, J. Wu, and W. Wei, Arc erosion characteristics of cu-impregnated carbon materials used for current collection in high-speed railways, IEEE Transaction on Components, Packaging and Manufacturing Technology, 2018. 8(6): p. 1014-1023.
Singh M.K. and R.K. Gautam, Mechanical and tribological properties of plastically deformed copper metal matrix nano composite, Materials Today: Proceedings, 2018. 5(2): p. 5727–5736.
Xu E., Jianxiang Huang, Y. Li, Z. Zhu, M. Cheng, D. Li, H. Zhong, J. Liu, and Y. Jiang, Graphite cluster/copper-based powder metallurgy composite for pantograph slider with well-behaved mechanical and wear performance, Powder Technology, 2019. 344: p. 551–560.
Tu C., L. Hong, T. Song, X. Li, Q. Dou, Y. Ding, T. Liao, S. Zhang, G. Gao, Z. Wang, and Y. Jiang, Superior mechanical properties of sulfonated graphene reinforced carbon-graphite composites, Carbon, 2019. 148: p. 378–386.
Chen W., T. Yang, L. Dong, A. Elmasry, J. Song, N. Deng, A. Elmarakbi, T. Liu, H. Bao, and Y. Qing, Nanotechnology and Precision Engineering Advances in graphene reinforced metal matrix nanocomposites: Mechanisms, processing, modelling, properties and applications, Nanotechnology and Precision Engineering, 2020. 3: p. 189–210.
Zhang S. and C. Tu, Sulfonated graphene improves the wear resistance of pantograph carbon slider materials under normal and wet conditions, New Carbon Materials, 38(2): p. 378-383.
Yuan H., C. Wang, W. Lu, and S. Zhang, Preparation and tribological behavior of carbon fiber reinforced pantograph slide plate, in Advanced Materials Research, 2012. 430-432: p. 378–382.
Li M., B. Ren, W. Wu, K. Jiang, J. Zhang, E. Xu, J. Liu, H. Zhong, G. Tong, and Y. Jiang, Copper fiber reinforced needle-coke/carbon composite for pantograph slide and its current-carrying wear performance, Materials Research Express, 2022. 9(055605): p, 1-12.
Wang P., Y. Jia, Y. Li, Y. Liu, Z. Hao, G. Deng, and L. Wang, Microstructural, mechanical and tribological performances of copper foam modified CFRP composite for pantograph strip, Journal of Applied Polymer Science, 2021. 142(106247).
Wang M., M. Li, K. Jiang, E. Xu, J. Liu, H. Zhong, and Y. Jiang, Full density graphite/copper-alloy matrix composite fabricated via hot powder forging for pantograph slide, Materials Research Express, 2021. 8(6): p. 1-30.
Raw materials for a truly green future, Nature Reviews Materials, 2021. 6(455). https://doi.org/10.1038/s41578-021-00333-9
Aziz A.A., I. Ismail, M. Deraman, R. Mamat, A. Mokhtar, W.H.W. Hasan, R. Ramli, High porosity carbon powder from oil palm empty bunches for adsorbent product, Malaysian Palm Oil Board Transfer of Technology, 2006. 332. http://tot.mpob.gov.my/tt-no-332-high-porosity-carbon-powder-from-oil-palm-empty-fruit-bunches-for-adsorbent-products/
Hayawin N., Development of technologies for the carbonisation of palm kernel shells, Palm Oil Engineering Buletin, 2016. 119: p. 11–16.
Thio C.W., W.H. Lim, U.K. Umi, and L.Y. Phang, Palm kernel fatty acid distillate as substrate for rhamnolipids production using Pseudomonas sp. LM19, Green Chemistry Letter and Reviews, 2022. 15(1): p. 81–90.
Andas J., M. L. A. Rahman, and M. S. M. Yahya, Preparation and Characterization of Activated Carbon from Palm Kernel Shell, IOP Conference Series: Material Science and Engineering, 2017. 226(012156): p. 1-6.
Hidayu A.R., M.Z. Sukor, N.F. Mohammad, O.S.J. Elham, N.I. Azri, M.A.I. Azhar, and M.J. Jalil, Preparation of activated carbon from palm kernel shell by chemical activation and its application for -carotene adsorption in crude palm oil preparation of activated carbon from palm kernel shell by chemical activation and its application for β -carotene, Journal of Physics: Conference Series, 2019. 1349(012103): p. 1-8.
Selamat M.A., A.A. Mahaidin, M.A.N. Hadi, Z.S. Sulaiman, and M.I.A. Razak, Fabrication of carbon-copper composites using local carbon material: microstructure, mechanical, electrical and wear properties, Advanced Materials Research, 2016. 1133: p. 171–174.
Ibrahim M.H.I., M.I. Abdul Razak, N. Mustafa, and M.A. Selamat, Carbon-copper (C-Cu) composites using local carbon material through warm compaction process for potential electrical and electronic application, ARPN Journal of Engineering and Applied Sciences, 2016. 11(18): p. 11117–11123.
Mancuso L., S. Arienti, and A.F. Wheeler, Petroleum coke (petcoke) and refinery residues, 2017, Elsevier Ltd.
Sierra U., A. Mercado, E. Cuara, E.D. Barriga-castro, A. Cortés, C. Gallardo-vega, and S. Fernández, Coke-derived few layer graphene-like materials by mild planetary milling exfoliation, Fuel, 2020. 262: p. 116455.
Saha S., P. Lakhe, M.J. Mason, B.J. Coleman, K. Arole, S. Uppili, M.J. Green, and R.A. Hule, Sustainable production of graphene from petroleum coke using electrochemical exfoliation, npj 2D Materials and Applications, 2021. 5(75): p. 1–8.
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