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2019 | OriginalPaper | Buchkapitel

5. Study of Tribo-Performance and Application of Polymer Composite

verfasst von : Hemalata Jena

Erschienen in: Automotive Tribology

Verlag: Springer Singapore

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Abstract

Research on composite materials has got much attention for the development of social and economic growth. The Polymer composite is a material which is highly advantageous in the area of construction, packaging and automotive application due to its high strength to the weight ratio, self-lubrication properties, improved fatigue resistance, higher resistance to thermal expansion, wear, and corrosion resistance. Tribo-performance of polymer composite indicates the behaviour of friction and wear of polymer composite which is basically decided by amount and types of polymer matrix and reinforcement. In the past decade, a large number of studies have been carried out the feasibility of the application of polymer composite in tribological applications. However, a very few study has been conducted on the tribological performance of composite material in an automotive application. Here attempts have been to provide a review on tribological performance of polymer and its composites which deals with the application of polymer composite in automotive application and recent developments of polymer composite in tribo-performance. It also deals with the effects of different process and material parameters on tribological properties of the polymer composite.

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Vorheriges Kapitel Future of Metal Foam Materials in Automotive Industry

Nächstes Kapitel Mechanical and Erosion Characteristics of Natural Fiber Reinforced Polymer Composite: Effect of Filler Size

Abadi SBK, Khavandi A, Kharazi Y (2010) Effects of mixing the steel and carbon fibres on the friction and wear properties of a PMC friction material. Appl Compos Mater 17(2):151–158CrossRef

Aggarval BD, Lawrence J, Broutman K et al (2006) Analysis and performance of fibre composites, 3rd edn. ISBN: 978-0-471-26891-8. 2

Agrawal S, Singh KK, Sarkar PK (2016) A comparative study of wear and friction characteristics of glass fibre reinforced epoxy resin, sliding under dry, oil-lubricated and inert gas environments. Tribo Int 96:217–224CrossRef

Ahmadijokani F, Shojaei A, Arjmand M et al (2019a) Effect of short carbon fibre on thermal, mechanical and tribological behaviour of phenolic-based brake friction materials. Compos 68:98–105CrossRef

Ahmadijokani F, Alaei Y, Shojaei A et al (2019b) Frictional behaviour of resin-based brake composites: effect of carbon fibre reinforcement. Wear 420–421:108–115CrossRef

Ahmed KS, Khalid SS, Mallinatha V, Amith Kumar SJ (2012) Dry sliding wear behavior of SiC/Al2O3 filled jute/epoxy composites. Mater Des 36:306–315CrossRef

Aigbodion VS, Akadike U, Hassan SB et al (2010) Development of asbestos- free brake pad using bagasse. Tribol Ind 32:12–18

Aireddy H, Mishra SC (2011) Tribological behaviour and mechanical properties of bio-waste reinforced polymer matrix composites. J Metall Mater Sci 53(2):139–152

Akpan EI, Wetzel B, Friedrich K (2018) A fully biobased tribology material based on acrylic resin and short wood fibres. Tribo Int 120:381–390CrossRef

Algbory AMRM (2011) Wear rate behaviour of carbon/epoxy composite materials at different working condition. Iraqi J Mech Mater Eng 11(3):475–485

Almajid A, Friedrich K, Floeck J, Burkhart T (2011) Surface damage characteristics and specific wear rates of a new continuous carbon fibre (CF)/polyetheretherketone (PEEK) composite under sliding and rolling contact conditions. Appl Compos Mater 18(3):211–230CrossRef

Arman M, Singhal S, Chopra P et al (2018) A review on material and wear analysis of automotive Brake Pad. Mater Today Proc 5:28305–28312CrossRef

ASM Handbook (1992) vol 8. ASM International, Materials Park. Qhio, USA

Basavarajappa S, Arun KV, Paulo Davim J (2009) Effect of filler material on dry sliding wear behaviour of polymer matrix composites-A Taguchi approach. J Miner Mater Character Eng 8:379–391

Bijwe J (2002) Wear failure of polymer composites. In: Hawk J, Wilson R (eds) Failure analysis and prevention. In: Becker WT, Shipley RJ (eds) ASM handbook, vol 11. ASM Intl., OH, USA, p 1028–1043

Bijwe J, Rattan R (2007) Influence of weave of carbon fabric in polyetherimide composites in various wear situations. Wear 263:984–991CrossRef

Bijwe J, Indumathi J, John Rajesh J et al (2001) Friction and wear behaviour of polyetherimide composites in various wear modes. Wear 249:715–726CrossRef

Boopathi L, Sampath PS, Mylsamy K (2012) Influence of fibre length in the wear behaviour of borassus fruit fibre reinforced epoxy composites. Int J Eng Sci Tech 4(9):4119–4129

Burwell JT (1957) Survey of possible wear mechanisms. Wear 58:119–141CrossRef

Carrion-Vilches FJ, Gonzalez-Vivas A, Martinez-Mateo IJ et al (2015) Study of the abrasion resistance under scratching of polybutylenetereftalate–glass fibre composites. Tribo Int 92:365–378CrossRef

Carrión-Vilches FJ, Gonzalez-Vivas A, Martinez-Mateo IJ et al (2015) Study of the abrasion resistance under scratching of polybutylenetereftalate–glass fibre composites. Trib Int 92:365–378CrossRef

Chandra Rao CH, Madhusudan S, Raghavendra G et al (2012) Investigation in to wear behaviour of coir fibre reinforced epoxy composites with the Taguchi method. Int J Eng Res Appl 2(5):371–374

Chand N, Fahim M, Hussain SG (1993) Effect of 60Co gamma-irradiation on interface and abrasive wear of glass-reinforced polyester composite. J Mater Sci Lett 12:1603–1605CrossRef

Chand N, Naik A, Neogi S (2000) Three-body abrasive wear of short glass fibre polyester composite. Wear 242:38–46CrossRef

Chaudhari SB, Shekhawat SP (2013) Wear analysis of Polytetrafluroethylene (PTFE) and its composites under wet condition. IOSR J Mech Civil Eng 8(2):7–18CrossRef

Chin CW, Yousif BF (2009) Potential of kenaf fibres as reinforcement for tribological applications. Wear 267:1550–1557CrossRef

Chiu CH, Hwan CL, Tsai HS et al (2007) An experimental investigation into the mechanical behaviours of helical composite springs. Compos Struct 77:331–340CrossRef

Choi BL, Choi BH (2015) Numerical method for optimizing design variables of carbon-fibre-reinforced epoxy composite coil springs. Compos Part B: Eng 82:42–49CrossRef

Cirino M, Friedrich K, Pipes RB (1988) The effect of fibre orientation on the abrasive wear behaviour of polymer composite materials. Wear 121:127–141CrossRef

Cox RL (2011) Engineered tribological composites: the art of friction material development. SAE Intenational

Dadkar N, Tomar BS, Satapathy BK (2009) Evaluation of flyash-filled and aramid fibre reinforced hybrid polymer matrix composites (PMC) for friction braking applications. Mater Des 30:4369–4376CrossRef

Desale DD, Pawar HB (2018) Performance analysis of Polytetrafluoroethylene as journal bearing material. Proc Manuf 20:414–419

Dwivedi UK, Chand N (2008) Influence of wood flour loading on tribological behaviour of epoxy composites.polym. Compos 29:1189–1192

El-Sayed AA, El-Sherbiny MG, Abo-El-Ezz AS et al (1995) Friction and wear properties of polymeric composite materials for bearing applications. Wear 184:45–53CrossRef

El-Tayeb NSM (2008) A study on the potential of sugarcane fibres/polyester composite for tribological applications. Wear 265(1–2):223–235CrossRef

Faruk O, Bledzki AK, Fink H, Sain M (2012) Biocomposites reinforced with natural fibres: 2000–2010. Prog Polym Sci 37(11):1552–1596CrossRef

Fiore V, Scalici T, Bella GD et al (2015) A review on basalt fibre and its composites. Compos Part B Eng 74:74–94CrossRef

Foard JHD, Rollason D, Thite AN, Bell C (2019) Polymer composite Belleville springs for an automotive application. Compos Struct. https://doi.org/10.1016/j.compstruct.2019.04.063CrossRef

Ganguly A, George R (2008) Asbestos free friction composition for brake linings. Bull Mater Sci 31(1):19–22CrossRef

Gassan J (2002) A study of fibre and interface parameters affecting the fatigue behaviour of natural fibre composites. Compos Part A 33:369–374CrossRef

Georgescu C, Deleanu L, Botan M (2014) Dry sliding of composites with PBT matrix and micro glass beads on steel. Ind Lubr Tribol 66:424–433CrossRef

Gopal P, Dharani LR, Blum FD (1995) Load, speed and temperature sensitivities of a carbon-fibre-reinforced phenolic friction material. Wear 181:913–921CrossRef

Guan QF, Li GY, Wang HY, An J (2004) Friction-wear characteristics of carbon fibre reinforced friction material. J Mater Sci 39(2):641–643CrossRef

Gurunath PV, Bijwe J (2007) Friction and wear studies on brake-pad materials based on newly developed resin. Wear 263:1212–1219CrossRef

Gweon JH, Joo BS, Jang H (2016) The effect of short glass fibre dispersion on the friction and vibration of brake friction materials. Wear 362–363:61–67CrossRef

Hanchi J, Eiss NS (1994) The tribological behavior of blends of PEEK, PEI at elevated temperatures. Tribol Trans 37:494–504CrossRef

He Q, Zhou Y, Qu W et al (2019) Wear property improvement by short carbon fibre as enhancer for rubber compound. Polym Test. https://doi.org/10.1016/j.polymertesting.2019.04.026CrossRef

Idris UD, Aigbodion VS, Abubakar IJ et al (2015) Ecofriendly asbestos free brake-pad: using banana peels. J King Saud Univ Eng Sci 27:185–192

Ikpambese KK, Gundu DT, Tuleun LT (2016) Evaluation of palm kernel fibres (PKFs) for production of asbestos-free automotive brake pads. J King Saud Univ Eng Sci 28(1):110–118

Jang BZ (1994) Advanced polymer composites: principles and applications. ASM International, Materials Park, OH, USA Chapter 2

Jena H, Pradhan AK, Pandit MK (2016) Study of solid particle erosion wear behavior of bamboo fibre reinforced polymer composite with cenosphere filler. Adv Polym Technol. https://doi.org/10.1002/adv.21718CrossRef

Jones RM (1999) Mechanics of composite materials, 2nd edn. ISBN Number 13: 978-1-56032-712-7

Kara Y (2017) A review: fibre reinforced polymer composite helical springs. J Mater Sci Nanotechnol 5(1):101–106

Karandikar PM, Kharde RR, Bhoyar SB et al (2014) Study the tribological properties of PEEK/PTFE reinforced with glass fibres and solid lubricants at room temperature. Int J Cur Eng Tech 4(4):2401–2404

Kato T, Magario A (1994) The wear of aramid fibre reinforced brake pads: the role of aramid fibres. Tribol Trans 37(3):559–565

Khun NW, Zhang H, Yang JL et al (2012) Tribological performance of silicone composite coatings filled with wax-containing microcapsules. Wear 296:575–582CrossRef

Kong H, Han HG, Yoon ES et al (1998) Evaluation of the wear life of MoS₂-bonded-films in tribo-testers with different contact configuration. Wear 215(1–2):25–33CrossRef

Koya OA, Fono TR (2009) Palm kernel shell in the manufacture of automotive brake pad. International Seminar on Harnessing Natural Resources for National Development, Raw Materials Research & Development Council, 10–13 Feb 2009

Kumar S, Panneerselva K (2016) Two-body abrasive wear behavior of Nylon 6 and glass fibre reinforced (GFR) Nylon 6 composite. Procedia Tech 25:1129–1136CrossRef

Kurokawa M, Uchiyama Y, Iwai T, Nagai S (2003) Performance of plastic gear made of carbon fibre reinforced polyamide 12. Wear 254:468–473CrossRef

Lancaster JK (1972) In: Jenkins AD (ed) Polymer science: a material science handbook. North Holland, Amsterdam

Lau KT, Zheng BF, Rong MZ et al (2009) Imparting ultra-low friction and wear rate to epoxy by the incorporation of microcapsulated lubricant. Macromol Mater Eng 294:20–24CrossRef

Lin LM, Ahsan Q et al (2015) Wear behaviour of cryogenic treated recycled carbon fibres filled epoxy composite. Appl Mech Mater 761:489–493CrossRef

Li X, Tabil LG, Panigrah S (2007) Chemical treatments of natural fibre for use in natural fibre-reinforced composites: a review. J Polym Environ 15:25–33CrossRef

Li DX, You YL, Deng X et al (2013a) Tribological properties of solid lubricants filled glass fibre reinforced polyamide 6 composites. Mater Des 46:809–815CrossRef

Li EZ, Guo WL, Wang HD et al (2013b) Research on tribological behavior of PEEK and glass fibre reinforced PEEK composite. Physics Procedia 50:453–460CrossRef

Lugscheider E, Bobzin K, Maes M et al (2004) On the coating of polymers—basic investigations. Thin Solid Films 459:313–317CrossRef

Majhi S, Samantarai SP, Acharya SK (2012) Tribological behavior of modified rice husk filled epoxy composite. Int J Scient Eng Res 3(6):1–5

Maleque MA, Atiqah A (2013) Development and characterization of coir fibre reinforced composite brake friction materials. Arab J Sci Eng 38(11):3191–3199CrossRef

Manjunatha TS, Budan DA (2012) Manufacturing and experimentation of composite helical springs for automotive suspension. Int J Mech Eng Robot Res 1:229–241

Mao K (2007) A new approach for polymer composite gear design. Wear 262:432–441CrossRef

Mao K, Greenwood D, Ramakrishnan R, Goodship V, Shrouti C, Chetwynd D, Paul L (2019) The wear resistance improvement of fibre reinforced polymer composite gears. Wear 426–427:1033–1039CrossRef

McKeen L (2006) Fluorinated coatings and finishes handbook

Mishra P, Acharya SK (2010) Anisotropy abrasive wear behaviour of bagasse fibre reinforced polymer composite. Int J Eng Sci Tech 2(11):104–112

Mittmann HU, Czichos H (1975) Reibungsmessungen und Oberflächenuntersuchungen an KunststoffMetall-Gleitpaarungen. Materialprüfung 17:366–372

Mohanty AK, Misra M, Drzal TL (2005) Natural fibres, biopolymers, and bio composites. CRC Press, Technology & Engineering, Boca RatonCrossRef

Mohan N, Mahesha CR, Rajaprakash BM (2013) Erosive wear behaviour of WC filled glass epoxy composites. Procedia Eng 68:694–702CrossRef

Myshkin NK, Pesetskii SS, Grigoriev AYA (2015) Polymer tribology: current state and applications. Trib Ind 37(3):284–290

Namdeo R, Tiwari S, Manepatil S (2015) Development of rubber wheel abrasion testing machine for estimation of three body abrasive wear of automobile components. Int J Des Manuf Technol 9(1)

Nirmal U, Hashim J, Lau STW (2011) Testing methods in tribology of polymeric composites. Int J Mech Mater Eng 6(3):367–373

Nirmal N, Hashim J, Megat Ahmad MMH (2015) A review on tribological performance of natural fibre polymeric composites. Tribol Int 83:77–104CrossRef

Olofsson U, Minghui Tu, Nosko O, Lyu Y, Dizdar S (2018) A pin-on-disc study of airborne wear particle emissions from studded tyre on concrete road contacts. Wear 410–411:165–172CrossRef

Ovaert TC, Cheng HS (1991) Counterface topographical effects on the wear of polyetheretherketone and a polyetheretherketone-carbon fibre composite. Wear 150:150–157CrossRef

Panda P, Mantry S, Mohapatra S et al (2014) A study on erosive wear analysis of glass fibre–epoxy–AlN hybrid composites. J Compos Mater 48(1):107–118CrossRef

Parikh HH, Gohil PP (2017) Experimental investigation and prediction of wear behaviour of cotton fibre polyester composites. Friction 5(2):83–193CrossRef

Parikh HH, Gohil PP (2015) Tribology of fibre reinforced polymer matrix composites—a review. J Reinf Plast Compos 34(16):1340–1346CrossRef

Patel P, Richard Hull T, Lyon Richard E et al (2011) Investigation of the thermal decomposition and flammability of PEEK and its carbon and glass-fibre composites. Polym Degrad Stab 96:12–22CrossRef

Pihtili H, Tosun N (2002) Effect of load and speed on the wear behaviour of woven glass fabrics and aramid fibre-reinforced composites. Wear 252:979–984CrossRef

Prabakaran S, Satyanarayana N, Sinha SK (2013) Self-lubricating SU-8 nano-composites for micro electro mechanical systems applications. Tribol Lett 49:169–178CrossRef

Pujari S, Srikiran S (2019) Experimental investigations on wear properties of Palm kernel reinforced composites for brake pad applications. Defence Technol. https://doi.org/10.1016/j.dt.2018.11.006

Purboputro PI, Hendrawan MA, Hariyanto A (2017) Use of bamboo fibre as a brake pad lining material and the influence of its portion on hardness and durability. In: 1st International conference on engineering and applied technology (ICEAT), IOP conference series: materials science and engineering. https://doi.org/10.1088/1757-899x/403/1/012100

Rao KS, Varadarajan YS, Rajendra N (2015) Erosive wear behaviour of carbon fibre-reinforced epoxy composite. Mater Today Proc 2:2975–2983CrossRef

Rathnakar G, Pandian PP (2015) A review on the use and application of polymer composites in automotive industries. Int J Res Appl Sci Eng Technol 3(4):898–903

Ravi Kumar V, Lalitha Narayana V, Srinivas Ch (2013) Analysis of natural fibre composite leaf spring. Int J Latest Trends Eng Technol 3(1):182–191

Ray D, Gnanamoorthy R (2007) Friction and wear behavior of vinylester resin matrix composites filled with fly ash particles. J Reinf Plast Compos 26:57–63

Samad MA, Sinha SK (2010) Nanocomposite UHMWPE–CNT polymer coatings for boundary lubrication on aluminium substrates. Tribol Lett 38:301–311CrossRef

Senthilvelan S, Gnanamoorthy R (2006) Carbon fibre reinforced nylon 66 spur gears: development and performance. Appl Compos Mater 13(1):43–56CrossRef

Serfaty IW (1984) Polyetherimide: a versatile, processable thermoplastic. In: Mittal KL (ed) Polyimides. Springer, Boston, MA

Sharma M, Bijwe Singh K (2011) Studies for wear property correlation for carbon fabric- reinforced PES composites. Tribol Lett 43:267–273CrossRef

Shivamurthy B, Siddaramaiah, Prabhuswamy MS (2009) Influence of SiO₂ fillers on sliding wear resistance and mechanical properties of compression moulded glass epoxy composites. J Min Mater Charact Eng 8:513–530

Siddhartha V, Gupta K (2012) Mechanical and abrasive wear characterization of bidirectional and chopped E-glass fibre reinforced composite materials. Mater Des 35:467–479

Singh PK, Siddhartha, Singh AK (2018) An investigation on the thermal and wear behavior of polymer based spur gears. Tribol Int 118:264–272

Singh N, Yousif BF, Rilling D (2011) Tribological characteristics of sustainable fibre Reinforced thermoplastic composites under wet adhesive wear. Tribo Trans 54:736–748CrossRef

Singh AK, Vashishtha S (2018) Thermal and wear behavior of glass fibre-filled functionally graded material-based polyamide 66 spur gears manufactured by a novel technique. J Tribol 140(2):021601

Song F, Wang Q, Wang T (2016) Effects of glass fibre and molybdenum disulfide on tribological behaviours and PV limit of chopped carbon fibre reinforced Polytetrafluoroethylene composites. Trib Int 104:392–401CrossRef

Stevenson ANJ, Hutchings IM (1996) Development of the dry sand/rubber wheel abrasion test. Wear 195:232–240CrossRef

Strumberger N, Gospocic A, Bratulic C (2005) Polymeric materials in automobiles. Promet Traffic Traffico 17(3):149–160

Subramanian C, Senthilvelan S (2010) Effect of reinforced fibre length on the joint performance of thermoplastic leaf spring. Mater Des 31:3733–3741CrossRef

Suh NP (1986) Tribophysics. Prentice-Hall, Englewood Cliffs, New Jersey

Sumithra H, Sidda Reddy B (2018) A review on tribological behaviour of natural reinforced composites. J Reinf Plast Compos 37(5):349–353CrossRef

Suresha B, Chandramohan G, Renukappa MN et al (2007) Mechanical and tribological properties of glass-epoxy composites with and without graphite particulate filler. J Appl Polym Sci 103:2472–2480CrossRef

Theiler G, Gradt TH (2007) Polymer composites for tribological applications in hydrogen environment. In: International conference in hydrogen safety, Sept 2017

Tiwari S, Bijwe J, Panier S (2011a) Influence of plasma treatment on carbon fabric for enhancing abrasive wear properties of polyetherimide composites. Tribol Lett 41:153–162CrossRef

Tiwari S, Sharma M, Panier S et al (2011b) Influence of cold remote nitrogen oxygen plasma treatment on carbon fabric and its composites with specialty polymers. J Mater Sci 46:964–974CrossRef

Tyagi R (2015) Processing techniques and tribological behavior of composite materials. IGI Global

Xin X, Guangxu C, Feiqing L (2005) Research progress of friction properties for fibre reinforced resin matrix composite materials. J Mater Sci Eng 23(3):457–461

Xin X, Xu CG, Qing LF (2007) Friction properties of sisal fibre reinforced resin brake composites. Wear 262:736–741CrossRef

Yang L, Hui T, Peng W (2019) Tribological properties of carbon fibre toughened SiC prepared by hot pressing sintering. Ceram Int 45:832–838CrossRef

Ye Sujuan, Xingrong Z (2014) Tribological properties of PTFE and PTFE composites at different temperatures. Trib Trans 57:382–386CrossRef

Yousif BF (2013) Design of newly fabricated tribological machine for wear and frictional experiments under dry/wet condition. Mater Des 48:2–13CrossRef

Yousif BF, Lau Saijod TW, Mc William S (2010a) Polyester composite based on betelnut fibre for tribological applications. Tribol Int 43:503–511CrossRef

Yousif BF, Nirmal U, Wong KJ (2010b) Three-body abrasion on wear and frictional performance of treated betelnut fibre reinforced epoxy (T-BFRE) composite. Mater Des 31(9):4514–4521CrossRef

Zhang SW (2004) Tribology of elastomers. Elsevier, Amsterdam

Zhao ZK, Du SS, Li F et al (2018) Mechanical and tribological properties of short glass fibre and short carbon fibre reinforced polyethersulfone composites: A comparative study. Compos Commun 8:1–6CrossRef

Zum Gahr KH (1987) Microstructure and wear of materials. Tribology series, vol 10. Elsevier, Amsterdam

Titel: Study of Tribo-Performance and Application of Polymer Composite
verfasst von: Hemalata Jena
Verlag: Springer Singapore
Buch: Automotive Tribology
Print ISBN: 978-981-15-0433-4

Electronic ISBN: 978-981-15-0434-1

Copyright-Jahr: 2019
DOI: https://doi.org/10.1007/978-981-15-0434-1_5

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