Abstract
Designing a friction material for a brake system entails considering the effects of each constituent and the interactions that they may present between them. In the present work, a characterization of the influence of the resin-rubber ratio in a brake block material is carried out. Railway brake shoes were produced and tested in a full-scale railway dynamometer in demanding conditions. The brake blocks had also their physical and mechanical properties tested. The progressive addition of resin was proven to heavily affect the friction level in dry and wet conditions. Interestingly, the use of 5% of resin showed significantly higher friction in wet conditions. This composition also presented a more severe metal pick-up. The nature of the binder also affected wear-rates (which were lower for lower resin contents) and the wear mechanism. The sample using only rubber presented thermal cracks and heavier delamination as specific failure modes. Differences in the microstructure of the friction materials were observed depending on the binder. About 5% of resin appears as a very interesting choice to avoid friction loss in wet environments without incurring high wear-rates, as long as metal pick-up is diminished by different means. Otherwise, 100% of rubber as a binder grants the instantaneous friction stability that is often threatened by thermal fade.
Issue Section:
Friction and Wear
Keywords:
brakes,
friction,
polymeric additives,
sliding,
surface fracture cracking,
third bodies,
wear,
wear mechanisms
References
1.
Talegaonkar
, R. P.
, and Gopinath
, K.
, 2008
, “Influence of Alumina Fiber Content on Properties of Non-Asbestos Organic Brake Friction Material
,” J. Reinf. Plast. Compos.
, 28
(17
), pp. 2069
–2081
. 2.
Smales
, H.
, 1995
, “Friction Materials—Black Art or Science?
,” Proc. Inst. Mech. Eng., Part D
, 209
(3
), pp. 151
–157
. 3.
Sudhan Raj
, J.
, Christy
, T. V.
, Darius Gnanaraj
, S.
, and Sugozu
, B.
, 2020
, “Influence of Calcium Sulfate Whiskers on the Tribological Characteristics of Automotive Brake Friction Materials
,” Eng. Sci. Technol. Int. J.
, 23
(2
), pp. 445
–451
. 4.
Satapathy
, B. K.
, and Bijwe
, J.
, 2004
, “Performance of Friction Materials Based on Variation in Nature of Organic Fibres Part I. Fade and Recovery Behaviour
,” p. 12
.5.
Hong
, U. S.
, Jung
, S. L.
, Cho
, K. H.
, Cho
, M. H.
, Kim
, S. J.
, and Jang
, H.
, 2009
, “Wear Mechanism of Multiphase Friction Materials with Different Phenolic Resin Matrices
,” Wear
, 266
(7
), pp. 739
–744
. 6.
Singh
, T.
, Patnaik
, A.
, Chauhan
, R.
, and Rishiraj
, A.
, 2017
, “Assessment of Braking Performance of Lapinus–Wollastonite Fibre Reinforced Friction Composite Materials
,” J. King Saud Univ., Eng. Sci.
, 29
(2
), pp. 183
–190
. 7.
Singh
, T.
, Patnaik
, A.
, Gangil
, B.
, and Chauhan
, R.
, 2015
, “Optimization of Tribo-Performance of Brake Friction Materials: Effect of Nano Filler
,” Wear
, 324–325
, pp. 10
–16
. 8.
Kunz
, A.
, Meyer
, M.
, Göcze
, C.
, Martinotto
, L.
, and Lieberherr
, W.
, 2019
, “Strategy Panel
,” Eurobrake 2019
, Dresden, Germany
, May 21–23, 2009
.9.
Ciudin
, R.
, Verma
, P. C.
, Gialanella
, S.
, and Straffelini
, G.
, 2014
, “Wear Debris Materials From Brake Systems: Environmental and Health Issues
,” Siena, Italy, pp. 1423
–1434
.10.
Triono
, A.
, Ign
, W. P.
, and Brodjonegoro
, S. S.
, 2013
, “Modification of Pin on Disc Test to Measure Railway Brake Block Friction Coefficient
,” KEM
, 594–595
, pp. 639
–643
. www.scientific.net/KEM.594-595.63911.
Zhang
, P.
, Zhang
, L.
, Wei
, D.
, Wu
, P.
, Cao
, J.
, Shijia
, C.
, Qu
, X.
, and Fu
, K.
, 2019
, “Effect of Graphite Type on the Contact Plateaus and Friction Properties of Copper-Based Friction Material for High-Speed Railway Train
,” Wear
, 432–433
, pp. 202927
. 12.
Wasilewski
, P.
, 2018
, “Full-Scale Dynamometer Test of Composite Railway Brake Shoes—Study on the Effect of the Reinforcing Fibre Type
,” Acta Mech. et Autom.
, 12
(3
), pp. 204
–208
. 13.
Vakkalagadda
, M. R. K.
, Srivastava
, D. K.
, Mishra
, A.
, and Racherla
, V.
, 2015
, “Performance Analyses of Brake Blocks Used by Indian Railways
,” Wear
, 328–329
, pp. 64
–76
. 14.
Walia
, M. S.
, Vernersson
, T.
, Lundén
, R.
, Blennow
, F.
, and Meinel
, M.
, 2019
, “Temperatures and Wear at Railway Tread Braking: Field Experiments and Simulations
,” Wear
, 440–441
, p. 203086
. 15.
Bijwe
, J.
, 1997
, “Composites as Friction Materials: Recent Developments in Non-Asbestos Fiber Reinforced Friction Materials?A Review
,” Polym. Compos.
, 18
(3
), pp. 378
–396
. 16.
Shojaei
, A.
, and Abbasi
, F.
, 2006
, “Cure Kinetics of a Polymer-Based Composite Friction Material
,” J. Appl. Polym. Sci.
, 100
(1
), pp. 9
–17
. 17.
Saffar
, A.
, and Shojaei
, A.
, 2012
, “Effect of Rubber Component on the Performance of Brake Friction Materials
,” Wear
, 274–275
, pp. 286
–297
. 18.
Huang
, F.
, Mo
, Y.
, and Lv
, J.
, 2010
, “Study on Heat Fading of Phenolic Resin Friction Material for Micro-Automobile Clutch
,” 2010 International Conference on Measuring Technology and Mechatronics Automation
, pp. 596
–599
.19.
Fei
, J.
, Li
, H.-J.
, Fu
, Y.-W.
, Qi
, L.-H.
, and Zhang
, Y.-L.
, 2010
, “Effect of Phenolic Resin Content on Performance of Carbon Fiber Reinforced Paper-Based Friction Material
,” Wear
, 269
(7–8
), pp. 534
–540
. 20.
Kim
, Y. C.
, Cho
, M. H.
, Kim
, S. J.
, and Jang
, H.
, 2008
, “The Effect of Phenolic Resin, Potassium Titanate, and CNSL on the Tribological Properties of Brake Friction Materials
,” Wear
, 264
(3–4
), pp. 204
–210
. 21.
Kim
, S. J.
, and Jang
, H.
, 2000
, “Friction and Wear of Friction Materials Containing Two Different Phenolic Resins Reinforced with Aramid Pulp
,” Tribol. Int.
, 33
(7
), pp. 477
–484
. 22.
Liu
, X.
, Wang
, H.
, Wu
, X.
, Bu
, J.
, and Cong
, P.
, 2014
, “Effect of the Rubber Components on the Mechanical Properties and Braking Performance of Organic Friction Materials
,” Journal of Macromolecular Science, Part B
, 53
(4
), pp. 707
–720
. 23.
Chang
, Y. H.
, Joo
, B. S.
, Lee
, S. M.
, and Jang
, H.
, 2018
, “Size Effect of Tire Rubber Particles on Tribological Properties of Brake Friction Materials
,” Wear
, 394–395
, pp. 80
–86
. 24.
Union Internationale des Chemins de fer
, 2010
, Brakes—Brakes with Composite Brake Blocks—General Conditions for Certification of Composite Brake Blocks. UIC Leaflet 541–4
, 4th ed, Union Internationale des Chemins de fer
, Paris, France
.25.
European Railway Agency
, 2015
, Friction Elements for Wheel Tread Brakes for Freight Wagons (ERA/TD/2013-02/INT v 3.0), https://www.era.europa.eu/sites/default/files/activities/docs/era_td_2013_02_int_en.pdf, Accessed August 1, 2021.26.
Nukumizu
, K.
, Kobayashi
, T.
, Abe
, T.
, and Unno
, M.
, 2008
, “Study of the Formulation Mechanism for Metal Pick-up on the Frictional Surface of a Disc Brake Pad
,” p. 2008
.27.
Monreal
, P.
, Clavería
, I.
, Arteta
, P.
, and Rouzaut
, T.
, 2021
, “Effect of Modified Novolac Resins on the Physical Properties and Friction Performance of Railway Brake Blocks
,” Tribol. Int.
, 154
, p. 106722
. 28.
Cox
, R.
, 2011
, Engineered Tribological Composites
, SAE International
, Warrendale, PA
.29.
Matějka
, V.
, Simha Martynková
, G.
, Ma
, Y.
, and Lu
, Y.
, 2009
, “Semimetallic Brake Friction Materials Containing ZrSiO4: Friction Performance and Friction Layers Evaluation
,” J. Compos. Mater.
, 43
(13
), pp. 1421
–1434
. 30.
Sugözü
, B.
, and Dağhan
, B.
, 2016
, “Effect of BaSO4 on Tribological Properties of Brake Friction Materials
”, p. 4
.31.
Sutikno
, M.
, Marwoto
, P.
, and Rustad
, S.
, 2010
, “The Mechanical Properties of Carbonized Coconut Char Powder-Based Friction Materials
,” Carbon
, 48
(12
), pp. 3616
–3620
. 32.
Shin
, M. W.
, Kim
, Y. H.
, and Jang
, H.
, 2014
, “Effect of the Abrasive Size on the Friction Effectiveness and Instability of Brake Friction Materials: A Case Study with Zircon
,” Tribol. Lett.
, 55
(3
), pp. 371
–379
. 33.
Saffar
, A.
, 2012
, “Effect of Rubber Component on the Performance of Brake Friction Materials
”, p. 12
.34.
Bijwe
, J.
, Majumdar
, N.
, and Satapathy
, B. K.
, 2005
, “Influence of Modified Phenolic Resins on the Fade and Recovery Behavior of Friction Materials
”, p. 11
.35.
Balotin
, J. G.
, Neis
, P. D.
, and Ferreira
, N. F.
, 2009
, “Analysis of the Influence of Temperature on the Friction Coefficient of Friction Materials
,” 4, p. 9
.36.
Laguna-Camacho
, J. R.
, Juárez-Morales
, G.
, Calderón-Ramón
, C.
, Velázquez-Martínez
, V.
, Hernández-Romero
, I.
, Méndez-Méndez
, J. V.
, and Vite-Torres
, M.
, 2015
, “A Study of the Wear Mechanisms of Disk and Shoe Brake Pads
,” Eng. Failure Anal.
, 56
, pp. 348
–359
. 37.
Eriksson
, M.
, and Jacobson
, S.
, 2000
, “Tribological Surfaces of Organic Brake Pads
,” Tribol. Int.
, 33
(12
), pp. 817
–827
. 38.
Eriksson
, M.
, Bergman
, F.
, and Jacobson
, S.
, 2002
, “On the Nature of Tribological Contact in Automotive Brakes
,” Wear
, 252
(1–2
), pp. 26
–36
. 39.
Knorr-Bremse—Friction material application guide
, https://www.knorr-bremse.com/remote/media/documents/railvehicles/product_broschures/brake_systems/Friction_Material_P_1258_EN.pdf. Accessed 1 August 202140.
Ria
, T.
, Soib
, M.
, and Kasir
, R.
, 2012
, Powder Metallurgy
, K.
Kondoh
, ed., InTech
, London, UK
.41.
Wang
, J.
, and Gu
, M.
, 2004
, “Wear Properties and Mechanisms of Nylon and Carbon-Fiber-Reinforced Nylon in Dry and Wet Conditions
,” J. Appl. Polym. Sci.
, 93
(2
), pp. 789
–795
. 42.
Kato
, T.
, and Magario
, A.
, 1994
, “The Wear of Aramid Fiber Reinforced Brake Pads: The Role of Aramid Fibers
,” Tribology Transactions
, 37
(3
), pp. 559
–565
. 43.
Cox
, R.
, 2012
, Engineered Tribological Composites
, SAE International
, Warrendale, PA
, pp. 247
–266
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