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Tribology Letters

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01.06.2016 | Original Paper

Wear and Contact Temperature Evolution in Pin-on-Disc Tribotesting of Low-Metallic Friction Material Sliding Against Pearlitic Cast Iron

verfasst von: Giovanni Straffelini, Sergey Verlinski, Piyush Chandra Verma, Giorgio Valota, Stefano Gialanella

Erschienen in: Tribology Letters | Ausgabe 3/2016

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Abstract

Pin-on-disc tribotesting is widely used to investigate the sliding behaviour of materials, including friction materials used in braking systems. The evaluation of the average contact temperature is paramount to understand the acting friction and wear mechanisms, and to determine the role of the materials. In the present work, the tribological behaviour of a commercial low-metallic friction material during dry sliding against a pearlitic cast iron has been investigated and the evolution of pin and disc temperature was recorded. The temperature distributions in the pin and the disc were modelled using a finite element analysis with three different approaches, i.e. considering a perfect contact, the separated bodies concept, and the presence of a third body between the sliding surfaces. The results were then discussed by considering the damaging phenomena occurring at the sliding contact. Wear was found to be nearly mild in nature in agreement with the contact temperatures that were determined to be lower than 100 °C. During sliding, a limited third body was formed, made of a partially covering friction layer on the pin surface, and a thin and irregular oxide layer on the cast iron wear track. The approach based on the perfect contact with thermal continuity at the interface was found to better fit the experimental temperature records and to be in substantial agreement with the observed wear phenomena occurring at the pin–disc interface.

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Chan, D., Stachowiak, G.W.: Review of automotive brake friction materials. Proc. Inst. Mech. Eng. D J. Automob. Eng. 218(9), 953–966 (2004)CrossRef

Eriksson, M., Bergman, F., Jacobson, S.: On the nature of tribological contact in automotive brakes. Wear 252, 26–36 (2002)CrossRef

Bode, K., Ostermayer, G.-P.: A comprehensive approach for the simulation of heat and heat-induced phenomena in friction materials. Wear 311, 47–56 (2014)CrossRef

Sanders, P., Xu, N., Dalka, T.M., Maricq, M.M.: Airborne brake wear debris: size distributions, composition, and a comparison of dynamometer and vehicle tests. Environ. Sci. Technol. 37, 4060–4069 (2003)CrossRef

Kukutschova, J., Roubicek, V., Malachova, K., Pavlickova, Z., Holusa, R., Kubackova, J., Micka, V., MacCrimmon, D., Filip, P.: Wear mechanism in automotive brake materials, wear debris and its potential environmental impact. Wear 267, 807–817 (2009)CrossRef

Thorpe, A., Harrison, R.M.: Sources and properties of non-exhaust particulate matter from road traffic: a review. Sci. Total Environ. 400, 270–282 (2008)CrossRef

Wahsltröm, J., Gventsadze, D., Olander, L., Kutelia, E., Gventsadze, L., Tsurtsumia, O., Olofsson, U.: A pin-on-disc investigation of novel nanoporous composite-based and conventional brake pad materials focusing on airborne wear particles. Tribol. Int. 42, 1838–1843 (2011)

Ciudin, R., Verma P.C., Gialanella, S., Straffelini, G.: Wear debris materials from brake systems: environmental and health issues. In: Proceedings of 9th International Conference on Urban Regeneration and Sustainability (The Sustainable City IX), Wit Press, Southampton, pp. 1423–1434. (2014)

Straffelini, G.: Friction and Wear, Methodologies for Design and Control. Springer, Berlin (2015)

10.

Kennedy, F.E.: Thermal and thermomechanical effects in dry sliding. Wear 100, 453–476 (1984)CrossRef

11.

Kennedy, F.E., Lu, Y., Baker, I.: Contact temperatures and their influence on wear during pin-on-disk tribotesting. Tribol. Int. 82, 534–542 (2015)CrossRef

12.

Laraqui, N., Alilat, N., Garcia de Maria, J.M., Bairi, A.: Temperature and division of heat in a pin-on-disc frictional device-Exact analytical solution. Wear 266, 765–770 (2009)CrossRef

13.

Blok, H.: Theoretical field study of temperature rise at surfaces of actual contact under oiliness lubricating conditions. Proc. Inst. Mech. Eng. Lond. 45, 222–235 (1937)

14.

Jaeger, J.C.: Moving surfaces of heat and the temperature at sliding surfaces. Proc. R. Soc. N.S.W. 76, 203–224 (1942)

15.

Grzes, P.: Partition of heat in 2D finite element model of a disc brake. Acta Mech. Autom. 5, 35–41 (2011)

16.

Nosko, O.: Partition of friction heat between sliding semispaces due to adhesion-deformational heat generation. Int. J. Heat Mass Transf. 64, 1189–1195 (2013)CrossRef

17.

Ashby, M.F., Abulawi, J., Kong, H.S.: Temperature maps for frictional heating in dry sliding. Tribol. Trans. 34, 577–587 (1991)CrossRef

18.

Day, A.: Braking of Road Vehicles. Elsevier, Amsterdam (2014)

19.

Majcherczak, D., Dufrenoy, P., Nait-Abdelaziz, M.: Third body influence on thermal friction contact problems: application to braking. ASME J. Tribol. 127, 89–95 (2005)CrossRef

20.

Loizou, A., Qui, H.S., Day, A.J.: A fundamental study on the heat partition ratio of vehicle disk brakes. J. Heat Transf. 135, 121302-1–121302-8 (2013)CrossRef

21.

Talati, F., Jalalifar, S.: Analysis of heat conduction in a disk brake system. Heat Mass Transf. 45, 1047–1059 (2009)CrossRef

22.

Verma, P.C., Alemani, M., Gialanella S., Lutterotti, L., Olofsson, U., Straffelini, G.: Wear debris from brake system materials: a multi-analytical characterization approach. Tribol. Int. 94, 249–259 (2016)CrossRef

23.

Straffelini, G., Maines, L.: The relationship between wear of semimetallic friction materials and pearlitic cast iron in dry sliding. Wear 307, 75–80 (2013)CrossRef

24.

Mkhitarian, S.M., Shekyan, L.A., Verlinski, S.V., Aidun, D., Marzocca, P.: Stationary theory of heat-conductivity for an axi-symmetrical piece homogeneous space with circular inclusion. J. Therm. Stress. 35, 424–447 (2012)CrossRef

25.

Majcherczak, D., Dufrenoy, P., Berthier, Y., Nait-Abdelaziz, M.: Experimental thermal study of contact with third body. Wear 261, 467–478 (2006)CrossRef

26.

Lutterotti, L.: Total pattern fitting for the combined size-strain-stress-texture determination in thin film diffraction. Nucl. Instrum. Methods Phys. Res. B268, 334–340 (2010)CrossRef

27.

Lutterotti, L., Matthies, S., Wenk, H.-R.: MAUD: a friendly Java program for material analysis using diffraction. IUCr Newsl. CPD 21, 14–15 (1999)

28.

ANSYS v. 16.0: Ansys User Manual. ANSYS, Inc., Houston (1996)

29.

Belhocine, A., Bouchetara, M.: Thermal analysis of a solid brake disc. Appl. Therm. Eng. 32, 59–67 (2012)CrossRef

30.

Zhang, J., Xia, C.G.: Research of the transient temperature field and friction properties on disc brakes. Adv. Mater. Res. 756–759, 4331–4335 (2013)CrossRef

31.

Handbook, A.S.M.: Properties and Selection: Iron, Steels, and High-Performance Alloys, vol. 1, 10th edn. ASM Handbook, Metals Park (1990)

32.

Valota, G., De Luca, S., Soderberg, A.: Use of FEA to clarify pin-on-disc tribometer tests of disc brake materials. In: Proceedings of Eurobrake, Dresden, Germany, 4–6 May 2015

33.

Osterle, W., Griepentrog, M., Gross, Th, Urban, I.: Chemical and microstructural changes induced by friction and wear of brakes. Wear 251, 1469–1476 (2001)CrossRef

34.

Verma, P.C., Menapace, L., Bonfanti, A., Ciudin, R., Gialanella, S., Straffelini, G.: Braking pad–disc system: wear mechanisms and formation of wear fragments. Wear 322–323, 251–258 (2015)CrossRef

35.

Straffelini, G., Trabucco, D., Molinari, A.: Oxidative wear of heat-treated steels. Wear 250, 485–491 (2001)CrossRef

36.

Straffelini, G., Molinari, A.: Mild sliding wear of Fe-0.2%C, Ti-5%Al-4%V and Al-7072: a comparative study. Tribol. Lett. 41, 227–238 (2011)CrossRef

37.

Cho, M.H., Kim, S.J., Kim, D., Jang, H.: Effects of ingredients on tribological characteristics of a brake lining: an experimental case study. Wear 258, 1682–1687 (2005)CrossRef

Titel: Wear and Contact Temperature Evolution in Pin-on-Disc Tribotesting of Low-Metallic Friction Material Sliding Against Pearlitic Cast Iron
verfasst von: Giovanni Straffelini
Sergey Verlinski
Piyush Chandra Verma
Giorgio Valota
Stefano Gialanella
Publikationsdatum: 01.06.2016
Verlag: Springer US
Erschienen in: Tribology Letters / Ausgabe 3/2016
Print ISSN: 1023-8883
Elektronische ISSN: 1573-2711
DOI: https://doi.org/10.1007/s11249-016-0684-9

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