ARTICLE
Comparative evaluation of wear behavior of tribo-pairs in reciprocating pumps with multiple materials under different conditions
Ran Li 1,2
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1
Graduate School, China Coal Research Institute, Beijing, China
 
2
Beijing Tianma Intelligent Control Technology Co., Ltd. Beijing, China
 
3
School of Mechanical Electronic and Information Engineering, China University of Mining and Technology Beijing, Beijing, China
 
 
Submission date: 2022-07-07
 
 
Final revision date: 2022-10-18
 
 
Acceptance date: 2022-10-14
 
 
Online publication date: 2023-01-02
 
 
Publication date: 2023-01-30
 
 
Corresponding author
Dalong Wang   

School of Mechanical Electronic & Information Engineering, China University of Mining and Technology Beijing, China
 
 
Journal of Theoretical and Applied Mechanics 2023;61(1):77-87
 
KEYWORDS
TOPICS
ABSTRACT
In the study of wear behavior of tribo-pairs in reciprocating pumps, the tribo-pairs can be considered as contact pairs consisting of a disc and pin. In this paper, pin-on-disc wear tests were carried out by using two types of cast iron pin specimens with different materials. Additionally, the effects of the lubrication condition, test load, diamond-like carbon (DLC) coating and plateau honing cross-hatch pattern on wear behavior of the tribo-pairs were investigated. Experimental results based on surface topography analysis and scanning elec- tron micrograph (SEM) analysis show that the lubricant and DLC coating have a positive effect on wear resistance of test specimens. Disc specimens of three material types (i.e. ISO 185/JL/250, tin-bronze, zirconia) are able to show good anti-wear behavior. The tribo-pairs composed of spheroidal graphite cast irons as well as implementation of the plateau honing cross hatch on disc specimens have no significant effect on the wear resistance. The Archard model was used to estimate abrasive wear under dry conditions, which was over-predicted compared to the experimental results.
 
REFERENCES (25)
1.
ASTM D., 2010, 6425: Standard test method for measuring friction and wear properties of extreme pressure (EP) lubricating oils using SRV test machine, ASTM International.
 
2.
Ausserer F., Klien S., Velkavrh I., Forêt P., Diem A., 2016, Investigations of the sliding and wear behaviour in various gaseous atmospheres using a SRV testing apparatus, Tribologie und Schmierungstechnik, 63, 1, 22-28.
 
3.
Ayyagari A., Barthelemy C., Gwalani B., Banerjee R., Scharf T.W., Mukherjee S., 2018, Reciprocating sliding wear behavior of high entropy alloys in dry and marine environments, Materials Chemistry and Physics, 210, 162-169.
 
4.
Balarini R., Diniz G.A.S., Profito F.J., Souza R.M.D., 2020, Comparison of unidirectional and reciprocating tribometers in tests with MoDTC-containing oils under boundary lubrication, Tribology International, 149, 105686.
 
5.
Cabanettes F., Dimkovski Z., Rosén B.G., 2015, Roughness variations in cylinder liners induced by honing tools’ wear, Precision Engineering, 41, 40-46.
 
6.
Carrera-Espinoza R., Figueroa-López U., Martinez-Trinidad J., Campos-Silva I., Hernández-Sánchez E., Motallebzadeh A., 2016, Tribological behavior of borided AISI 1018 steel under linear reciprocating sliding conditions, Wear, 362-363, 1-7
 
7.
Dang G., Tieu A.K., Su L., Wang P., Wang L., Lan X., Cui S., Zhu H., 2020, Investigation into reciprocating dry sliding friction and wear properties of bulk CoCrFeNiMo high entropy alloys fabricated by spark plasma sintering and subsequent cold rolling processes: Role of Mo element concentration, Wear, 460-461,15, 203440.
 
8.
Gore M., Perera M., Styles G., King P.D., Rahnejat H., 2011, Wear characteristics of advanced honed and cross-hatched coated cylinder liners, Proceedings of the 66th annual meeting and exhibition of the STLE, 73, 1-6.
 
9.
ISO-14242-2, 2016, Implants for surgery-wear of total hip-joint prostheses – Part 2: Methods of measurement.
 
10.
Jocsak J., Tomanik E., Wong V.W., Tian T., 2005, The characterization and simulation of cylinder liner surface finishes, ASME Internal Combustion Engine Division Spring Technical Conference, 41847, 457-467.
 
11.
Khanlari K., Ramezani M., Kelly P., Cao P., Neitzert T., 2018, Comparison of the reciprocating sliding wear of 58Ni39Ti-3Hf alloy and baseline 60NiTi, Wear, 408-409, 15, 120-130.
 
12.
Kim E.-S, Kim S.-M., Lee Y.-Z., 2018, The effect of plateau honing on the friction and wear of cylinder liners, Wear, 400-401, 15, 207-212.
 
13.
Kim E.-S., Lee Y.-Z., 2021, Investigation of the effects of uneven plateau grinding on friction, wear rate, and localized surface damage on internal combustion engine cylinder liners, International Journal of Automotive Technology, 22, 3, 561-567.
 
14.
Li R., Wang D.L., Wei, W., Li, S., 2021, Analysis of the movement characteristics of the pump valve of the mine emulsion pump based on the internet of things and cellular automata, Mobile Information Systems, 2021.
 
15.
Liu K., Kang J.J., Zhang G.A., Lu Z.B., Yue W., 2021, Effect of temperature and mating pair on tribological properties of DLC and GLC coatings under high pressure lubricated by MoDTC and ZDDP, Friction, 9, 6, 1390-1405.
 
16.
Malburg M.C., Raja J.,Whitehouse D.J., 1993, Characterization of surface texture generated by plateau honing process, CIRP Annals, 42, 1, 637-639.
 
17.
Miller J.E, 1987, The Reciprocating Pump: Theory, Design, and Use, Wiley-Interscience.
 
18.
Mohamadzadeh H., Saghafiany H., Kheirandish S., 2009, Sliding wear behavior of a grey cast iron surface remelted by TIG, Journal of Materials Science and Technology, 25, 5, 622.
 
19.
Okubo H., Watanabe S., Sasaki S., Tokuta Y., Moriguchi H., Iba D., Moriwaki I., 2021, Tribological properties of a Mesh-Like nanostructured Diamond-Like Carbon (DLC) lubricated with a fully formulated oil at DLC/Steel contacts under boundary lubrication, Coatings, 11, 7, 746.
 
20.
Onuoha C., Jin C., Farhat Z.N., Kipouros G.J., Plucknett K., 2016, The effects of TiC grain size and steel binder content on the reciprocating wear behaviour of TiC-316L stainless steel cermets, Wear, 350-351, 15, 116-129.
 
21.
Rajkumar K., Aravindan S., 2013, Tribological behavior of microwave processed copper-nanographite composites, Tribology International, 57, 282-296.
 
22.
Saeidi F., Meylan B., Hoffmann P., Wasmer K., 2016, Effect of surface texturing on cast iron reciprocating against steel under starved lubrication conditions: A parametric study, Wear, 348-349, 17-26.
 
23.
Woydt M., Ebrecht J., 2003, Influence of test parameters on tribological measurements – results from international round robin tests, Tribotest, 10, 1, 59-76.
 
24.
Yin F.L., Wang Y., Ji H., Ma Z.H., Nie S.L., 2021, Impact of sliding speed on the tribological behaviors of cermet and steel balls sliding against SiC lubricated with seawater, Tribology Letters, 69, 2, 1-16.
 
25.
Zhang Z., Nie S., Yuan S., Liao W., 2015, Comparative evaluation of tribological characteristics of CF/PEEK and CF/PTFE/graphite filled PEEK sliding against AISI630 steel for seawater hydraulic piston pumps/motors, Tribology Transactions, 58, 6, 1096-1104.
 
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