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Journal of Materials Engineering and Performance
Published in: Journal of Materials Engineering and Performance 10/2021

07-06-2021

Effect of Material Hardness on Water Lubrication Performance of Thermoplastic Polyurethane under Sediment Environment

Authors: Zhengming Jia, Zhiwei Guo, Chengqing Yuan

Published in: Journal of Materials Engineering and Performance | Issue 10/2021

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Abstract

Water-lubricated stern tube bearings are widely used in marine shaft systems, where their lubrication performance determines the efficiency and navigation safety of ships. The hardness of materials is an important factor affecting the tribological performance of water-lubricated bearings under sediment conditions. This study investigated the wear behavior of thermoplastic polyurethane (TPU) materials with different shore hardnesses under sediment conditions. Four kinds of TPU with different shore hardness were selected. The test results showed that the shore hardness of TPU depended on the content of the TPU hard segment. With increasing hardness, the absorption peak strength of the functional groups increased, and the increase in hardness could enhance the tensile strength of the TPU materials. In all test groups, the friction coefficient of TPU with 60 and 70 A hardness was relatively stable. The total wear volume of TPU with 70 A hardness was 45.9% lower than that of TPU with 60 A hardness. TPU with 70 A hardness had better ductility and embedded possession. The wear modes of TPU with 70 A hardness were crimping and micro-plowing. Only mild wear occurred on the wear surface of TPU with 70 A hardness. The main wear mechanisms of the TPU with 70 A hardness were abrasive wear and fatigue wear under sediment conditions. In summary, TPU with 70 A hardness was the most suitable for water-lubricated stern bearings under sediment conditions. The data from this study provide deep insight into the wear process of TPU materials with different hardness under sediment conditions and may be useful for selecting the proper TPU material hardness for water-lubricated stern bearings.
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Literature
1.
Z.L. Xie, N. Ta and Z.S. Rao, The Lubrication Performance of Water Lubricated Bearing with Consideration of Wall Ship and Inertial Force, J. Hydrodyn., 2017, 29, p 52–60.CrossRef
2.
W. Litwin, Experimental Research on Water Lubricated Three Layer Sliding Bearing with Lubrication Grooves in the Upper Part of the Bush and Its Comparison with a Rubber Bearing, Tribol. Int., 2015, 82, p 153–161.CrossRef
3.
F. Andritsos, H. Cozijn. An Innovative Oil Pollution Containment Method for Ship Wrecks Proposed for Offshore Well Blow-Outs. In: ASME 2011 30th International Conference on Ocean, Offshore Arctic Engineering, 2011, 73–81.
4.
Y.W. Sun, X.P. Yan, C.Q. Yuan and X.Q. Bai, Insight into Tribological Problems of Green Ship and Corresponding Research Progresses, Friction, 2018, 4, p 1–12.
5.
W.H. Briscoe, S. Titmuss, F. Tibeng, R.K. Thomas, D.J. McGillivray and J. Klein, Boundary Lubrication Under Water, Nature, 2006, 444, p 191–194.CrossRef
6.
X.P. Yan, C.Q. Yuan, X.Q. Bai and L. Xu, Research Status and Advances of Tribology of Green Ship, Tribology, 2012, 32(4), p 410–420.
7.
T.D. Ta, A.K. Tieu, H. Zhu et al., Tribological Behavior of Aqueous Copolymer Lubricant in Mixed Lubrication Regime, ACS Appl. Mater. Inter., 2016, 8, p 5641–5652.CrossRef
8.
D. Savio, K. Falk and M. Moseler, Slipping Domains in Water-Lubricated Microsystems For Improved Load Support, Tribol. Int., 2018, 120, p 269–279.CrossRef
9.
C.Q. Yuan, Z.X. Peng, X.C. Zhou and X.P. Yan, The Surface Roughness Evolutions of Wear Particles and Wear Components Under Lubricated Rolling Wear Condition, Wear, 2005, 259, p 512–518.CrossRef
10.
Z.W. Guo, C.Q. Yuan, A.X. Liu et al., Study on Tribological Properties of Novol Biomimetic Material for Water-Lubricated Stern Tube Bearing, Wear, 2017, 376–377, p 911–919.CrossRef
11.
Changjiang Water Resources Commission of the Ministry of Water Resources. Changjiang Sediment Bulletin 2018, China, 2019.
12.
Q.X. Xu, G. Shi and Z.F. Chen, Analysis of Recent Changing Characteristics and Tendency Runoff and Sediment Transport in the Upper Reach of Yangtze River, Adv. Water Sci., 2004, 15(14), p 420–426.
13.
S.M. Nahvi, P.H. Shipway and D.G. McGartney, Effects of Particle Crushing in Abrasion Testing of Steels with Ash from Biomass-Fired Powerplants, Wear, 2009, 267(1–4), p 34–42.CrossRef
14.
C.Q. Yuan, Z.W. Guo, W. Tao, C.L. Dong and X.Q. Bai, Effects of Different Grain Sized Sands on Wear Behaviours of NBR/Casting Copper Alloys, Wear, 2017, 384–385, p 185–191.CrossRef
15.
C.L. Dong, C.Q. Yuan, X.Q. Bai, Y. Yang and X.P. Yan, Study on Wear Behaviours for NBR/Stainless Steel Under Sand Water-Lubricated Conditions, Wear, 2015, 332–333, p 1012–1020.CrossRef
16.
S. Xiao and H. Sue, Effect of Molecular Weight on Scratch and Abrasive Wear Behaviors of Thermoplastic Polyurethane Elastomers, Polymer, 2019, 169, p 124–130.CrossRef
17.
M. Avalle and R. Elisa, Tribological Characterization of Modified Polymeric Blends, Procedia Struct. Integr., 2018, 8, p 239–255.CrossRef
18.
M. Zahid, A.E.D.R. Castillo, S.B. Thorat et al., Graphene Morphology Effect on the Gas Barrier, Mechanical and Thermal Properties of Thermoplastic Polyurethane, Compos. Sci. Technol., 2020, 200, p 108461.CrossRef
19.
X.Y. Li, G.L. Wang, C.X. Yang et al., Mechanical and EMI Shielding Properties of Solid and Microcellular TPU/Nanographite Composite Membranes, Polym. Test., 2021, 93, p 106891.CrossRef
20.
J.L. Xuan, I.T. Hong and E.C. Fitch, Hardness Effect on Three-Body Abrasive Wear Under Fluid Lubrication, J. Tribol-T ASME, 1989, 111, p 35–40.CrossRef
21.
A.A. SemenetsEmail and V.N. Anisimov, Development of Triboengineering Composite Materials Based on Thermoplastic Polyurethanes, J. Frict. Wear, 2010, 31, p 208–213.CrossRef
22.
Ministry of Water Resources of the People’s Republic of China. China River Sediment Bulletin 2018, China, 2019.
23.
H. Wang, X.B. Ran, J. Liu, W.T. Wu, M.L. Li and J.Y. Zang, Response of the Sediment Geochemistry of the Changjiang River (Yangtze River) to the Impoundment of the Three Gorges Dam, J. Environ. Sci-China, 2019, 83, p 161–173.CrossRef
24.
Department of Defense, MIL-DTL-17901C (SH). Bearing Components, Bonded Synthetic Rubber, Water Lubricated, 2005, p. 8.
25.
R. Gheisari and A.A. Polycarpou, Three-Body Abrasive Wear of Hard Coatings: Effects of Hardness and Roughness, Thin Solid Films, 2018, 666, p 66–75.CrossRef
26.
G.M. Krolczyk, R.W. Maruda, J.B. Krolczyk, P. Nieslony, S. Wojciechowski and S. Legutko, Parametric and Nonparametric Description of the Surface Topography in the Dry and MQCL Cutting Conditions, Measurement, 2018, 121, p 225–239.CrossRef
27.
G.M. Krolczyk, J.B. Krolczyk, R.W. Maruda, S. Legutko and M. Tomaszewski, Metrological Changes in Surface Morphology of High-Strength Steels in Manufacturing Processes, Measurement, 2016, 88, p 176–185.CrossRef
28.
J.J. Han, W. Zheng and G.C. Wang, Investigation of Influence Factors on Surface Roughness of Micro-Scale Features, Precis. Eng., 2019, 56, p 524–529.CrossRef
29.
I. Saravanan, A.E. Perumal and V. Balasubramanian, A Study of Frictional Wear Behavior of Ti6Al4V and UHMWPE Hybrid Composite on TiN Surface for Bio-Medical Applications, Tribol. Int., 2016, 98, p 179–189.CrossRef
30.
S.F. Weng and Y.Z. Xu, Fourier Transform Infrared Spectroscopy, 3rd ed. Chemical Industry Press, China, 2016.
31.
P. Siddaramaiah, B. Suresha and J. Lee, Mechanical and Three-Body Abrasive Wear Behaviour of PMMA/TPU Blends, Mater. Sci. Eng. A, 2008, 492(1–2), p 486–490.
32.
P. Nieslony, G.M. Krolczyk, S. Wojciechowski, R. Chudy, K. Zak and R.W. Maruda, Surface Quality and Topographic Inspection of Variable Compliance Part After Precise Turning, Appl. Surf. Sci., 2018, 434, p 91–101.CrossRef
33.
V.L. Popov, Contact Mechanics and Friction: Physical Principles and Applications, 2nd ed. Springer, Germany, 2016.
34.
S.Z. Wen and P. Huang, Principles of Tribology, 4th ed. Tsinghua University Press, China, 2012.
35.
W. Litwin and C. Dymarski, Experimental Research on Water-Lubricated Marine Stern Tube Bearings in Conditions of Improper Lubrication and Cooling Causing Rapid Bush Wear, Tribol. Int., 2016, 95, p 449–455.CrossRef
36.
J.Y. Gong, Y. Jin, Z.L. Liu, H. Jiang and M.H. Xiao, Study on Influencing Factors of Lubrication Performance of Water-Lubricated Micro-Groove Bearing, Tribol. Int., 2019, 129, p 390–397.CrossRef
37.
W. Litwin, Influence of Local Bush Wear on Water Lubricated Sliding Bearing Load Carrying Capacity, Tribol. Int., 2016, 103, p 352–358.CrossRef
Metadata
Title
Effect of Material Hardness on Water Lubrication Performance of Thermoplastic Polyurethane under Sediment Environment
Authors
Zhengming Jia
Zhiwei Guo
Chengqing Yuan
Publication date
07-06-2021
Publisher
Springer US
Published in
Journal of Materials Engineering and Performance / Issue 10/2021
Print ISSN: 1059-9495
Electronic ISSN: 1544-1024
DOI
https://doi.org/10.1007/s11665-021-05912-z

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