SURFACE MODIFICATION OF RING-TRAVELER OF TEXTILE SPINNING MACHINE FOR SUBSTANTIALITY

Preetkanwal Singh Bains, Jasmaninder Singh Grewal, Sarabjeet Singh Sidhu, Sandeep Kaur, Gurpreet Singh

DOI Number
https://doi.org/10.22190/FUME190623005B
First page
031
Last page
042

Abstract


In this report, a study of the wear mechanisms involved in spinning Ring and Traveler of textile industry have been presented. These components, after surface processing with various coatings techniques, were analyzed on the test rig to analyze the wear mechanism. The objective was accomplished by comparing various plasma sprayed coatings on E52100 steel pins using a Pin-on-Disc machine. The surface morphology as well as mechanical properties of the deposited coatings namely WC-Co-Cr, Al2O3+TiO2 (Alumina-Titania) and Cr3C2NiCr, as well as uncoated E52100, were comparatively studied. This study elucidates towards improving the working life of the Ring in a Textile mill while spinning operation. An X-ray diffractometer (XRD) and Scanning Electron Microscope (SEM) was employed to characterize the unworn and worn surfaces of the specimens. The study revealed that the wear rate of Plasma sprayed thermal coatings enhanced with augmenting load. The Plasma sprayed WC-Co-Cr, Cr3C2NiCr, Al2O3+13TiO2 coatings developed on workpiece pins exhibited a notable decrease in volume loss of the material as compared to uncoated E52100 substrate. WC-Co-Cr coating turned out to be the best performer in terms of lowest cumulative volume loss among all the variants of coatings.


Keywords

Pin-on-disc, Thermal, Al2O3, Coatings, SEM, Traveler, XRD, Ring

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References


Usta, I., Canoglu, S., 2003, Influence of ring traveler weight and coating on hairiness of acrylic and cotton yarns, Indian Journal of Fibre and Textile Research, 28(2), pp. 157-162.

Hess, M., 2019, A study on gross slip and fretting wear of contacts involving a power-law graded elastic half-space, Facta Universitatis-Series Mechanical Engineering, 17(1), pp. 47-64.

Wang, Y., Jiang, S., Wang, M., Wang, S., Xiao, T.D., Strutt, P.R., 2000, Abrasive wear characteristic of plasma sprayed nanostructured alumina/titania coatings, Wear, 237(2), pp. 176-185.

Yılmaz, R., Kurt, A.O., Demir, A., Tatl, Z., 2007, Effects of TiO2 on the mechanical properties of the Al2O3-TiO2 plasma sprayed coating, Journal of the European Ceramic Society, 27(2-3), pp. 1319-1323.

Singh, G., Sidhu, S.S., Bains, P.S., Bhui, A.S., 2019, Improving microhardness and wear resistance of 316L by TiO2 powder mixed electro-discharge treatment, Materials Research Express 6(8):086501.

Cukul, D., Beceren, Y., 2016, Yarn hairiness and the effect of surface characteristics of the ring traveler, Textile Research Journal, 86(15), pp. 1668-1674.

Yılmaz, S., 2009, An evaluation of plasma-sprayed coatings based on Al2O3 and Al2O3-13 wt. % TiO2 with bond coat on pure titanium substrate, Ceramics International, 35(5), pp. 2017-2022.

Clyne, T.W., Troughton, S.C., 2018, A review of recent work on discharge characteristics during plasma electrolytic oxidation of various metals, International Materials Reviews, 64(3), pp. 127-162.

Zhang, B., Dong, Q., Zhu, N., Ba, Z., Han, Y., Wang, Z., 2019, Microstructure and wear behaviors of plasma-sprayed FeCrNiMoCBSi coating with nano-grain dispersed amorphous phase in reciprocating sliding contact, Tribology Transactions, 62(2), pp. 274-282.

Tao, S., Zhijian, Y., Xiaming, Z., Chuanxian, D., 2010, Sliding wear characteristics of plasma-sprayed Al2O3 and Cr2O3 coatings against copper alloy under severe conditions, Tribology International, 43(1-2), pp. 69-75.

Wang, L., Liu, S., Gou, J., Zhang, Q., Zhou, F., Wang, Y., Chu, R., 2019, Study on the wear resistance of graphene modified nanostructured Al2O3/TiO2 coatings, Applied Surface Science, 492(1), pp. 272-279.

Niu, B., Qiang, L., Zhang, J., Zhang, F., Hu, Y., Chen, W., Liang, A., 2018, Plasma sprayed α-Al2O3 main phase coating using γ-Al2O3 powders, Surface Engineering, 35(9), pp. 801-808.

Rickerby, D.S., Winstone, M.R., 1992, Coatings for gas turbines, Material and Manufacturing Processes, 7(4), pp. 495-526.

Li, Q., Yuan, X., Xu, H., Song, P., Li, Q., Lu, K., Huang, T., Li, C., Lu, J., 2019, Microstructure and fracture toughness of in-situ nanocomposite coating by thermal spraying of Ti3AlC2/Cu powder, Ceramics International, 45(10), pp. 13119-13126.

Pawlowski, L., 1995, The Science and Engineering of Thermal Spray Coatings, John Wiley & Sons, Inc.: Oxford, UK, pp. 626.

Rhys, J., Thomas, N., 1990, Thermally sprayed coating systems for surface protection and clearance control applications in aero engines, Surface and Coatings Technology, 43(1), pp. 402-415.

Li, C.J., Guan-Jun, Y., Cheng-Xin, L., 2013, Development of particle interface bonding in thermal spray coatings: A review, Journal of Thermal Spray Technology, 22(2-3), pp. 192-206.

Giaglianonia, W.C., Cunha, M.A., Bergmanna, C.P., Fragassa, C., Pavlovic, A., 2018, Synthesis, characterization and application by HVOF of a WC-Co-Cr/NiCr nanocomposite as protective coating against erosive wear, Tribology in Industry, 40(3), pp. 477-487.

Marques, A.S., Dalcin, R.L., Oliveira, L.F., Vitor-da-Silva, L.A., Santos, G.R., Alexandre-da-Silva, R., 2018, Comparative analysis of the friction and microstructural properties of WC-10Co-4Cr and Cr3C2-25NiCr coatings sprayed by high-velocity oxy-fuel (HVOF), American Journal of Materials Science, 8(3), pp. 51-57.

Dhakar, B., Chatterjee, S., Sabiruddin, K., 2016, Influence of process parameters on the formation of phases and mechanical properties of plasma sprayed Al2O3–Cr2O3 coatings, Materials Research Innovations, 21(6), pp. 367-376.

Manjunatha, S.S., Manjaiah, M., Basavarajappa, S., 2017, Predictive modelling of dry sliding wear in sealed plasma-sprayed Mo coating using response surface methodology, Tribology - Materials, Surfaces and Interfaces, 12(1), pp. 1-8.

Chatha, S.S., Sidhu, H.S., Sidhu B.S., 2012, Characterisation and corrosion-erosion behaviour of carbide based thermal spray coatings, Journal of Minerals and Materials Characterization and Engineering, 11(6), pp. 569-586.

Murthy, J.K.N., Venkataraman, B., 2006, Abrasive wear behavior of WC-Co-Cr and Cr3C2–20(NiCr) deposited by HVOF and detonation spray processes, Surface and Coatings Technology, 200(8), pp. 2642-2652.

Fujino, K., Shimotsuma, Y., 1955, Studies on spinning rings and travelers, Textile Research Journal, 25(9), pp. 799-811.

Lingzhong, D., Chuanbing, H., 2011, Preparation and Wear Performance of NiCr/Cr3C2–NiCr/hBN Plasma Sprayed Composite Coating, Surface and Coatings Technology, 205(12), pp. 3722-3728.

Karimi, A., Verdon, C., Barbezat, G., 1993, Microstructure and hydroabrasive wear behaviour of high velocity oxy-fuel thermally sprayed WC-Co (Cr) coatings, Surface and Coating Technology, 57(1), pp. 81-89.

Mahajan, A., Sidhu, S.S., 2018, Enhancing biocompatibility of Co-Cr alloy implants via electrical discharge process, Materials Technology, 33(8), pp. 524-531.

Bagde, P., Sapate, S.G., Khatirkar, R.K., Vashishtha, N., 2018, Friction and abrasive wear behaviour of Al2O3 -13TiO2 and Al2O3 -13TiO2 +Ni Graphite coatings, Tribology International, 121(1), 353-372.

Li, Z., Wei, M., Xiao, K., Bai, Z., Xue, W., Dong, C., Wei, D., Li, X., 2019, Microhardness and wear resistance of Al2O3-TiB2-TiC ceramic coatings on carbon steel fabricated by laser cladding, Ceramics International, 45(1), pp. 115-121.

Mahajan, A., Sidhu, S.S., 2019, Potential of electrical discharge treatment to enhance the in vitro cytocompatibility and tribological performance of Co–Cr implant, Journal of Materials Research, 34(16), pp. 2837-2847.

Nasiri-Vatan, H., Adabi, M., 2017, Investigation of wear and corrosion resistance of nanocomposite coating formed on AZ31B Mg alloy by plasma electrolytic oxidation, Transactions of the IMF, 95(6), pp. 308-315.

Pinzon, A.V., Urrego, K.J., Gonzalez-Hernandez, A., Ortiz, M.R., Galvis, F.V., 2018, Corrosion protection of carbon steel by alumina-titania ceramic coatings used for industrial applications, Ceramics International, 44(17), pp. 21765-21773.




DOI: https://doi.org/10.22190/FUME190623005B

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ISSN: 2335-0164 (Online)

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