Abstract:In order to improve the high-temperature wear resistance of nickel-base alloy cladding, this paper employs laser cladding technology to prepare TiC reinforced Inconel 718 composite cladding layers, and investigats the effects of TiC content on the microstructures and high-temperature friction behaviour of Inconel 718 composite cladding layer by scanning electron microscope, energy spectrometer, super depth of field microscope, and ball-disc high temperature friction and wear test machine. The results show that the addition of TiC results in the formation of (Nb,Ti)C, NbC, and different scale TiC particles, the grains of the composite cladding layers are refined. The composite cladding layer with w(TiC)=30% has the highest hardness (HV0.2) of 660.0, which is 150.0% higher than that of the Inconel 718 cladding layer (264.0); at room temperature, the volume loss of the composite cladding layer is 93.4% lower than that of the Inconel 718 cladding layer; and at high temperature, the composite cladding layer still has excellent wear resistance with a volume loss of 0.83×108 μm3. The wear mechanism of cladding layers change from abrasive wear to adhesive wear with the increace of TiC content. The improvement in hardness and room and high temperature wear resistance of the cladding layers is attributed to the formation of different scale carbide-reinforced phases and grain refinement.
卢盛儒, 仝永刚, 胡永乐, 伍鹏飞, 吉希希, 王开明. TiC含量对激光熔覆Inconel 718复合涂层组织和性能的影响[J]. 粉末冶金材料科学与工程, 2025, 30(1): 11-21.
LU Shengru, TONG Yonggang, HU Yongle, WU Pengfei, JI Xixi, WANG Kaiming. Effects of TiC content on microstructures and properties of laser cladding Inconel 718 composite coatings. Materials Science and Engineering of Powder Metallurgy, 2025, 30(1): 11-21.
[1] TESTA V, MORELLI S, BOLELLI G, et al.Alternative metallic matrices for WC-based HVOF coatings[J].Surface Coatings Technology, 2020, 402: 126308. [2] 王三星. 基于激光熔覆技术的轧辊再制造研究[D].秦皇岛: 燕山大学, 2015. WANG Sanxing.Research on remanufacturing of roll based on laser cladding technology[D].Qinhuangdao: Yanshan University, 2015. [3] HU Z, LI Y, LU B, et al.Effect of WC content on microstructure and properties of high-speed laser cladding Ni-based coating[J].Optics & Laser Technology, 2022, 155: 108449. [4] 钟斌, 王攀, 李飞, 等. 感应熔覆技术研究现状及发展[J].精密成形工程, 2023, 15(8): 191-203. ZHONG Bin, WANG Pan, LI Fei, et al.Current situation and development of induction cladding technology[J].Journal of Netshape Forming Engineering, 2023, 15(8): 191-203. [5] PADMANABHAM G, RAVI B.Laser materials processing for industrial applications[J].Proceedings of the National Academy of Sciences, India Section A: Physical Sciences, 2018, 88: 359-374. [6] ZHU L, XUE P, LAN Q, et al.Recent research and development status of laser cladding: a review[J].Optics & Laser Technology, 2021, 138: 106915. [7] 张艺, 马志凯, 孙铂, 等. 激光熔覆材料的研究现状及发展[J].热加工工艺, 2015, 44(14): 40-44. ZHANG Yi, MA Zhikai, SUN Bo, et al.Present status and development of material for laser cladding[J].Hot Working Technology, 2015, 44(14): 40-44. [8] 孙士雷, 赵杰, 袁玮骏, 等. GH4169 镍基高温合金表面加工硬化研究[J].工具技术, 2016, 50(10): 24-27. SUN Shilei, ZHAO Jie, YUAN Weijun, et al.Study on surface hardening in high speed milling super alloy GH4169[J].Tool Engineering, 2016, 50(10): 24-27. [9] 迟静, 王淑峰, 李敏, 等. WC与TiC复合增强镍基涂层的组织和性能[J].中国表面工程, 2021, 34(1): 85-96. CHI Jing, WANG Shufeng, LI Min, et al.Microstructure and properties of WC and TiC composite reinforcement Ni-based coatings[J].China Surface Engineering, 2021, 34(1): 85-96. [10] MAS-GUINDAL M J, CONTRERAS L, TURRILLAS X, et al. Self-propagating high-temperature synthesis of TiC-WC composite materials[J].Journal of Alloys Compounds, 2006, 419(1/2): 227-233. [11] TANG B H, TAN Y F, XU T, et al.Effects of TiB2 particles content on microstructure, mechanical properties and tribological properties of Ni-based composite coatings reinforced with TiB2 particles by laser cladding[J].Coatings, 2020, 10(9): 813. [12] 袁涛, 蔡养川, 罗震, 等. Al2O3陶瓷颗粒对镍基合金涂层耐磨性能的影响[J].上海交通大学学报, 2016, 50(10): 1635-1639. YUAN Tao, CAI Yangchuan, LUO Zhen, et al.Effect of Al2O3 composite ceramic reinforcement on wear behavior of laser cladding Ni-based alloys coatings[J].Journal of Shanghai Jiaotong University,2016, 50(10): 1635-1639. [13] HUEBNER J, RUTKOWSKI P, KATA D, et al.Microstructural and mechanical study of Inconel 625-tungsten carbide composite coatings obtained by powder laser cladding[J].Archives of Metallurgy and Materials, 2017, 62(2): 529-536. [14] 范福杰. 激光熔覆718高温合金涂层的研究[D].兰州: 兰州理工大学, 2018. FAN Fujie.Research on laser cladding coating of 718 superalloy[D].Lanzhou: Lanzhou University of Technology, 2018. [15] SUN X, REN X H, QIANG W J, et al.Microstructure and properties of Inconel 718 matrix composite coatings reinforced with submicron TiC particles prepared by laser cladding[J].Applied Surface Science, 2023, 637: 157920. [16] SUI S, TAN H, CHEN J, et al.The influence of Laves phases on the room temperature tensile properties of Inconel 718 fabricated by powder feeding laser additive manufacturing[J].Acta Materialia, 2019, 164: 413-427. [17] LIU F C, LYU F Y, LIU F G, et al.Laves phase control of inconel 718 superalloy fabricated by laser direct energy deposition via δ aging and solution treatment[J].Journal of Materials Research and Technology, 2020, 9(5): 9753-9765. [18] KUMAR V P, JEBARAJ A V.Influence of double aging heat treatment on phase transformation and dimensional accuracy of Inconel 718 alloy made through laser-based additive manufacturing[J].Transactions of the Indian Institute of Metals, 2021, 74(12): 3103-3117. [19] 石晨晓, 刘元富, 李勇, 等. 等离子熔化沉积TiC增强Inconel 718基原位自生复合材料显微组织及高温耐磨性[J].稀有金属材料与工程, 2019, 48(5): 1497-1504. SHI Chenxiao, LIU Yuanfu, LI Yong, et al.Microstructure and high temperature wear resistance of TiC/Inconel 718 composites in-situ synthesized by plasma melting deposition technique[J].Rare Metal Materials and Engineering, 2019, 48(5): 1497-1504. [20] MUVVALA G, KARMAKAR D P, NATH A K.Online assessment of TiC decomposition in laser cladding of metal matrix composite coating[J].Materials Design, 2017, 121: 310-320. [21] ZHANG J D, MENG G R, ZHU L D, et al.Formation mechanism and mechanical properties of TiC reinforced Inconel 718 composite coatings by laser cladding on H13 steel[J].The International Journal of Advanced Manufacturing Technology, 2022, 121(5/6): 3597-3611. [22] ZHANG Z H, WANG X, ZHANG Q Q, et al.Fabrication of Fe-based composite coatings reinforced by TiC particles and its microstructure and wear resistance of 40Cr gear steel by low energy pulsed laser cladding[J].Optics & Laser Technology, 2019, 119: 105622. [23] LEI Y W, SUN R L, TANG Y, et al.Numerical simulation of temperature distribution and TiC growth kinetics for high power laser clad TiC/NiCrBSiC composite coatings[J].Optics & Laser Technology, 2012, 44(4): 1141-1147. [24] ZHANG J F, ANDRÄ H, ZHANG X X, et al.An enhanced finite element model considering multi strengthening and damage mechanisms in particle reinforced metal matrix composites[J].Composite Structures, 2019, 226: 111281. [25] SAHOO B P, DAS D, CHAUBEY A K.Strengthening mechanisms and modelling of mechanical properties of submicron-TiB2 particulate reinforced Al 7075 metal matrix composites[J].Materials Science and Engineering A, 2021, 825: 141873. [26] CAI Y C, ZHU L S, CUI Y, et al.Fracture and wear mechanisms of FeMnCrNiCo + x(TiC) composite high- entropy alloy cladding layers[J].Applied Surface Science, 2021, 543: 148794. [27] GAO Z M, NIU Z M, GAO Z T, et al.Microstructure and wear behavior of in-situ synthesized TiC-reinforced CoCrFeNi high entropy alloy prepared by laser cladding[J].Applied Surface Science, 2024, 670: 160720. [28] LI X F, FENG Y H, LIU B, et al.Influence of NbC particles on microstructure and mechanical properties of AlCoCrFeNi high-entropy alloy coatings prepared by laser cladding[J].Journal of Alloys Compounds, 2019, 788: 485-494.
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