Materials Performance

SEP 2018

Materials Performance is the world's most widely circulated magazine dedicated to corrosion prevention and control. MP provides information about the latest corrosion control technologies and practical applications for every industry and environment.

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33 MATERIALS PERFORMANCE: VOL. 57, NO. 9 SEPTEMBER 2018 2 H. Singh, et al., "Use of Plasma Spray Tech- nology for Deposition of High Temperature Oxidation/Corrosion Resistant Coatings," Mates. Corros. 58 (2007): pp. 92-102. 3 S. Lu, O. Kwon, "Microstructure and Bonding Strength of WC Reinforced Ni-Base Alloy Brazed Composite Coating," Surface and Coatings Technology 153 (2002): pp. 40-48. 4 K. Van Acker, et al., "Inf luence of Tungsten Carbide Particle Size and Distribution on the Wear Resistance of Laser Clad WC/Ni Coat- ings," Wear 258 (2005): pp. 194-202. 5 N. Espallargas, et al., "Cr 3 C 2 -NiCr and WC-Ni Thermal Spray Coatings as Alternatives to Hard Chromium for Erosion-Corrosion Re- sistance," Surface and Coating Technolog y 202 (2008): pp. 1,405-1,417. 6 S.P. Lu, O.Y. Kwon, Y. Guo, "Wear Behavior of Brazed WC/NiCrBSi(Co) Composite Coat- ings," Wear 254 (2003): pp. 421-428. 7 G.B. Stachowiak, G.W. Stachowiak, " Tribo- logical Characteristics of WC-Based Clad- dings Using a Ball-Cratering Method," Int. J. Refractor y Metals and Hard Materials 28 (2010): pp. 95-105. 8 L.X. Gao, T. Liu, D.Q. Zhang, "Preparation of NiCrBSi-WC Brazed Coating and Its Micro- structure Characteristics," Surface Interface Analysis 45 (2013): pp. 767-772. 9 H. Klaasen, et al., "Reliability of Dual Com- pounds 'Carbide Composite+Steel' Produced by Diffusion Welding," Int. J. Refractory Met- als and Hard Materials 28 (2010): pp. 580-586. 10 E.J. Wentzel, C. Allen, " The Erosion-Corro- sion Resistance of Tungsten-Carbide Hard Metals," Int. J. Refractory Metals and Hard Materials 15 (1997): pp. 81-87. 11 E.J. Wentzel, C. Allen, "Erosion-Corrosion Resistance of Tungsten Carbide Hard Metals with Different Binder Compositions," Wear 181-183 (1995): pp. 63-69. 12 M. Reyes, A. Neville, "Degradation Mecha- nisms of Co-Based Alloy and WC Metal- Matrix Composites for Drilling Tools Off- shore," Wear 255 (2003): pp. 1,143-1,156. 13 A. Neville, et al., "Erosion-Corrosion Behav- iour of WC-Based MMCs in Liquid-Solid Slurries," Wear 259 (2005): pp. 181-195. 14 K.R. Sriraman, et al., "Corrosion Behaviour of Electrodeposited Nanocrystalline Ni–W and Ni–Fe–W Alloys," Mater. Sci. Eng. A 460-461 (2007): pp. 39-45. 15 J.H. Chang, et al., "Corrosion Behaviour of Vacuum Induction-Melted Ni-Based Alloy," Corros. Sci. 52 (2010): pp. 2,323-2,330. FIGURE 5 The weight loss of specimens after tests. HYUNG GOUN JOO is with the School of Mechanical Engineering, Yonsei University, Seoul, South Korea. KANG YONG LEE is with the State Key Laboratory of Structural Analysis for Industrial Equipment, Department of Engineering Mechanics, Dalian University of Technology, Liaoning, People's Republic of China. GUO MING LUO is with the Department of Environmental Engineering, Shanghai University of Electric Power, Shanghai, People's Republic of China. DA QUAN ZHANG is with the Department of Environmental Engineering, Shanghai University of Electric Power, Shanghai, People's Republic of China. Development of WC-Ni Cermet Brazing Process

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