Tytuł artykułu
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The selection and use of high strength alloys with high wear resistance (at room and high temperature) are mandatory in aerospace, nuclear, automotive, petroleum, space, furnace, and chemical industries in which Incoloy 800H superalloy is the right choice. However, this alloy is under the class of ‘difficult to cut material’ caused by their significant properties. In the present work, the heat treatment on Incoloy 800H superalloy was carried out at 1075 °C for 60 min and then the samples were cooled in the air (air cooling, AC) and furnace (furnace cooling, FC) to modify the microstructure. The mechanical and tribological behavior were examined on the heat-treated samples at room temperature to eliminate the effect of dynamic strain aging (DSA) which usually occurs at elevated temperatures in superalloys. Hardness measurement and compression tests were carried out to examine the variation of strength. Further, the dry sliding wear tests at room temperature were performed to analyze wear resistance of heat-treated specimens and compared with the as-received (AR) sample. Besides, the wear mechanism and surface roughness of worn-out specimens were analyzed. The result indicates that the air-cooled (AC) sample possessed high hardness, high compression strength, and more resistance to wear as compared to AR and FC samples. The identified wear mechanisms in AR and FC samples were abrasive, deep grooves, plastic deformation while the AC specimen exhibits mild grooves and lesser debris particles. Fractography analysis was also performed to find the nature or mode of fractures on the samples. ANOVA result indicates that the sample hardness after heat treatment has the most influencing parameter followed by the applied load on the wear rate and the coefficient of friction (CoF). The measured average roughness of the AC specimen has shown lesser value than the AR and FC specimens due to refined grain structure.
Czasopismo
Rocznik
Tom
Strony
171--185
Opis fizyczny
Bibliogr. 36 poz., rys., tab., wykr.
Twórcy
autor
- Department of Mechanical Engineering, Surya Engineering College, Erode 638107, Tamilnadu, India
autor
- Additive Manufacturing Center for Mass Customization Production, National Taipei University of Technology, Taipei 10608, Taiwan ROC
autor
- Department of Mechanical Engineering, St. John College of Engineering and Management, Palghar, Maharashtra 401404, India
autor
- Department of Mechanical Engineering, College of Engineering, Qassim University, Buraidah 51452, Saudi Arabia
Bibliografia
- [1] Srirangan ArunKumar, Paulraj S. Multi-response optimization of process parameters for TIG welding of Incoloy 800HT by Taguchi grey relational analysis. Eng Sci Technol Int J. 2016;19:811–7.
- [2] Ren W, Swindeman R. Status of Alloy 800 H in considerations for the Gen IV nuclear energy systems. J Pressure Vessel Technol. 2014;136(5):054001–0540012.
- [3] Anand K, Barik BK, Tamilmannan K, Sathiya P. Artificial neural network modeling studies to predict the friction welding process parameters of Incoloy 800H joints. Eng Sci Technol Int J. 2015;18:394–407.
- [4] Guo W, Dong S, Guo W, Francis JA, Li L. Microstructure and mechanical characteristics of a laser welded joint in SA508 nuclear pressure vessel steel. Mater Sci Eng A. 2015;625:65–80.
- [5] Li MH, Sun XF, Li JG, Zhang ZY, Jin T, Guan HR, Hu ZQ. Oxidation behaviour of a single-crystal Ni-base superalloy in air-I: at 800 and 900uC. Oxid Met. 2003;59:591–605.
- [6] Palanisamy A, Selvaraj T. Optimisation of turning parameters on heat treated INCOLOY 800H using cryogenically treated CVD tool with grey-based entropy method. Int J Mach Machin Mater . 2018;20(5):401–24.
- [7] Günen A. Properties and high temperature dry sliding wear behavior of boronized Inconel 718. Metallur Mater Trans A. 2020;51(2):927–39.
- [8] Jeyaprakash N, Yang CH, Ramkumar KR. Microstructure and wear resistance of laser cladded Inconel 625 and Colmonoy 6 depositions on Inconel 625 substrate. Appl Phys . 2020;126:1–11.
- [9] Palanisamy A, Selvaraj T, Sivasankaran S. Heat treatment effect on CNC turning of Incoloy 800H superalloy. Mater Manuf Processes. 2018;33(14):1594–601.
- [10] Amini K, Hoda MR, Shafyei A. Investigation of the effect of heat treatment on the mechanical properties and microstructure of DIN 1.4057 martensitic stainless steel. Metal Sci Heat Treatm. 2014;55:499–503.
- [11] Jeshvaghani RA, Jaberzadeh M, Zohdi H, Shamanian M. Microstructural study and wear behavior of ductile iron surface alloyed by Inconel 617. Mater Design. 2014;54:491–7.
- [12] Thirugnanasambantham KG, Natarajan S. Mechanistic studies on degradation in sliding wear behavior of IN718 and Hastelloy X superalloys at 500° C. Tribol Intl. 2016;101:324–30.
- [13] Rahman MS, Ding J, Beheshti A, Zhang X, Polycarpou AA. Elevated temperature tribology of Ni alloys under helium environment for nuclear reactor applications. Tribolol Int. 2018;123:372–84.
- [14] Cao Yu. Xinjun Shen, Hongshuang Di, Guangjie Huang, Texture and microstructure evolution of Incoloy 800H superal-loy during hot rolling and solution treatment. J Alloys Comp. 2017;698:304–16.
- [15] Dunder M, Vuherer T, Samardžić I, Marić D. Analysis of heat-affected zone microstructures of steel P92 after welding and after post-weld heat treatment. Int J Adv Manufact Technol. 2019;102:3801–12.
- [16] Liu H, Liu J, Lic Xi, Chend P, Yang H, Hao J. Effect of heat treatment on phase stability and wear behavior of laser clad AlCoCrFeNiTi0.8high-entropy alloy coatings. Surface Coatings Technol. 2020;392:125758.
- [17] M.G. Yin, Z. B. Cai, Z, Y. Q. Yu, Y, M. H. Zhu, Impact-sliding wear behaviors of influenced by different impact kinetic energy and sliding velocity. Tribol Int 143 (2020) 106057.
- [18] Poulia A, Georgatis E, Lekatou A, Karantzalis A. Dry-Sliding Wear Response of MoTaWNbV High Entropy Alloy. Adv Eng Mater. 2017;19(2):1600535.
- [19] Gao W, Lian Y, Xie G, Huang J, Zhang L, Ma M, Zhang J. Study of dry sliding wear characteristics of stellite 6B versus AISI M2 steel at various sliding velocities. Wear. 2018;402:169–78.
- [20] Beese AM, Wang Z, Stoica AD, Ma D. Absence of dynamic strain aging in an additively manufactured nickel-base superalloy. Nat Commun. 2018;9(1):1–8.
- [21] M. Hörnqvist, C. Joseph, C. Persson, J. Weidow, and H. Lai, “Dynamic strain aging in Haynes 282 superalloy,” in MATEC Web of Conferences, 2014, vol. 14, p. 16002.
- [22] Committee PV, Metals S. Incoloy Alloy 800H. Alloy Dig. 1978;27(1):1–16. https://doi.org/10.31399/asm.ad.ss0347.
- [23] Cao Y, et al. Effect of dynamic strain aging and precipitation on the hot deformation behavior of 253MA heat-resistant alloy. J Mater Sci. 2019;54(2):1716–27.
- [24] Wang XG, Liu JL, Jin T, et al. Tensile behaviors and deformation mechanisms of a nickel-base single crystal superalloy at different temperatures. Mat Sci Eng A. 2014;598:154–61.
- [25] Osada T, Gu YF, Nagashima N, et al. Optimum microstructure combination for maximizing tensile strength in a poly-crystalline superalloy with a two-phase structure. Acta Mater. 2013;61:1820–9.
- [26] Sheng LY, Yang F, Guo JT, et al. Anomalous yield and intermediate temperature brittleness behaviors of directionally solidified nickel-based superalloy. T Nonferr Metal Soc. 2014;24:673–81.
- [27] Wei CN, Bor HY, Chang L. The effects of carbon content on the microstructure and elevated temperature tensile strength of a nickel-base superalloy. Mat Sci Eng A. 2010;527:3741–7.
- [28] Mishra SB, Chandra K, Prakash S. Dry sliding wear behaviour of nickel-, iron-and cobalt-based superalloys. Tribol Surfaces Interfaces. 2013;7(3):122–8.
- [29] Panagopoulos CN, Giannakopoulos KI, Saltas V. Wear behavior of nickel superalloy, CMSX-186. Mater Lett. 2003;57(29):4611–6.
- [30] E. Hamzah, M. Mudang, M.A. Khattak, Effect of variation in microstructure on high temperature creep of Fe-Ni-Cr superalloy. The world congress on Advances in Structural Engineering and Mechanics (ASEM13) 2457–2467.
- [31] Rashid MWA, Gakim M. Zulkifli Mohd Rosli, Mohd Asyadi Azam, Formation of Cr23C6 during the Sensitization of AISI 304. Int J Electrochem Sci. 2012;7:9465–77.
- [32] Thakare AS, Butee SP, Dhanorkar R, K.R. . Kambale, Phase transformations and mechanical properties of thermomechanically processed 34CrMo4 steel. Heliyon. 2019;5:e01610.
- [33] Yıldız G, Gursel A, Akca E. Effects of Cooling Rate on Strength and Microstructure of Powder Metallurgy Superalloys. Period Eng Natural Sci. 2017;5(3):251–5.
- [34] Ding H-H, He G-a, Wang X, Liu F, Huang L, Jiang L. Effect of cooling rate on microstructure and tensile properties of powder metallurgy Ni-based superalloy. Trans Nonferrous Met Soc China. 2018;28:451–60.
- [35] N. Jeyaprakash, Che-Hua Yang, Muthukannan Duraiselvam, S. Sivasankaran, Comparative study of laser melting and pre-placed Ni–20% Cr alloying over nodular iron surface. Arch Civil Mechan Eng (2020) 20:20, https://doi.org/10.1007/s43452-020-00030.
- [36] Chelladurai SJS, Arthanari R, Nithyanandam N, Rajendran K, Radhakrishnan KK. Investigation of mechanical properties and dry sliding wear behaviour of squeeze cast LM6 aluminium alloy reinforced with copper coated short steel fibers. Trans Indian Inst Met. 2018;71(4):813–22.
Uwagi
PL
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-489d7e06-beff-4745-81a7-617ff0bb3ae1