Manufacturing Technology 2022, 22(1):26-33 | DOI: 10.21062/mft.2022.013
Nanoindentation Analysis of Inconel 625 Alloy Weld Overlay on 16Mo3 Steel
- Faculty of Special Technology, Alexander Dubček University of Trenčín, Ku Kyselke 469, 911 06, Trenčín, Slovakia
This article deals with nanoindentation analysis of welded overlay layer of Inconel 625 alloy on 16Mo3 steel and their interface (transition zone). The microstructure of weld metal is analyzed, as well as the weld-on steel and subsequently nanoindentation properties (nanohardnes, reduced modulus of elastic-ity) of selected structural components. The weld of Inconel 625 alloy is realized on a tube made of 16Mo3 steel, which is bent by the so-called critical bending (d≤0,7D). The article also deals with the change of investigated properties of the weld after that bending. The samples prepared from the areas with highest compressive and tensile load after the tube bending on outer, respectively inner bend arc were used for the research. Nanoindentation analysis was performed with using a Hysitron Triboin-denter TI950 and its evaluation software Triboscan.
Keywords: nanoindentation, weld overlay, Inconel 625 alloy, 16Mo3 steel, microstructure
Grants and funding:
This publication was created in the frame of the project: Advancement and support of R&D for “Centre for diagnostics and quality testing of materials“ in the domains of the RIS3 SK specialization, ITMS2014+:313011W442, based on the Operational Programme Integrated Infrastructure and funded from the European Regional Development Fund.
Received: November 1, 2021; Revised: February 8, 2022; Accepted: February 11, 2022; Prepublished online: February 11, 2022; Published: February 26, 2022 Show citation
References
- KUREK, A., (2020).: Using fatigue characteristics to analyse test results for 16Mo3 Steel under tension-compression and oscillatory bending conditions. Opole, Poľsko: Faculty of Mechanical Engineering, Opole University of Technology, pp. 12.
Go to original source...
- HE, X., CHEN, J., TIAN, W., JIN, W., (2018).: Low Cycle Fatigue Behavior of Steam Generator Tubes under AxialLoading. Materials.
Go to original source...
- Available on: http://www.techmagazin.cz/2138
- Available on: https://www.basedosteel.com/en/materials/material/15415.html
- S. Rajendra Prasad, Dr. K.Ravindranath, Dr.M.L.S. Devakumar: Experimental Study and Optimization in Modified Air Abrasive Jet Machining on Nickel-233 Alloy Using MCDM Techniques, Manufacturing Technology 2019, 19(6):1010-1019 | DOI: 10.21062/ujep/411.2019/a/1213-2489/MT/19/6/1010
Go to original source...
- KEJHA, R., (2017).: Výroba, použití a vlastnosti niklových slitin: Bakalárska práca. Brno : VUT, 2017. pp. 42, available on: https://www.vutbr.cz/www_base/zav_prace_soubor_verejne.php?file_id=149955
- Nickel alloys, (2017).: Special Metals & PCC company. Available on: http://www.specialmetalswiggin.co.uk/products/by-alloy
- Nickel & High Temp Alloys, (2017).: Continental Steel & Tube Company. Fort Lauderdale, FL, 33303: Continental Steel & Tube Company, 2017. Available on: http://continentalsteel.com/nickel-alloys/
- KASSNER, M.E., et al., (2021).: Low Cycle Fatigue Behavior of Steam Generator Tubes under AxialLoading. Materials, pp. 14.
- AZO Materials, (2017).: London: AZO Materials, 2017. Available on: http://www.azom.com/
- FLOREEN, S., FUCHS, G.E., YANG, W.J., (1994).: The metallurgy of alloy IN625, in: E.A. Loria (Ed.), Superalloys 718, IN625, 706 and Various Derivatives, TMS, Warrendale, pp. 13-37.
Go to original source...
- HAN, P., (2017).: Additive design and manufacturing of jet engine parts, Engineering 3 (2017), pp. 648-652.
Go to original source...
- Kusmierczak S., Peslova F., Naprstkova N.: Influence of Heat Treatment Regime on Corrosion Resistance of Clad Aluminium Alloy, Manufacturing Technology 2019, 19(4):624-631 | DOI: 10.21062/ujep/345.2019/a/1213-2489/MT/19/4/624
Go to original source...
- NEMECEK, S., FIDLER, L., FI_SEROV_A, (2014).: Corrosionresistance of laser clads of Inconel625 and Metco 41C, Phys. Procedia 56(2014) 294e300, https://doi.org/10.1016/j.phpro.2014.08.174.
Go to original source...
- ABIOYE, T.E., FARAYIBI, P.K, CLARE, A.T., (2017).: A comparative study of Inconel 625 lasercladding by wire and powderfeedstock, Mater. Manuf. Process. 32 (2017)1653e1659, https://doi.org/10.1080/10426914.2017.1317787.
Go to original source...
- SOLECKA, M., KOPIA, A., RADISZEWSKA, A., RUTKOWSKI, B., (2018).:Microstructure, microsegregation and nanohardness of CMT cladlayers of Ni-base alloy on 16Mo3 steel, Journal of Alloys and Compounds, pp. 86 - 95. Vol. 751
Go to original source...
- ZHANG, Y., LI, Z., NIE, P., WU, Y., (2013).: Carbide and nitrideprecipitationduring lasercladding of Inconel 718 alloycoatings, Optic Laser. Technol. 52 (2013) 30e36,https://doi.org//10.1016/j.optlastec.2013.03.023.
Go to original source...
- EN 10028-2, FlatProducts Made of SteelsforPressurePurposes - Part 2: Nonalloyand alloySteelswithSpecifiedElevatedTemperatureProperties, vol. 3,2000.
- SpecialMetalsCorporation, Corporationinformationmaterials, http://www.specialmetals.com/assets/smc/documents/alloys/inconel/inconel-alloy-625.
- R.M. Sharp, M.C. Flemings, Soluteredistribution in cellularsolidification,Metall. Trans. 5 (1974) pp. 823-830, https://doi.org/10.1007/BF02643134.
Go to original source...
- DURST, H.V.K, GOKEN, M.,(2004).: Finite element study for nanoindentation measurementson two-phasematerials, J. Mater. Res. 19 (2004) 85e93, https://doi.org//10.1557/jmr.2004.19.1.85.
Go to original source...
- ROZMUS-GÓRNIKOWSKA, M., BLICHARSKI, M., KUSINSKI, J., (2014).: Influence of weldoverlyingmethods on microstructure and chemicalcomposition of Inconel 625 boilerpipecoatings. Metalic Materials, pp. 141-147, Vol. 521.
Go to original source...
- ZHANG, Y.C., YU, X.T., JIANG, W., TU, S.T., ZHANG, X.C.,(2020).: Elasticmodulus and hardnesscharacteriziationformicroregion of Inconel 625/BNi-2 vacuumbrazedjoint by hightemperature nanoindentation . Vacuum, Vol. 181., Article No.109582
Go to original source...
- ARAFIN, M., MEDJAR, M., TURNER, D., BOCHER, P.,(2007).: Transientliquidphasebonding of Inconel 718 and Inconel 625 with BNi-2: modeling and experimentalinvestigations, Mater. Sci. Eng. A 447 (2007) pp. 125-133.
Go to original source...
- WHEELER, J.M., MICHLER, J.,(2013).: Indentermaterialsforhightemperature nanoindentation, Rev. Sci. Instrum. Vol. 84 (2013) 101301.
Go to original source...
- ZHANG, Y.C., JIANG, W., TU, S.T., WEN, J.F., WOO,W.,(2014).: Usingshort-timecreeprelaxationeffect to decreasetheresidualstress in thebondedcompliantseal of planarsolid oxide fuelcell-A finite element simulation, J. PowerSources, pp. 108-115, Vol. 255.
Go to original source...
- DONG, H., XIA, Y., XU, X., NAZ, G.J., HAO, X., LI, P., ZHOU, J., DONG,C.,(2020).: Performance of GH4169 brazedjointusing a new designednickel-basedfiller metal viacluster-plus-glue-atom model, J. Mater. Sci. Technol. pp.89-98, Vol. 39.
Go to original source...
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