nach oben

The International Journal of Advanced Manufacturing Technology

Erschienen in:

09.02.2022 | ORIGINAL ARTICLE

Microstructure evolution and mechanical property of W/Ta bimetal foil produced by a high wave impedance explosive welding technology

verfasst von: Qichao Tian, Ming Yang, Junfeng Xu, Honghao Ma, Yang Zhao, Zhaowu Shen, Zhiqiang Ren, Heng Zhou, Jie Tian

Erschienen in: The International Journal of Advanced Manufacturing Technology | Ausgabe 1-2/2022

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

Welding of dissimilar metal foils is challenging, especially between high melting temperature and brittle metals. In this study, the direct welding of tungsten foil and tantalum foil was achieved using metal protection plates in an explosive welded configuration. The microstructure, chemical composition, and hardness distribution in the corresponding microscopic regions of the W/Ta interface were characterized by electron backscattered diffraction (EBSD), energy-dispersive spectroscopy (EDS), and nano-indentation. The W/Ta interface formed a wavy bonding interface, and a large number of refined grains smaller than 1 µm were created at the interface. Different melting zones were investigated employed EBSD and nano-indentation to understand the vortex structure’s evolution mechanism. It was found that the formation of holes in the melting zone was mainly due to the cooling shrinkage after intense jet agitation. Besides, the more intense jet promotes recovery and recrystallization. However, the stronger intrusion of the jet causes higher nano-hardness in the melt zone, which is attributed to the effect of the jet on the heterogeneous microstructure. Mechanical tests show that the tensile strength of W/Ta bimetal foil exceeds 850 MPa, and there is no crack propagation on the surface of the metal foil. The analysis of welding parameters and material properties revealed that increasing the material temperature during the explosive welding process and providing high-impedance material confinement are the main ways to solve the problem of explosive welding of brittle materials.

Vorheriger Artikel Direct metal laser sintering of Ti-6Al-4V parts with reused powder

Nächster Artikel Circle detection with model fitting in polar coordinates for glass bottle mouth localization

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Mashalkar A, Nandedkar V (2019) Effect of crystallographic texture on the forming limit in microforming of brass. Manuf Rev 6 (2019)

Razali AR, Qin Y (2012) A review on micro-manufacturing, micro-forming and their key issues. Malaysian Technical Universities Conference on Engineering & Technology (Mucet 2012) 53(2013):665–672

Zheng JY, Shi SQ, Fu MW (2020) Progressive microforming of pin-shaped plunger parts and the grain size effect on its forming quality. Materials & Design 187

Rieth M, Boutard JL, Dudarev SL, Ahlgren T, Antusch S, Baluc N, Barthe MF, Becquart CS, Ciupinski L, Correia JB, Domain C, Fikar J, Fortuna E, Fu CC, Gaganidze E, Galan TL, Garcia-Rosales C, Gludovatz B, Greuner H, Heinola K, Holstein N, Juslin N, Koch F, Krauss W, Kurzydlowski KJ, Linke J, Linsmeier C, Luzginova N, Maier H, Martinez MS, Missiaen JM, Muhammed M, Munoz A, Muzyk M, Nordlund K, Nguyen-Manh D, Norajitra P, Opschoor J, Pintsuk G, Pippan R, Ritz G, Romaner L, Rupp D, Schaublin R, Schlosser J, Uytdenhouwen I, van der Laan JG, Veleva L, Ventelon L, Wahlberg S, Willaime F, Wurster S, Yar MA (2011) Review on the EFDA programme on tungsten materials technology and science. J Nucl Mater 417(1–3):463–467CrossRef

Yuan Y, Wang T, Kreter A, Reinhart M, Terra A, Moeller S, Cheng L, Linsmeier C, Lu GH (2021) Influence of neon seeding on the deuterium retention and surface modification of ITER-like forged tungsten. Nucl Fusion 61(1)

Yin W, Jia XJ, Yu QZ, Liang TJ (2016) First-principles study of the interaction between helium and the defects in tantalum. J Nucl Mater 480:202–206CrossRef

You YW, Hou J, Sun JJ, Kong XS, Wu XB, Liu CS, Chen JL (2018) The behaviors of helium atoms in tantalum, rhenium and osmium. J Nucl Mater 499:1–8CrossRef

Shao Y, Yu KY, Jiang DQ, Yu C, Ren Y, Jiang XH, Guo FM, Cui LS (2016) High strength W/TiNi micro-laminated composite with transformation-mediated ductility. Mater Des 106:415–419CrossRef

Zhang Y, Xu GY, Wang Y, Zhang C, Feng SJ, Suo JP (2017) Mechanical properties study of W/TiN/Ta system multilayers. J Alloy Compd 725:283–290CrossRef

10.

Chen C, Qian SF, Liu R, Wang S, Liao B, Zhong ZH, Cao LF, Coenen JW, Wu YC (2019) The microstructure and tensile properties of W/Ti multilayer composites prepared by spark plasma sintering. J Alloy Compd 780:116–130CrossRef

11.

Chen C, Xu J, Liu R, Xia X, Wang S, Zhang Z, Zhong ZH, Wu YC (2019) The effect of sintering temperature on the tensile properties and fracture behaviors of W/Ta multilayer composites. Mat Sci Eng a-Struct 768

12.

Liu DG, Zheng L, Luo LM, Zan X, Song JP, Xu Q, Zhu XY, Wu YC (2018) An overview of oxidation-resistant tungsten alloys for nuclear fusion. J Alloy Compd 765:299–312CrossRef

13.

Guillen DP, Pagan DC, Getto EM, Wharry JP (2018) In situ tensile study of PM-HIP and wrought 316 L stainless steel and Inconel 625 alloys with high energy diffraction microscopy. Mat Sci Eng a-Struct 738:380–388CrossRef

14.

Bassini E, Marchese G, Cattano G, Lombardi M, Biamino S, Ugues D, Vallillo G, Picque B (2017) Influence of solutioning on microstructure and hardness of hot isostatically pressed Astroloy. J Alloy Compd 723:1082–1090CrossRef

15.

Baccino R, Moret F, Pellerin F, Guichard D, Raisson G (2000) High performance and high complexity net shape parts for gas turbines: the ISOPREC (R) powder metallurgy process. Mater Des 21(4):345–350CrossRef

16.

Thebaud L, Villechaise P, Crozet C, Devaux A, Bechet D, Franchet JM, Rouffie AL, Mills M, Cormier J (2018) Is there an optimal grain size for creep resistance in Ni-based disk superalloys? Mat Sci Eng a-Struct 716:274–283CrossRef

17.

Bina MH, Dehghani F, Salimi M (2013) Effect of heat treatment on bonding interface in explosive welded copper/stainless steel. Mater Des 45:504–509CrossRef

18.

Parchuri P, Kotegawa S, Yamamoto H, Ito K, Mori A, Hokamoto K (2019) Benefits of intermediate-layer formation at the interface of Nb/Cu and Ta/Cu explosive clads. Mater Des 166

19.

Satyanarayan A, Mori M, Nishi K (2019) Hokamoto, Underwater shock wave weldability window for Sn-Cu plates. J Mater Process Technol 267:152–158CrossRef

20.

Liang HL, Luo N, Chen YL, Dong JW, Zhai C, Yang W, Li XJ (2020) Experimental and numerical simulation study of Fe-based amorphous foil/Al-1060 composites fabricated by an underwater explosive welding method. Compos Interface

21.

Wang CJ, Wang HY, Chen G, Zhang P (2019) Anisotropy in mechanical properties during microscale uniaxial tensile deformation of Cu/Ni clad foils. Mat Sci Eng a-Struct 750:14–19CrossRef

22.

Zhou BB, Ye C, Zhang BJ, Li J, Chang L, Qiu WG, Zhou CY (2020) Effect of heat treatment on the mechanical properties and microstructures of zirconium-titanium-steel composite plate. Rare Metal Mat Eng 49(1):59–67

23.

Ning J, Zhang LJ, Xie MX, Yang HX, Yin XQ, Zhang JX (2017) Microstructure and property inhomogeneity investigations of bonded Zr/Ti/steel trimetallic sheet fabricated by explosive welding. J Alloy Compd 698:835–851CrossRef

24.

Zhou Q, Feng JR, Chen PW (2017) Numerical and experimental studies on the explosive welding of tungsten foil to copper. Materials 10(9)

25.

Manikandan P, Lee JO, Mizumachi K, Mori A, Raghukandan K, Hokamoto K (2011) Underwater explosive welding of thin tungsten foils and copper. J Nucl Mater 418(1–3):281–285CrossRef

26.

Sun CX, Wang SM, Guo WH, Shen WP, Ge CC (2014) Bonding interface of W-CuCrZr explosively welded composite plates for plasma facing components. J Mater Sci Technol 30(12):1230–1234CrossRef

27.

Bataev IA, Lazurenko DV, Tanaka S, Hokamoto K, Bataev AA, Guo Y, Jorge AM (2017) High cooling rates and metastable phases at the interfaces of explosively welded materials. Acta Mater 135:277–289CrossRef

28.

Zhang TT, Wang WX, Zhang W, Wei Y, Cao XQ, Yan ZF, Zhou J (2018) Microstructure evolution and mechanical properties of an AA6061/AZ31B alloy plate fabricated by explosive welding. J Alloy Compd 735:1759–1768CrossRef

29.

Sun ZR, Shi CG, Shi H, Li F, Gao L, Wang G (2020) Comparative study of energy distribution and interface morphology in parallel and double vertical explosive welding by numerical simulations and experiments. Mater Des 195

30.

Paul H, Chulist R, Bobrowski P, Perzynski K, Madej L, Mania I, Miszczyk M, Cios G (2020) Microstructure and properties of the interfacial region in explosively welded and post-annealed titanium-copper sheets. Mater Charact 167

31.

Bataev IA, Tanaka S, Zhou Q, Lazurenko DV, Jorge Junior AM, Bataev AA, Hokamoto K, Mori A, Chen P (2019) Towards better understanding of explosive welding by combination of numerical simulation and experimental study. Mater Des 169

32.

Gladkovsky SV, Kuteneva SV, Sergeev SN (2019) Microstructure and mechanical properties of sandwich copper/steel composites produced by explosive welding. Mater Charact 154:294–303CrossRef

33.

Zhang H, Jiao KX, Zhang JL, Li JP (2018) Microstructure and mechanical properties investigations of copper-steel composite fabricated by explosive welding. Mat Sci Eng a-Struct 731:278–287CrossRef

34.

Saravanan S, Raghukandan K (2020) Effect of silicon carbide and wire-mesh reinforcements in dissimilar grade aluminium explosive clad composites. Def Technol 16(6):1160–1166CrossRef

35.

Paul H, Miszczyk MM, Chulist R, Prazmowski M, Morgiel J, Galka A, Faryna M, Brisset F (2018) Microstructure and phase constitution in the bonding zone of explosively welded tantalum and stainless steel sheets. Mater Des 153:177–189CrossRef

36.

Xia CQ, Jin ZP (2000) Interfacial reactions in an explosively-welded tantalum clad steel plate. Surf Coat Tech 130(1):29–32MathSciNetCrossRef

37.

Zhang H, Jiao KX, Zhang JL, Liu J (2019) Comparisons of the microstructures and micro-mechanical properties of copper/steel explosive-bonded wave interfaces. Mater Sci Eng, A 756:430–441CrossRef

38.

Wu DT, An Q, Matsuda K, Zhang YG, Yu BJ, Zou Y (2021) Characteristics of bypass coupling twin-wire indirect arc welding with high-speed welding mode. J Mater Process Technol 291

39.

Soifer YM, Verdyan A, Kazakevich M, Rabkin E (2002) Nanohardness of copper in the vicinity of grain boundaries. Scripta Mater 47(12):799–804CrossRef

40.

Hosseini-Toudeshky H, Anbarlooie B, Kadkhodapour J (2015) Micromechanics stress-strain behavior prediction of dual phase steel considering plasticity and grain boundaries debonding. Mater Des 68:167–176CrossRef

41.

Blazynski TZ (2012) Explosive welding, forming and compaction, Springer Science & Business Media

42.

Kennedy J (1970) Gurney energy of explosives: estimation of the velocity and impulse imparted to driven metal

43.

Cooper PW (2018) Explosives engineering. John Wiley & Sons

44.

Deribas AA, Zakharenko ID (1974) Surface effects with oblique collisions between metallic plates, combustion explosion and shock waves. 10(3):358–367

45.

Chen X, Sun W, Li XJ, Wang XH, Yan HH, Li KB (2018) Experimental and numerical studies on W-Cu functionally graded materials produced by explosive compaction-welding sintering. Fusion Eng Des 137:349–357CrossRef

46.

Hokamoto K, Manikandan P, Mori A (2010) Some trials on underwater explosive welding of thin W plate onto copper substrate, Thermec 2009. Pts 1–4(638–642):1041–1046

47.

Zhou Q, Chen PW, Ma DZ (2013) Tungsten-copper composite fabricated by hot-shock consolidation. Materials Performance, Modeling and Simulation 749:372–377

48.

Yang M, Ma HH, Shen ZW, Huang ZC, Tian QC, Tian J (2020) Dissimilar material welding of tantalum foil and Q235 steel plate using improved explosive welding technique. Mater Des 186

49.

Carvalho GHSFL, Galvao I, Mendes R, Leal RM, Loureiro A (2019) Microstructure and mechanical behaviour of aluminium-carbon steel and aluminium-stainless steel clads produced with an aluminium interlayer. Mater Charact 155

50.

Carvalho GHSFL, Mendes R, Leal RM, Galvao I, Loureiro A (2017) Effect of the flyer material on the interface phenomena in aluminium and copper explosive welds. Mater Des 122:172–183

51.

Liu YB, Li C, Hu XY, Yin CF, Liu TS (2019) Explosive welding of copper to high nitrogen austenitic stainless steel. Metals-Basel 9(3)

52.

Wang YX, Li XJ, Wang XH, Yan HH (2018) Fabrication of a thick copper-stainless steel clad plate for nuclear fusion equipment by explosive welding. Fusion Eng Des 137:91–96CrossRef

53.

Zhang TT, Wang WX, Zhou J, Yan ZF, Zhang J (2019) Interfacial characteristics and nano-mechanical properties of dissimilar 304 austenitic stainless steel/AZ31B Mg alloy welding joint. J Manuf Process 42:257–265CrossRef

54.

Chu Q, Zhang M, Li J, Yan C (2017) Experimental and numerical investigation of microstructure and mechanical behavior of titanium/steel interfaces prepared by explosive welding. Mater Sci Eng, A 689:323–331CrossRef

55.

Parchuri P, Kotegawa S, Yamamoto H, Ito K, Mori A, Hokamoto K (2019) Benefits of intermediate-layer formation at the interface of Nb/Cu and Ta/Cu explosive clads. Mater Des 166:107610

56.

Kosturek R, Wachowski M, Sniezek L, Gloc M (2019) The influence of the post-weld heat treatment on the microstructure of Inconel 625/carbon steel bimetal joint obtained by explosive welding. Metals-Basel 9(2)

57.

Prazmowski M, Rozumek D, Paul H (2017) Static and fatigue tests of bimetal Zr-steel made by explosive welding. Eng Fail Anal 75:71–81CrossRef

58.

Grady DE (2010) Structured shock waves and the fourth-power law. J Appl Phys 107(1)

59.

Grady D (1998) Scattering as a mechanism for structured shock waves in metals. J Mech Phys Solids 46(10):2017–2032MATHCrossRef

60.

Chen X, Chandra N (2004) The effect of heterogeneity on plane wave propagation through layered composites. Compos Sci Technol 64(10–11):1477–1493CrossRef

61.

Mori D, Kasada R, Konishi S, Morizono Y, Hokamoto K (2014) Underwater explosive welding of tungsten to reduced-activation ferritic steel F82H. Fusion Eng Des 89(7–8):1086–1090CrossRef

62.

Matsuoka C (2014) Kelvin-Helmholtz instability and roll-up. Scholarpedia 9(3):11821CrossRef

63.

Prummer RA (1977) Explosive cladding of thin-films. Thin Solid Films 45(1):205–210CrossRef

64.

Zhang J, Luo G, Wang Y, Xiao Y, Shen Q, Zhang L (2013) Effect of Al thin film and Ni foil interlayer on diffusion bonded Mg–Al dissimilar joints. J Alloy Compd 556:139–142CrossRef

65.

Liang HL, Luo N, Li XJ, Sun X, Shen T, Ma ZG (2019) Joining of Zr60Ti17Cu12Ni11 bulk metallic glass and aluminum 1060 by underwater explosive welding method. J Manuf Process 45:115–122CrossRef

66.

Li XJ, Chen X, Li KB, Yan HH, Wang XH (2019) Fabrication of tungsten-tin alloy powder and its explosive consolidation. Rare Metal Mat Eng 48(3):782–787

Titel: Microstructure evolution and mechanical property of W/Ta bimetal foil produced by a high wave impedance explosive welding technology
verfasst von: Qichao Tian
Ming Yang
Junfeng Xu
Honghao Ma
Yang Zhao
Zhaowu Shen
Zhiqiang Ren
Heng Zhou
Jie Tian
Publikationsdatum: 09.02.2022
Verlag: Springer London
Erschienen in: The International Journal of Advanced Manufacturing Technology / Ausgabe 1-2/2022
Print ISSN: 0268-3768
Elektronische ISSN: 1433-3015
DOI: https://doi.org/10.1007/s00170-021-08502-4

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 1-2/2022

Research on the axial elongation and springback law of thick-walled tubes in cold bending forming

Three-dimensional finite element analysis of unintended deformation of polycrystalline billet in micro-extrusion

Application of optimized lubri-cooling technique in through-feed centerless grinding process of bearing steel SAE 52100

Study on cutting performance in ultrasonic-assisted milling of titanium alloy with circular-arc milling cutters

Analysis and optimization of the properties of the grinding contact line for form-grinding modified helical gears

Effect of coupling misalignment fault on vibration response and machined surface topography in ultra-precision lathe turning

Premium Partner

Marktübersichten