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The International Journal of Advanced Manufacturing Technology

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12.05.2019 | ORIGINAL ARTICLE

Weldability of aluminium-copper in explosive welding

verfasst von: G. H. S. F. L. Carvalho, I. Galvão, R. Mendes, R. M. Leal, A. Loureiro

Erschienen in: The International Journal of Advanced Manufacturing Technology | Ausgabe 5-8/2019

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Abstract

A large number of aluminium-copper explosive welds were produced under different welding conditions to perform a broad analysis of the weldability of this combination. The influence of the explosive mixture and the relative positioning of the plates on the welding results were analysed. When the aluminium alloy is positioned as the flyer plate, continuous interfacial melting occurred under the low values of energy lost by the collision, and collision point velocity. This proved that the weldability of the aluminium-copper combination is higher when the copper is positioned as the flyer. A mismatch between the experimental results and the existing theories that define the requirements for achieving consistent welds was noticed. Especially for welds produced using the aluminium alloy as the flyer, the experiments proved to be more restrictive than the theories. These theories, despite being widely applied in dissimilar welding literature, present several limitations concerning aluminium-copper welding. New approaches considering the formation of intermetallic phases at the interface, the properties of both welded metals, and/or the difference in their properties should be developed.

Vorheriger Artikel Influences of postproduction heat treatments on the material anisotropy of nickel-aluminum bronze fabricated using wire-arc additive manufacturing process

Nächster Artikel Energy consumption optimization with geometric accuracy consideration for fused filament fabrication processes

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El-Sobky H (1983) Mechanics of explosive welding. In: Blazynski TZ (ed) Explosive Welding, Forming and Compaction. Applied Science Publishers, Essex, pp 189–217CrossRef

Mousavi AAA, Al-Hassani STS (2005) Numerical and experimental studies of the mechanism of the wavy interface formations in explosive/impact welding. J Mech Phys Solids 53:2501–2528CrossRef

Carvalho GHSFL, Galvão I, Mendes R, Leal RM, Loureiro A (2018) Influence of base material properties on copper and aluminium-copper explosive welds. Sci Technol Weld Join 23(6):501–507CrossRef

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

Loureiro A, Mendes R, Ribeiro JB, Leal RM, Galvão I (2016) Effect of explosive mixture on quality of explosive welds of copper to aluminium. Mater Des 95:256–267CrossRef

Athar MMH, Tolaminejad B (2015) Weldability window and the effect of interface morphology on the properties of Al/Cu/Al laminated composites fabricated by explosive welding. Mater Des 86:516–525CrossRef

Paul H, Litynska-Dobrzynska L, Prazmowski M (2013) Microstructure and phase constitution near the interface of explosively welded aluminum/copper plates. Metall Mater Trans A 44(8):3836–3851CrossRef

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

Fronczek DM, Chulist R, Litynska-Dobrzynska L, Kac S, Schell N, Kania Z, Szulc Z, Wojewoda-Budka J (2017) Microstructure and kinetics of intermetallic phase growth of three-layered A1050/AZ31/A1050 clads prepared by explosive welding combined with subsequent annealing. Mater Des 130:120–130CrossRef

10.

Arisova VN, Trykov YP, Slautin OV, Ponomareva IA, Kondakov AE (2015) Effect of heat treatment on mechanical properties and phase composition of magnesium-aluminum composite prepared by explosive welding. Met Sci Heat Treat 57(5–6):291–294CrossRef

11.

Zhang N, Wang W, Cao X, Wu J (2015) The effect of annealing on the interface microstructure and mechanical characteristics of AZ31B/AA6061 composite plates fabricated by explosive welding. Mater Des 65:1100–1109CrossRef

12.

Guo X, Ma Y, Jin K, Wang H, Tao J, Fan M (2017) Effect of stand-off distance on the microstructure and mechanical properties of Ni/Al/Ni laminates prepared by explosive bonding. J Mater Eng Perform 26(9):4235–4244CrossRef

13.

Bataev IA, Ogneva TS, Bataev AA, Mali VI, Esikov MA, Lazurenko DV, Guo Y, Junior AMJ (2015) Explosively welded multilayer Ni-Al composites. Mater Des 88:1082–1087CrossRef

14.

Chulist R, Fronczek DM, Szulc Z, Wojewoda-Budka J (2017) Texture transformations near the bonding zones of the three-layer Al/Ti/Al explosively welded clads. Mater Charact 129:242–246CrossRef

15.

Fan M, Yu W, Wang W, Guo X, Jin K, Miao R, Hou W, Kim N, Tao J (2017) Microstructure and mechanical properties of thin-multilayer Ti/Al laminates prepared by one-step explosive bonding. J Mater Eng Perform 26(1):277–284CrossRef

16.

Bazarnik P, Adamczyk-Cieślak B, Gałka A, Płonka B, Snieżek L, Cantoni M, Lewandowska M (2016) Mechanical and microstructural characteristics of Ti6Al4V/AA2519 and Ti6Al4V/AA1050/AA2519 laminates manufactured by explosive welding. Mater Des 111:146–157CrossRef

17.

Fronczek DM, Wojewoda-Budka J, Chulist R, Sypien A, Korneva A, Szulc Z, Schell N, Zieba P (2016) Structural properties of Ti/Al clads manufactured by explosive welding and annealing. Mater Des 91:80–89CrossRef

18.

Lazurenko DV, Bataev IA, Mali VI, Bataev AA, Maliutina IN, Lozhkin VS, Esikov MA, Jorge AMJ (2016) Explosively welded multilayer Ti-Al composites: structure and transformation during heat treatment. Mater Des 102:122–130CrossRef

19.

Carvalho GHSFL, Galvão I, Mendes R, Leal RM, Loureiro A (2018) Formation of intermetallic structures at the interface of steel-to-aluminium explosive welds. Mater Charact 142:432–442CrossRef

20.

Guo X, Wang H, Liu Z, Wang L, Ma F, Tao J (2016) Interface and performance of CLAM steel/aluminum clad tube prepared by explosive bonding method. Int J Adv Manuf Technol 82:543–548CrossRef

21.

Aizawa Y, Nishiwaki J, Harada Y, Muraishi S, Kumai S (2016) Experimental and numerical analysis of the formation behavior of intermediate layers at explosive welded Al/Fe joint interfaces. J Manuf Process 24(1):100–106CrossRef

22.

Li X, Ma H, Shen Z (2015) Research on explosive welding of aluminum alloy to steel with dovetail grooves. Mater Des 87:815–824CrossRef

23.

Carvalho GHSFL, Galvão I, Mendes R, Leal RM, Loureiro A (2018) Explosive welding of aluminium to stainless steel. J Mater Process Technol 262:340–349CrossRef

24.

Shiran MKG, Khalaj G, Pouraliakbar H, Jandaghi M, Bakhtiari H, Shirazi M (2017) Effects of heat treatment on the intermetallic compounds and mechanical properties of the stainless steel 321-aluminum 1230 explosive-welding interface. Int J Miner Metall Mater 24:1267–1277CrossRef

25.

Guo X, Fan M, Wang L, Ma F (2016) Bonding interface and bending deformation of Al/316LSS clad metal prepared by explosive welding. J Mater Eng Perform 25(6):2157–2163CrossRef

26.

Xunzhong G, Jie T, Wentao W, Huaguan L, Chen W (2013) Effects of the inner mould material on the aluminium-316L stainless steel explosive clad pipe. Mater Des 49:116–122CrossRef

27.

Mendes R, Ribeiro J, Plaksin I, Campos J, Tavares B (2014) Differences between the detonation behavior of emulsion explosives sensitized with glass or with polymeric micro-balloons. J Phys Conf Ser 500:1–6CrossRef

28.

Mendes R, Ribeiro J, Plaksin I, Campos J (2012) Non ideal detonation of emulsion explosives mixed with metal particles. AIP Conf Proc 1426:267–270CrossRef

29.

Mendes R, Ribeiro JB, Loureiro A (2013) Effect of explosive characteristics on the explosive welding of stainless steel to carbon steel in cylindrical configuration. Mater Des 51:182–192CrossRef

30.

Kennedy JE (1970) Gurney energy of explosives: Estimation of the velocity and impulse imparted to driven metal. Sandia National Laboratories, New MexicoCrossRef

31.

Cooper PW (1996) Explosives engineering. Wiley-VCH, USA

32.

Hokamoto K, Izuma T, Fujita M (1993) New explosive welding technique to weld aluminum alloy and stainless steel plates using a stainless steel intermediate plate. Metall Mater Trans A 24(10):2289–2297CrossRef

33.

Hokamoto K, Chiba A, Nishida M, Fujita M (1995) Experimental conditions for fabrication of multilayered metal base composites by single-shot explosive welding. Weld Int 9(2):116–120CrossRef

34.

ASM (1992) Binary phase diagrams. ASM handbook, vol 3 - Alloy Phase Diagrams. ASM International, Materials Park, Ohio, USA

35.

Wulff FW, Breach CD, Stephan D, Saraswati T, Dittmer KJ (2004) Characterisation of intermetallic growth in copper and gold ball bonds on aluminium metallization. Paper presented at the 6th Electronics Packaging Technology Conference (EPTC 2004) (IEEE Cat. No.04EX971), Singapore, 348–353

36.

Ribeiro JB, Mendes R, Loureiro A (2014) Review of the weldability window concept and equations for explosive welding. J Phys Conf Ser 500:1–6

37.

Cowan GR, Bergmann OR, Holtzman AH (1971) Mechanism of bond zone wave formation in explosion-clad metals. Metall Trans A 2(11):3145–3155CrossRef

38.

Walsh JM, Shreffler RG, Willig FJ (1953) Limiting conditions for jet formation in high velocity collisions. J Appl Phys 24(3):349–359CrossRef

39.

Deribas AA, Zakharenko ID (1974) Surface effects with oblique collisions between metallic plates. Combust Explos Shock Waves 10(3):358–367CrossRef

40.

Carpenter SH, Wittman RH (1975) Explosion welding. Annu Rev Mater Sci 5:177–199CrossRef

41.

Rosset WSD (2006) Analysis of explosive bonding parameters. Mater Manuf Process 21(6):634–638CrossRef

42.

Zakharenko ID (1972) Critical conditions in detonation welding. Fiz Goreniya Vzryva 8(3):422–427

43.

Efremov VV, Zakharenko ID (1976) Determination of the upper limit to explosive welding. Fiz Goreniya Vzryva 12(2):255–260

44.

Amani H, Soltanieh M (2016) Intermetallic phase formation in explosively welded Al/cu bimetals. Metall Mater Trans B Process Metall Mater Process Sci 47:2524–2534CrossRef

45.

Chen P, Feng J, Zhou Q, An E, Li J, Yuan Y, Ou S (2016) Investigation on the explosive welding of 1100 aluminum alloy and AZ31 magnesium alloy. J Mater Eng Perform 25(7):2635–2641CrossRef

46.

Ashani JZ, Bagheri SM (2009) Explosive scarf welding of aluminum to copper plates and their interface properties. Mat-wiss u Werkstofftech 40(9):690–698CrossRef

47.

Greenberg BA, Ivanov MA, Rybin VV, Elkina OA, Antonova OV, Patselov AM, Inozemtsev AV, Plotnikov AV, Volkova AY, Besshaposhnikov YP (2013) The problem of intermixing of metals possessing no mutual solubility upon explosion welding (Cu-Ta, Fe-Ag, Al-Ta). Mater Charact 75:51–62CrossRef

Titel: Weldability of aluminium-copper in explosive welding
verfasst von: G. H. S. F. L. Carvalho
I. Galvão
R. Mendes
R. M. Leal
A. Loureiro
Publikationsdatum: 12.05.2019
Verlag: Springer London
Erschienen in: The International Journal of Advanced Manufacturing Technology / Ausgabe 5-8/2019
Print ISSN: 0268-3768
Elektronische ISSN: 1433-3015
DOI: https://doi.org/10.1007/s00170-019-03841-9

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