Abstract
An analysis is made of the main kinematic parameters that determine the beginning of weld formation near the lower boundary of the region of explosion welding. The welding of aluminum with steel is considered. The paper reports experimental results for the flow of material in the gap under oblique collision of metal plates. Key words: oblique collision, particle flow, explosion welding.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
REFERENCES
A. A. Deribas, “Classification of the flows produced by oblique collisions of metal plates,” in: Explosive Working of Metals (2nd Int. Symp. on the Application of Explosion Energy), Marianske Lasne, October (1973), pp. 31–43.
R. H. Wittman, “The influence of collision parameters on the strength and microstructure of the explosion welded aluminum alloy,” ibid., pp. 153–168.
A. A. Deribas, A. I. Gulidov, B. S. Zlobin, et al., “On the oblique collisions of the metallic plates at extreme conditions,” in: Proc. XIII AIRAPT Int. Conf. on High Pressure Science and Technology (Bangalore, 1991), IBH Publ., Oxford (1992), pp. 712–718.
V. G. Petushkov, “Physical interpretation of explosion welding near its low boundary,” Combust. Expl. Shock Waves, 36, No. 6, 771–776 (2000).
I. V. Yakovlev et al. (eds.), Wave Formation upon Oblique Collisions (collected scientific papers) [in Russian], Novosibirsk, Izd. Sib. Otd. Ross. Akad. Nauk (2000).
M. P. Bondar', “Scientific fundamentals of the production of materials by dynamic methods,” Doct. Dissertation in Phys.-Mat. Sci., Novosibirsk (1996).
L. D. Dobrushin, “On the problem of the low boundary of explosion welding,” Avtomat. Svar., No. 6, 64–65 (1979).
I. D. Zakharenko, Explosion Welding of Metals [in Russian], Nauka i Tekhnika, Minsk (1990).
K. K. Botros and T. K. Groves, “Fundamental impact-welding parameter — an experimental investigation using 76-mm powder cannon,” J. Appl. Phys., 51, No. 7, 3706–3714 (1980).
B. S. Zlobin, V. V. Kiselev, and A. I. Gulidov, “Flow of material in the gap between colliding plates,” in: Treatment of Materials by Pulsed Loads [in Russian], Inst. Theor. and Appl. Mech., Novosibirsk (1990), pp. 216–224.
I. I. Sidorov, A. M. Tyntarev, and É. F. Kirilin, “Bimetal titanium-steel produced by explosion welding and its applications,” Vopr. Material., 20, No. 3, 276–292 (1999).
Yu. A. Konon, L. B. Pervykhin, and A. D. Chudnovskii, Explosion Welding [in Russian], Mashinostroenie, Moscow (1987).
V. I. Lysak, P. V. Bersenev, S. V. Kuz'min, et al., “Procedure for estimating jet losses during explosion welding of metals,” in: Explosion Welding and Properties of Welds [in Russian], Volgograd Polytech. Inst., Volgograd (1988), pp. 25–40.
A. P. Sonnov, “Influence of the initial physical-mechanical properties of welded materials on explosion welding parameters,” ibid., pp. 3–17.
V. I. Lysak, S. V. Kuz'min, Yu. G. Dosgii, et al., “Analysis of the kinetics of formation of layered composites by explosion welding,” Fiz. Khim. Obrab. Mater., No. 6, 57–63 (2000).
B. S. Zlobin, “Influence of the strength properties of materials on explosion welding conditions,” in: Application of Explosion Energy to the Production of Metal Materials with New Properties, Proc. of the VI Int. Symp., October Gotvaldov (1985), pp. 271–278.
V. I. Chernoivanov and É. S. Karakozov, “Physicochemical processes of weld formation during spraying of powder materials. Formulation of the problem,” Svar. Proizv., No. 1, 2–5 (1984).
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Zlobin, B.S. Explosion Welding of Steel with Aluminum. Combustion, Explosion, and Shock Waves 38, 374–377 (2002). https://doi.org/10.1023/A:1015674407898
Issue Date:
DOI: https://doi.org/10.1023/A:1015674407898