Hostname: page-component-586b7cd67f-rdxmf Total loading time: 0 Render date: 2024-11-25T15:40:07.988Z Has data issue: false hasContentIssue false
  • English
  • Français

Cold Spray Direct Fabrication – High Rate, Solid State, Material Consolidation

Published online by Cambridge University Press:  10 February 2011

M. F. Smith ,
J. E. Brockmann ,
R. C. Dykhuizen ,
D. L. Gilmore ,
R. A. Neiser  and
T. J. Roemer
M. F. Smith
Affiliation:
Sandia National Laboratories, Albuquerque, NM 87185-1130, [email protected]
J. E. Brockmann
Affiliation:
Sandia National Laboratories, Albuquerque, NM 87185-1130, [email protected]
R. C. Dykhuizen
Affiliation:
Sandia National Laboratories, Albuquerque, NM 87185-1130, [email protected]
D. L. Gilmore
Affiliation:
Sandia National Laboratories, Albuquerque, NM 87185-1130, [email protected]
R. A. Neiser
Affiliation:
Sandia National Laboratories, Albuquerque, NM 87185-1130, [email protected]
T. J. Roemer
Affiliation:
Ktech Corporation, Albuquerque, NM 87106-4265
Get access

Abstract

Direct fabrication of metal near-net shapes from a computer model typically involves melting and solidification, which can cause high residual stresses, undesirable phases, poor microstructures, rough surface finishes, warpage, and other problems. This paper describes a new technology, still under development, that might be used to directly fabricate solid, near-fulldensity, free-form shapes of many metals, and even some composite materials, at or near room temperature without melting and solidification. In this process, tentatively called Cold Spray Direct Fabrication (CSDF), powder particles in a supersonic jet of compressed gas impact a solid surface with sufficient energy to cause plastic deformation and consolidation with the underlying material by a process thought to be analogous to explosive welding. Material deposition by cold spray methods has already been successfully demonstrated by several investigators. This paper presents results of an experimental study to investigate the effects of selected process variables on cold spray particle velocities. In addition, a key technical barrier to the CSDF concept is focusing the spray stream down to dimensions that would permit a useful level of part detail, while still providing practical build rates. This paper presents results of initial research to develop an aerodynamic lens that may provide the required particle stream focusing.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 542: Symposium V – Solid Freeform and Additive Fabrication , 1998 , 65
Copyright
Copyright © Materials Research Society 1999

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Keicher, D.M. and Smuggeresky, J.E., JOM 49 (5), 5154 (1997).Google Scholar
2. Mah, R., Adv. Materials & Processes 151 (3), 3133 (1997).Google Scholar
3. Nutt, K., Photonics Spectra 25 (9), 102104 (1991).Google Scholar
4. Weiss, L.E., Thuel, D.G., Schultz, L., and Prinz, F.B., J. Thermal Spray Technology 3 (3), 275281 (1994).Google Scholar
5. Atwood, C.L., McCarty, G.D., Pardo, B.T., and Bryce, E.A., IFIP Trans. B 17, 339348 (1994).Google Scholar
6. EI-Sobky, H., Explosive Welding, Forming and Compaction, Edited by Blazynski, T.Z., Applied Science Publishers, London, 1983.Google Scholar
7. Papyrin, A. N., The Pennsylvania State University, personal communication.Google Scholar
8. Alkimov, A. P., Kosarev, V.F., and Papyrin, A.N., Sov. Phys. Dokl. 35 (12), 1047–49 (1990), translation American Inst. of Physics (1991).Google Scholar
9. Tokarev, A.O., Metal Science and Heat Treating, 38 (3–4), 136139 (1996).Google Scholar
10. Alekseev, A. Y., Mogorychnyi, V. I., Volkov, V.T., Krysa, V.K., and Mukhametzyanov, A.G., Chemical and Petroleum Engineering, 32 (4), 393396(1996).Google Scholar
11. Alkimov, A.P. Papyrin, A. N., Kosarev, V.F., Nesterovich, N.I., and Shushspanov, M., U.S. Patent No. 5, 302, 414 (12 April 1994).Google Scholar
12. McCune, R.C., Papyrin, A.N., Hall, J.N., Riggs, W.L., and Zajchowski, P.H., Advances in Thermal Spray Science and Technology, edited by Berndt, C.C. and Sampath, S. (ASM International Proc. NTSC'95, Materials Park, OH, 1995) pp. 15.Google Scholar
13. McCune, R.C., Donlon, W.T., Cartwright, E.L., Papyrin, A.N., Rybicki, E.F., and Shadley, J.R., Thermal Spray: Practical Solutions for Engineering Problems, edited by Berndt, C.C. (ASM International Proc. NTSC'96, Materials Park, OH, 1996) pp. 397403.Google Scholar
14. Dykhuizen, R.C. and Smith, M.F., J. Thermal Spray Technology 7 (2), 205212 (1998).Google Scholar
15. Dykhuizen, R.C., Smith, M.F., Gilmore, D.L., Neiser, R.A., Jiang, X., and Sampath, S. J. Thermal Spray Technology, submitted for publication (1998).Google Scholar
16. Gilmore, D.L., Dykhuizen, R.C., Neiser, R.A., Roemer, T.J., and Smith, M.F., J. Thermal Spray Technology, submitted for publication (1998).Google Scholar
17. Smith, M.F., O'Hern, T.J., Brockmann, J.E., Neiser, R.A., and Roemer, T.J., Advances in Thermal Spray Science & Technology edited by Berndt, C.C. and Sampath, S. (ASM International Proc. NTSC'95, Materials Park, OH, 1995) pp. 105110.Google Scholar
18. Fuerstenau, S., Gomez, A., and Fernandez de la Mora, J., J. Aerosol Sci., 25, 165173 (1994).Google Scholar
19. Liu, P., Ziemann, P.J., Kittelson, D.B., McMurry, P.H., Aerosol Sci. and Tech., 22, 293324 (1995).Google Scholar
20. Rao, N.P., Navascues, J., Delamora, J.F., J. Aerosol Sci., 24, 879892 (1996).Google Scholar