Biomedical Engineering Reference
In-Depth Information
235. Zhu D., X. Zhang, and H. Ding, Tool wear characteristics in machin-
ing of nickel-based superalloys.
International Journal of Machine Tools &
Manufacture
, 2013. 64: p. 60-77.
236. BarabashO.M.,
et al.
, X-ray microdif raction and EBSD study of FSP induced
structural/phase transitions in a Ni-based superalloy.
Materials Science and
Engineering a-Structural Materials Properties Microstructure and Processing
,
2009. 524(1-2): p. 10-19.
237. Chen Y.H.,
et al.
, Inl uence of shot peening on surface-layer characteristics of
a monocrystalline nickel-based superalloy.
Powder Dif raction
, 2010. 25(4):
p. 355-358.
238. Tian J.W.,
et al.
, A study of the ef ect of nanostructured surface layers on the
fatigue behaviors of a C-2000 superalloy.
Materials Science and Engineering
a-Structural Materials Properties Microstructure and Processing
, 2007. 468:
p. 164-170.
239. Marinescu I.,
et al.
, Assessment of thread-cutting strategies to enable
damage-tolerant surfaces on an advanced Ni-based aerospace superal-
loy.
Proceedings of the Institution of Mechanical Engineers Part B-Journal of
Engineering Manufacture
, 2011. 225(B1): p. 12-24.
240. Moraux J.Y. and M. Pierronnet, “PM” used for bio-metallic materials.
Application to a cobalt base alloy with 28%Cr and 6%Mo.
Powder Metallurgy
World Congress & Exhibition (PM2004)
, 2004: p. 7.
241. Ahmed R.,
et al.
, Inl uence of Re-HIPing on the structure-property relation-
ships of cobalt-based alloys.
Tribology International
, 2013. 57: p. 8-21.
242. Hirschhorn J.S. and J.T. Reynolds, Powder Metallurgy Fabrication Of Cobalt
Alloy Surgical Implant Materials. Korostof , Edward1969. 137-150.
243. Li Y.,
et al.
, Equal channel angular pressing and torsion (ECAPT) for den-
sii cation and strengthening properties of powder sintered materials, in
Advances in Superalloys
, Pts 1 and 2, S. Jiao, Z.Y. Jiang, and J.L. Bu, Editors.
2011. p. 101-104.
244. Stolyarov V.V.,
et al.
, h e ef ect of backpressure on the structure and mechan-
ical properties of the Al-5 wt % Fe alloy produced by equal-channel angular
pressing. Physics of Metals and Metallography, 2005. 100(2): p. 182-91.
245. Hockauf M.,
et al.
, Equal-channel angular pressing of medium- to
high-strength precipitation hardening aluminium wrought alloys.
Materialwissenschat Und Werkstot echnik, 2009. 40(7): p. 540-550.
246. Frint P.,
et al.
, h e role of backpressure during large scale Equal-Channel
Angular Pressing.
Materialwissenschat Und Werkstot echnik
, 2012. 43(7):
p. 668-672.
247. Rosochowski A. and L. Olejnik, FEM simulation of incremental shear, in
10th ESAFORM Conference on Material Forming
, Pts A and B, E. Cueto and
F. Chinesta, Editors. 2007. p. 653-658.
248. Olejnik L., A. Rosochowski, and M. Richert, Incremental ECAP of plates, in
Nanomaterials by Severe Plastic Deformation
IV, Pts 1 and 2, Y. Estrin and
H.J. Maier, Editors. 2008. p. 108-113.