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Arman Hasani

Arman Hasani

Academic rank: Assistant Professor
ORCID:
Education: PhD.
ScopusId: 23481834900
HIndex:
Faculty: Faculty of Engineering
Address:
Phone:

Research

Title
Principles of Nonequal Channel Angular Pressing
Type
JournalPaper
Keywords
ECAP, DCAP, simple shear, flow line modeling, texture
Year
2010
Journal Journal of Engineering Materials and Technology, Transactions of the ASME
DOI
Researchers Arman Hasani ، Laszlo S. Toth ، Benoit Beausir

Abstract

A variant of the equal channel angular pressing (ECAP) process is examined in this paper where the channels are of rectangular shape with different thicknesses while the widths of the channels are the same. The process is named nonequal channel angular pressing and it is similar to the earlier introduced dissimilar channel angular pressing (DCAP) process. In DCAP, however, the diameters are near values, with the exit channel being slightly larger, while in NECAP, the exit channel is much smaller attributing sev-eral advantages to nonequal channel angular pressing (NECAP) with respect to ECAP. In this work an analysis is performed to determine the strain mode in a 90 deg NECAP die. A new flow line function is also presented to better describe the deformation field. The proposed flow line function is validated using finite element simulations. A comparison is made between ECAP and NECAP. Finally, texture predictions are presented for NECAP of fcc polycrystals. The advantages of this severe plastic deformation process are the following: (i) significantly larger strains can be obtained in one pass with respect to the classical ECAP process, (ii) grains become more elongated that enhances their fragmen-tation, and (iii) large hydrostatic stresses develop that improve the stability of the defor-mation process for difficult-to-work materials. The results obtained concerning the de-formation field are also applicable in the machining process for the plastic strains that imparted into the chips.