msepostdoc-list Seminar Notice - Efe, Tue. 7/17/12, 9:30 AM, ARMS Rm 3115

Stacey, Lisa A staceyl at purdue.edu
Wed Jul 11 16:05:41 EDT 2012


MATERIALS SCIENCE AND ENGINEERING
SEMINAR


Extrusion Machining:  A Thermo-Mechanical Process for
Producing Strips of Alloys Having Limited Workability
by

Mert Efe
Ph.D. Final Exam

Advisor
Professor K. Trumble

ABSTRACT

Deformation processing of alloys with limited workability is one of the principal technological challenges for the metal manufacturing industry. Traditional processes (rolling, extrusion) are usually performed at high temperatures (0.5 Tm) for increased plasticity and crack-free products, which makes them costly, energy intensive and raw material inefficient. In this thesis, extrusion machining (EM) a shear-type deformation process is applied to alloys with limited workability for sheet and foil production from bulk forms in a single step. EM is shown to have a narrowly confined and controllable deformation zone, with attributes ranging from conventional deformation processing to severe plastic deformation. Controllable deformation parameters include strain, strain rate, hydrostatic pressure, temperature and deformation path. These attributes are highlighted in deformation processing of two classes of limited workability alloys: 1) Alloys with intrinsic susceptibility to cracking (and segmentation) due to flow localization and shear band formation and 2) Alloys with extrinsic susceptibility to cracking due to macroscopic defects such as porosity, casting defects and weak second phases. Magnesium AZ31 alloy is selected as a model material for the first class and sintered copper and cast brass alloys are selected for the second class.  Noteworthy features of the process are suppression of segmentation by combinations of high hydrostatic pressures (p/2k = 1.7) and deformation temperatures (T > 0.5 Tm) realized by in-situ plastic heating, realization of a range of strains [cid:image006.png at 01CD5F7F.0480AF00] and deformation rates [cid:image007.png at 01CD5F7F.0480AF00] , engineering of microstructures ranging from conventional to ultrafine grained, and creation of sheet from the bulk in a single step of deformation without pre-heating. The thermo-mechanical conditions and microstructural processes that are responsible for continuous and sound sheet products are established. Guidelines for scalability and cost-effectiveness of EM for commercial production are analyzed and discussed.

Date:   Tuesday, July 17, 2012
Time:   9:30 AM
Place:   ARMS 3115


Lisa Stacey
Secretary/Development Assistant
Purdue University
School of Materials Engineering
765/494-4100

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