Upper-bound analysis of equal channel angular extrusion using linear and rotational velocity fields: Fid-Bau Portal

Fachinformationsdienst BAUdigital

A platform for research: civil engineering, architecture and urbanism

Upper-bound analysis of equal channel angular extrusion using linear and rotational velocity fields

Reihanian, M. / Ebrahimi, R. / Moshksar, M.M.

AbstractAn upper-bound approach based on the rotational and linear velocity fields is used to analyze the equal channel angular extrusion process. Using this model, plastic deformation zone (PDZ) is divided into three rotational velocity fields. The equations and center axis of each velocity discontinuity surface are derived. The total power loss is optimized numerically with respect to the boundary points of discontinuity surfaces. Results show that PDZ becomes larger with increasing the constant friction factor and the inner corner radius. Also, the experimental and theoretical forces needed for the equal channel angular extrusion process are in a good agreement.

Access

Check availability in my library

Order at Subito €

Page navigation

Document information

Export, share and cite

Upper-bound analysis of equal channel angular extrusion using linear and rotational velocity fields

Reihanian, M. / Ebrahimi, R. / Moshksar, M.M.

AbstractAn upper-bound approach based on the rotational and linear velocity fields is used to analyze the equal channel angular extrusion process. Using this model, plastic deformation zone (PDZ) is divided into three rotational velocity fields. The equations and center axis of each velocity discontinuity surface are derived. The total power loss is optimized numerically with respect to the boundary points of discontinuity surfaces. Results show that PDZ becomes larger with increasing the constant friction factor and the inner corner radius. Also, the experimental and theoretical forces needed for the equal channel angular extrusion process are in a good agreement.

Upper-bound analysis of equal channel angular extrusion using linear and rotational velocity fields

Reihanian, M. / Ebrahimi, R. / Moshksar, M.M.

AbstractAn upper-bound approach based on the rotational and linear velocity fields is used to analyze the equal channel angular extrusion process. Using this model, plastic deformation zone (PDZ) is divided into three rotational velocity fields. The equations and center axis of each velocity discontinuity surface are derived. The total power loss is optimized numerically with respect to the boundary points of discontinuity surfaces. Results show that PDZ becomes larger with increasing the constant friction factor and the inner corner radius. Also, the experimental and theoretical forces needed for the equal channel angular extrusion process are in a good agreement.

Access

Check availability in my library

Order at Subito €

Page navigation

Document information

Export, share and cite

Document information

Title:

Upper-bound analysis of equal channel angular extrusion using linear and rotational velocity fields

Contributors:

Reihanian, M. (author) / Ebrahimi, R. (author) / Moshksar, M.M. (author)

Publication date:

2008-04-21

Size:

7 pages

ISSN:

DOI:

https://doi.org/10.1016/j.matdes.2008.04.059

Type of media:

Article (Journal)

Type of material:

Electronic Resource

Language:

English

Keywords:

Extrusion (C) , Plastic behavior (F)

Similar titles

Upper-bound analysis of equal channel angular extrusion using linear and rotational velocity fields

Reihanian, M. / Ebrahimi, R. / Moshksar, M. M. | British Library Online Contents | 2009

Upper-bound analysis of dual equal channel lateral extrusion

Talebanpour, B. / Ebrahimi, R. | British Library Online Contents | 2009

Upper-bound analysis of dual equal channel lateral extrusion

Talebanpour, B. / Ebrahimi, R. | Elsevier | 2008

Upper-Bound Analysis for Change-Channel Angular Extrusion

Liu, T.M. / Liu, Y. / Lu, L.W. et al. | British Library Online Contents | 2009

An upper-bound solution of equal channel angular pressing

Wei, W. / Chen, G. | British Library Online Contents | 2005