International Research Journal on Advanced Science Hub

Current Issue

By Issue

By Subject

Keyword Index

Author Index

Indexing Databases XML

About Journal

Aims and Scope

Editorial Board

Editorial Staff

Publication Ethics

Indexing and Abstracting

Related Links

Peer Review Process

News

Digital Archiving & Preservation Policy

Editor and Reviewer guidelines

A Review on Effect of Stress and Strain Distribution on the AA5083 With Respect to Different Channel Angle of ECAP

International Research Journal on Advanced Science Hub, 2022, Volume 4, Issue 03, Pages 57-66
10.47392/irjash.2022.013

Abstract

The focus of this study was on the effect of channel angle on stress distribution in the material aluminum alloy 5083. The mechanical properties of a mate- rial are related to the grain size. Equal channel angular pressing (ECAP) is a method for deforming materials in such a way that a strong mechanical prop- erties material is formed while the dimensions of the work piece stay fixed in order to make ultra-fine-grained materials. One of the parameters of ECAP is the channel angle. It’s crucial to understand the impact of a die channel angle on material stress distribution before designing one. When the work piece passes through the channel angle, the die channel angle is built differently to see the effect of stress distribution. At the place where the die’s channels angle intersected, the grain structure was evaluated. The result of the influence of die channel angle on stress distribution is shown in this study’s analysis. It is well established that the channel angle has an impact on mechanical behaviour. The inhomogeneity index (Ci)and standard deviation (S.D.) are two approaches for assessing strain homogeneity. Ciis demonstrated to be an ineffective tool for analysing strain distribution homogeneity. Furthermore, it is advised that constructing Equal Channel Angular Pressing die geometry to obtain the best strain circulation homogeneity rather also the best efficient strain consequence is preferable.
Keywords:

 

 

AAL, Mohamed Ibrahim ABD EL and M. M. SADAWY. “Influence of ECAP as grain refine- ment technique on microstructure evolution, mechanical properties and corrosion  behavior  of pure aluminum”. Transactions of Nonferrous Metals Society of China 25.12 (2015): 3865–3876. 10.1016/s1003-6326(15)64034-1.

Azushima, A., et al. “Severe plastic deformation (SPD) processes for metals”. CIRP Annals 57.2 (2008): 716–735. 10.1016/j.cirp.2008.09.005.

Bagherpour, E., et al. “An overview on severe plastic deformation: research status, techniques classification, microstructure evolution, and applications”. The International Journal of Advanced Manufacturing Technology 100.5-8 (2019): 1647–1694. 10.1007/s00170- 018- 2652-z.

Carazo, Fernando D., et al. “Analysis of Strain Inho- mogeneity in Extruded Al 6061-T6 Processed by ECAE”. Metals 12.2 (2022): 299–299. 10.3390/ met12020299.

Djavanroodi, F., et al. “Designing of ECAP param- eters based on strain distribution uniformity”. Progress in Natural Science: Materials Interna- tional 22.5 (2012): 452–460. 10 . 1016 / j . pnsc .2012.08.001.

Ebrahimi, M., F. Pashmforoush, and C. Gode. “Eval- uating influence degree of equal-channel angular pressing parameters based on finite element anal- ysis and response surface methodology”. Journal of the Brazilian Society of Mechanical Sciences and Engineering 41.2 (2019): 1–12. 10 . 1007 / s40430-019-1597-y.

Eivani, A. R., et al. “Simulation of deformation and fracture initiation during equal channel angular pressing of AZ31 magnesium alloy with covered tube casing”. Journal of Materials Research and Technology 12 (2021): 1913–1923. 10 . 1016 / j . jmrt.2021.03.096.

Gzyl, Michal, et al. “Producing High-Strength Met- als by I-ECAP”. Advanced Engineering Materi- als 18.8 (2016): 1519–1519. 10 . 1002 / adem .201600261.

Kamaruddin, Akmalia, Mohd Shahira, and Nizam Katimon. “Simulation study on the material stress distribution respect to different angle of ECAP”. Research Progress in Mechanical and Manufac- turing Engineering 2 (2021): 433–441.

Mousavi, Seyed Elias, et al. “Effect of the equal channel angular pressing route on the microstruc- tural and mechanical behavior of Al-5086 alloy”. Materialia 4 (2018): 310–322. 10 . 1016 / j . mtla.2018.10.007.

Sadasivan, N., M. Balasubramanian, and B. R. Rameshbapu. “A comprehensive review on equal channel angular pressing of bulk metal and sheet metal process methodology and its varied appli- cations”. Journal of Manufacturing Processes 59 (2020): 698–726. 10.1016/j.jmapro.2020.10.032.

Samsudin, M. H. M., D. Kurniawan, and Fethma M. Nor. “Strain Distribution Equal Channel Angular Pressing of Magnesium alloy at 90and 120Cor- ner Angles”.  Procedia Manufacturing 2 (2015):

230–235. 10.1016/j.promfg.2015.07.040.

Sanusi, Kazeem O., Oluwole D. Makinde, and Graeme J. Oliver. “Equal channel angular press- ing technique for the formation of ultra-fine grained structures”. South African Journal of Sci- ence 108.9/10 (2012): 1–7. 10.4102/sajs.v108i9/10.212.

Sklenicka, Vaclav, et al. “Equal-Channel Angular Pressing and Creep in Ultrafine-Grained Alu- minium and Its Alloys”. Aluminium Alloys - New Trends in Fabrication and Applications (2012): 3–45. 10.4102/sajs.v108i9/10.212.

Vishnu, P., et al. “A review on processing of alu- minium and its alloys through Equal Channel Angular Pressing die”. Materials Today: Pro- ceedings 21 (2020): 212–222. 10 . 1016 / j . matpr.2019.04.223.

  • Article View: 44
  • PDF Download: 42