Mamusi H, Bakhshi Jooybari M, Gorji H, Hashemi R. Forming Limit Curves Prediction of Low-Carbon Steel Sheets Using Ductile Fracture Criteria. Modares Mechanical Engineering 2021; 21 (4) :247-261
URL:
http://mme.modares.ac.ir/article-15-43840-en.html
1- Ph.D. candidate, Faculty of Mechanical Engineering, Babol Noshirvani University of Technology, Babol
2- Professor, Faculty of Mechanical Engineering, Babol Noshirvani University of Technology, Babol, Iran
3- Associate Professor, Faculty of Mechanical Engineering, Babol Noshirvani University of Technology, Babol, Iran , hamidgorji@nit.ac.ir
4- Associate Professor, Faculty of mechanical engineering, Iran University of Science and Technology, Tehran, Iran
Abstract: (1938 Views)
Forming Limit Diagrams (FLDs) are very useful measures for safe forming of sheet metals without failure due to necking or fracture under different loading conditions. This paper uses ductile fracture criteria to predict the formability of low carbon steel sheets to evaluate their accuracy in predicting the FLDs. In addition, the fracture forming limit curves (FFLD) and necking forming limit curves (NFLD) for St12 low-carbon steel have been extracted experimentally and numerically. In the experimental procedure, the Nakazima stretching test was used. In the numerical procedure, by defining six phenomenological ductile fracture criteria in ABAQUS / Explicit finite element software, the failure is predicted and compared with the experimental results. These criteria were calibrated using 6 tests namely as In-plane shear, uniaxial tensile test, circle hole test, notched tension test, plane stress test, and Nakazima stretching test. The results showed that the criteria, which include both the stress triaxiality (η) and Lode parameter (L), provide a more accurate prediction of failure. Also to predict necking during numerical simulation of Nakazima test and also to extract the NFLD, three criteria of the second derivative of major strain, the second derivative of thickness strain and the second derivative of equivalent plastic strain have been used.
Article Type:
Original Research |
Subject:
Damage Mechanics Received: 2020/06/21 | Accepted: 2021/01/22 | Published: 2021/03/30