Influence of the Determination of FLC’s and FLSC’s and Their Application for Deep Drawing Process with Additional Force Transmission

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • B. A. Behrens
  • A. Bouguecha
  • C. Bonk
  • D. Rosenbusch
  • N. Grbic
  • M. Vucetic

Organisationseinheiten

Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)405-415
Seitenumfang11
FachzeitschriftLecture Notes in Mechanical Engineering
PublikationsstatusVeröffentlicht - 23 Apr. 2017

Abstract

This contribution deals with the experimental and numerical analysis of the material fracture behavior of steel sheet material HCT 600 X + Z (1.0941) in thickness s0 = 1.0 mm using the Nakajima test. Firstly, the Nakajima test is carried out, whereby the major and minor strains are measured with the optical measuring system ARAMIS. Here, two different estimation methods for determination of the strains are applied and sensitivity of estimated results related to different strain gauge lengths was analyzed. Hereby, the forming limit curve (FLC) is determined experimentally. Subsequently, the FEA of a Nakajima test was carried out and compared with corresponding experimental results. The flow behavior of HCT 600 is modelled using a planar anisotropic material model based on the Hill’s 1948 criterion, which was validated in previous work. Using FLC the simulation-based determination of the forming limit stress curve (FLSC) is carried out. Furthermore, two deep drawing processes, conventional and process with activation of additional force transmission are carried out producing the rectangle cups. Here, the larger process window is achieved. Within the numerical investigation of the material fracture behavior the FLC and FLSC are applied by FEA of both deep drawing processes. Finally, the assessment of the performed material modelling is presented.

ASJC Scopus Sachgebiete

Zitieren

Influence of the Determination of FLC’s and FLSC’s and Their Application for Deep Drawing Process with Additional Force Transmission. / Behrens, B. A.; Bouguecha, A.; Bonk, C. et al.
in: Lecture Notes in Mechanical Engineering, 23.04.2017, S. 405-415.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Behrens, BA, Bouguecha, A, Bonk, C, Rosenbusch, D, Grbic, N & Vucetic, M 2017, 'Influence of the Determination of FLC’s and FLSC’s and Their Application for Deep Drawing Process with Additional Force Transmission', Lecture Notes in Mechanical Engineering, S. 405-415. https://doi.org/10.1007/978-3-319-56430-2_30
Behrens, B. A., Bouguecha, A., Bonk, C., Rosenbusch, D., Grbic, N., & Vucetic, M. (2017). Influence of the Determination of FLC’s and FLSC’s and Their Application for Deep Drawing Process with Additional Force Transmission. Lecture Notes in Mechanical Engineering, 405-415. https://doi.org/10.1007/978-3-319-56430-2_30
Behrens BA, Bouguecha A, Bonk C, Rosenbusch D, Grbic N, Vucetic M. Influence of the Determination of FLC’s and FLSC’s and Their Application for Deep Drawing Process with Additional Force Transmission. Lecture Notes in Mechanical Engineering. 2017 Apr 23;405-415. doi: 10.1007/978-3-319-56430-2_30
Behrens, B. A. ; Bouguecha, A. ; Bonk, C. et al. / Influence of the Determination of FLC’s and FLSC’s and Their Application for Deep Drawing Process with Additional Force Transmission. in: Lecture Notes in Mechanical Engineering. 2017 ; S. 405-415.
Download
@article{64afe771352e410fb72145b058b079d2,
title = "Influence of the Determination of FLC{\textquoteright}s and FLSC{\textquoteright}s and Their Application for Deep Drawing Process with Additional Force Transmission",
abstract = "This contribution deals with the experimental and numerical analysis of the material fracture behavior of steel sheet material HCT 600 X + Z (1.0941) in thickness s0 = 1.0 mm using the Nakajima test. Firstly, the Nakajima test is carried out, whereby the major and minor strains are measured with the optical measuring system ARAMIS. Here, two different estimation methods for determination of the strains are applied and sensitivity of estimated results related to different strain gauge lengths was analyzed. Hereby, the forming limit curve (FLC) is determined experimentally. Subsequently, the FEA of a Nakajima test was carried out and compared with corresponding experimental results. The flow behavior of HCT 600 is modelled using a planar anisotropic material model based on the Hill{\textquoteright}s 1948 criterion, which was validated in previous work. Using FLC the simulation-based determination of the forming limit stress curve (FLSC) is carried out. Furthermore, two deep drawing processes, conventional and process with activation of additional force transmission are carried out producing the rectangle cups. Here, the larger process window is achieved. Within the numerical investigation of the material fracture behavior the FLC and FLSC are applied by FEA of both deep drawing processes. Finally, the assessment of the performed material modelling is presented.",
keywords = "Deep drawing, Forming limit curve, Forming limit stress curve",
author = "Behrens, {B. A.} and A. Bouguecha and C. Bonk and D. Rosenbusch and N. Grbic and M. Vucetic",
note = "Funding information: This paper is based on investigations of the project (BE169/139-1): “Deep drawing with additional force transmission”, which is kindly supported by the German Research Foundation (DFG). The authors thank the DFG for project foundation.",
year = "2017",
month = apr,
day = "23",
doi = "10.1007/978-3-319-56430-2_30",
language = "English",
pages = "405--415",

}

Download

TY - JOUR

T1 - Influence of the Determination of FLC’s and FLSC’s and Their Application for Deep Drawing Process with Additional Force Transmission

AU - Behrens, B. A.

AU - Bouguecha, A.

AU - Bonk, C.

AU - Rosenbusch, D.

AU - Grbic, N.

AU - Vucetic, M.

N1 - Funding information: This paper is based on investigations of the project (BE169/139-1): “Deep drawing with additional force transmission”, which is kindly supported by the German Research Foundation (DFG). The authors thank the DFG for project foundation.

PY - 2017/4/23

Y1 - 2017/4/23

N2 - This contribution deals with the experimental and numerical analysis of the material fracture behavior of steel sheet material HCT 600 X + Z (1.0941) in thickness s0 = 1.0 mm using the Nakajima test. Firstly, the Nakajima test is carried out, whereby the major and minor strains are measured with the optical measuring system ARAMIS. Here, two different estimation methods for determination of the strains are applied and sensitivity of estimated results related to different strain gauge lengths was analyzed. Hereby, the forming limit curve (FLC) is determined experimentally. Subsequently, the FEA of a Nakajima test was carried out and compared with corresponding experimental results. The flow behavior of HCT 600 is modelled using a planar anisotropic material model based on the Hill’s 1948 criterion, which was validated in previous work. Using FLC the simulation-based determination of the forming limit stress curve (FLSC) is carried out. Furthermore, two deep drawing processes, conventional and process with activation of additional force transmission are carried out producing the rectangle cups. Here, the larger process window is achieved. Within the numerical investigation of the material fracture behavior the FLC and FLSC are applied by FEA of both deep drawing processes. Finally, the assessment of the performed material modelling is presented.

AB - This contribution deals with the experimental and numerical analysis of the material fracture behavior of steel sheet material HCT 600 X + Z (1.0941) in thickness s0 = 1.0 mm using the Nakajima test. Firstly, the Nakajima test is carried out, whereby the major and minor strains are measured with the optical measuring system ARAMIS. Here, two different estimation methods for determination of the strains are applied and sensitivity of estimated results related to different strain gauge lengths was analyzed. Hereby, the forming limit curve (FLC) is determined experimentally. Subsequently, the FEA of a Nakajima test was carried out and compared with corresponding experimental results. The flow behavior of HCT 600 is modelled using a planar anisotropic material model based on the Hill’s 1948 criterion, which was validated in previous work. Using FLC the simulation-based determination of the forming limit stress curve (FLSC) is carried out. Furthermore, two deep drawing processes, conventional and process with activation of additional force transmission are carried out producing the rectangle cups. Here, the larger process window is achieved. Within the numerical investigation of the material fracture behavior the FLC and FLSC are applied by FEA of both deep drawing processes. Finally, the assessment of the performed material modelling is presented.

KW - Deep drawing

KW - Forming limit curve

KW - Forming limit stress curve

UR - http://www.scopus.com/inward/record.url?scp=85019572029&partnerID=8YFLogxK

U2 - 10.1007/978-3-319-56430-2_30

DO - 10.1007/978-3-319-56430-2_30

M3 - Article

AN - SCOPUS:85019572029

SP - 405

EP - 415

JO - Lecture Notes in Mechanical Engineering

JF - Lecture Notes in Mechanical Engineering

SN - 2195-4356

ER -