SIMPLE PREDICTION OF SHEET METAL FORMING LIMIT STRESSES AND STRAINS

K.P. Rao; Emani V.R. Mohan

SIMPLE PREDICTION OF SHEET METAL FORMING LIMIT STRESSES AND STRAINS

K.P. Rao, Emani V.R. Mohan

Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review

Abstract

Forming limit curves or diagrams (FLCs or FLDs) are widely used for troubleshooting purposes in sheet metal stamping industry. Their prediction using analytical approaches has assumed significant importance recently since the FLCs obtained experimentally pose several limitations while the former provides a high level of flexibility in adopting a variety of conditions. Generally, FLCs indicate the maximum strain achievable for a constant strain ratio path during forming operations. However, constant strain ratio condition does not exist in practical situations, particularly, when pressing complex shapes involving multiple stages of forming. This is mainly due to variations in material properties like strain hardening, strength and anisotropy that often lead to deviations in strain path. Equally important are the imposed process conditions that also exert considerable influence on the forming limits.

A method is proposed to predict FLCs from tensile test data of sheet materials. A single limit yield stress is first obtained from simple tensile test. Following Hill's anisotropic yield criteria, a continuous limit yield locus is obtained, which can be termed as Forming Limit Stress Curve (FLSC). If necessary, it can be linearized following a regression method, and FLCs are obtained using relevant hardening equation, normality flow rule and Hill's anisotropic yield criterion. It has been found that the predicted FLCs with this approach have yielded consistently fair results in the case of several deep-drawing-quality steels. The second aspect addressed is on establishing the forming limit bands, which could be achieved by considering the tensile properties of a material in the three important directions and subsequently applying the prediction model. Results obtained with the model for brass are presented, and have been verified using the strains obtained in experiments on a dome-shaped cup formed in predominantly stretch type deformation mode.

Original language	English
Title of host publication	SHEET METAL FORMING TECHNOLOGY
Editors	Mahmoud Y. Demeri
Place of Publication	Warrendale, Pennsylvania
Publisher	Minerals, Metals & Materials Society
Pages	205-231
ISBN (Print)	0873394267
Publication status	Published - Feb 1999
Event	128th Annual Meeting & Exhibition of The Minerals, Metals & Materials Society (1999 TMS) - San Diego Convention Center, San Diego, United States Duration: 28 Feb 1999 → 4 Mar 1999 https://www.tms.org/Meetings/Annual-99/AnnMtg99Home.html https://www.tms.org/Meetings/Annual-99/Annual99-TechProgram.pdf

Conference

Conference	128th Annual Meeting & Exhibition of The Minerals, Metals & Materials Society (1999 TMS)
Abbreviated title	1999 TMS
Place	United States
City	San Diego
Period	28/02/99 → 4/03/99
Internet address	https://www.tms.org/Meetings/Annual-99/AnnMtg99Home.html https://www.tms.org/Meetings/Annual-99/Annual99-TechProgram.pdf

Bibliographical note

Full text of this publication does not contain sufficient affiliation information. With consent from the author(s) concerned, the Research Unit(s) information for this record is based on the existing academic department affiliation of the author(s).

Research Keywords

YIELD SURFACES
INSTABILITY
FORMABILITY
PRESTRAIN
DIAGRAMS
BEHAVIOR
TEXTURE
PATHS
FLOW

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@inproceedings{ad5b0ecdc46b44cf9250f4c826358b1e,

title = "SIMPLE PREDICTION OF SHEET METAL FORMING LIMIT STRESSES AND STRAINS",

abstract = "Forming limit curves or diagrams (FLCs or FLDs) are widely used for troubleshooting purposes in sheet metal stamping industry. Their prediction using analytical approaches has assumed significant importance recently since the FLCs obtained experimentally pose several limitations while the former provides a high level of flexibility in adopting a variety of conditions. Generally, FLCs indicate the maximum strain achievable for a constant strain ratio path during forming operations. However, constant strain ratio condition does not exist in practical situations, particularly, when pressing complex shapes involving multiple stages of forming. This is mainly due to variations in material properties like strain hardening, strength and anisotropy that often lead to deviations in strain path. Equally important are the imposed process conditions that also exert considerable influence on the forming limits.A method is proposed to predict FLCs from tensile test data of sheet materials. A single limit yield stress is first obtained from simple tensile test. Following Hill's anisotropic yield criteria, a continuous limit yield locus is obtained, which can be termed as Forming Limit Stress Curve (FLSC). If necessary, it can be linearized following a regression method, and FLCs are obtained using relevant hardening equation, normality flow rule and Hill's anisotropic yield criterion. It has been found that the predicted FLCs with this approach have yielded consistently fair results in the case of several deep-drawing-quality steels. The second aspect addressed is on establishing the forming limit bands, which could be achieved by considering the tensile properties of a material in the three important directions and subsequently applying the prediction model. Results obtained with the model for brass are presented, and have been verified using the strains obtained in experiments on a dome-shaped cup formed in predominantly stretch type deformation mode.",

keywords = "YIELD SURFACES, INSTABILITY, FORMABILITY, PRESTRAIN, DIAGRAMS, BEHAVIOR, TEXTURE, PATHS, FLOW",

author = "K.P. Rao and Mohan, {Emani V.R.}",

note = "Full text of this publication does not contain sufficient affiliation information. With consent from the author(s) concerned, the Research Unit(s) information for this record is based on the existing academic department affiliation of the author(s).; 128th Annual Meeting & Exhibition of The Minerals, Metals & Materials Society (1999 TMS), 1999 TMS ; Conference date: 28-02-1999 Through 04-03-1999",

year = "1999",

month = feb,

language = "English",

isbn = "0873394267",

pages = "205--231",

editor = "Demeri, {Mahmoud Y.}",

booktitle = "SHEET METAL FORMING TECHNOLOGY",

publisher = "Minerals, Metals & Materials Society",

address = "United States",

url = "https://www.tms.org/Meetings/Annual-99/AnnMtg99Home.html, https://www.tms.org/Meetings/Annual-99/Annual99-TechProgram.pdf",

}

SIMPLE PREDICTION OF SHEET METAL FORMING LIMIT STRESSES AND STRAINS. / Rao, K.P.; Mohan, Emani V.R.
SHEET METAL FORMING TECHNOLOGY. ed. / Mahmoud Y. Demeri. Warrendale, Pennsylvania: Minerals, Metals & Materials Society, 1999. p. 205-231.

Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review

TY - GEN

T1 - SIMPLE PREDICTION OF SHEET METAL FORMING LIMIT STRESSES AND STRAINS

AU - Rao, K.P.

AU - Mohan, Emani V.R.

N1 - Full text of this publication does not contain sufficient affiliation information. With consent from the author(s) concerned, the Research Unit(s) information for this record is based on the existing academic department affiliation of the author(s).

PY - 1999/2

Y1 - 1999/2

N2 - Forming limit curves or diagrams (FLCs or FLDs) are widely used for troubleshooting purposes in sheet metal stamping industry. Their prediction using analytical approaches has assumed significant importance recently since the FLCs obtained experimentally pose several limitations while the former provides a high level of flexibility in adopting a variety of conditions. Generally, FLCs indicate the maximum strain achievable for a constant strain ratio path during forming operations. However, constant strain ratio condition does not exist in practical situations, particularly, when pressing complex shapes involving multiple stages of forming. This is mainly due to variations in material properties like strain hardening, strength and anisotropy that often lead to deviations in strain path. Equally important are the imposed process conditions that also exert considerable influence on the forming limits.A method is proposed to predict FLCs from tensile test data of sheet materials. A single limit yield stress is first obtained from simple tensile test. Following Hill's anisotropic yield criteria, a continuous limit yield locus is obtained, which can be termed as Forming Limit Stress Curve (FLSC). If necessary, it can be linearized following a regression method, and FLCs are obtained using relevant hardening equation, normality flow rule and Hill's anisotropic yield criterion. It has been found that the predicted FLCs with this approach have yielded consistently fair results in the case of several deep-drawing-quality steels. The second aspect addressed is on establishing the forming limit bands, which could be achieved by considering the tensile properties of a material in the three important directions and subsequently applying the prediction model. Results obtained with the model for brass are presented, and have been verified using the strains obtained in experiments on a dome-shaped cup formed in predominantly stretch type deformation mode.

AB - Forming limit curves or diagrams (FLCs or FLDs) are widely used for troubleshooting purposes in sheet metal stamping industry. Their prediction using analytical approaches has assumed significant importance recently since the FLCs obtained experimentally pose several limitations while the former provides a high level of flexibility in adopting a variety of conditions. Generally, FLCs indicate the maximum strain achievable for a constant strain ratio path during forming operations. However, constant strain ratio condition does not exist in practical situations, particularly, when pressing complex shapes involving multiple stages of forming. This is mainly due to variations in material properties like strain hardening, strength and anisotropy that often lead to deviations in strain path. Equally important are the imposed process conditions that also exert considerable influence on the forming limits.A method is proposed to predict FLCs from tensile test data of sheet materials. A single limit yield stress is first obtained from simple tensile test. Following Hill's anisotropic yield criteria, a continuous limit yield locus is obtained, which can be termed as Forming Limit Stress Curve (FLSC). If necessary, it can be linearized following a regression method, and FLCs are obtained using relevant hardening equation, normality flow rule and Hill's anisotropic yield criterion. It has been found that the predicted FLCs with this approach have yielded consistently fair results in the case of several deep-drawing-quality steels. The second aspect addressed is on establishing the forming limit bands, which could be achieved by considering the tensile properties of a material in the three important directions and subsequently applying the prediction model. Results obtained with the model for brass are presented, and have been verified using the strains obtained in experiments on a dome-shaped cup formed in predominantly stretch type deformation mode.

KW - YIELD SURFACES

KW - INSTABILITY

KW - FORMABILITY

KW - PRESTRAIN

KW - DIAGRAMS

KW - BEHAVIOR

KW - TEXTURE

KW - PATHS

KW - FLOW

M3 - RGC 32 - Refereed conference paper (with host publication)

SN - 0873394267

SP - 205

EP - 231

BT - SHEET METAL FORMING TECHNOLOGY

A2 - Demeri, Mahmoud Y.

PB - Minerals, Metals & Materials Society

CY - Warrendale, Pennsylvania

T2 - 128th Annual Meeting & Exhibition of The Minerals, Metals & Materials Society (1999 TMS)

Y2 - 28 February 1999 through 4 March 1999

ER -

SIMPLE PREDICTION OF SHEET METAL FORMING LIMIT STRESSES AND STRAINS

Abstract

Conference

Bibliographical note

Research Keywords

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