This paper presents a formability analysis of tailor-welded blanks (TWBs) made of cold rolled steel sheets with varying thicknesses. Steel sheets ranging between 0.5 mm, 0.6 mm, 0.7 mm, 0.8 mm, 0.9 mm, and 1.0 mm in thickness were used to produce TWBs of different thickness combinations. The primary objective of this paper is to characterize the effects of thickness ratios on the forming limit diagram (FLD) for a particular type of TWB. The TWBs chosen for the investigation are designed with the weld line located in the center of the specimens perpendicular to the principal strain direction. Nd:YAG laser butt-welding was used to prepare different tailor-made blank specimens for uniaxial tensile tests and Swift tests. The experimental results of the uniaxial tensile test clearly revealed that there were no significant differences between the tensile strengths of TWBs and those of the base metals. After the Swift tests, the formability of TWBs was analyzed in terms of two measures: The forming limit diagram and minimum major strain. The experimental findings indicated that the higher the thickness ratio, the lower the level of the forming limit curve (FLC) and the lower the formability of the TWBs. The findings also show an inverse proportional relationship between thickness ratios and minimum major strains. TWBs with a thickness ratio of close to 1 were found to have a minimum major strain closer to those of base metals. The effects of different thickness ratios on TWBs were further analyzed with a finite element code in a computer-aided engineering package, PAM-STAMP, while the failure criteria of the TWBs in the finite element analysis were addressed by the FLCs which were obtained from the experiments. However, the weld of the TWB in the simulation was simply treated as a thickness step, whereas its heat affected zones were sometimes disregarded, so that the effects of the thickness ratio could be significantly disclosed without the presence of weld zones. The results of the simulation should certainly assist to clarify and explain the effects of different thickness ratios on TWBs.

1.
Kridli
,
G. T.
,
Friedmean
,
P. A.
, and
Sherman
,
A. M.
, 2000, “
Formability of Aluminum Tailor-Welded Blanks
,”
SAE 2000 World Congress
,
Detroit
, Michigan, pp.
1
9
.
2.
Saunders
,
F. I.
, and
Wagoner
,
R. H.
, 1995, “
The Use of Tailor-Welded Blanks in Automotive Applications
,”
Simulation of Materials Processing: Theory, Methods, and Applications - Proc. NUMIFORM 95
,
S.-F.
Shen
and
P.
Dawson
, eds.,
Balkema
, Rotterdam, pp.
157
164
.
3.
Saunders
,
F. I.
, and
Wagoner
,
R. H.
, 1996, “
Forming of Tailor-Welded Blanks
,”
Metall. Mater. Trans. A
1073-5623,
27A
, pp.
2605
2615
.
4.
Stasik
,
M. C.
, and
Wagoner
,
R. H.
, 1998, “
Forming of Tailor-Welded Aluminum Blanks
,”
Int. J. Form. Processes
1292-7775,
1
(
1
), pp.
1
33
.
5.
Stasik
,
M. C.
, and
Wagoner
,
R. H.
, 1996, “
Forming of Tailor-Welded Aluminum Blanks
,”
Aluminum of Magnesium for Automotive Applications
,
J. D.
Bryant
, ed.,
The Minerals Metals and Materials Society
, pp.
69
83
.
6.
Scriven
,
P. J.
,
Brandon
,
J. A.
, and
Williams
,
N. T.
, 1996, “
Influence of Weld Orientation on Forming Limit,” Diagrams of Similar/Dissimilar Thickness Laser Welded Joints
,”
Proceedings of the Institute of Materials
,
Ironmaking Steelmaking
0301-9233,
23
(
2
), pp.
177
182
.
7.
Keeler
,
S. P.
, 1974, “
Forming Limit Criteria Sheets
,”
Advanced in Deformation Processing, 21st Sagamore Conference
,
Plenum
, New York.
8.
Haberfield
,
A. B.
, and
Boyles
,
M. W.
, 1973, “
Laboratory Determined Forming Limit Diagram
,”
Sheet Metal Industries
,
50
, pp.
400
405
.
9.
Chen
,
L. X.
,
Bhandhubanyong
,
P.
,
Vajragupta
,
W.
, and
Somsiri
,
C.
, 1997, “
Plastic Properties of Low-Carbon Steel Sheets
,”
J. Mater. Process. Technol.
0924-0136,
63
(
1–3
), pp.
95
99
.
10.
Zimniak
,
Z.
, and
Piela
,
A.
, 2000, “
Finite Element Analysis of a Tailored Blanks Stamping Process
,”
J. Mater. Process. Technol.
0924-0136,
106
(
1–3
), pp.
254
260
.
11.
Meinders
,
T.
,
van den Berg
,
A.
, and
Huetink
,
J.
, 2000, “
Deep Drawing Simulations of Tailored Blanks and Experimental Verification
,”
J. Mater. Process. Technol.
0924-0136
103
(
1
), pp.
65
73
.
12.
Zhao
,
K. M.
,
Chun
,
B. K.
, and
Lee
,
J. K.
, 2001, “
Finite Element Analysis of Tailor-Welded Blanks
,”
Finite Elem. Anal. Design
0168-874X,
37
(
2
), pp.
117
130
.
13.
Chan
,
S. M.
,
Chan
,
L. C.
, and
Lee
,
T. C.
, 2001, “
Deformation Mode Analysis of Forming Limit Diagrams for Tailor-Welded Blanks
,”
SAE 2001 World Congress
,
Detroit
, Michigan, pp.
119
126
.
14.
Radlmayr
,
K. M.
, and
Szinyur
,
J.
, 1991, “
Laser Welded Sheet Panels for the Body in White
,”
Proc. IDDRG Working Groups Meeting
, Milano, Vol.
2
.
15.
Sigeert
,
K.
, and
Knabe
,
E.
, 1995, “
Fundamental Research and Draw Die Concepts for Deep Drawing of Tailored Blanks
,” SAE Technical paper, Paper No. 950921.
16.
Rao
,
K. P.
, and
Mohan
,
E. V. R.
, 2000, “
Direct Evaluation of Sheet Metal Forming Properties Under Various Deformation Conditions
,”
Key Eng. Mater.
1013-9826,
177–180
, pp.
509
516
.
17.
Shi
,
M. F.
, and
Pickett
,
K. M.
, 1993, “
Formability Issues in the Application of Tailor Welded Blank Sheets
,” SAE Technical Papers,
Society of Automotive Engineers, Inc.
, Warrendale, PA, pp.
27
34
.
18.
Banabic
,
D.
, 2000,
Formability of Metallic Materials
,
Springer
, New York, pp.
198
203
.
You do not currently have access to this content.