Cold forming initiates a change of the material properties like flow stress and hardness. Due to work hardening and the accompanied loss of formability some intermediate heat treatment may become necessary in multi-stage forming processes. One possibility to avoid this heat treatment is to adjust the forming characteristics in terms of flow stress and formability by rotary swaging. This process is particularly suitable not only for producing of the target geometry but also for modifying of the material properties during the process and thus, rotary swaging can prepare the parts for further forming, such as extrusion. In this contribution, the process chain “rotary swaging – extrusion” for austenite stainless steel AISI304 was investigated. The forming characteristics of the semi-finished products for the extrusion were influenced by the previous swaging process. The conditioning by changing of the microstructure, the work hardening and the geometry of the processed wires was achieved by the process design. For this purpose, the geometry of the swaging dies, the feeding velocity as well as the process kinematics (eccentric swaging) and a stroke following angle Δɸ were varied. In particular, the novel geometry of the swaging dies with extraordinary sloped faces generated a non-symmetric material flow with severe shear deformation and thus an extreme change of the microstructure. The required forming force of the following extrusion process reflected the range of achievable conditioning. The micro rotary swaging process positively improved the formability of AISI304 by work softening.

1.
R.
von Bargen
,
A.
von Hehl
and
H.-W.
Zoch
,
HTM Journal of Heat Treatment and Materials
67
,
6
(
2012
), pp.
25
30
.
2.
A.
Ameli
and
M. R.
Movahhedy
,
Int. Journal of Advanced Manufacturing Technology
33
(
2007
), pp.
7
17
.
3.
M.
Herrmann
,
E.
Moumi
,
S.
Ishkina
,
C.
Schenck
,
Y.
Liu
and
B.
Kuhfuss
, “Werkstofffluss beim Rundkneten,”
23
.
Sächsische Fachtagung Umformtechnik
(
TU Dresden
,
Dresden, Germany
,
2016
).
4.
B.
Kuhfuss
and
E.
Moumi
, “Incremental forming,” in
Micro Metal Forming
, edited by
F.
Vollertsen
(
Springer
Berlin
,
2013
), pp.
104
113
.
5.
S.
Ishkina
,
B.
Kuhfuss
and
C.
Schenck
, “Beeinflussung der Umformbarkeit von Halbzeugen durch Modifikationen beim Mikrorundkneten,”
7
.
Kolloquium Mikroproduktion
(
Aachen
,
Germany
,
2015
).
6.
S.
Ishkina
,
C.
Schenck
and
B.
Kuhfuß
, “
Influence of the relative rotational speed on component features in micro rotary swaging
,”
Proceedings of the 4ᵗʰ Int. Conf. on New Form. Technology
(
Glasgow
,
UK
,
2015
).
7.
S.
Ishkina
,
C.
Schenck
,
B.
Kuhfuß
,
E.
Moumi
and
K.
Tobeck
,
International Journal of Precision Engineering and Manufacturing
18
,
7
(
2017
), pp.
1035
1041
.
8.
B.
Kuhfuss
,
E.
Moumi
and
V.
Piwek
,
Microsyst Technol
14
(
2008
), pp.
1995
2000
.
9.
A.
Tönjes
,
S.
Ishkina
,
A.
von Hehl
,
C.
Schenck
,
H.-W.
Zoch
and
B.
Kuhfuss
, “Examination of the microstructure of eccentric rotary swaged components of X5CrNi18-1 (in German),”
8
.
Kolloquium Mikroproduktion in Bremen
(
BIAS
,
Bremen
,
2017
), pp.
107
112
(online).
10.
S.
Ishkina
,
B.
Kuhfuss
and
C.
Schenck
, “
Grain size modification by micro rotary swaging
,”
Proceeding of the 18th International Conference on Material Forming ESAFORM
(
Graz
,
Austria
,
2015
).
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