Additive manufacturing of AlSi10Mg has obtained increased attention due to its lightweight feature. However, handling of loose powder, efficient usage of feedstock, and powder recycling still remain major open challenges. Herein, a novel additive manufacturing method based on metal additive manufacturing using powder sheet (MAPS) is proposed, which leverages composite flexible films made of the feedstock of metal powder and a polymeric binder, aiming to extend the range of applicability of AlSi10Mg-based additive manufacturing technologies, for example, vehicle components. In situ high-speed imaging is used to explore the underlying manufacturing mechanisms of the proposed MAPS concept and investigate the laser–powder sheet interaction. In addition, a representative computational thermo-mechanical model was used to evaluate the substrate deformation due to the printing process, a critical aspect that must be minimized in order to transfer this technology to larger scale applications.

1.
A.
Tommasi
,
N.
Maillol
,
A.
Bertinetti
,
P.
Penchev
,
J.
Bajolet
,
F.
Gili
,
D.
Pullini
, and
D.
Busquets-Mataix
, “
Influence of surface preparation and heat treatment on mechanical behavior of hybrid aluminum parts manufactured by a combination of laser powder bed fusion and conventional manufacturing processes
,”
Metals
11
,
522
(
2021
).
2.
F.
Bruzzo
,
M. P. R.
Medapati
,
D.
Pullini
et al, “
Sustainable laser metal deposition of aluminum alloys for the automotive industry
,”
J. Laser Appl.
34
, 042004 (
2022
).
3.
D.
Bhaduri
,
P.
Penchev
,
K.
Essa
,
S.
Dimov
,
L. N.
Carter
,
C. I.
Pruncu
, and
D.
Pullini
, “
Evaluation of surface/interface quality, microstructure and mechanical properties of hybrid additive-subtractive aluminium parts
,”
CIRP Ann.
68
,
237
240
(
2019
).
4.
R.
Lupoi
,
W. M.
Abbott
,
R.
Senthamaraikannan
,
S.
McConnell
,
J.
Connolly
,
S.
Yin
, and
R. B.
Padamati
, “
Metal additive manufacturing via a novel composite material using powder and polymers formed in sheets
,”
CIRP Ann.
71, 181–184 (
2022
).
5.
W.
Zhang
,
X.
Lu
,
A.
Coban
et al, “
Powder sheet additive manufacturing of multi-material structures: Experimental and computational characterizations
,”
Compos. Part B: Eng.
272
,
111203
(
2024
).
6.
J.
Volpp
,
W.
Zhang
,
W.
Abbott
et al, “
Binder evaporation during powder sheet additive manufacturing
,” in
Solid Freeform Fabrication Symposium
,
Austin, Texas
, 14–18 August 2023 (University of Texas, Austin, TX,
2023
), pp.
324
328
.
7.
W.
Zhang
,
A.
Sasnauskas
,
A.
Coban
,
S.
Marola
,
R.
Casati
,
S.
Yin
,
R. P.
Babu
, and
R.
Lupoi
, “
Powder sheets additive manufacturing: Principles and capabilities for multi-material printing
,”
Addit. Manuf. Lett.
8
,
100187
(
2024
).
8.
S.
Patel
,
H.
Chen
,
M.
Vlasea
, and
Y.
Zou
, “
The influence of beam focus during laser powder bed fusion of a high reflectivity aluminium alloy—AlSi10Mg
,”
Addit. Manuf.
59
,
103112
(
2022
).
9.
H.
Kyogoku
and
T.-T.
Ikeshoji
, “
A review of metal additive manufacturing technologies: Mechanism of defects formation and simulation of melting and solidification phenomena in laser powder bed fusion process
,”
Mech. Eng. Rev.
7
, 19-00182 (
2019
).
10.
N.
Aboulkhair
, “Additive manufacture of an aluminium alloy: Processing, microstructure, and mechanical properties,” Ph.D. thesis, University of Nottingham, 2016.
11.
See https://www.comsol.com/ for the finite element method (FEM) software COMSOL Multiphysics®.
12.
M.
Leitner
,
T.
Leitner
,
A.
Schmon
,
K.
Aziz
, and
G.
Pottlacher
, “
Thermophysical properties of liquid aluminum
,”
Metall. Mater. Trans. A
48
,
3036
3045
(
2017
).
13.
T.
Mukherjee
,
H. L.
Wei
,
A.
De
, and
T.
DebRoy
, “
Heat and fluid flow in additive manufacturing—Part II: Powder bed fusion of stainless steel, and titanium, nickel and aluminum base alloys
,”
Comput. Mater. Sci.
150
,
369
380
(
2018
).
14.
C.
Liu
,
C.
Li
,
Z.
Zhang
,
S.
Sun
,
M.
Zeng
,
F.
Wang
,
Y.
Guo
, and
J.
Wang
, “
Modeling of thermal behavior and microstructure evolution during laser cladding of AlSi10Mg alloys
,”
Opt. Laser Technol.
123
,
105926
(
2020
).
15.
Y.
Agari
and
A.
Ueda
, “
Thermal conductivity of poly(vinyl chloride)/polycaprolactone blends
,”
J. Polym. Sci. Part B: Polym. Phys.
32
,
59
62
(
1994
).
16.
See supplementary material online for details of the computational modeling methods.

Supplementary Material

You do not currently have access to this content.