TY - GEN
T1 - Temperature-controlled friction stir welding process of Al-Cu joints with complex geometries
AU - Grabmann, Sophie
AU - Zens, Amanda
AU - Marstatt, Roland
AU - Haider, Ferdinand
AU - Zaeh, Michael F.
N1 - Publisher Copyright:
© 2019 Author(s).
PY - 2019/7/2
Y1 - 2019/7/2
N2 - Multi-material joints, for instance of aluminum and copper, are of great industrial interest for the production of components used in modern electrical applications. Conventional fusion welding techniques are not suitable to weld such joints as a multitude of brittle intermetallic phases are formed upon joint solidification. Friction stir welding (FSW) is a promising solid state process for producing mixed material joints. Here, the layer thickness of the intermetallic compound (IMC) is reduced to nanometer scale. The IMC layer thickness depends on the welding temperature and can be correlated with the joint properties. Temperature-controlled FSW has been shown to produce welds with homogeneous and repeatable intermetallic layers for simple geometries in lap joint configuration. However, in real applications, the components may have complex geometries or non-linear welding paths may be employed. This can lead to heat accumulation and inconsistent weld properties. The implementation of a temperature-controlled FSW process is a promising method to improve the weld homogeneity in such workpieces. In this study, aluminum and copper were welded in lap joint configuration. A complex part geometry was designed in order to induce heat accumulation in designated areas during a conventional FSW process. Initial experiments were performed using a fixed rotational speed. The variance in the stir zone temperature was measured in-situ by a thermocouple placed in the probe. Subsequently, the degree of heat accumulation was determined. Next, joints of the same geometry were welded using a temperature-controlled FSW process set to five different welding temperatures. The control system adjusts the rotational speed of the tool to maintain a constant welding temperature. It was shown that the set temperature in the weld zone was held constant, even in parts with complex geometries. The weld seams were examined by shear tensile tests, optical microscopy and scanning electron microscopy (SEM) of the interface.
AB - Multi-material joints, for instance of aluminum and copper, are of great industrial interest for the production of components used in modern electrical applications. Conventional fusion welding techniques are not suitable to weld such joints as a multitude of brittle intermetallic phases are formed upon joint solidification. Friction stir welding (FSW) is a promising solid state process for producing mixed material joints. Here, the layer thickness of the intermetallic compound (IMC) is reduced to nanometer scale. The IMC layer thickness depends on the welding temperature and can be correlated with the joint properties. Temperature-controlled FSW has been shown to produce welds with homogeneous and repeatable intermetallic layers for simple geometries in lap joint configuration. However, in real applications, the components may have complex geometries or non-linear welding paths may be employed. This can lead to heat accumulation and inconsistent weld properties. The implementation of a temperature-controlled FSW process is a promising method to improve the weld homogeneity in such workpieces. In this study, aluminum and copper were welded in lap joint configuration. A complex part geometry was designed in order to induce heat accumulation in designated areas during a conventional FSW process. Initial experiments were performed using a fixed rotational speed. The variance in the stir zone temperature was measured in-situ by a thermocouple placed in the probe. Subsequently, the degree of heat accumulation was determined. Next, joints of the same geometry were welded using a temperature-controlled FSW process set to five different welding temperatures. The control system adjusts the rotational speed of the tool to maintain a constant welding temperature. It was shown that the set temperature in the weld zone was held constant, even in parts with complex geometries. The weld seams were examined by shear tensile tests, optical microscopy and scanning electron microscopy (SEM) of the interface.
UR - http://www.scopus.com/inward/record.url?scp=85068833747&partnerID=8YFLogxK
U2 - 10.1063/1.5112568
DO - 10.1063/1.5112568
M3 - Conference contribution
AN - SCOPUS:85068833747
T3 - AIP Conference Proceedings
BT - Proceedings of the 22nd International ESAFORM Conference on Material Forming, ESAFORM 2019
A2 - Arrazola, Pedro
A2 - Saenz de Argandona, Eneko
A2 - Otegi, Nagore
A2 - Mendiguren, Joseba
A2 - Saez de Buruaga, Mikel
A2 - Madariaga, Aitor
A2 - Galdos, Lander
PB - American Institute of Physics Inc.
T2 - 22nd International ESAFORM Conference on Material Forming, ESAFORM 2019
Y2 - 8 May 2019 through 10 May 2019
ER -