Torque-Based Temperature Control in Friction Stir Welding by Using a Digital Twin

Sigl, Martina E.; Bachmann, Andreas; Mair, Thomas; Zaeh, Michael F.

doi:10.3390/met10070914

Cited by 12 publications

(4 citation statements)

References 31 publications

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“…The control algorithm was implemented in a real-time system (MicroLabBox, dSPACE GmbH, Paderborn, Germany). Further information regarding the research machine setup is given in [12].…”

Section: Methodsmentioning

confidence: 99%

Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing

Sigl

Danninger

Bernauer

et al. 2022

KEM

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Friction Stir Additive Manufacturing (FSAM) is a novel process with which large-scale aluminum structures can be produced from high-strength alloys such as the 7xxx series. Due to the prevalence of these alloys in airplanes and rockets, the process offers high application potential, for example in fabricating stringers and stiffeners. The building process in FSAM is characterized by sequentially stacking and friction stir lap welding (FSLW) metal sheets. Before adding the next layer, the surface is machined (i.e., by milling). So far, this is a necessary step to enable gap-free welding of the layers, which results in increased costs and reduced layer heights. The investigations described in this paper were aimed at improving the weld surface quality to enable defect-free FSAM without the additional machining step. For this, FSLW was conducted using different welding tools. The resulting welds were evaluated based on superficial and internal characteristics as well as the mechanical properties (shear strength). With a welding tool in which both a rotating and a stationary shoulder were combined, defect-free weld seams with a mean underfill and a mean flash height of 0.07 mm were produced. In a subsequent study, it was proven that defect-free FSAM without surface machining is possible up to the fifth layer using the combined welding tool.

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“…The control algorithm was implemented in a real-time system (MicroLabBox, dSPACE GmbH, Paderborn, Germany). Further information regarding the research machine setup is given in [12].…”

Section: Methodsmentioning

confidence: 99%

Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing

Sigl

Danninger

Bernauer

et al. 2022

KEM

Self Cite

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“…Chen et al [20] introduced a digital twin modeling approach for FSW using sensor-based numerical simulation, achieving the synchronization of the simulation and physical process with a high temporal precision for effective cyber-physical integration. Sigl et al [21] proposed a new welding temperature feedback system for the FSW process, using a digital twin and an adaptive controller. It demonstrates improved weld quality through experimental validation.…”

Section: Introductionmentioning

confidence: 99%

Digital Twin Virtual Welding Approach of Robotic Friction Stir Welding Based on Co-Simulation of FEA Model and Robotic Model

Chen,

Zong,

Kang

et al. 2024

Sensors

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Robotic friction stir welding has become an important research direction in friction stir welding technology. However, the low stiffness of serial industrial robots leads to substantial, difficult-to-measure end-effector deviations under the welding forces during the friction stir welding process, impacting the welding quality. To more effectively measure the deviations in the end-effector, this study introduces a digital twin model based on the five-dimensional digital twin theory. The model obtains the current data of the robot and six-axis force sensor and calculates the real-time end deviations using the robot model. Based on this, a virtual welding model was realized by integrating the FEA model with the digital twin model using a co-simulation approach. This model achieves pre-process simulation by iteratively cycling through the simulated force from the FEA model and the end displacement from the robot model. The virtual welding model effectively predicts the welding outcomes with a mere 6.9% error in lateral deviation compared to actual welding, demonstrating its potential in optimizing welding parameters and enhancing accuracy and quality. Employing digital twin models to monitor, simulate, and optimize the welding process can reduce risks, save costs, and improve efficiency, providing new perspectives for optimizing robotic friction stir welding processes.

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“…Beispielsweise ermöglicht dies auch Schweißnähte auf Freiformflächen. Die hohe Nachgiebigkeit von Industrierobotern im Vergleich zu konventionellen Portalmaschinen führt dazu, dass eine Regelung der Prozesskraft vorteilhaft ist [6]. Ein Prozessmodell zur Vorhersage der auftretenden Prozesskräfte ermöglicht die Optimierung der Prozessparameter sowie die Auslegung einer entsprechenden Regelung.…”

Section: Introductionunclassified

Prozessmodellierung für das Rührreibschweißen/Process modeling of friction stir welding – Semi-analytical process model of robotic friction stir welding

Kamm¹,

Mesmer²,

Lechler³

et al. 2023

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Das Rührreibschweißen ist ein modernes Fügeverfahren, das aufgrund zahlreicher Vorteile gegenüber konventionellen Schweißmethoden vor allem für den Leichtbau interessant ist. Die Modellierung des Verfahrens ermöglicht sowohl ein tiefer gehendes Verständnis als auch die Entwicklung von Methoden zur Prozessoptimierung. In diesem Beitrag wird ein Modell zur Vorhersage der auftretenden Prozesskräfte während der Eintauchphase beim roboterbasierten Rührreibschweißen von Polycarbonat vorgestellt. Friction stir welding is a modern joining process that is particularly interesting for lightweight construction due to numerous advantages over conventional welding methods. Modeling the process provides both a deeper understanding of the process as well as the development of methods for process optimization. This paper presents a model to predict the process forces occurring during the plunging phase in robotic friction stir welding of polycarbonate.

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Torque-Based Temperature Control in Friction Stir Welding by Using a Digital Twin

Cited by 12 publications

References 31 publications

Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing

Efficient Build-Up of High-Strength Aluminum Structures Using Friction Stir Additive Manufacturing

Digital Twin Virtual Welding Approach of Robotic Friction Stir Welding Based on Co-Simulation of FEA Model and Robotic Model

Prozessmodellierung für das Rührreibschweißen/Process modeling of friction stir welding – Semi-analytical process model of robotic friction stir welding

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