Sophie Grabmann scite author profile

Sophie Grabmann

5Publications

42Citation Statements Received

45Citation Statements Given

How they've been cited

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Affiliations

Technical University of Munich, Fraunhofer Institute for Machine Tools and Forming Technology, Max Planck Computing and Data Facility

Publications

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Design, evaluation, and implementation of a model-predictive control approach for a force control in friction stir welding processes

Meyer

Bernauer

Grabmann

et al. 2020

Prod. Eng. Res. Devel.

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Friction press joining is an innovative joining process for bonding plastics and metals without additives in an overlap configuration. A model-based approach for the design of an axial force controller for friction press joining is presented in this paper. A closed-loop control was set up on the machining center, in which the plunge depth was used as the controlling variable. In order to support the controller development, a nonparametric dynamic process model was developed via a data-based system identification. Subsequently, various control concepts were designed off-line and verified on the actual system. The most promising ones, a proportional controller, a controller created with the pole placement method, and a model predictive controller, were selected for further investigations. The three controllers were re-evaluated and compared by means of a defined input of disturbance variables and reference variables. The model predictive control (MPC) approach as well as the proportional controller were also tested for model uncertainties. For this purpose, different material combinations were joined using the different controllers. Thereby, it was shown that the MPC controller resulted in smaller standard deviations when encountering large model uncertainties. The investigations demonstrated the high potential of friction press joining of plastic components with metals. The results form the basis for future research, whereby the force can be specified as an additional input parameter instead of the plunge depth.

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Laser welding of current collector foil stacks in battery production–mechanical properties of joints welded with a green high-power disk laser

Grabmann

Kriegler

Harst

et al. 2021

Int J Adv Manuf Technol

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The qualification of production systems that enable reliable and stable production processes is a major challenge in manufacturing large-format lithium-ion batteries. During cell assembly, the electrode sheets of the anode and the cathode are stacked, and are electrically contacted by a welding process. It was shown that laser beam welding employing a beam source in the green wavelength range is a promising joining approach in terms of high productivity. Therefore, the influence of the process parameters, such as the laser power, the welding speed, the pulse frequency, and the pulse duration, on the weld seam quality was investigated. Particular emphasis was placed on the mechanical strength of the weld seam. Statistically planned experiments were used to determine feasible parameter sets for welding the most common current collectors of lithium-ion battery electrodes, copper (Cu), and aluminum (Al). The influence of the individual process parameters on the tensile shear force was evaluated. Stacks of 40 metal foils were welded with a thin metal sheet in lap joint configuration. Based on an analysis of the requirements for minimum mechanical seam strengths, this study confirms that laser beam welding using a green high-power disk source is an auspicious process for the internal contacting of lithium-ion batteries.

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Laser beam welding of copper foil stacks using a green high power disk laser

2020

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Processing of lithium metal for the production of post-lithium-ion batteries using a pulsed nanosecond fiber laser

Kriegler¹,

Nguyen²,

Tomcic³

et al. 2022

Results in Materials

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Enhancing laser-based contacting of aluminum current collector foils for the production of lithium-ion batteries using a nanosecond pulsed fiber laser

et al. 2022

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Sophie Grabmann

Design, evaluation, and implementation of a model-predictive control approach for a force control in friction stir welding processes

Laser welding of current collector foil stacks in battery production–mechanical properties of joints welded with a green high-power disk laser

Laser beam welding of copper foil stacks using a green high power disk laser

Processing of lithium metal for the production of post-lithium-ion batteries using a pulsed nanosecond fiber laser

Enhancing laser-based contacting of aluminum current collector foils for the production of lithium-ion batteries using a nanosecond pulsed fiber laser

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