Jan-Lukas Archut scite author profile

Jan-Lukas Archut

5Publications

4Citation Statements Received

14Citation Statements Given

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RWTH Aachen University

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A Study of the Mechanical Response of Nonwovens Excited by Plate Vibration

et al. 2022

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Nonwovens are a type of textile that possess a wide range of unique properties, such as lightweight and damping characteristics, which make them suitable for many applications as in medicine and engineering. In this study, the focus lies on the mechanical response of nonwovens as a multiphase porous layer excited by an underlying vibrating plate. The material properties of the nonwovens are characterized via laboratory measurements applied to different samples. In particular, a dynamic analysis of the underlying thin plate is carried out to obtain its eigenmodes and, thus, the maximum response. These eigenmodes are then utilized in the boundary conditions in an advanced numerical porous media model to simulate the dynamic response of the anisotropic fibrous material. To understand the coupled processes in the fibrous textile material, a three-dimensional initial-boundary-value problem of porous media dynamics is introduced. The numerical results demonstrate the capability of the proposed model to realize the interplay between the pore-air pressure and the effective stresses during nonwovens vibration and, thus, the role of the pore air in vibration-induced fiber-fiber friction reduction as well as the effectiveness of the nonwovens in the dissipation of the kinetic energy, i.e., damping propagating acoustic waves.

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Haptic simulation and synthesis of mechanisms

Paris

Archut

Hüsing

et al. 2020

Mechanism and Machine Theory

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Estimation of Damage Value of SAE4340 Steel and 5A02 Aluminium Alloy

Archut

Vinyas²,

Upadhyaya

2018

Int. J. Automot. Mech. Eng.

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Damage value of two materials SAE 4340 steel and 5A02 aluminium alloy was estimated using Gurson-Tvergaard-Needleman (GTN) model and BhattacharyaEllingwood model. Damage prediction using the GTN model demands for value of porosity which can be obtained by simulating monotonic tensile tests with finite element method (FEM). Damage value obtained from FEM was compared with the damage value obtained analytically through Bhattacharya-Ellingwood model. Predicted damage values by the two models were differing in an acceptable limit considering the applicability of various definitions for damage.

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Haptic Simulation of Mechanisms

Paris

Archut

Hüsing

et al. 2019

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A Computationally Efficient Multibody Simulation Model of a Suspension System Including Elastokinematic Properties

Archut

Cleven

Wahle

et al. 2022

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Jan-Lukas Archut

A Study of the Mechanical Response of Nonwovens Excited by Plate Vibration

Haptic simulation and synthesis of mechanisms

Estimation of Damage Value of SAE4340 Steel and 5A02 Aluminium Alloy

Haptic Simulation of Mechanisms

A Computationally Efficient Multibody Simulation Model of a Suspension System Including Elastokinematic Properties

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