%0 Journal Article %1 Capobianco&Harsch&Eugster&Leine2021 %A Capobianco, G. %A Harsch, J. %A Eugster, S. R. %A Leine, R. I. %D 2021 %J International Journal for Numerical Methods in Engineering %K eugster from:rleine imported inm journal leine project_capobianco project_harsch_nonsmooth %N 22 %P 6497--6526 %R https://doi.org/10.1002/nme.6801 %T A nonsmooth generalized-alpha method for mechanical systems with frictional contact %V 122 %X In this article, the existing nonsmooth generalized-alpha method for the simulation of mechanical systems with frictionless contacts, modeled as unilateral constraints, is extended to systems with frictional contacts. On that account, we complement the unilateral constraints with set-valued Coulomb-type friction laws. Moreover, we devise a set of benchmark systems, which can be used to validate numerical schemes for mechanical systems with frictional contacts. Finally, this set of benchmarks is used to numerically assert the properties striven for during the derivation of the presented scheme. Specifically, we show that the presented scheme can reproduce the dynamics of the frictional contact adequately and no numerical penetration of the contacting bodies arises—a big issue for most popular time-stepping schemes such as the one of Moreau. Moreover, we demonstrate that the presented scheme performs well for multibody systems containing flexible parts and that it allows general parametrizations such as the use of unit quaternions for the rotation of rigid bodies.

@article{Capobianco&Harsch&Eugster&Leine2021, abstract = {In this article, the existing nonsmooth generalized-alpha method for the simulation of mechanical systems with frictionless contacts, modeled as unilateral constraints, is extended to systems with frictional contacts. On that account, we complement the unilateral constraints with set-valued Coulomb-type friction laws. Moreover, we devise a set of benchmark systems, which can be used to validate numerical schemes for mechanical systems with frictional contacts. Finally, this set of benchmarks is used to numerically assert the properties striven for during the derivation of the presented scheme. Specifically, we show that the presented scheme can reproduce the dynamics of the frictional contact adequately and no numerical penetration of the contacting bodies arises—a big issue for most popular time-stepping schemes such as the one of Moreau. Moreover, we demonstrate that the presented scheme performs well for multibody systems containing flexible parts and that it allows general parametrizations such as the use of unit quaternions for the rotation of rigid bodies.}, added-at = {2022-03-22T14:39:07.000+0100}, author = {Capobianco, G. and Harsch, J. and Eugster, S. R. and Leine, R. I.}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2c840ce57e9d87af02742534d0602f7e6/inm}, doi = {https://doi.org/10.1002/nme.6801}, interhash = {f1317623c53977f73df1ce5cbcd253b8}, intrahash = {c840ce57e9d87af02742534d0602f7e6}, journal = {International Journal for Numerical Methods in Engineering}, keywords = {eugster from:rleine imported inm journal leine project_capobianco project_harsch_nonsmooth}, number = 22, pages = {6497--6526}, timestamp = {2023-07-21T12:25:29.000+0200}, title = {A nonsmooth generalized-alpha method for mechanical systems with frictional contact}, volume = 122, year = 2021 }