bibtype J - Journal Article
ARLID 0647376
utime 20260316082412.7
mtime 20260314235959.9
SCOPUS 85200393388
WOS 001290169400001
DOI 10.1016/j.cma.2024.117262
title (primary) (eng) Third medium finite element contact formulation for pneumatically actuated systems
specification
page_count 23 s.
media_type P
serial
ARLID cav_un_epca*0256442
ISSN 0045-7825
title Computer Methods in Applied Mechanics and Engineering
volume_id 431
publisher
name Elsevier
keyword Contact
keyword Second-order continuum formulation
keyword Third medium
keyword Pneumatic actuation
author (primary)
ARLID cav_un_auth*0505485
name1 Faltus
name2 O.
country CZ
garant K
author
ARLID cav_un_auth*0439612
name1 Horák
name2 Martin
institution UTIA-B
full_dept (cz) Matematická teorie rozhodování
full_dept Department of Decision Making Theory
department (cz) MTR
department MTR
country CZ
fullinstit Ústav teorie informace a automatizace AV ČR, v. v. i.
author
ARLID cav_un_auth*0479359
name1 Doškář
name2 M.
country CZ
author
ARLID cav_un_auth*0347118
name1 Rokoš
name2 O.
country CZ
source
url https://library.utia.cas.cz/separaty/2026/MTR/horak-0647376.pdf
source
url https://www.sciencedirect.com/science/article/pii/S0045782524005188?via%3Dihub
cas_special
abstract (eng) Active mechanical metamaterials are artificially engineered microstructures that can be externally controlled to exhibit novel and switchable mechanical behavior on the macroscopic scale. Pneumatically actuated variants of these metamaterials can then change their mechanical, acoustic, or other types of effective behavior in response to applied pressure with possible applications ranging from soft robotic actuators to phononic crystals. Such materials often undergo large deformations, leading to self-contact, which makes their modeling and generative design challenging. We propose to use the third medium method to simulate both pneumatic actuation and contact behavior. In contrast to existing formulations, we (i) combine together contact with pneumatic actuation in a single material model for the third medium, (ii) include more permissive regularization scheme for our model, penalizing gradient of pseudo-rotation and gradient of volume change only, and (iii) introduce pneumatic actuation as an exact value of Cauchy stress. Our formulation is energetically consistent and admits advanced finite element solvers, such as the modified Cholesky decomposition to detect instabilities. We demonstrate the behavior of the proposed formulation on several examples of traditional contact benchmarks, including a standard patch test, and validate it with experimental measurement.
result_subspec WOS
RIV IN
FORD0 10000
FORD1 10200
FORD2 10201
reportyear 2026
num_of_auth 4
inst_support RVO:67985556
permalink https://hdl.handle.net/11104/0376950
cooperation
ARLID cav_un_auth*0505484
name Czech Technical University in Prague, Faculty of Civil Engineering, Department of Mechanics
institution CVUT-FSV-MECH
country CZ
cooperation
ARLID cav_un_auth*0505486
name Mechanics of Materials, Department of Mechanical Engineering, Eindhoven University of Technology
country NL
confidential S
article_num 117262
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arlyear 2024
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mrcbU34 001290169400001 WOS
mrcbU63 cav_un_epca*0256442 Computer Methods in Applied Mechanics and Engineering 431 1 2024 0045-7825 1879-2138 Elsevier