Mesoscopic modelling of the dynamic compaction of a polymeric foam

Polymeric foams are widely used in many industrial fields as shock wave mitigators. They can be, for instance, interesting materials for the protection of structures against intense and brief mechanical loads. According to the literature, there are several models representing the macroscopic mechani...

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Hauptverfasser:	Pradel, P., Malaise, F., Bertron, I., Hébert, D.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Elastoplasticity Equations of state Mathematical models Mechanical properties Numerical models Plastic foam Plate impact tests Polyurethane foam Porous materials Velocity distribution
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creator	Pradel, P. Malaise, F. Bertron, I. Hébert, D.
description	Polymeric foams are widely used in many industrial fields as shock wave mitigators. They can be, for instance, interesting materials for the protection of structures against intense and brief mechanical loads. According to the literature, there are several models representing the macroscopic mechanical behavior of porous materials, but few take into account a direct influence of the microstructural parameters. However, the search for the optimal size and shape of porosities, and their distribution are essential data to improve the mitigation ability of foams. This article presents several 2D mesoscopic numerical models to study the dynamic behavior of a polyurethane foam subjected to plate impact loadings. We assume a linear periodically arranged circular cells structure, a staggered circular cells structure and a scattered distribution of circular cells. The matrix is made of solid polyurethane with a dynamic behavior represented using an equation of state and an elastoplastic constitutive law. Numerical computations of two plate impact experiments were performed. Velocity profiles measured by a VISAR at the rear surface of the foam and computed results obtained from a 2D Euler code are compared. Elastic precursor and compaction wave propagations through the foam are fairly well reproduced by models based on regular and staggered arrangements of cells. Experimental results are not better reproduced by using the model which assumes scattered circular cells.
doi_str_mv	10.1063/12.0020371
format	Conference Proceeding
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Matthew D. ; Jordan, Jennifer L.</contributor><creatorcontrib>Pradel, P. ; Malaise, F. ; Bertron, I. ; Hébert, D. ; Germann, Timothy C. ; Gleason, Arianna E. ; Armstrong, Michael R. ; Lane, J. Matthew D. ; Jordan, Jennifer L.</creatorcontrib><description>Polymeric foams are widely used in many industrial fields as shock wave mitigators. They can be, for instance, interesting materials for the protection of structures against intense and brief mechanical loads. According to the literature, there are several models representing the macroscopic mechanical behavior of porous materials, but few take into account a direct influence of the microstructural parameters. However, the search for the optimal size and shape of porosities, and their distribution are essential data to improve the mitigation ability of foams. This article presents several 2D mesoscopic numerical models to study the dynamic behavior of a polyurethane foam subjected to plate impact loadings. We assume a linear periodically arranged circular cells structure, a staggered circular cells structure and a scattered distribution of circular cells. The matrix is made of solid polyurethane with a dynamic behavior represented using an equation of state and an elastoplastic constitutive law. Numerical computations of two plate impact experiments were performed. Velocity profiles measured by a VISAR at the rear surface of the foam and computed results obtained from a 2D Euler code are compared. Elastic precursor and compaction wave propagations through the foam are fairly well reproduced by models based on regular and staggered arrangements of cells. 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Matthew D.</contributor><contributor>Jordan, Jennifer L.</contributor><creatorcontrib>Pradel, P.</creatorcontrib><creatorcontrib>Malaise, F.</creatorcontrib><creatorcontrib>Bertron, I.</creatorcontrib><creatorcontrib>Hébert, D.</creatorcontrib><title>Mesoscopic modelling of the dynamic compaction of a polymeric foam</title><title>AIP conference proceedings</title><description>Polymeric foams are widely used in many industrial fields as shock wave mitigators. They can be, for instance, interesting materials for the protection of structures against intense and brief mechanical loads. According to the literature, there are several models representing the macroscopic mechanical behavior of porous materials, but few take into account a direct influence of the microstructural parameters. However, the search for the optimal size and shape of porosities, and their distribution are essential data to improve the mitigation ability of foams. This article presents several 2D mesoscopic numerical models to study the dynamic behavior of a polyurethane foam subjected to plate impact loadings. We assume a linear periodically arranged circular cells structure, a staggered circular cells structure and a scattered distribution of circular cells. The matrix is made of solid polyurethane with a dynamic behavior represented using an equation of state and an elastoplastic constitutive law. Numerical computations of two plate impact experiments were performed. Velocity profiles measured by a VISAR at the rear surface of the foam and computed results obtained from a 2D Euler code are compared. Elastic precursor and compaction wave propagations through the foam are fairly well reproduced by models based on regular and staggered arrangements of cells. Experimental results are not better reproduced by using the model which assumes scattered circular cells.</description><subject>Elastoplasticity</subject><subject>Equations of state</subject><subject>Mathematical models</subject><subject>Mechanical properties</subject><subject>Numerical models</subject><subject>Plastic foam</subject><subject>Plate impact tests</subject><subject>Polyurethane foam</subject><subject>Porous materials</subject><subject>Velocity distribution</subject><issn>0094-243X</issn><issn>1551-7616</issn><fulltext>true</fulltext><rsrctype>conference_proceeding</rsrctype><creationdate>2023</creationdate><recordtype>conference_proceeding</recordtype><recordid>eNotkL1OwzAURi0EEqGw8ASRGFGKbxxfxyNUFJCKGGBgs2zHgVRJHOJ0yNvjqJ3ucM79-wi5BboGiuwB8jWlOWUCzkgCnEMmEPCcJJTKIssL9n1JrkLYR0kKUSbk6d0FH6wfGpt2vnJt2_Q_qa_T6del1dzrLgLru0HbqfH9QnQ6-Hbu3BhJ7XV3TS5q3QZ3c6or8rl9_tq8ZruPl7fN4y4bpOCZNtaBtLR0UCLXHGhdV2g1dQhGFmgqcEZYNKI0zlrMDUPkknETWwRlK3J3nDqM_u_gwqT2_jD2caHKS5SsiB9htO6PVrDNpJeL1TA2nR5nBVQtESnI1Ski9g-eA1gz</recordid><startdate>20230926</startdate><enddate>20230926</enddate><creator>Pradel, P.</creator><creator>Malaise, F.</creator><creator>Bertron, I.</creator><creator>Hébert, D.</creator><general>American Institute of Physics</general><scope>8FD</scope><scope>H8D</scope><scope>L7M</scope></search><sort><creationdate>20230926</creationdate><title>Mesoscopic modelling of the dynamic compaction of a polymeric foam</title><author>Pradel, P. ; Malaise, F. ; Bertron, I. ; Hébert, D.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-p975-abce19c08e1865a510ffd6ca0e61b946bd1eb7c6b78becc62b3665935b08e703</frbrgroupid><rsrctype>conference_proceedings</rsrctype><prefilter>conference_proceedings</prefilter><language>eng</language><creationdate>2023</creationdate><topic>Elastoplasticity</topic><topic>Equations of state</topic><topic>Mathematical models</topic><topic>Mechanical properties</topic><topic>Numerical models</topic><topic>Plastic foam</topic><topic>Plate impact tests</topic><topic>Polyurethane foam</topic><topic>Porous materials</topic><topic>Velocity distribution</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Pradel, P.</creatorcontrib><creatorcontrib>Malaise, F.</creatorcontrib><creatorcontrib>Bertron, I.</creatorcontrib><creatorcontrib>Hébert, D.</creatorcontrib><collection>Technology Research Database</collection><collection>Aerospace Database</collection><collection>Advanced Technologies Database with Aerospace</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Pradel, P.</au><au>Malaise, F.</au><au>Bertron, I.</au><au>Hébert, D.</au><au>Germann, Timothy C.</au><au>Gleason, Arianna E.</au><au>Armstrong, Michael R.</au><au>Lane, J. Matthew D.</au><au>Jordan, Jennifer L.</au><format>book</format><genre>proceeding</genre><ristype>CONF</ristype><atitle>Mesoscopic modelling of the dynamic compaction of a polymeric foam</atitle><btitle>AIP conference proceedings</btitle><date>2023-09-26</date><risdate>2023</risdate><volume>2844</volume><issue>1</issue><issn>0094-243X</issn><eissn>1551-7616</eissn><coden>APCPCS</coden><abstract>Polymeric foams are widely used in many industrial fields as shock wave mitigators. They can be, for instance, interesting materials for the protection of structures against intense and brief mechanical loads. According to the literature, there are several models representing the macroscopic mechanical behavior of porous materials, but few take into account a direct influence of the microstructural parameters. However, the search for the optimal size and shape of porosities, and their distribution are essential data to improve the mitigation ability of foams. This article presents several 2D mesoscopic numerical models to study the dynamic behavior of a polyurethane foam subjected to plate impact loadings. We assume a linear periodically arranged circular cells structure, a staggered circular cells structure and a scattered distribution of circular cells. The matrix is made of solid polyurethane with a dynamic behavior represented using an equation of state and an elastoplastic constitutive law. Numerical computations of two plate impact experiments were performed. Velocity profiles measured by a VISAR at the rear surface of the foam and computed results obtained from a 2D Euler code are compared. Elastic precursor and compaction wave propagations through the foam are fairly well reproduced by models based on regular and staggered arrangements of cells. Experimental results are not better reproduced by using the model which assumes scattered circular cells.</abstract><cop>Melville</cop><pub>American Institute of Physics</pub><doi>10.1063/12.0020371</doi><tpages>6</tpages></addata></record>
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source	AIP Journals Complete
subjects	Elastoplasticity Equations of state Mathematical models Mechanical properties Numerical models Plastic foam Plate impact tests Polyurethane foam Porous materials Velocity distribution
title	Mesoscopic modelling of the dynamic compaction of a polymeric foam
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