Plate impact shock experiments and numerical modeling of lightweight adobe masonry material

Plate impact shock experiments and numerical modeling of lightweight adobe masonry material

In this contribution, we summarize and extend the experimental and numerical investigation of the shock response of lightweight adobe masonry, previously published in [C. Sauer et al., J. Dyn. Behav. Mater. (submitted)]. It is demonstrated that inverse planar plate impact (PPI) experiments are feasi...

Full description

Bibliographic Details
Main Authors: Sauer Christoph, Bagusat Frank, Heine Andreas, Werner Riedel
Format: Article
Language:English
Published: EDP Sciences 2018-01-01
Series:EPJ Web of Conferences
Online Access:https://doi.org/10.1051/epjconf/201818301017
id doaj-4a2db56794c541fa8b76666c6a99d543
record_format Article
spelling doaj-4a2db56794c541fa8b76666c6a99d5432021-08-02T06:00:42ZengEDP SciencesEPJ Web of Conferences2100-014X2018-01-011830101710.1051/epjconf/201818301017epjconf_dymat2018_01017Plate impact shock experiments and numerical modeling of lightweight adobe masonry materialSauer ChristophBagusat FrankHeine AndreasWerner RiedelIn this contribution, we summarize and extend the experimental and numerical investigation of the shock response of lightweight adobe masonry, previously published in [C. Sauer et al., J. Dyn. Behav. Mater. (submitted)]. It is demonstrated that inverse planar plate impact (PPI) experiments are feasible for lightweight adobe. From the obtained free surface velocity time curves, a linear shock velocity vs. particle velocity relation is derived within the measured range of particle velocities. Numerical simulations of these curves show that the employed homogenous numerical model is capable of properly treating the shock response of this porous, inhomogeneous, and low-strength material. This numerical model is then applied to the example of the ballistic impact of steel spheres on targets consisting of one lightweight adobe brick. The experimentally obtained penetration craters are properly reproduced by the simulated target damage. Moreover, we find good agreement of the measured and simulated residual velocities within the presented range of impact velocities.https://doi.org/10.1051/epjconf/201818301017
collection DOAJ
language English
format Article
sources DOAJ
author Sauer Christoph
Bagusat Frank
Heine Andreas
Werner Riedel
spellingShingle Sauer Christoph
Bagusat Frank
Heine Andreas
Werner Riedel
Plate impact shock experiments and numerical modeling of lightweight adobe masonry material
EPJ Web of Conferences
author_facet Sauer Christoph
Bagusat Frank
Heine Andreas
Werner Riedel
author_sort Sauer Christoph
title Plate impact shock experiments and numerical modeling of lightweight adobe masonry material
title_short Plate impact shock experiments and numerical modeling of lightweight adobe masonry material
title_full Plate impact shock experiments and numerical modeling of lightweight adobe masonry material
title_fullStr Plate impact shock experiments and numerical modeling of lightweight adobe masonry material
title_full_unstemmed Plate impact shock experiments and numerical modeling of lightweight adobe masonry material
title_sort plate impact shock experiments and numerical modeling of lightweight adobe masonry material
publisher EDP Sciences
series EPJ Web of Conferences
issn 2100-014X
publishDate 2018-01-01
description In this contribution, we summarize and extend the experimental and numerical investigation of the shock response of lightweight adobe masonry, previously published in [C. Sauer et al., J. Dyn. Behav. Mater. (submitted)]. It is demonstrated that inverse planar plate impact (PPI) experiments are feasible for lightweight adobe. From the obtained free surface velocity time curves, a linear shock velocity vs. particle velocity relation is derived within the measured range of particle velocities. Numerical simulations of these curves show that the employed homogenous numerical model is capable of properly treating the shock response of this porous, inhomogeneous, and low-strength material. This numerical model is then applied to the example of the ballistic impact of steel spheres on targets consisting of one lightweight adobe brick. The experimentally obtained penetration craters are properly reproduced by the simulated target damage. Moreover, we find good agreement of the measured and simulated residual velocities within the presented range of impact velocities.
url https://doi.org/10.1051/epjconf/201818301017
work_keys_str_mv AT sauerchristoph plateimpactshockexperimentsandnumericalmodelingoflightweightadobemasonrymaterial
AT bagusatfrank plateimpactshockexperimentsandnumericalmodelingoflightweightadobemasonrymaterial
AT heineandreas plateimpactshockexperimentsandnumericalmodelingoflightweightadobemasonrymaterial
AT wernerriedel plateimpactshockexperimentsandnumericalmodelingoflightweightadobemasonrymaterial
_version_ 1721240718272364544

Similar Items