Impact wear stress distribution and total deformation on dental material under chewing cycles: 3D finite element analysis
Background: The finite element solution estimates have been improving in recent years in biomedical applications. This method provides many advantages to researchers such as specimen force distribution, total deformation, and strain energy. The data obtained after the experimental methods can be exa...
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Format: | Article |
Language: | English |
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Wolters Kluwer Medknow Publications
2022-01-01
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Series: | Journal of Dental Research and Review |
Subjects: | |
Online Access: | http://www.jdrr.org/article.asp?issn=2348-2915;year=2022;volume=9;issue=2;spage=159;epage=164;aulast=Yilmaz |
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author | Efe Çetin Yilmaz |
author_facet | Efe Çetin Yilmaz |
author_sort | Efe Çetin Yilmaz |
collection | DOAJ |
description | Background: The finite element solution estimates have been improving in recent years in biomedical applications. This method provides many advantages to researchers such as specimen force distribution, total deformation, and strain energy. The data obtained after the experimental methods can be examined for the finite element solutions. Aim: Thus, this study aims to a finite element study of total deformation and strain energy on dental material under chewing impact force simulation after experimental study; prediction of maximum and minimum stress distribution. Materials and Methods: In this study, impact wear stress distribution and total deformation analyses were performed on test samples with different geometries. A cylindrical specimen with a diameter of 12 mm and a square geometry specimen with a size of 8 mm was designed for chewing test procedures. The chewing force was applied to the samples over a while and the effect of this force on the wear surface of the sample was investigated through chewing test procedures. Results: In this study obtained data, the chewing force showed a more homogeneous distribution in the cylindrical sample than in the square sample. Conclusion: In addition, it was observed that the concentration of strength mechanism was present at the time of the maximum chewing force of the sample with square geometry. |
first_indexed | 2024-04-11T10:55:48Z |
format | Article |
id | doaj.art-daeb9ec5b16e4566aa9c8887649f33fd |
institution | Directory Open Access Journal |
issn | 2348-2915 2348-3172 |
language | English |
last_indexed | 2024-04-11T10:55:48Z |
publishDate | 2022-01-01 |
publisher | Wolters Kluwer Medknow Publications |
record_format | Article |
series | Journal of Dental Research and Review |
spelling | doaj.art-daeb9ec5b16e4566aa9c8887649f33fd2022-12-22T04:28:46ZengWolters Kluwer Medknow PublicationsJournal of Dental Research and Review2348-29152348-31722022-01-019215916410.4103/jdrr.jdrr_35_22Impact wear stress distribution and total deformation on dental material under chewing cycles: 3D finite element analysisEfe Çetin YilmazBackground: The finite element solution estimates have been improving in recent years in biomedical applications. This method provides many advantages to researchers such as specimen force distribution, total deformation, and strain energy. The data obtained after the experimental methods can be examined for the finite element solutions. Aim: Thus, this study aims to a finite element study of total deformation and strain energy on dental material under chewing impact force simulation after experimental study; prediction of maximum and minimum stress distribution. Materials and Methods: In this study, impact wear stress distribution and total deformation analyses were performed on test samples with different geometries. A cylindrical specimen with a diameter of 12 mm and a square geometry specimen with a size of 8 mm was designed for chewing test procedures. The chewing force was applied to the samples over a while and the effect of this force on the wear surface of the sample was investigated through chewing test procedures. Results: In this study obtained data, the chewing force showed a more homogeneous distribution in the cylindrical sample than in the square sample. Conclusion: In addition, it was observed that the concentration of strength mechanism was present at the time of the maximum chewing force of the sample with square geometry.http://www.jdrr.org/article.asp?issn=2348-2915;year=2022;volume=9;issue=2;spage=159;epage=164;aulast=Yilmazchewing simulationdental materialfinite elementstress distributionwear |
spellingShingle | Efe Çetin Yilmaz Impact wear stress distribution and total deformation on dental material under chewing cycles: 3D finite element analysis Journal of Dental Research and Review chewing simulation dental material finite element stress distribution wear |
title | Impact wear stress distribution and total deformation on dental material under chewing cycles: 3D finite element analysis |
title_full | Impact wear stress distribution and total deformation on dental material under chewing cycles: 3D finite element analysis |
title_fullStr | Impact wear stress distribution and total deformation on dental material under chewing cycles: 3D finite element analysis |
title_full_unstemmed | Impact wear stress distribution and total deformation on dental material under chewing cycles: 3D finite element analysis |
title_short | Impact wear stress distribution and total deformation on dental material under chewing cycles: 3D finite element analysis |
title_sort | impact wear stress distribution and total deformation on dental material under chewing cycles 3d finite element analysis |
topic | chewing simulation dental material finite element stress distribution wear |
url | http://www.jdrr.org/article.asp?issn=2348-2915;year=2022;volume=9;issue=2;spage=159;epage=164;aulast=Yilmaz |
work_keys_str_mv | AT efecetinyilmaz impactwearstressdistributionandtotaldeformationondentalmaterialunderchewingcycles3dfiniteelementanalysis |