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Mechanics of Paperboard Packages : Performance at Short Term Static Loading

Beldie, Liliana LU (2001) In TVSM-3000 200(TVSM-3059).
Abstract
Paper 1
Several problems emerge when a paperboard package is modeled by means of the nite element method. One of the issues that one has to deal with is the constitutive model of the paperboard. Paperboard and paper in general are
orthotropic materials, which means that constitutive parameters in three orthogonal directions must be determined. Furthermore, the geometry of paper
sheets makes it dicult to measure the out-of-plane elastic and plastic parameters. In addition, in the case of paperboard, the material parameters of
the dierent layers must be determined in order to obtain an accurate material
model. This report comprises two parts. In the rst part, the implementation of
a constitutive model for paperboard... (More)
Paper 1
Several problems emerge when a paperboard package is modeled by means of the nite element method. One of the issues that one has to deal with is the constitutive model of the paperboard. Paperboard and paper in general are
orthotropic materials, which means that constitutive parameters in three orthogonal directions must be determined. Furthermore, the geometry of paper
sheets makes it dicult to measure the out-of-plane elastic and plastic parameters. In addition, in the case of paperboard, the material parameters of
the dierent layers must be determined in order to obtain an accurate material
model. This report comprises two parts. In the rst part, the implementation of
a constitutive model for paperboard by means of the commercial computational
programe ABAQUS was discussed. The second part consists of a presentation
of some experimental work performed for the validation of the results from the
computer simulations.

Paper 2
The aim of this study was to analyse the mechanical behaviour of paperboard packages subjected to static compressive loads. The study was divided into three parts and experiments and nite element analysis conducted for eachpart. First, a panel of paperboard was subjected to edge compressive loadingas a means of checking the material model. Second, the package was cut intosegments and each segment subjected to compression in order to determine thecontribution of the dierent parts to the overall behaviour of the package. Third, a whole package loaded in compression was studied. In the nite element simulations,the paperboard was modeled as an orthotropic, linear, elastic-plasticlaminate. The study utilized a non-linear nite element analysis based on theplasticity of the material and large displacements. The results show that the
middle segment of the package exhibits a higher stiness than that of the upper
and lower package segments and that of the whole package, which leads to the
conclusion that the low initial stiness of the package is a consequence of the
low stiness of the upper and lower corners, i.e. of the horizontal creases.

Paper 3
The study of a paperboard package subjected to vertical compression presents several complicated issues. A nite element simulation of such a package has to take into account both the material non-linearity and the geometrical nonlinearity due to large deformations. Previous work concerning the nite element modelling of a whole package has shown that it is dicult to achieve the correct stiness in the nite element model without adopting a more accurate model for the creases in the paperboard package. This paper proposes a new approach in modelling the paperboard creases, using a special nite element for the creases. The element is of a feedback link type, giving stiness as a function of displacement at its nodes. Experiments were conducted in order to determine the behaviour of the creases during compression and the results were used to implemen the special element with the capability of behaving as a crease. The element was tested with good results in the models of a creased panel, a package segment and a whole package. The proposed approach to modelling the creases opens up new possibilities for the design of creases and, consequently, of the whole package. (Less)
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author
supervisor
organization
publishing date
type
Thesis
publication status
published
subject
in
TVSM-3000
volume
200
issue
TVSM-3059
edition
1
pages
59 pages
publisher
Division of Structural Mechanics, LTH
ISSN
0281-667
language
English
LU publication?
yes
id
acd79620-0f9d-480c-a8b5-f5c82d3ae16f
date added to LUP
2023-09-14 15:53:23
date last changed
2023-10-16 09:46:54
@misc{acd79620-0f9d-480c-a8b5-f5c82d3ae16f,
  abstract     = {{Paper 1<br/>Several problems emerge when a paperboard package is modeled by means of the nite element method. One of the issues that one has to deal with is the constitutive model of the paperboard. Paperboard and paper in general are<br/>orthotropic materials, which means that constitutive parameters in three orthogonal directions must be determined. Furthermore, the geometry of paper<br/>sheets makes it dicult to measure the out-of-plane elastic and plastic parameters. In addition, in the case of paperboard, the material parameters of<br/>the dierent layers must be determined in order to obtain an accurate material<br/>model. This report comprises two parts. In the rst part, the implementation of<br/>a constitutive model for paperboard by means of the commercial computational<br/>programe ABAQUS was discussed. The second part consists of a presentation<br/>of some experimental work performed for the validation of the results from the<br/>computer simulations.<br/><br/>Paper 2<br/>The aim of this study was to analyse the mechanical behaviour of paperboard packages subjected to static compressive loads. The study was divided into three parts and experiments and nite element analysis conducted for eachpart. First, a panel of paperboard was subjected to edge compressive loadingas a means of checking the material model. Second, the package was cut intosegments and each segment subjected to compression in order to determine thecontribution of the dierent parts to the overall behaviour of the package. Third, a whole package loaded in compression was studied. In the nite element simulations,the paperboard was modeled as an orthotropic, linear, elastic-plasticlaminate. The study utilized a non-linear nite element analysis based on theplasticity of the material and large displacements. The results show that the<br/>middle segment of the package exhibits a higher stiness than that of the upper<br/>and lower package segments and that of the whole package, which leads to the<br/>conclusion that the low initial stiness of the package is a consequence of the<br/>low stiness of the upper and lower corners, i.e. of the horizontal creases.<br/><br/>Paper 3<br/>The study of a paperboard package subjected to vertical compression presents several complicated issues. A nite element simulation of such a package has to take into account both the material non-linearity and the geometrical nonlinearity due to large deformations. Previous work concerning the nite element modelling of a whole package has shown that it is dicult to achieve the correct stiness in the nite element model without adopting a more accurate model for the creases in the paperboard package. This paper proposes a new approach in modelling the paperboard creases, using a special nite element for the creases. The element is of a feedback link type, giving stiness as a function of displacement at its nodes. Experiments were conducted in order to determine the behaviour of the creases during compression and the results were used to implemen the special element with the capability of behaving as a crease. The element was tested with good results in the models of a creased panel, a package segment and a whole package. The proposed approach to modelling the creases opens up new possibilities for the design of creases and, consequently, of the whole package.}},
  author       = {{Beldie, Liliana}},
  issn         = {{0281-667}},
  language     = {{eng}},
  note         = {{Licentiate Thesis}},
  number       = {{TVSM-3059}},
  publisher    = {{Division of Structural Mechanics, LTH}},
  series       = {{TVSM-3000}},
  title        = {{Mechanics of Paperboard Packages : Performance at Short Term Static Loading}},
  url          = {{https://lup.lub.lu.se/search/files/160554327/web3059.pdf}},
  volume       = {{200}},
  year         = {{2001}},
}