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==1 Title, abstract and keywords==
+
==Summary==
  
Your document should start with a concise and informative title. Titles are often used in information-retrieval systems. Avoid abbreviations and formulae where possible. Capitalize the first word of the title.
+
Lagrangian finite element methods emerged in fluid dynamics when the deficiencies of the Eulerian
 +
methods in treating free surface flows (or generally domains undergoing large shape deformations)
 +
were faced. Their advantage relies upon natural tracking of boundaries and interfaces, a feature
 +
particularly important for interaction problems. Another attractive feature is the absence of the
 +
convective term in the fluid momentum equations written in the Lagrangian framework resulting
 +
in a symmetric discrete system matrix, an important feature in case iterative solvers are utilized.
 +
Unfortunately, the lack of the control over the mesh distortions is a major drawback of Lagrangian
 +
methods. In order to overcome this, a Lagrangian method must be equipped with an efficient
 +
re-meshing tool.
  
Provide a maximum of 6 keywords, and avoiding general and plural terms and multiple concepts (avoid, for example, 'and', 'of'). Be sparing with abbreviations: only abbreviations firmly established in the field should be used. These keywords will be used for indexing purposes.
 
  
An abstract is required for every document; it should succinctly summarize the reason for the work, the main findings, and the conclusions of the study. Abstract is often presented separately from the article, so it must be able to stand alone. For this reason, references and hyperlinks should be avoided. If references are essential, then cite the author(s) and year(s). Also, non-standard or uncommon abbreviations should be avoided, but if essential they must be defined at their first mention in the abstract itself.
+
This work aims at developing formulations and algorithms where maximum advantage of using
 +
Lagrangian finite element fluid formulations can be taken. In particular we concentrate our attention
 +
at fluid-structure interaction and thermally coupled applications, most of which originate from
 +
practical “real-life” problems. Two fundamental options are investigated - coupling two Lagrangian
 +
formulations (e.g. Lagrangian fluid and Lagrangian structure) and coupling the Lagrangian and
 +
Eulerian fluid formulations.
 +
In the first part of this work the basic concepts of the Lagrangian fluids, the so-called Particle
 +
Finite Element Method (PFEM) [1], [2] are presented. These include nodal variable storage, mesh
 +
re-construction using Delaunay triangulation/tetrahedralization and alpha shape-based method for
 +
identification of the computational domain boundaries. This shall serve as a general basis for all the
 +
further developments of this work.
  
==2 The main text==
 
  
You can enter and format the text of this document by selecting the ‘Edit’ option in the menu at the top of this frame or next to the title of every section of the document. This will give access to the visual editor. Alternatively, you can edit the source of this document (Wiki markup format) by selecting the ‘Edit source’ option.
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Next we show how an incompressible Lagrangian fluid can be used in a partitioned fluid-structure
 +
interaction context. We present an improved Dirichlet-Neumann strategy for coupling the incompressible
 +
Lagrangian fluid with a rigid body. This is finally applied to an industrial problem dealing
 +
with the sea-landing of a satellite capsule.
  
Most of the documents in Scipedia are written in English (write your manuscript in American or British English, but not a mixture of these). Anyhow, specific publications in other languages can be published in Scipedia. In any case, the documents published in other languages must have an abstract written in English.
 
  
===2.1 Subsections===
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In the following, an extension of the method is proposed to allow dealing with fluid-structure
 +
problems involving general flexible structures. The method developed takes advantage of the symmetry
 +
of the discrete system matrix and by introducing a slight fluid compressibility allows to treat
 +
the fluid-structure interaction problem efficiently in a monolithic way. Thus, maximum benefit from
 +
using a similar description for both the fluid (updated Lagrangian) and the solid (total Lagrangian)
 +
is taken. We show next that the developed monolithic approach is particularly useful for modeling
 +
the interaction with light-weight structures. The validation of the method is done by means of comparison with experimental results and with a number of different methods found in literature.
  
Divide your article into clearly defined and numbered sections. Subsections should be numbered 1.1, 1.2, etc. and then 1.1.1, 1.1.2, ... Use this numbering also for internal cross-referencing: do not just refer to 'the text'. Any subsection may be given a brief heading. Capitalize the first word of the headings.
 
  
===2.2 General guidelines===
+
The second part of this work aims at coupling Lagrangian and Eulerian fluid formulations. The
 +
application area is the modeling of polymers under fire conditions. This kind of problem consists
 +
of modeling the two subsystems (namely the polymer and the surrounding air) and their thermomechanical
 +
interaction. A compressible fluid formulation based on the Eulerian description is used for
 +
modeling the air, whereas a Lagrangian description is used for the polymer. For the surrounding air
 +
we develop a model based upon the compressible Navier-Stokes equations. Such choice is dictated by
 +
the presence of high temperature gradients in the problem of interest, which precludes the utilization
 +
of the Boussinesq approximation. The formulation is restricted to the sub-sonic flow regime, meeting
 +
the requirement of the problem of interest. The mechanical interaction of the subsystems is modeled
 +
by means of a one-way coupling, where the polymer velocities are imposed on the interface elements
 +
of the Eulerian mesh in a weak way. Thermal interaction is treated by means of the energy equation
 +
solved on the Eulerian mesh, containing thermal properties of both the subsystems, namely air and
 +
polymer. The developments of the second part of this work do not pretend to be by any means
 +
exhaustive; for instance, radiation and chemical reaction phenomena are not considered. Rather we
 +
make the first step in the direction of modeling the complicated thermo-mechanical problem and
 +
provide a general framework that in the future can be enriched with a more detailed and sophisticated
 +
models. However this would affect only the individual modules, preserving the overall architecture
 +
of the solution procedure unchanged.
  
Some general guidelines that should be followed in your manuscripts are:
 
  
:*  Avoid hyphenation at the end of a line.
+
Each chapter concludes with the example section that includes both the validation tests and/or
 +
applications to the real-life problems. The final chapter highlights the achievements of the work and
 +
defines the future lines of research that naturally evolve from the results of this work.
  
:*  Symbols denoting vectors and matrices should be indicated in bold type. Scalar variable names should normally be expressed using italics.
 
  
:*  Use decimal points (not commas); use a space for thousands (10 000 and above).
+
<pdf>Media:Draft_Samper_363862394_4237_M121optimizado.pdf</pdf>
 
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:*  Follow internationally accepted rules and conventions. In particular use the international system of units (SI). If other quantities are mentioned, give their equivalent in SI.
+
 
+
===2.3 Tables, figures, lists and equations===
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+
Please insert tables as editable text and not as images. Tables should be placed next to the relevant text in the article. Number tables consecutively in accordance with their appearance in the text (<span id='cite-_Ref382560620'></span>[[#_Ref382560620|table 1]], table 2, etc.) and place any table notes below the table body. Be sparing in the use of tables and ensure that the data presented in them do not duplicate results described elsewhere in the article.
+
 
+
<span id='_Ref382560620'></span>
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{| style="margin: 1em auto 1em auto;border: 1pt solid black;border-collapse: collapse;"
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|-
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| style="text-align: center;"|Thickness
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| style="text-align: center;"|3.175 mm
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|-
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| style="text-align: center;"|Young Modulus
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| style="text-align: center;"|12.74 MPa
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|-
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| style="text-align: center;"|Poisson coefficient
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| style="text-align: center;"|0.25
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|-
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| style="text-align: center;"|Density
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| style="text-align: center;"|1107 kg/m<sup>3</sup>
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|}
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<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
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<span style="text-align: center; font-size: 75%;">Table 1: Material properties</span></div>
+
 
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Graphics may be inserted directly in the document and positioned as they should appear in the final manuscript.
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<span id='_Ref448852946'></span>
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<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
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[[Image:Scipedia.gif|center|480px]]
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</div>
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<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
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<span style="text-align: center; font-size: 75%;">Figure 1. Scipedia logo.</span></div>
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Number the figures according to their sequence in the text (<span id='cite-_Ref448852946'></span>[[#_Ref448852946|figure 1]], figure 2, etc.). Ensure that each illustration has a caption. A caption should comprise a brief title. Keep text in the illustrations themselves to a minimum but explain all symbols and abbreviations used. Try to keep the resolution of the figures to a minimum of 300 dpi. If a finer resolution is required, the figure can be inserted as supplementary material
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+
For tabular summations that do not deserve to be presented as a table, lists are often used. Lists may be either numbered or bulleted. Below you see examples of both.
+
 
+
1. The first entry in this list
+
 
+
2. The second entry
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2.1. A subentry
+
 
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3. The last entry
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* A bulleted list item
+
 
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* Another one
+
 
+
You may choose to number equations for easy referencing. In that case they must be numbered consecutively with Arabic numerals in parentheses on the right hand side of the page. Below is an example of formulae that should be referenced as eq. <span id='cite-_Ref424030152'></span>[[#_Ref424030152|(1)]].
+
 
+
{| style="width: 100%;"
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|-
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| style="vertical-align: top;"| <math>{\nabla }^{2}\phi =0</math>
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| style="text-align: right;"|<span id='_Ref424030152'></span>
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(1)
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|}
+
 
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===2.4 Supplementary material===
+
 
+
Supplementary material can be inserted to support and enhance your article. This includes video material, animation sequences, background datasets, computational models, sound clips and more. In order to ensure that your material is directly usable, please provide the files with a preferred maximum size of 50 MB. Please supply a concise and descriptive caption for each file.
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+
==3 Bibliography==
+
 
+
<span id='_Ref449344604'></span>
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Citations in text will follow a citation-sequence system (i.e. sources are numbered by order of reference so that the first reference cited in the document is [<span id='cite-1'></span>[[#1|1]]], the second [<span id='cite-2'></span>[[#2|2]]], and so on) with the number of the reference in square brackets. Once a source has been cited, the same number is used in all subsequent references. If the numbers are not in a continuous sequence, use commas (with no spaces) between numbers. If you have more than two numbers in a continuous sequence, use the first and last number of the sequence joined by a hyphen (e.g. [<span id='cite-1'></span>[[#1|1]], <span id='cite-3'></span>[[#3|3]]] or [<span id='cite-2'></span>[[#2|2]]-<span id='cite-2'></span>[[#4|4]]]).
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<span id='_Ref449084254'></span>
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You should ensure that all references are cited in the text and that the reference list. References should preferably refer to documents published in Scipedia. Unpublished results should not be included in the reference list, but can be mentioned in the text. The reference data must be updated once publication is ready. Complete bibliographic information for all cited references must be given following the standards in the field (IEEE and ISO 690 standards are recommended). If possible, a hyperlink to the referenced publication should be given. See examples for Scipedia’s articles [<span id='cite-1'></span>[[#1|1]]], other publication articles [<span id='cite-2'></span>[[#2|2]]], books [<span id='cite-3'></span>[[#3|3]]], book chapter [<span id='cite-4'></span>[[#4|4]]], conference proceedings [<span id='cite-5'></span>[[#5|5]]], and online documents [<span id='cite-6'></span>[[#6|6]]], shown in references section below.
+
 
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==4 Acknowledgments==
+
 
+
Acknowledgments should be inserted at the end of the document, before the references section.
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==5 References==
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+
<span id='_Ref449083719'></span>
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<div id="1"></div>
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[[#cite-1|[1]]] Author, A. and Author, B. (Year) Title of the article. Title of the Publication. Article code. Available: [http://www.scipedia.com/ucode. http://www.scipedia.com/ucode.]
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<div id="2"></div>
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[[#cite-2|[2]]] Author, A. and Author, B. (Year) Title of the article. Title of the Publication. Volume number, first page-last page.
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<div id="3"></div>
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[[#cite-3|[3]]] Author, C. (Year). Title of work: Subtitle (edition.). Volume(s). Place of publication: Publisher.
+
 
+
<div id="4"></div>
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[[#cite-4|[4]]] Author of Part, D. (Year). Title of chapter or part. In A. Editor & B. Editor (Eds.), Title: Subtitle of book (edition, inclusive page numbers). Place of publication: Publisher.
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<div id="5"></div>
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[[#cite-5|[5]]] Author, E. (Year, Month date). Title of the article. In A. Editor, B. Editor, and C. Editor. Title of published proceedings. Paper presented at title of conference, Volume number, first page-last page. Place of publication.
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<div id="6"></div>
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[[#cite-6|[6]]] Institution or author. Title of the document. Year. [Online] (Date consulted: day, month and year). Available: [http://www.scipedia.com/document.pdf http://www.scipedia.com/document.pdf]. [Accessed day, month and year].
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Latest revision as of 12:27, 11 July 2018

Summary

Lagrangian finite element methods emerged in fluid dynamics when the deficiencies of the Eulerian methods in treating free surface flows (or generally domains undergoing large shape deformations) were faced. Their advantage relies upon natural tracking of boundaries and interfaces, a feature particularly important for interaction problems. Another attractive feature is the absence of the convective term in the fluid momentum equations written in the Lagrangian framework resulting in a symmetric discrete system matrix, an important feature in case iterative solvers are utilized. Unfortunately, the lack of the control over the mesh distortions is a major drawback of Lagrangian methods. In order to overcome this, a Lagrangian method must be equipped with an efficient re-meshing tool.


This work aims at developing formulations and algorithms where maximum advantage of using Lagrangian finite element fluid formulations can be taken. In particular we concentrate our attention at fluid-structure interaction and thermally coupled applications, most of which originate from practical “real-life” problems. Two fundamental options are investigated - coupling two Lagrangian formulations (e.g. Lagrangian fluid and Lagrangian structure) and coupling the Lagrangian and Eulerian fluid formulations. In the first part of this work the basic concepts of the Lagrangian fluids, the so-called Particle Finite Element Method (PFEM) [1], [2] are presented. These include nodal variable storage, mesh re-construction using Delaunay triangulation/tetrahedralization and alpha shape-based method for identification of the computational domain boundaries. This shall serve as a general basis for all the further developments of this work.


Next we show how an incompressible Lagrangian fluid can be used in a partitioned fluid-structure interaction context. We present an improved Dirichlet-Neumann strategy for coupling the incompressible Lagrangian fluid with a rigid body. This is finally applied to an industrial problem dealing with the sea-landing of a satellite capsule.


In the following, an extension of the method is proposed to allow dealing with fluid-structure problems involving general flexible structures. The method developed takes advantage of the symmetry of the discrete system matrix and by introducing a slight fluid compressibility allows to treat the fluid-structure interaction problem efficiently in a monolithic way. Thus, maximum benefit from using a similar description for both the fluid (updated Lagrangian) and the solid (total Lagrangian) is taken. We show next that the developed monolithic approach is particularly useful for modeling the interaction with light-weight structures. The validation of the method is done by means of comparison with experimental results and with a number of different methods found in literature.


The second part of this work aims at coupling Lagrangian and Eulerian fluid formulations. The application area is the modeling of polymers under fire conditions. This kind of problem consists of modeling the two subsystems (namely the polymer and the surrounding air) and their thermomechanical interaction. A compressible fluid formulation based on the Eulerian description is used for modeling the air, whereas a Lagrangian description is used for the polymer. For the surrounding air we develop a model based upon the compressible Navier-Stokes equations. Such choice is dictated by the presence of high temperature gradients in the problem of interest, which precludes the utilization of the Boussinesq approximation. The formulation is restricted to the sub-sonic flow regime, meeting the requirement of the problem of interest. The mechanical interaction of the subsystems is modeled by means of a one-way coupling, where the polymer velocities are imposed on the interface elements of the Eulerian mesh in a weak way. Thermal interaction is treated by means of the energy equation solved on the Eulerian mesh, containing thermal properties of both the subsystems, namely air and polymer. The developments of the second part of this work do not pretend to be by any means exhaustive; for instance, radiation and chemical reaction phenomena are not considered. Rather we make the first step in the direction of modeling the complicated thermo-mechanical problem and provide a general framework that in the future can be enriched with a more detailed and sophisticated models. However this would affect only the individual modules, preserving the overall architecture of the solution procedure unchanged.


Each chapter concludes with the example section that includes both the validation tests and/or applications to the real-life problems. The final chapter highlights the achievements of the work and defines the future lines of research that naturally evolve from the results of this work.


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