Users:General FEM Analysis/Elements Reference/Membrane NURBS

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!INT_TYPE_MEMBRANE_NURBS
 
!INT_TYPE_MEMBRANE_NURBS
 
|FULL or USER
 
|FULL or USER
|type of numerical integration. With FULL the integration rule is automatically chosen, with USER it can manually be defined. For USER also the parameters GAUSS_U and GAUSS_V have to be defined.
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|Type of numerical integration. With FULL the integration rule is automatically chosen, with USER it can manually be defined. For USER also the parameters GAUSS_U and GAUSS_V have to be defined.
 
|-
 
|-
 
!GAUSS_U, GAUSS_V
 
!GAUSS_U, GAUSS_V
 
|''int''
 
|''int''
|number of integration points in u and v-direction, respectively. In case of INT_TYPE_MEMBRANE_NURBS = FULL this specification is not required.
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|Number of integration points in u and v-direction, respectively. In case of INT_TYPE_MEMBRANE_NURBS = FULL this specification is not required.
 
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!A_X, A_Y, A_Z  
 
!A_X, A_Y, A_Z  
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SIG12
 
SIG12
 
|''reals''
 
|''reals''
|Prestress state of the membrane. (see description below)
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|Prestress state of the membrane. (see description of Membrane1-element)
 
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|-
 
|}
 
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Latest revision as of 09:01, 13 January 2017

Contents

General Description

Element Type

  • This membrane element is an isotropic plane stress element accounting for prestress
  • The membrane element neglects bending stiffness
  • The ratio of the thickness and the lengths in the other two directions is much smaller than one ( t/Lx << 1 and t/Ly << 1), the membrane is reduced to its mid-surface
  • The thickness is constant over the element

An extensive description of the element can be found in [1]


Input Parameters

Parameter Description

Compulsory Parameters
Parameter Values, Default(*) Description
MAT EL-MAT int Number for the used Material

e.g. MAT=EL-MAT 1

THICKNESS real Thickness of the membrane
INT_TYPE_MEMBRANE_NURBS FULL or USER Type of numerical integration. With FULL the integration rule is automatically chosen, with USER it can manually be defined. For USER also the parameters GAUSS_U and GAUSS_V have to be defined.
GAUSS_U, GAUSS_V int Number of integration points in u and v-direction, respectively. In case of INT_TYPE_MEMBRANE_NURBS = FULL this specification is not required.
A_X, A_Y, A_Z

B_X, B_Y, B_Z

Definition of the principal directions of the surface to define the prestress directions, only applied with anisotropic prestress conditions. (see description of Membrane1-element)
SIG11

SIG22 SIG12

reals Prestress state of the membrane. (see description of Membrane1-element)

Example of a Complete Input Block

EL-PROP 1 : MEMBRANE_NURBS
  MAT= EL-MAT 1
  THICKNESS= 1.0
  INT_TYPE_MEMBRANE_NURBS = FULL !or USER
  PROJECTED_PRESTRESS=1 SIG11=400.0     SIG22=400.0      SIG12=0.0
  A_X=1.0     A_Y=0.0    A_Z=0.0   !AREA FOR THE DEFINITION OF THE PRESTRESS
  B_X=0.0     B_Y=1.0    B_Z=0.0   !VECTOR A AND VECTOR B DEFINE THE AREA

The possibility for oriented anisotropic prestress fields is foreseen, yet no distortion control as for the classical FEM Membrane1-element is implemented.

Tests and Benchmarks

The element Membrane_NURBS has successfully been applied in 3D in various geometrically non-linear static applications, as well as in form-finding.

Benchmark examples

  • form-finding of a four-point sail with with B-Rep edge cables and elastic columns as supports: ..\examples\benchmark_examples\isogeometric\iga_formfinding_4point_with_trusses\cbm_4PointSailwTrusses.txt
  • static geometrically non-linear analysis of a prestressed single-patch membrane with fixed boundaries: ..\examples\benchmark_examples\isogeometric\iga_membrane_nln_1\cbm_iga_membrane_nln_1.txt

References

  1. B. Philipp, M. Breitenberger, I. D’Auria, R.Wüchner, and K.-U. Bletzinger. "Integrated design and analysis of structural membranes using the Isogeometric B-Rep Analysis." In: Computer Methods in AppliedMechanics and Engineering 303 (May 2016), pp. 312–340. DOI: 10.1016/j.cma.2016.02.003.




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