Abaqus Analysis User's Guide  


32.9.2 Line spring element library

Product: Abaqus/Standard  

References

Overview

This section provides a reference to the line spring elements available in Abaqus/Standard.

Element types

LS66-node general second-order line spring
LS3S3-node second-order line spring for use on a symmetry plane

Active degrees of freedom

1, 2, 3, 4, 5, 6

Additional solution variables

None.

Nodal coordinates required

X, Y, Z required at each node and, optionally, , , (direction cosines of the normal to the shell) at each node.

A user-defined normal definition (see Normal definitions at nodes, Section 2.1.4) can also be used to specify , , . If these are not specified, they are constructed as for all other shell elements—by averaging over the shell elements attached to each node.

Element property definition

The only element property used is the thickness; the number of integration points is ignored, since the elements work on the basis of section properties.

Input File Usage:          Use the following option to define line spring element properties:
*SHELL SECTION

Use the following option to define the depth of the crack as a function of position:

*SURFACE FLAW

Element-based loading

Distributed loads

Distributed loads are specified as described in Distributed loads, Section 34.4.3.

Three Gauss points are used for crack face pressure loading.


Load ID (*DLOAD):  HP

Units:  FL–2

Description:  Hydrostatic surface pressure on the crack faces, with magnitude varying linearly with the global Z-direction.


Load ID (*DLOAD):  P

Units:  FL–2

Description:  Surface pressure on the crack faces.

Element output

Nodes 1, 2, and 3 on the element define side B and nodes 4, 5, and 6 define side A (see Figure 32.9.2–1). The sign of the crack is defined by the surface of the shell from which the crack originates, which you identify when you define the depth of the crack (see Line spring elements for modeling part-through cracks in shells, Section 32.9.1). If the crack originates from the positive surface of the shell, sign(crack)=1.0; if the crack originates from the negative surface of the shell, sign(crack)=–1.0.

The vector is defined by the right-hand rule from the cross product of the tangent, , which is positive going from node 1 to node 3 of the element, and the normal, , defined when the coordinates are given (or by a user-defined normal definition). For element type LS3S the vector must point into the model (away from the symmetry plane). For element type LS6 the vector must point from side A to side B.

“Strains”

E11

Mode I opening displacement,

E22

Mode I opening rotation,


The following strains exist only for LS6:

E33

Mode II through thickness shear,

E12

Mode II rotation, (this strain plays no role)

E13

Mode III antiplane shear,

E23

Mode III opening rotation,


The conjugate forces and moments are available by requesting “stress” output.

The J-integral is provided at each integration point. If elastic-plastic material behavior is defined, the elastic and plastic parts of J are provided. The stress intensity factors, K, are also provided corresponding to the elastic parts of J.

Figure 32.9.2–1 Notation for line spring strains.

Nodes associated with the element

Numbering of integration points for output

Three points (these points are at the nodes) are used for integration and element output.

 
Abaqus Analysis User's Guide  
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32.9.2 Line spring element library

Product: Abaqus/Standard  

References
Your query was poorly formed. Please make corrections.

Overview

This section provides a reference to the line spring elements available in Abaqus/Standard.

Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.

Element types

LS66-node general second-order line spring
LS3S3-node second-order line spring for use on a symmetry plane

Your query was poorly formed. Please make corrections.
Active degrees of freedom

1, 2, 3, 4, 5, 6

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Your query was poorly formed. Please make corrections.
Additional solution variables

None.

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Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.

Nodal coordinates required

X, Y, Z required at each node and, optionally, , , (direction cosines of the normal to the shell) at each node.

A user-defined normal definition (see Normal definitions at nodes, Section 2.1.4) can also be used to specify , , . If these are not specified, they are constructed as for all other shell elements—by averaging over the shell elements attached to each node.

Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.

Element property definition

The only element property used is the thickness; the number of integration points is ignored, since the elements work on the basis of section properties.

Input File Usage:          Use the following option to define line spring element properties:
*SHELL SECTION

Use the following option to define the depth of the crack as a function of position:

*SURFACE FLAW

Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.

Element-based loading

Your query was poorly formed. Please make corrections.

Distributed loads

Distributed loads are specified as described in Distributed loads, Section 34.4.3.

Three Gauss points are used for crack face pressure loading.


Load ID (*DLOAD):  HP

Units:  FL–2

Description:  Hydrostatic surface pressure on the crack faces, with magnitude varying linearly with the global Z-direction.


Load ID (*DLOAD):  P

Units:  FL–2

Description:  Surface pressure on the crack faces.

Your query was poorly formed. Please make corrections.
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Element output

Nodes 1, 2, and 3 on the element define side B and nodes 4, 5, and 6 define side A (see Figure 32.9.2–1). The sign of the crack is defined by the surface of the shell from which the crack originates, which you identify when you define the depth of the crack (see Line spring elements for modeling part-through cracks in shells, Section 32.9.1). If the crack originates from the positive surface of the shell, sign(crack)=1.0; if the crack originates from the negative surface of the shell, sign(crack)=–1.0.

The vector is defined by the right-hand rule from the cross product of the tangent, , which is positive going from node 1 to node 3 of the element, and the normal, , defined when the coordinates are given (or by a user-defined normal definition). For element type LS3S the vector must point into the model (away from the symmetry plane). For element type LS6 the vector must point from side A to side B.

Your query was poorly formed. Please make corrections.

“Strains”

E11

Mode I opening displacement,

E22

Mode I opening rotation,


The following strains exist only for LS6:

E33

Mode II through thickness shear,

E12

Mode II rotation, (this strain plays no role)

E13

Mode III antiplane shear,

E23

Mode III opening rotation,


The conjugate forces and moments are available by requesting “stress” output.

The J-integral is provided at each integration point. If elastic-plastic material behavior is defined, the elastic and plastic parts of J are provided. The stress intensity factors, K, are also provided corresponding to the elastic parts of J.

Figure 32.9.2–1 Notation for line spring strains.

Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.
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Nodes associated with the element
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Your query was poorly formed. Please make corrections.

Numbering of integration points for output

Three points (these points are at the nodes) are used for integration and element output.

Your query was poorly formed. Please make corrections.
Your query was poorly formed. Please make corrections.