김경종
18 KiB
| Load ID (*DLOAD) | Abaqus/CAE Load/Interaction | Units | Description |
| P2 | Line load | $FL^{-1}$ | Force per unit length in beam local 2-direction. |
| P1NU | Line load | $FL^{-1}$ | Nonuniform force per unit length in beam local 1-direction with magnitude supplied via user subroutine DLOAD in Abaqus/Standard and VDLOAD in Abaqus/Explicit. (Only for beams in space.) |
| P2NU | Line load | $FL^{-1}$ | Nonuniform force per unit length in beam local 2-direction with magnitude supplied via user subroutine DLOAD in Abaqus/Standard and VDLOAD in Abaqus/Explicit. |
| $ROTA^{(S)}$ | Rotational body force | $T^{-2}$ | Rotary acceleration load (magnitude is input as $\alpha$ , where $\alpha$ is the rotary acceleration). |
| $ROTDYNF^{(S)}$ | Not supported | $T^{-1}$ | Rotordynamic load (magnitude is input as $\omega$ , where $\omega$ is the angular velocity). |
The following load types are available only for PIPE elements:
| Load ID (*DLOAD) | Abaqus/CAE Load/Interaction | Units | Description |
| HPI | Pipe pressure | $FL^{-2}$ | Hydrostatic internal pressure (closed-end condition), varying linearly with the global Z-coordinate. |
| HPE | Pipe pressure | $FL^{-2}$ | Hydrostatic external pressure (closed-end condition), varying linearly with the global Z-coordinate. |
| PI | Pipe pressure | $FL^{-2}$ | Uniform internal pressure (closed-end condition). |
| PE | Pipe pressure | $FL^{-2}$ | Uniform external pressure (closed-end condition). |
| Load ID(*DLOAD) | Abaqus/CAELoad/Interaction | Units | Description |
| PENU | Pipe pressure | $FL^{-2}$ | Nonuniform external pressure (closed-end condition) with magnitude supplied via user subroutine DLOAD. |
| PINU | Pipe pressure | $FL^{-2}$ | Nonuniform internal pressure (closed-end condition) with magnitude supplied via user subroutine DLOAD. |
Abaqus/Aqua loads
Abaqus/Aqua loads are specified as described in “Abaqus/Aqua analysis,” Section 6.11.1. They are not available for open-section beams and do not apply to beams that are defined to have additional inertia due to immersion in fluid (see “Additional inertia due to immersion in fluid” in “Beam section behavior,” Section 29.3.5). In Abaqus/Explicit, Aqua loads can be applied only on linear beam and pipe elements.
| Load ID(*CLOAD/*DLOAD) | Abaqus/CAELoad/Interaction | Units | Description |
| $FDD^{(A)}$ | Not supported | $FL^{-1}$ | Transverse fluid drag load. |
| $FD1^{(A)}$ | Not supported | F | Fluid drag force on the first end of the beam (node 1). |
| $FD2^{(A)}$ | Not supported | F | Fluid drag force on the second end of the beam (node 2 or node 3). |
| $FDT^{(A)}$ | Not supported | $FL^{-1}$ | Tangential fluid drag load. |
| $FI^{(A)}$ | Not supported | $FL^{-1}$ | Transverse fluid inertia load. |
| $FI1^{(A)}$ | Not supported | F | Fluid inertia force on the first end of the beam (node 1). |
| $FI2^{(A)}$ | Not supported | F | Fluid inertia force on the second end of the beam (node 2 or node 3). |
| $PB^{(A)}$ | Not supported | $FL^{-1}$ | Buoyancy load (closed-end condition). |
| $WDD^{(A)}$ | Not supported | $FL^{-1}$ | Transverse wind drag load. |
| $WD1^{(A)}$ | Not supported | F | Wind drag force on the first end of the beam (node 1). |
| Load ID(*CLOAD/*DLOAD) | Abaqus/CAELoad/Interaction | Units | Description |
| WD2(A) | Not supported | F | Wind drag force on the second end of the beam (node 2 or node 3). |
Foundations
Foundations are available only in Abaqus/Standard and are specified as described in “Element foundations,” Section 2.2.2.
| Load ID(*FOUNDATION) | Abaqus/CAE Load/Interaction | Units | Description |
| $FX^{(S)}$ | Not supported | $FL^{-2}$ | Stiffness per unit length in global X-direction. |
| $FY^{(S)}$ | Not supported | $FL^{-2}$ | Stiffness per unit length in global Y-direction. |
| $FZ^{(S)}$ | Not supported | $FL^{-2}$ | Stiffness per unit length in global Z-direction (only for beams in space). |
| $F1^{(S)}$ | Not supported | $FL^{-2}$ | Stiffness per unit length in beam local 1-direction (only for beams in space). |
| $F2^{(S)}$ | Not supported | $FL^{-2}$ | Stiffness per unit length in beam local 2-direction. |
Surface-based loading
Distributed loads
Surface-based distributed loads are specified as described in “Distributed loads,” Section 34.4.3.
| Load ID(*DSLOAD) | Abaqus/CAELoad/Interaction | Units | Description |
| P | Pressure | $FL^{-1}$ | Force per unit length in beam local 2-direction. The distributed surface force is positive in the direction opposite to the surface normal. |
| PNU | Pressure | $FL^{-1}$ | Nonuniform force per unit length in beam local 2-direction with magnitude supplied via user subroutine DLOAD in |
Load ID (*DSLOAD)
Abaqus/CAE Load/Interaction
Units
Description
Abaqus/Standard and VDLOAD in Abaqus/Explicit. The distributed surface force is positive in the direction opposite to the surface normal.
Incident wave loading
Incident wave loading is also available for these elements, with some restrictions. See “Acoustic and shock loads,” Section 34.4.6.
Element output
See “Beam cross-section library,” Section 29.3.9, for a description of the beam element output locations.
Stress, strain, and other tensor components
Stress and other tensors (including strain tensors) are available for elements with displacement degrees of freedom. All tensors, except for meshed sections, have the same components. For example, the stress components are as follows:
S11 Axial stress.
S22 Hoop stress (available only for pipe elements).
S33 Radial stress (available only for thick-walled pipe elements).
S12 Shear stress caused by torsion (available only for beam-type elements in space). This component is not available when thin-walled, open sections are employed (I-section, L-section, and arbitrary open section).
Stress and strain for section points for meshed sections
S11 Axial stress.
S12 Shear stress along the second cross-section axis caused by shear force and, for beam elements in space, torsion.
S13 Shear stress along the first cross-section axis caused by shear force and torsion (available only for beams in space).
Section forces, moments, and transverse shear forces
SF1 Axial force.
SF2 Transverse shear force in the local 2-direction (not available for B23, B23H, B33, B33H).
SF3 Transverse shear force in the local 1-direction (available only for beams in space, not available for B33, B33H).
| SM1 | Bending moment about the local 1-axis. |
| SM2 | Bending moment about the local 2-axis (available only for beams in space). |
| SM3 | Twisting moment about the beam axis (available only for beams in space). |
| BIMOM | Bimoment due to warping (available only for open-section beams in space). |
| ESF1 | Effective axial force for beams subjected to pressure loading (available for all Abaqus/Standard stress/displacement analysis types except response spectrum and random response). |
See “Beam element formulation,” Section 3.5.2 of the Abaqus Theory Guide, for the definitions of the section forces and moments.
The effective axial section force for beams subjected to pressure loading is defined as
\mathrm{ESF1} = \mathrm{SF1} + p _ {e} A _ {e} - p _ {i} A _ {i},
where p _ { e } and p _ { i } are the external and the internal pressures, respectively, and A _ { e } and A _ { i } are the external and the internal pipe areas as defined in the load definition. The pressure loadings (with a closedend condition) that are relevant to the effective axial force are external/internal pressure (load types PE, PI, PENU, and PINU); external/internal hydrostatic pressure (load types HPE and HPI); and, in an Abaqus/Aqua environment, buoyancy pressure, PB, which includes dynamic pressure if waves are present.
For beams that are not subjected to pressure loading, the effective axial force ESF1 is equal to the usual axial force SF1.
Section strains, curvatures, and transverse shear strains
| SE1 | Axial strain. |
| SE2 | Transverse shear strain in the local 2-direction (not available for B23, B23H, B33, and B33H). |
| SE3 | Transverse shear strain in the local 1-direction (available only for beams in space, not available for B33 and B33H). |
| SK1 | Curvature change about the local 1-axis. |
| SK2 | Curvature change about the local 2-axis (available only for beams in space). |
| SK3 | Twist of the beam (available only for beams in space). |
| BICURV | Bicurvature due to warping (available only for open-section beams in space). |
Node ordering on elements
natural_image
Simple line segment connecting two numbered points (no text or symbols)
2 - node element
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1 2 3
3 - node element
For beams in space an additional node may be given after a beam element’s connectivity (in the element definition—see “Element definition,” Section 2.2.1) to define the approximate direction of the first crosssection axis, . See “Beam element cross-section orientation,” Section 29.3.4, for details.
Numbering of integration points for output
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1 × 1 2
2 - node element
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1 1 2 2 3
3 - node quadratic element
flowchart
graph TD
1 -->|1| 2
2 -->|2| 3
3 -->|3| 2
2 - node cubic element
29.3.9 BEAM CROSS-SECTION LIBRARY
Products: Abaqus/Standard Abaqus/Explicit Abaqus/CAE
References
• “Beam modeling: overview,” Section 29.3.1
• “Choosing a beam cross-section,” Section 29.3.2
• “Frame elements,” Section 29.4.1
• “Defining profiles,” Section 12.2.2 of the Abaqus/CAE User’s Guide
Overview
This section describes the standard beam sections that are available in Abaqus/Standard and Abaqus/Explicit for use with beam elements. A subset of the standard beam sections are available for use with frame elements in Abaqus/Standard. General (nonstandard) beam cross-sections can be defined as described in “Choosing a beam cross-section,” Section 29.3.2.
Arbitrary, thin-walled, open and closed sections
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A 1 t_AB 2 B 3 4 5 t_BC C 6 t_CD 7 D 1 2
Example of arbitrary section
The arbitrary section type is provided to permit modeling of simple, arbitrary, thin-walled, open and closed sections. You specify the section by defining a series of points in the thin-walled cross-section of the beam; these points are then linked by straight line segments, each of which is integrated numerically
along the axis of the section so that the section can be used together with nonlinear material behavior. An independent thickness is associated with each of the segments making up the arbitrary section.
Warping effects are included when an arbitrary section is used with open-section beam elements (available only in Abaqus/Standard).
Input File Usage: Use either of the following options:
*BEAM SECTION, SECTION=ARBITRARY
*BEAM GENERAL SECTION, SECTION=ARBITRARY
Abaqus/CAE Usage: Property module: Create Profile: Arbitrary
Restrictions
• An arbitrary section can be used only with beams in space (three-dimensional models).
• An arbitrary section should not be used to define closed sections with branches, multiply connected closed sections, or open sections with disconnected regions.
• For each individual segment of an arbitrary section there is no bending stiffness about the line joining the end points of the segment. Thus, an arbitrary section cannot be made up of only one segment.
Geometric input data
First, give the number of segments, the local coordinates of points A and B, and the thickness of the segment connecting these two vertices. Then, proceed by giving the local coordinates of point C and the thickness of the segment between points B and C, followed by the local coordinates of point D and the thickness of the segment between points C and D, and so on. An arbitrary section can contain as many segments as needed. All coordinates of section definition points are given in the local 1–2 axis system of the section.
The origin of the local 1–2 axis system is the beam node, and the position of this node used to define the section is arbitrary: it does not have to be the centroid.
Defining a closed section
A closed section is defined by making the starting and end points coincident. Only single-cell closed sections can be modeled accurately. Closed sections with fins (single branches attached to the cell) cannot be modeled with the capability in Abaqus.
Defining an arbitrary section with discontinuous branches
If the arbitrary section contains discontinuous sections (branches), a section with zero thickness should be used to return from the ending point of the branch to the starting point of the subsequent section. This zero thickness section should always coincide with a nonzero thickness section. For an example of an I-section defined using this method, see “Buckling analysis of beams,” Section 1.2.1 of the Abaqus Benchmarks Guide.
Default integration
A three-point Simpson integration scheme is used for each segment making up the section. For more detailed integration, specify several segments along each straight portion of the section.
Default stress output points if a beam section integrated during the analysis is used
The vertices of the section.
Temperature and field variable input at specific points through beam sections integrated during the analysis
Give the value at each vertex of the section (points A, B, C, D in the figure).
Box section
Input File Usage: Use one of the following options:
*BEAM SECTION, SECTION=BOX
*BEAM GENERAL SECTION, SECTION=BOX
*FRAME SECTION, SECTION=BOX
Abaqus/CAE Usage: Property module: Create Profile: Box
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2 5 4 t1 t2 b 3 2 t3 t4 1 a 5 4 1 3 2 1
Default integration, beam in a plane
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2 8 7 6 9 10 t2 t1 4 b 11 t3 t4 3 1 12 13 14 15 16 a 2 1
Default integration, beam in space
Geometric input data
\textbf {a}, \textbf {b}, t _ {1}, t _ {2}, t _ {3}, t _ {4}
Default integration (Simpson)
Beam in a plane: 5 points
Beam in space: 5 points in each wall (16 total)
Nondefault integration input for a beam section integrated during the analysis
Beam in a plane: Give the number of points in each wall that is parallel to the 2-axis. This number must be odd and greater than or equal to three.
Beam in space: Give the number of points in each wall that is parallel to the 2-axis, then the number of points in each wall that is parallel to the 1-axis. Both numbers must be odd and greater than or equal to three.
Default stress output points if a beam section integrated during the analysis is used
Beam in a plane: Bottom and top (points 1 and 5 above for default integration).
Beam in space: 4 corners (points 1, 5, 9, and 13 above for default integration).
Temperature and field variable input at specific points for beam sections integrated during the analysis
Give the value at each of the points shown below.
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2 3 2 1 2 1
Beam in a plane
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2 3 2 4 1
Beam in space
Temperature input for a frame section
Constant temperature throughout the element cross-section is assumed; therefore, only one temperature value per node is required.
Circular section
Input File Usage: Use one of the following options:
*BEAM SECTION, SECTION=CIRC
*BEAM GENERAL SECTION, SECTION=CIRC
*FRAME SECTION, SECTION=CIRC
Abaqus/CAE Usage: Property module: Create Profile: Circular