are 2-node, initially straight, slender beam elements intended for use
in the elastic or elastic-plastic analysis of frame-like structures;
are available in two or three dimensions;
have elastic response that follows Euler-Bernoulli beam theory with
fourth-order interpolation for the transverse displacements;
have plastic response that is concentrated at the element ends
(plastic hinges) and is modeled with a lumped plasticity model that includes
nonlinear kinematic hardening;
are implemented for small or large displacements (large rotations with
small strains);
output forces and moments at the element ends and midpoint;
output elastic axial strain and curvatures at the element ends and
midpoint and plastic displacements and rotations at the element ends only;
admit, optionally, a uniaxial “buckling strut” response where the
axial response of the element is governed by a damaged elasticity model in
compression and an isotropic hardening plasticity model in tension and where
all transverse forces and moments are zero;
can switch to buckling strut response during the analysis (for pipe
sections only); and
can be used in static, implicit dynamic, and eigenfrequency extraction
analyses only.
Frame elements are designed to be used for small-strain elastic or
elastic-plastic analysis of frame-like structures composed of slender,
initially straight beams. Typically, a single frame element will represent the
entire structural member connecting two joints. A frame element's elastic
response is governed by Euler-Bernoulli beam theory with fourth-order
interpolations for the transverse displacement field; hence, the element's
kinematics include the exact (Euler-Bernoulli) solution to concentrated end
forces and moments and constant distributed loads. The elements can be used to
solve a wide variety of civil engineering design applications, such as truss
structures, bridges, internal frame structures of buildings, off-shore
platforms, and jackets, etc. A frame element's plastic response is modeled with
a lumped plasticity model at the element ends that simulates the formation of
plastic hinges. The lumped plasticity model includes nonlinear kinematic
hardening. The elements can, thus, be used for collapse load prediction based
on the formation of plastic hinges.
Slender, frame-like members loaded in compression often buckle in such a way
that only axial force is supported by the member; all other forces and moments
are negligibly small. Frame elements offer optional buckling strut response
whereby the element only carries axial force, which is calculated based on a
damaged elasticity model in compression and an isotropic hardening plasticity
model in tension. This model provides a simple phenomenological approximation
to the highly nonlinear geometric and material response that takes place during
buckling and postbuckling deformation of slender members loaded in compression.
For pipe sections only, frame elements allow switching to optional uniaxial
buckling strut response during the analysis. The criterion for switching is the
“ISO” equation together with the “strength”
equation (see
Buckling strut response for frame elements).
When the ISO and strength equations are
satisfied, the elastic or elastic-plastic frame element undergoes a
one-time-only switch in behavior to buckling strut response.
Element Cross-Sectional Axis System
The orientation of the frame element's cross-section is defined in
Abaqus/Standard
in terms of a local, right-handed (,
,
)
axis system, where is the tangent to the
axis of the element, positive in the direction from the first to the second
node of the element, and
and
are basis vectors that define the local 1- and 2-directions of the
cross-section.
is referred to as the first axis direction, and
is referred to as the normal to the element. Since these elements are initially
straight and assume small strains, the cross-section directions are constant
along each element and possibly discontinuous between elements.
Defining the N1-Direction at the Nodes
For frame elements in a plane the -direction
is always (0.0, 0.0, −1.0); that is, normal to the plane in which the motion
occurs. Therefore, planar frame elements can bend only about the first axis
direction.
For frame elements in space the approximate direction of
must be defined directly as part of the element section definition or by
specifying an additional node off the element's axis. This additional node is
included in the element's connectivity list (see
Element Definition).
If an additional node is specified, the approximate direction of
is defined by the vector extending from the first node of the element to the
additional node.
If both input methods are used, the direction calculated by using the
additional node will take precedence.
If the approximate direction is not defined by either of the above
methods, the default value is (0.0, 0.0, −1.0).
The -direction
is then the normal to the element's axis that lies in the plane defined by the
element's axis and this approximate -direction.
The -direction
is defined as .
Large-Displacement Assumptions
The frame element's formulation includes the effect of large rigid body
motions (displacements and rotations) when geometrically nonlinear analysis is
selected (see
General and Perturbation Procedures).
Strains in these elements are assumed to remain small.
Material Response (Section Properties) of Frame Elements
For frame elements the geometric and material properties are specified
together as part of the frame section definition. No separate material
definition is required. You can choose one of the section shapes that is valid
for frame elements from the beam cross-section library (see
Beam Cross-Section Library).
The valid section shapes depend upon whether elastic or elastic-plastic
material response is specified or whether buckling strut response is included.
See
Frame Section Behavior
for a complete discussion of specifying the geometric and material section
properties.
Mechanical Response and Mass Formulation
The mechanical response of a frame element includes elastic and plastic
behavior. Optionally, uniaxial buckling strut response is available.
Elastic Response
The elastic response of a frame element is governed by Euler-Bernoulli beam
theory. The displacement interpolations for the deflections transverse to the
frame element's axis (the local 1- and 2-directions in three dimensions; the
local 2-direction in two dimensions) are fourth-order polynomials, allowing
quadratic variation of the curvature along the element's axis. Thus, each
single frame element exactly models the static, elastic solution to force and
moment loading at its ends and constant distributed loading along its axis
(such as gravity loading). The displacement interpolation along an element's
axis is a second-order polynomial, allowing linear variation of the axial
strain. In three dimensions the twist rotation interpolation along an element's
axis is linear, allowing constant twist strain. The elastic stiffness matrix is
integrated numerically and used to calculate 15 nodal forces and moments in
three dimensions: an axial force, two shear forces, two bending moments, and a
twist moment at each end node, and an axial force and two shear forces at the
midpoint node. In two dimensions 8 nodal forces and moments exist: an axial
force, a shear force, and a moment at each end, and an axial force and a shear
force at the midpoint. The forces and moments are illustrated in
Figure 1.
Elastic-Plastic Response
The plastic response of the element is treated with a “lumped” plasticity
model such that plastic deformations can develop only at the element's ends
through plastic rotations (hinges) and plastic axial displacement. The growth
of the plastic zone through the element's cross-section from initial yield to a
fully yielded plastic hinge is modeled with nonlinear kinematic hardening. It
is assumed that the plastic deformation at an end node is influenced by the
moments and axial force at that node only. Hence, the yield function at each
node, also called the plastic interaction surface, is assumed to be a function
of that node's axial force and three moment components only. No length is
associated with the plastic hinge. In reality, the plastic hinge will have a
finite size determined by the element's length and the specific loading that
causes yielding; the hinge size will influence the hardening rate but not the
ultimate load. Hence, if the rate of hardening and, thus, the plastic
deformation for a given load are important, the lumped plasticity model should
be calibrated with the element's length and the loading situation taken into
account. For details on the elastic-plastic element formulation, see
Frame elements with lumped plasticity.
Uniaxial Linear Elastic and Buckling Strut Response with Tensile Yield
You can obtain a frame element's response to uniaxial force only, based on
linear elasticity, buckling strut response, and tensile yield. In that case all
transverse forces and moments in the element are zero. For linear elastic
response the element behaves like an axial spring with constant stiffness. For
buckling strut response if the tensile axial force in the element does not
exceed the yield force, the axial force in the element is constrained to remain
inside a buckling envelope. See
Frame Section Behavior
for a description of this envelope. Inside the envelope the force is related to
strain by a damaged elastic modulus. The cyclic, hysteretic response of this
model is phenomenological and approximates the response of thin-walled,
pipe-like members. When the element is loaded in tension beyond the yield
force, the force response is governed by isotropic hardening plasticity. In
reverse loading the response is governed by the buckling envelope translated
along the strain axis by an amount equal to the axial plastic strain. For
details of the buckling strut formulation, see
Buckling strut response for frame elements.
Mass Formulation
The frame element uses a lumped mass formulation for both dynamic analysis
and gravity loading. The mass matrix for the translational degrees of freedom
is derived from a quadratic interpolation of the axial and transverse
displacement components. The rotary inertia for the element is isotropic and
concentrated at the two ends.
For buckling strut response a lumped mass scheme is used, where the
element's mass is concentrated at the two ends; no rotary inertia is included.
Using Frame Elements in Contact Problems
When contact conditions play a role in a structure's behavior, frame
elements have to be used with caution. A frame element has one additional
internal node, located in the middle of the element. No contact constraint is
imposed on this node, so this internal node may penetrate the surface in
contact, resulting in a sagging effect.
Output
The forces and moments, elastic strains, and plastic displacements and
rotations in a frame element are reported relative to a corotational coordinate
system. The local coordinate directions are the axial direction and the two
cross-sectional directions. Output of section forces and moments as well as
elastic strains and curvatures is available at the element ends and midpoint.
Output of plastic displacement and rotations is available only at the element
ends. You can request output to the output database (at the integration points
only), to the data file, or to the results file (see
Output to the Data and Results Files
and
Frame Elements). Since
frame elements are formulated in terms of section properties, stress output is
not available.