*INITIAL CONDITIONS

Specify initial conditions for the model.

This option is used to prescribe initial conditions for an analysis.

This page discusses:

Required parameters

TYPE

Set TYPE=ACOUSTIC STATIC PRESSURE to define initial static pressure values at acoustic nodes for use in evaluating the cavitation status of the acoustic element nodes in Abaqus/Explicit.

Set TYPE=ACTIVATION to define the initial volume fraction for elements used in progressive element activation in an Abaqus/Standard analysis. The value of the volume fraction must be equal to zero or one, which means that an element at the beginning of an analysis must be either inactive or fully active.

Set TYPE=CONCENTRATION to give initial normalized concentrations for a mass diffusion analysis in Abaqus/Standard.

Set TYPE=CONTACT to specify initial bonded contact conditions on part of the secondary surface identified by a node set in an Abaqus/Standard analysis.

Set TYPE=DAMAGE INITIATION to specify initial values of the damage initiation measure. The CRITERION parameter must also be used to specify the damage initiation criterion for which initial conditions are being specified. The REBAR and SECTION POINTS parameters can be used with this parameter when CRITERION=DUCTILE or CRITERION=SHEAR.

Set TYPE=ENRICHMENT to specify initial location of an enriched feature, such as a crack, in an Abaqus/Standard analysis. Two signed distance functions per node are generally required to describe the crack location, including the location of crack tips, in a cracked geometry. The first describes the crack surface while the second is used to construct an orthogonal surface so that the intersection of the two surfaces gives the crack front. The first signed distance function is assigned only to nodes of elements intersected by the crack while the second signed distance function is assigned only to nodes of elements containing the crack tips. No explicit representation of the crack is needed as the crack is entirely described by the nodal data.

Set TYPE=ESDV to give initial values for element solution-dependent variables in an Abaqus/Standard analysis.

Set TYPE=FIELD to specify initial values of field variables. The VARIABLE parameter can be used with this parameter to define the field variable number. The STEP and INC parameters can be used in conjunction with the FILE parameter to define initial values of field variables from a results (.fil) or output database (.odb) file. The STEP and INC parameters can also be used in conjunction with the FILE and OUTPUT VARIABLE parameters to define initial values of field variables based on scalar nodal output variables read from an output database file.

Set TYPE=FLUID ELECTRIC POTENTIAL to give initial electric potential in the electrolyte for a coupled thermal-electrochemical analysis.

Set TYPE=FLUID PRESSURE to give initial pressures for hydrostatic fluid filled cavities.

Set TYPE=HARDENING to prescribe initial equivalent plastic strain and, if relevant, the initial backstress tensor or to prescribe initial volumetric compacting plastic strain for the crushable foam model. The REBAR and, in Abaqus/Standard, SECTION POINTS and USER parameters can be used with this parameter. If the USER parameter is used, the initial conditions on equivalent plastic strain and, if relevant, the backstress tensor must be specified via user subroutine HARDINI for each section point and for each rebar. Consequently, in this case the REBAR and SECTION POINTS parameters do not have any effect and are ignored. If the USER parameter is omitted, Abaqus/Standard assumes that the initial conditions are defined on the data lines.

Set TYPE=INITIAL GAP to identify the elements within which tangential fluid flow exists initially and to set the material initial damage variables at the integration points.

Set TYPE=ION CONCENTRATION to give initial concentrations in the electrolyte for a coupled thermal-electrochemical analysis.

Set TYPE=MASS FLOW RATE to specify initial values of mass flow rates in Abaqus/Standard heat transfer analyses involving forced convection modeled with the forced convection/diffusion heat transfer elements.

Set TYPE=NODE REF COORDINATE to define the reference mesh (initial metric) for membrane elements in Abaqus/Explicit using node numbers and the coordinates of each node. If a reference mesh is specified for an element, no initial stress or strain can be specified for the same element. The initial stress and strain are computed automatically to account for deformation from the reference to the initial configuration.

Set TYPE=PLASTIC STRAIN to specify initial plastic strains. The SECTION POINTS and REBAR parameters can be used with this parameter. It is assumed that the plastic strain components are defined on each data line in the order given for the element type, as defined in About the Element Library.

Set TYPE=PORE PRESSURE to give initial pore fluid pressures for a coupled pore fluid diffusion/stress analysis in Abaqus/Standard. The STEP and INC parameters can also be used with the FILE parameter to define initial values of pore fluid pressures based on scalar nodal output variables read from an output database (.odb) file.

Set TYPE=POROSITY to give initial porosity values for materials defined with the EOS COMPACTION option in Abaqus/Explicit or materials defined using the poroelastic acoustic models.

Set TYPE=PRESSURE STRESS to give initial pressure stresses for a mass diffusion analysis in Abaqus/Standard. The STEP and INC parameters can be used in conjunction with the FILE parameter to define initial values of pressure stress from the results (.fil) file of a previous Abaqus/Standard stress/displacement analysis.

Set TYPE=RATIO to give initial void ratio values for a coupled pore fluid diffusion/stress analysis in Abaqus/Standard. The STEP and INC parameters can be used in conjunction with the FILE parameter to define initial values of void ratio from the output database (.odb) file of a previous Abaqus/Standard soil analysis. The USER parameter can be used with this parameter to define initial void ratio values in user subroutine VOIDRI.

Set TYPE=REF COORDINATE to define the reference mesh (initial metric) for membrane elements in Abaqus/Explicit using the element number and the coordinates of all of the nodes associated with the element. If a reference mesh is specified for an element, no initial stress or strain can be specified for the same element. The initial stress and strain are computed automatically to account for deformation from the reference to the initial configuration.

Set TYPE=RELATIVE DENSITY to give initial relative density values for materials defined with the POROUS METAL PLASTICITY option.

Set TYPE=ROTATING VELOCITY to prescribe initial velocities in terms of an angular velocity and a global translational velocity.

Set TYPE=SATURATION to give initial saturation values for the analysis of flow through a porous medium in Abaqus/Standard. If no initial saturation values are given on this option, the default is fully saturated conditions (saturation of 1.0). For partial saturation the initial saturation and the pore fluid pressure must be consistent in the sense that the pore fluid pressure must lie within the range of absorption and exsorption values for the initial saturation value. If this is not the case, Abaqus/Standard will adjust the saturation value as needed to satisfy this requirement.

Set TYPE=SOLID ELECTRIC POTENTIAL to give initial electric potential in the solid phase for a coupled thermal-electrochemical analysis.

Set TYPE=SOLUTION to give initial values of solution-dependent state variables. The REBAR and USER parameters can be used with this parameter. If TYPE=SOLUTION is used without the USER parameter, element average quantities of the solution-dependent state variables must be defined on each data line.

Set TYPE=SPECIFIC ENERGY to give initial specific energy values for materials defined with the EOS option in Abaqus/Explicit.

Set TYPE=SPUD EMBEDMENT to give the initial embedment for a spud can in an Abaqus/Aqua analysis.

Set TYPE=SPUD PRELOAD to give the initial preload value for a spud can in an Abaqus/Aqua analysis.

Set TYPE=STRESS to give initial stresses. (These stresses are effective stresses when the analysis includes pore fluid flow.) The GEOSTATIC; the REBAR; the SECTION POINTS; and, in Abaqus/Standard, the USER parameters can be used with this parameter. If TYPE=STRESS is used without the USER parameter, it is assumed that the stress components are defined on each data line in the order given for the element type, as defined in About the Element Library. The STEP and INC parameters can also be used with the FILE parameter to define initial stress values based on stress output variables read from an output database (.odb or .sim) file.

Set TYPE=TEMPERATURE to give initial temperatures. The STEP and INC parameters can be used in conjunction with the FILE parameter to define initial temperatures from the results (.fil) or output database (.odb) file of a previous Abaqus/Standard heat transfer analysis.

Set TYPE=UNFOLD COORDINATE to give initial coordinates in an Abaqus/Standard one-step inverse analysis.

Set TYPE=VELOCITY to prescribe initial velocities. Initial velocities should be defined in the global directions, regardless of the use of the TRANSFORM option.

Set TYPE=VOLUME FRACTION to define the initial material content of Eulerian elements in an Abaqus/Explicit analysis.

Optional parameters

ABSOLUTE EXTERIOR TOLERANCE

This parameter is relevant only for use with the INTERPOLATE parameter. Set this parameter equal to the absolute value (given in the units used in the model) by which nodes of the current model may lie outside the region of the model in the output database specified by the FILE parameter. If this parameter is not used or has a value of 0.0, the EXTERIOR TOLERANCE parameter will apply.

CORRESPONDING CONTACT STRESS

This parameter applies only to Abaqus/Standard analyses.

This parameter is used only with TYPE=STRESS.

Set CORRESPONDING CONTACT STRESS=YES (default) to activate initial contact stress calculations.

Set CORRESPONDING CONTACT STRESS=NO to turn off initial contact stress calculations.

This parameter is a global setting and affects all contact definitions in a model. Also, if the INITIAL CONDITIONS options is repeated multiple times in an input file, the CORRESPONDING CONTACT STRESS parameter setting on the last occurrence prevails.

CRITERION

Set CRITERION=DUCTILE to provide the damage initiation measure for the ductile damage initiation criterion.

Set CRITERION=MSFLD to provide the damage initiation measure for the Müschenborn and Sonne forming limit diagram based damage initiation criterion.

Set CRITERION=SHEAR to provide the damage initiation measure for the shear damage initiation criterion.

DEFINITION

Set DEFINITION=COORDINATES (default) to define the axis of rotation for TYPE=ROTATING VELOCITY by giving the coordinates of the two points, a and b.

Set DEFINITION=NODES to define the axis of rotation for TYPE=ROTATING VELOCITY by giving global node numbers for points a and b.

DRIVING ELSETS

This parameter is relevant only for use with the INTERPOLATE parameter. Include this parameter to indicate that the field (temperature, void ratio, and pore pressure only) is interpolated from a user-specified element set from the previous analysis to a user-specified node set in the current job. This parameter is used to eliminate mapping ambiguity in cases where element regions in the previous analysis are close or touching. To accomplish part instance to part instance mapping, define your element and node sets to correspond to the respective instances in the previous and current analysis.

EXTERIOR TOLERANCE

This parameter is relevant only for use with the INTERPOLATE parameter. Set this parameter equal to the fraction of the average element size by which nodes of the current model may lie outside the region of the elements of the model in the output database specified by the FILE parameter. The default value is 0.05.

If both tolerance parameters are specified, Abaqus uses the tighter tolerance.

FILE

Set this parameter equal to the name of the results (.fil) file or output database (.odb) file from which initial field variable, void ratio, pore pressure, or pressure stress data are to be read.

Set this parameter equal to the name of output database (.odb or .sim) file from which initial stress is to be read.

This parameter must be used in conjunction with the STEP and INC parameters. For more information, see File Extension Definitions.

This parameter is ignored if the initial field values are specifed with the EXTERNAL FIELD option.

FULL TENSOR

Include this parameter if the kinematic shift tensor (backstress) components are specified using the full tensor format, regardless of the element type to which the initial conditions are applied.

This parameter can be used only in conjunction with the parameter TYPE=HARDENING. It cannot be used if any of the parameters REBAR, SECTION POINTS, or USER has been used.

GEOSTATIC

This parameter is used only with TYPE=STRESS to specify that a geostatic stress state, in which stresses vary with elevation only, is being defined.

INC

This parameter is used only with the FILE parameter. If this parameter is omitted, the initial conditions will be read from the last increment of the step specified on the STEP parameter or from the last step if the STEP parameter is omitted.

The parameter specifies the increment in the results (.fil) file of a previous Abaqus analysis from which prescribed fields of TYPE=FIELD, TYPE=PRESSURE STRESS, or TYPE=TEMPERATURE are to be read. It can also specify the increment in the output database (.odb) file of a previous Abaqus analysis from which prescribed fields of TYPE=FIELD, TYPE=PORE PRESSURE, TYPE=RATIO, or TYPE=TEMPERATURE are to be read. For TYPE=STRESS, this parameter specifies the increment in the output database (.odb or .sim) file of a previous Abaqus analysis from which initial stress is to be read.

INPUT

Set this parameter equal to the name of the alternate input file containing the data lines for this option. See Input Syntax Rules for the syntax of such file names. If this parameter is omitted, it is assumed that the data follow the keyword line.

INTERPOLATE

Include this parameter in conjunction with the FILE, STEP, and INC parameters to indicate that the nodal temperatures being read into the temperature field or the scalar nodal output variable being read into a predefined field needs to be interpolated between dissimilar meshes. This feature is used to read nodal values from an output database (.odb) file generated during a previous Abaqus analysis.

For void ratio initialization from a previous output database file, this parameter is automatically activated and the old void ratios from either the element integration points or the element nodes are read and mapped onto the current nodes.

For temperature fields this parameter and the MIDSIDE parameter are mutually exclusive. For temperature fields if the initial analysis uses first-order elements and the current mesh is the same but uses second-order elements, use the MIDSIDE parameter instead. The MIDSIDE parameter is not supported for predefined fields; therefore, the INTERPOLATE parameter is the only option for initializing predefined fields using scalar nodal output values from a dissimilar mesh.

MIDSIDE

This parameter applies only to Abaqus/Standard analyses.

Include this parameter in conjunction with the FILE, STEP, and INC parameters to indicate that midside node temperatures in second-order elements are to be interpolated from corner node temperatures. This feature is used to read temperatures from a results (.fil) or output database (.odb) file generated during a heat transfer analysis using first-order elements. This parameter and the INTERPOLATE parameter are mutually exclusive.

NORMAL

This parameter applies only to Abaqus/Standard analyses.

This parameter can be used only with TYPE=CONTACT to specify that the nodes in the node set (or the contact pair, if a node set is not defined) are bonded only in the normal (contact) direction and are allowed to move freely in the tangential direction. If the nodes in the node set (or the contact pair) are to be bonded in all directions, this parameter should be omitted.

NUMBER BACKSTRESSES

Set this parameter equal to the number of backstresses. This parameter can be used only in conjunction with TYPE=HARDENING. The default number of backstresses is 1, and the maximum allowed is 10.

OUTPUT VARIABLE

This parameter is required when TYPE=FIELD and the FILE parameter references an output database.

Set this parameter equal to the scalar nodal output variable that will be read from an output database and used to initialize a specified predefined field. For a list of scalar nodal output variables that can be used to initialize a predefined field, see Predefined Fields.

REBAR

This parameter can be used with TYPE=DAMAGE INITIATION, TYPE=HARDENING, TYPE=PLASTIC STRAIN, TYPE=SOLUTION, or TYPE=STRESS.

When used with TYPE=DAMAGE INITIATION, it specifies the initial value of the damage initiation measure in the rebar.

When used with TYPE=HARDENING, it specifies that rebars are in a work hardened state, with initial equivalent plastic strain and, possibly, initial backstress.

When used with TYPE=PLASTIC STRAIN, it specifies the initial plastic strain in the rebar.

When used with TYPE=SOLUTION, it specifies that rebars are being assigned initial solution-dependent state variable values.

When used with TYPE=STRESS, it specifies that prestress in rebars is being defined. When performing an Abaqus/Standard analysis, some iteration will usually be needed in this case to establish a self-equilibrating stress state in the rebar and concrete. The PRESTRESS HOLD option can be useful for post-tensioning simulations (see Defining Rebar as an Element Property).

SECTION POINTS

This parameter is used only with TYPE=DAMAGE INITIATION, TYPE=HARDENING, TYPE=PLASTIC STRAIN, and TYPE=STRESS to specify damage initiation measures, hardening variables, plastic strains, and stresses at individual section points through the thickness of a shell element. This parameter can be used only when shell properties are defined using the SHELL SECTION option. It cannot be used when properties are defined using the SHELL GENERAL SECTION option.

SECTION SPECIFICATION

This parameter is relevant only for TYPE=TEMPERATURE and TYPE=FIELD.

Set SECTION SPECIFICATION=UNIFORM to specify uniform temperatures and field variables.

The INPUT and VARIABLE parameters can be used with this parameter.

STEP

This parameter is used only with the FILE parameter. If this parameter is omitted, the initial conditions will be read from the last step.

The parameter specifies the step in the results (.fil) file of a previous Abaqus analysis from which prescribed fields of TYPE=FIELD, TYPE=PRESSURE STRESS, or TYPE=TEMPERATURE are to be read. It can also specify the step in the output database (.odb) file of a previous Abaqus analysis from which prescribed fields of TYPE=FIELD, TYPE=PORE PRESSURE, TYPE=RATIO, or TYPE=TEMPERATURE are to be read. For TYPE=STRESS, this parameter specifies the step in the output database (.odb or .sim) file of a previous Abaqus analysis from which initial stress is to be read.

UNBALANCED STRESS

This parameter applies only to Abaqus/Standard analyses.

This parameter is used only with TYPE=STRESS.

Set UNBALANCED STRESS=RAMP (default) if the unbalanced stress is to be resolved linearly over the step.

Set UNBALANCED STRESS=STEP if the unbalanced stress is to be resolved in the first increment.

If the INITIAL CONDITIONS option is repeated multiple times in an input file, the UNBALANCED STRESS parameter setting on the last occurrence prevails.

USER

In Abaqus/Standard, this parameter can be used with TYPE=HARDENING, TYPE=PORE PRESSURE, TYPE=RATIO, TYPE=SOLUTION, or TYPE=STRESS.

When used with TYPE=HARDENING, it specifies that the initial conditions on equivalent plastic strain and, if relevant, backstress tensor are to be given via user subroutine HARDINI.

When used with TYPE=PORE PRESSURE, it specifies that initial pore pressures are to be given via user subroutine UPOREP.

When used with TYPE=RATIO, it specifies that initial void ratios are to be given via user subroutine VOIDRI.

When used with TYPE=SOLUTION, it specifies that initial solution-dependent state variable fields are to be given via user subroutine SDVINI.

When used with TYPE=STRESS, it specifies that stresses are to be given in user subroutine SIGINI.

In Abaqus/Explicit, this parameter can be used only with TYPE=SOLUTION. It specifies that initial solution-dependent state variable fields are to be given in user subroutine VSDVINI.

VARIABLE

This parameter is used only with TYPE=FIELD when it is used to define the field variable number. The default is VARIABLE=1. Any number of separate field variables can be used: each must be numbered consecutively (1, 2, 3, etc.)

No data lines are required if the initial conditions are read from a file (the FILE parameter is included) unless the DRIVING ELSETS parameter is used; if the initial conditions are defined with the EXTERNAL FIELD option; or if the initial conditions are defined in a user subroutine (the USER parameter is included)

 

Data line for TYPE=ACOUSTIC STATIC PRESSURE

First (and only) line
  1. Node set or node number.

  2. Hydrostatic pressure at the first reference point.

  3. X-coordinate of the first reference point.

  4. Y-coordinate of the first reference point.

  5. Z-coordinate of the first reference point.

  6. Hydrostatic pressure at the second reference point.

  7. X-coordinate of the second reference point.

  8. Y-coordinate of the second reference point.

  9. Z-coordinate of the second reference point.

Data lines for TYPE=ACTIVATION

First line
  1. Element set or element number.

  2. Initial volume fraction of material in the element.

Repeat this data line as often as necessary to define the initial volume fraction of material in various elements or element sets.

Data lines for TYPE=CONCENTRATION

First line
  1. Node set or node number.

  2. Initial normalized concentration value at the node.

Repeat this data line as often as necessary to define the initial normalized concentration at various nodes or node sets.

Data lines for TYPE=CONTACT

First line
  1. Secondary surface name.

  2. Main surface name.

  3. Name of the node set associated with the secondary surface.

Repeat this data line as often as necessary to define partially bonded surfaces.

Data lines for TYPE=DAMAGE INITIATION, CRITERION=DUCTILE or CRITERION=SHEAR if the REBAR and SECTION POINTS parameters are omitted

First line
  1. Element number or element set label.

  2. Damage initiation measure for either the ductile or the shear damage initiation criterion, ω D or ω S .

Repeat this data line as often as necessary to define initial damage initiation measures in various elements or element sets.

Data lines for TYPE=DAMAGE INITIATION, CRITERION=DUCTILE or CRITERION=SHEAR with the REBAR parameter included

First line
  1. Element number or element set label.

  2. Rebar name. If this field is left blank, the initial conditions will be applied to all rebars in the model.

  3. Damage initiation measure for either the ductile or the shear damage initiation criterion, ω D or ω S .

Repeat this data line as often as necessary to define initial damage initiation measures for rebars in various elements or element sets.

Data lines for TYPE=DAMAGE INITIATION, CRITERION=DUCTILE or CRITERION=SHEAR with the SECTION POINTS parameter included

First line
  1. Element number or element set label.

  2. Section point number.

  3. Damage initiation measure for either the ductile or the shear damage initiation criterion, ω D or ω S .

Repeat this data line as often as necessary to define initial damage initiation measures in various elements or element sets. The initial damage initiation measures must be defined at all section points within an element.

Data lines for TYPE=DAMAGE INITIATION, CRITERION=MSFLD

First line
  1. Element number or element set label.

  2. Damage initiation measure for the Müschenborn and Sonne forming limit diagram based damage initiation criterion, ω M S F L D .

  3. Ratio of the principal strain rates, α .

Repeat this data line as often as necessary to define initial damage initiation measures in various elements or element sets.

Data lines for TYPE=ENRICHMENT

First line
  1. Element number or element set label.

  2. Relative position of the node forming the element connectivity.

  3. Name of the enriched feature specified on the ENRICHMENT option.

  4. Value of first signed distance function.

  5. Value of second signed distance function. Leave this entry blank if only the first signed distance function is needed.

Repeat this data line as often as necessary to define initial signed distance functions in various elements or element sets. The signed distance functions must be defined at all nodes within an element.

Data lines for TYPE=ESDV

First line
  1. Element number or element set label.

  2. Value of first element solution-dependent variable.

  3. Value of second element solution-dependent variable.

  4. Etc., up to seven element solution-dependent variables.

Subsequent lines (only needed if more than seven element solution-dependent variables exist in the model)
  1. Value of eighth element solution-dependent variable.

  2. Etc., up to eight element solution-dependent variables per line.

The total number of variables that Abaqus expects to read for any element is based on the maximum number of element solution-dependent variables for all the elements in the model. Therefore, it may be necessary to leave blank data lines for some elements if any other element in the model has more element solution-dependent variables. These trailing initial values will be zero and will not be used in the analysis.

Repeat this set of data lines as often as necessary to define initial values of element solution-dependent variables for various elements or element sets.

Data lines for TYPE=FIELD, VARIABLE=n

First line
  1. Node set or node number.

  2. Initial value of this field variable at the first temperature point. For shells and beams several values (or a value and the field variable gradients across the section) can be given at each node (see About Beam Modeling as well as About Shell Elements). For heat transfer shells the field variables at each temperature point through the shell thickness must be specified. The number of values depends on the (maximum) number of points specified on the data lines associated with the SHELL SECTION options.

  3. Initial value of this field variable at the second temperature point.

  4. Etc., up to seven values.

Subsequent lines (only needed if initial values must be specified at more than seven temperature points at any node)
  1. Eighth initial value of this field variable at this temperature point.

  2. Etc., up to eight initial values per line.

The total number of field variables that Abaqus expects to read for any node is based on the maximum number of field variable values for all the nodes in the model. Therefore, it may be necessary to leave blank data lines for some nodes if any other node in the model has more than seven field variable points. These trailing initial values will be zero and will not be used in the analysis.

Repeat this set of data lines as often as necessary to define initial temperatures at various nodes or node sets.

Data lines for TYPE=FIELD, SECTION SPECIFICATION=UNIFORM

First line
  1. Node set, node number, or blank.

  2. Uniform field variable value.

Repeat this data line as often as necessary to define uniform field variables at various nodes and node sets. If you omit both node numbers and node sets (that is, enter a blank space), the specified uniform field variable is applied to all nodes in the model.

Data lines for TYPE=FLUID ELECTRIC POTENTIAL

First line
  1. Node set or node number.

  2. Initial value of electric potential in the electrolyte at the node.

Repeat this data line as often as necessary to define the initial electric potential in the electrolyte at various nodes or node sets.

Data lines for TYPE=FLUID PRESSURE

First line
  1. Node set or node number of fluid cavity reference node.

  2. Fluid pressure.

Repeat this data line as often as necessary to define initial fluid pressure for various fluid-filled cavities.

Data lines to prescribe initial equivalent plastic strain or backstresses using TYPE=HARDENING if the REBAR, SECTION POINTS, and USER parameters are omitted

First line
  1. Element number or element set label.

  2. Initial equivalent plastic strain, ε ¯ p l | 0 .

  3. First value of the initial first backstress, α 1 11 0 .

  4. Second value of the initial first backstress, α 1 22 0 .

  5. Etc., up to six backstress components.

Subsequent lines (only needed if the NUMBER BACKSTRESSES parameter has a value greater than one)
  1. First value of the initial second backstress, α 2 11 0 .

  2. Second value of the initial second backstress, α 2 22 0 .

  3. Etc., backstress components for each backstress must be specified on a separate data line.

The backstress components are relevant only for the kinematic hardening models. Give the backstress components as defined for this element type in About the Element Library. Values given on the data lines are applied uniformly over the element. In any element for which an ORIENTATION option applies, backstresses must be given in the local system (Orientations).

Repeat this set of data lines as often as necessary to define the hardening parameters for various elements or element sets.

Data lines to prescribe initial volumetric compacting plastic strain for the crushable foam model using TYPE=HARDENING

First line
  1. Element number or element set label.

  2. Initial volumetric compacting plastic strain, - ε vol p l .

Repeat this data line as often as necessary to define the initial volumetric compacting plastic strain for various elements or element sets.

Data lines for TYPE=HARDENING, REBAR

First line
  1. Element number or element set label.

  2. Rebar name. If this field is left blank, the initial conditions will be applied to all rebars in the model.

  3. Initial equivalent plastic strain, ε ¯ p l | 0 .

  4. Initial first backstress, α 1 11 0 . (Only relevant for the kinematic hardening models.)

Subsequent lines (only needed if the NUMBER BACKSTRESSES parameter has a value greater than one)
  1. Initial second backstress, α 2 11 0 . (Only relevant for the kinematic hardening models.)

  2. Etc., backstress components for each backstress must be specified on a separate data line.

Repeat this set of data lines as often as necessary to define the hardening parameters for rebars in various elements or element sets.

Data lines for TYPE=HARDENING, SECTION POINTS

First line
  1. Element number or element set label.

  2. Section point number.

  3. Initial equivalent plastic strain, ε ¯ p l | 0 .

  4. First value of the first initial backstress, α 1 11 0 . (Only relevant for the kinematic hardening models.)

  5. Second value of the first initial backstress, α 1 22 0 .

  6. Third value of the first initial backstress, α 1 12 0 .

Subsequent lines (only needed if the NUMBER BACKSTRESSES parameter has a value greater than one)
  1. First value of the initial second backstress, α 2 11 0 .

  2. Second value of the initial second backstress, α 2 22 0 .

  3. Etc., backstress components for each backstress must be specified on a separate data line.

The backstress components are relevant only for the kinematic hardening model. Give the backstress components as defined for this element type in About the Element Library. In any element for which an ORIENTATION option applies, the backstress components must be given in the local system (Orientations).

Repeat this set of data lines as often as necessary to define the hardening parameters in various elements or element sets. The hardening parameters must be defined at all section points within an element.

Data lines for TYPE=INITIAL GAP

First line
  1. Element number or element set label.

  2. The material initial damage variable, D , at the first integration point.

  3. The material initial damage variable, D , at the second integration point.

  4. The material initial damage variable, D , at the third integration point.

  5. The material initial damage variable, D , at the fourth integration point.

Repeat this data line as often as necessary to identify various elements or element sets. Assigning the material initial damage variables at the integration points is optional. If no initial damage variables are assigned, the elements are considered fully damaged; that is, D = 1.0 . If you assign an initial damage variable to any of the integration points and leave the other fields blank, a value of D = 0.0 is assigned to the integration points of the blank fields.

Data lines for TYPE=ION CONCENTRATION

First line
  1. Node set or node number.

  2. Initial ion concentration value at the node.

Repeat this data line as often as necessary to define the initial ion concentrations in the electrolyte at various nodes or node sets.

Data lines for TYPE=MASS FLOW RATE

First line
  1. Node set or node number.

  2. Initial mass flow rate per unit area in the x-direction or total initial mass flow rate in the cross-section for one-dimensional elements.

  3. Initial mass flow rate per unit area in the y-direction (not needed for nodes associated with one-dimensional convective flow elements).

  4. Initial mass flow rate per unit area in the z-direction (not needed for nodes associated with one-dimensional convective flow elements).

Repeat this data line as often as necessary to define mass flow rates at various nodes or node sets.

Data lines for TYPE=NODE REF COORDINATE

First line
  1. Node number.

  2. X-coordinate of the node.

  3. Y-coordinate of the node.

  4. Z-coordinate of the node.

Repeat this data line as often as necessary to define the initial coordinates of the mesh using nodal coordinates.

Data lines to prescribe initial plastic strains using TYPE=PLASTIC STRAIN if the REBAR and SECTION POINTS parameters are omitted

First line
  1. Element number or element set label.

  2. Value of first plastic strain component, ε 11 p l .

  3. Value of second plastic strain component, ε 22 p l .

  4. Etc., up to six plastic strain components.

Give the plastic strain components as defined for this element type in About the Element Library. Values given on the data lines are applied uniformly over the element. In any element for which an ORIENTATION option applies, the plastic strains must be given in the local system (Orientations).

Repeat this data line as often as necessary to define initial plastic strains in various elements or element sets.

Data lines for TYPE=PLASTIC STRAIN, REBAR

First line
  1. Element number or element set label.

  2. Rebar name. If this field is left blank, the initial conditions will be applied to all rebars in the model.

  3. Initial plastic strain value.

Repeat this data line as often as necessary to define the initial plastic strain in the rebars of various elements or element sets.

Data lines for TYPE=PLASTIC STRAIN, SECTION POINTS

First line
  1. Element number or element set label.

  2. Section point number.

  3. Value of first plastic strain component, ε 11 p l .

  4. Value of second plastic strain component, ε 22 p l .

  5. Value of third plastic strain component, ε 12 p l .

Give the initial plastic strain components as defined for this element type in About the Element Library. In any element for which an ORIENTATION option applies, the plastic strain components must be given in the local system (Orientations).

Repeat this data line as often as necessary to define initial plastic strains in various elements or element sets. Plastic strains must be defined at all section points within an element.

Data lines for TYPE=PORE PRESSURE if the USER parameter is omitted

First line
  1. Node set or node number.

  2. First value of fluid pore pressure, u w .

  3. Vertical coordinate corresponding to the above value.

  4. Second value of fluid pore pressure, u w .

  5. Vertical coordinate corresponding to the above value.

Omit the elevation values and the second pore pressure value to define a constant pore pressure distribution.

Repeat this data line as often as necessary to define the fluid pore pressure at various nodes or node sets.

Data lines for TYPE=PORE PRESSURE, FILE=file, STEP=step, INC=inc, INTERPOLATE, DRIVING ELSETS

First line
  1. Element set, node set.

Repeat this data line as often as necessary. The node set identified on the data lines will be assigned values from the element set in the output database (.odb) file. If a duplicate node is defined on a subsequent data line, it will be removed from the subsequent void ratio mapping and printed out to the data (.dat) file.

Data lines for TYPE=POROSITY

First line
  1. Element number or element set label.

  2. Initial porosity.

Repeat this data line as often as necessary to define initial porosity in various elements or element sets.

Data lines for TYPE=PRESSURE STRESS

First line
  1. Node set or node number.

  2. Equivalent pressure stress, p.

Repeat this data line as often as necessary to define the pressure stress at various nodes or node sets.

Data lines for TYPE=RATIO if the USER parameter is omitted

First line
  1. Node set or node number.

  2. First value of void ratio.

  3. Vertical coordinate corresponding to the above value.

  4. Second value of void ratio.

  5. Vertical coordinate corresponding to the above value.

Omit the elevation values and the second void ratio value to define a constant void ratio distribution.

Repeat this data line as often as necessary to define void ratios at various nodes or node sets.

Data lines for TYPE=RATIO, FILE=file, STEP=step, INC=inc, INTERPOLATE, DRIVING ELSETS

First line
  1. Element set, node set.

Repeat this data line as often as necessary. The node set identified on the data lines will be assigned values from the element set in the output database (.odb) file. If a duplicate node is defined on a subsequent data line, it will be removed from the subsequent void ratio mapping and printed out to the data (.dat) file.

Data lines for TYPE=REF COORDINATE

First line
  1. Element number.

  2. X-coordinate of the first node.

  3. Y-coordinate of the first node.

  4. Z-coordinate of the first node.

  5. X-coordinate of the second node.

  6. Y-coordinate of the second node.

  7. Z-coordinate of the second node.

Second line
  1. X-coordinate of the third node.

  2. Y-coordinate of the third node.

  3. Z-coordinate of the third node.

  4. X-coordinate of the fourth node.

  5. Y-coordinate of the fourth node.

  6. Z-coordinate of the fourth node.

Repeat this pair of data lines as often as necessary to define the reference mesh in various elements. The order of the nodal coordinates must be consistent with the element connectivity.

Data lines for TYPE=RELATIVE DENSITY

First line
  1. Node set or node number.

  2. Initial relative density.

Repeat this data line as often as necessary to define initial relative density at various nodes or node sets.

Data lines for TYPE=ROTATING VELOCITY, DEFINITION=COORDINATES

First line
  1. Node set or node number.

  2. Angular velocity about the axis defined from point a to point b, where the coordinates of a and b are given below.

  3. Global X-component of translational velocity.

  4. Global Y-component of translational velocity.

  5. Global Z-component of translational velocity.

Second line
  1. Global X-component of point a on the axis of rotation.

  2. Global Y-component of point a on the axis of rotation.

  3. Global Z-component of point a on the axis of rotation.

  4. Global X-component of point b on the axis of rotation.

  5. Global Y-component of point b on the axis of rotation.

  6. Global Z-component of point b on the axis of rotation.

Repeat this pair of data lines as often as necessary to define the angular and translational velocities at various nodes or node sets.

Data lines for TYPE=ROTATING VELOCITY, DEFINITION=NODES

First line
  1. Node set or node number.

  2. Angular velocity about the axis defined from point a to point b, where the coordinates of a and b are given below.

  3. Global X-component of translational velocity.

  4. Global Y-component of translational velocity.

  5. Global Z-component of translational velocity.

Second line
  1. Node number of the node at point a.

  2. Node number of the node at point b.

Repeat this pair of data lines as often as necessary to define the angular and translational velocities at various nodes or node sets.

Data lines for TYPE=SATURATION

First line
  1. Node set or node number.

  2. Saturation value, s. Default is 1.0.

Repeat this data line as often as necessary to define saturation at various nodes or node sets.

Data lines for TYPE=SOLID ELECTRIC POTENTIAL

First line
  1. Node set or node number.

  2. Initial value of electric potential in the solid phase at the node.

Repeat this data line as often as necessary to define the initial electric potential in the solid phase at various nodes or node sets.

Data lines for TYPE=SOLUTION if the USER and REBAR parameters are omitted

First line
  1. Element number or element set label.

  2. Value of first solution-dependent state variable.

  3. Value of second solution-dependent state variable.

  4. Etc., up to seven solution-dependent state variables.

Subsequent lines (only needed if more than seven solution-dependent state variables exist in the model)
  1. Value of eighth solution-dependent state variable.

  2. Etc., up to eight solution-dependent state variables per line.

The total number of variables that Abaqus expects to read for any element is based on the maximum number of solution-dependent state variables for all the elements in the model. Therefore, it may be necessary to leave blank data lines for some elements if any other element in the model has more solution-dependent state variables. These trailing initial values will be zero and will not be used in the analysis. Values given on the data lines will be applied uniformly over the element.

Repeat this set of data lines as often as necessary to define initial values of solution-dependent state variables for various elements or element sets.

Data lines for TYPE=SOLUTION, REBAR

First line
  1. Element number or element set label.

  2. Rebar name. If this field is left blank, the solution-dependent state variables are applied to all rebars in these elements.

  3. Value of first solution-dependent state variable.

  4. Value of second solution-dependent state variable.

  5. Etc., up to six solution-dependent state variables.

Subsequent lines (only needed if more than six solution-dependent state variables exist in the model)
  1. Value of seventh solution-dependent state variable.

  2. Etc., up to eight solution-dependent state variables per line.

The total number of variables that Abaqus expects to read for any element is based on the maximum number of solution-dependent state variables for all the elements in the model. Therefore, it may be necessary to leave blank data lines for some elements if any other element in the model has more solution-dependent state variables. These trailing initial values will be zero and will not be used in the analysis. Values given on the data lines will be applied uniformly over the element.

Repeat this set of data lines as often as necessary to define initial values of solution-dependent state variables for various elements or element sets.

Data lines for TYPE=SPECIFIC ENERGY

First line
  1. Element number or element set label.

  2. Initial specific energy.

Repeat this data line as often as necessary to define initial specific energy in various elements or element sets.

Data lines for TYPE=SPUD EMBEDMENT

First line
  1. Element set or element number.

  2. Spud can embedment, ν i .

Repeat this data line as often as necessary to define initial embedment for various elements or element sets.

Data lines for TYPE=SPUD PRELOAD

First line
  1. Element set or element number.

  2. Spud can preload, V c ( i ) .

Repeat this data line as often as necessary to define initial preload for various elements or element sets.

Data lines for TYPE=STRESS if the GEOSTATIC, REBAR, SECTION POINTS, and USER parameters are omitted

First line
  1. Element number or element set label.

  2. Value of first (effective) stress component, axial force when used with the BEAM GENERAL SECTION or FRAME SECTION options, or direct membrane force per unit width in the local 1-direction when used with the SHELL GENERAL SECTION option.

  3. Value of second stress component.

  4. Etc., up to six stress components.

Give the stress components as defined for this element type in About the Element Library. Stress values given on data lines are applied uniformly and equally over all integration points of the element. In any element for which an ORIENTATION option applies, the stresses must be given in the local system (Orientations).

Repeat this data line as often as necessary to define initial stresses in various elements or element sets.

Data lines for TYPE=STRESS, GEOSTATIC

First line
  1. Element number or element set label.

  2. First value of vertical component of (effective) stress.

  3. Vertical coordinate corresponding to the above value.

  4. Second value of vertical component of (effective) stress.

  5. Vertical coordinate corresponding to the above value.

  6. First coefficient of lateral stress. This coefficient defines the x-direction stress components.

  7. Second coefficient of lateral stress. This coefficient defines the y-direction stress component in three-dimensional cases and the thickness or hoop direction component in plane or axisymmetric cases. If this value is omitted, it is assumed to be the same as the first lateral stress coefficient given in the previous field.

Repeat this data line as often as necessary to define an initial geostatic stress state in various elements or element sets.

Data lines for TYPE=STRESS, REBAR

First line
  1. Element number or element set label.

  2. Rebar name. If this field is left blank, the stress is applied to all rebars in these elements.

  3. Prestress value.

Repeat this data line as often as necessary to define initial stress in the rebars of various elements or element sets.

Data lines for TYPE=STRESS, SECTION POINTS

First line
  1. Element number or element set label.

  2. Section point number.

  3. Value of first stress component.

  4. Value of second stress component.

  5. Etc., up to three stress components.

Give the stress components as defined for this element type in About the Element Library. Stress values given on data lines are applied uniformly over the element. In any element for which an ORIENTATION option applies, the stresses must be given in the local system (Orientations).

Repeat this data line as often as necessary to define initial stresses in various elements or element sets. Stresses must be defined at all section points within an element.

Data lines for TYPE=TEMPERATURE

First line
  1. Node set or node number.

  2. First initial temperature value at the node or node set. For shells and beams several values (or a value and the temperature gradients across the section) can be given at each node (see Using a Beam Section Integrated during the Analysis to Define the Section Behavior, Using a General Beam Section to Define the Section Behavior, Using a Shell Section Integrated during the Analysis to Define the Section Behavior, and Using a General Shell Section to Define the Section Behavior). For heat transfer shells the temperature at each point through the shell thickness must be specified. The number of values depends on the (maximum) number of points specified on the data lines associated with the SHELL SECTION options.

  3. Second initial temperature value at the node or node set.

  4. Etc., up to seven initial temperature values at this node or node set.

Subsequent lines (only needed if there are more than seven temperature values at any node)
  1. Eighth initial temperature value at this node or node set.

  2. Etc., up to eight initial temperature values per line.

If more than seven temperature values are needed at any node, continue on the next line. The total number of temperatures that Abaqus expects to read for any node is based on the maximum number of temperature values of all the nodes in the model. Therefore, it may be necessary to leave blank data lines for some nodes if any other node in the model has more than seven temperature points. These trailing initial values will be zero and will not be used in the analysis.

Repeat this data line (or set of lines) as often as necessary to define initial temperatures at various nodes or node sets.

Data lines for TYPE=TEMPERATURE, FILE=file, STEP=step, INC=inc, INTERPOLATE, DRIVING ELSETS

First line
  1. Element set, node set.

Repeat this data line as often as necessary. The node set identified on the data lines will be assigned values from the element set in the output database (.odb) file. If a duplicate node is defined on a subsequent data line, it will be removed from the subsequent temperature mapping and printed out to the data (.dat) file.

Data lines for TYPE=TEMPERATURE, SECTION SPECIFICATION=UNIFORM

First line
  1. Node set, node number, or blank.

  2. Uniform temperature value.

Repeat this data line as often as necessary to define uniform temperatures at various nodes and node sets. If you omit both node numbers and node sets (that is, enter a blank space), the specified uniform temperature is applied to all nodes in the model.

Data lines for TYPE=UNFOLD COORDINATE

First line
  1. Node number.

  2. X-coordinate of the first node.

  3. Y-coordinate of the first node.

  4. Z-coordinate of the first node.

Repeat this data line as often as necessary to define the initial coordinates at various nodes.

Data lines for TYPE=VELOCITY

First line
  1. Node set or node number.

  2. Degree of freedom.

  3. Value of initial velocity.

Repeat this data line as often as necessary to define the initial velocity at various nodes or node sets.

Data lines for TYPE=VOLUME FRACTION

First line
  1. Eulerian element number or element set label.

  2. Name of the material instance as defined in the EULERIAN SECTION.

  3. Initial volume fraction, EVF, for this material (0.0 < EVF ≤ 1.0). EVF=0.0 indicates that none of this material is present in the element, while EVF=1.0 indicates that the element is completely full of this material.

Repeat this data line as often as necessary to define the initial geometry of all Eulerian material instances. An element may appear in more than one data line if it initially contains more than one material. Elements are filled incrementally by reading the data lines in the input file from bottom to top; once the volume fraction for an element reaches one, additional volume fractions assigned to that element are ignored. If the final volume fraction for an element is less than one, the remainder of that element is filled with void; similarly, uninitialized elements are filled with void.