LDREAD

LDREAD, Lab, LSTEP, SBSTEP, TIME, KIMG, Fname, Ext, --
Reads results from the results file and applies them as loads.

Valid Products: Pro | Premium | Enterprise | PrepPost | Solver | AS add-on

Lab

Valid load label:

TEMP

 — 

Temperatures from a thermal analysis are applied as body force nodal loads (BF) in a structural analysis or other type of analysis.

When used in conjunction with KIMG = 1 or KIMG = 2, temperatures can be applied to a subsequent thermal analysis as nodal loads (D) or initial conditions (IC), respectively.

See the "Notes" section for details on transferring temperatures from layered thermal shell elements (SHELL131, SHELL132, and SHELL294) and layered thermal solid elements (SOLID278, SOLID279).

FORC

 — 

Forces from an electromagnetic analysis are applied as force loads (F) in a structural analysis. LDREAD,FORC reads coupling forces. See the discussion on force computation in the Low-Frequency Electromagnetic Analysis Guide.

For a full harmonic magnetic analysis, FORC represents the time-averaged force (use in conjunction with KIMG = 2). Values are in the nodal coordinate system for the force loads (F).

HGEN

 — 

Heat generations from an electromagnetic analysis are applied as body-force loads (BFE) in a thermal analysis. For a full harmonic analysis, HGEN represents the time-averaged heat generation load (use in conjunction with KIMG = 2).

JS

 — 

Source current density from a current-conduction analysis are applied as body-force loads (BFE). Values are in the global Cartesian coordinate system.

EF

 — 

Electric field element centroid values from an electrostatic analysis are applied as body-force loads (BFE) in a magnetic analysis. Values are in the global Cartesian coordinate system.

REAC

 — 

Reaction loads from any analysis are applied as force loads (F) in any analysis. Values are in the nodal coordinate system.

CONC

 — 

Concentrations from a diffusion analysis are applied to a subsequent diffusion analysis as nodal loads (D) or initial conditions (IC) when used in conjunction with KIMG=1 or KIMG=2, respectively.

VMEN

 — 

Mean flow velocities from a static mean flow analysis are applied to a subsequent harmonic or modal solution of the convective wave equation as body-force loads (BF).

VOLT

 — 

Voltages from an electric, electrostatic, or electromagnetic analysis are applied to a subsequent electric, electrostatic, or electromagnetic analysis as nodal loads (D) when KIMG = 1 or as initial conditions (IC) when KIMG = 2.

LSTEP

Load step number of the data set to be read. Defaults to 1. If LAST, ignore SBSTEP and TIME and read the last data set.

SBSTEP

Substep number (within LSTEP). If zero (or blank), LSTEP represents the last substep of the load step.

TIME

Time-point identifying the data set to be read. Used only if both LSTEP and SBSTEP are zero (or blank). If TIME is between two solution time points on the results file, a linear interpolation is done between the two data sets. If TIME is beyond the last time point on the file, use the last time point.

KIMG

When used with results from harmonic analyses (ANTYPE,HARMIC) KIMG establishes which set of data to read:

0

 — 

Read the real part of the solution. Valid also for Lab = EHFLU to read in time-average heat flux.

1

 — 

Read the imaginary part of the solution.

2

 — 

Calculate and read the time-average part. Meaningful for Lab = HGEN or FORC.

When used with the PRES label, KIMG represents the shell element face on which to apply the pressure:

1

 — 

Apply pressure to face 1

2

 — 

Apply pressure to face 2

When used with the TEMP label, KIMG indicates how temperatures are to be applied.

0

 — 

Apply temperatures as body loads (BF)

1

 — 

Apply temperatures as nodal loads (D)

2

 — 

Apply temperatures as initial conditions (IC)

When used with the CONC label, KIMG indicates how concentrations are to be applied.

1

 — 

Apply concentrations as nodal loads (D)

2

 — 

Apply concentrations as initial conditions (IC)

When used with the VOLT label, KIMG indicates how voltages are to be applied.

1

 — 

Apply voltages as nodal loads (D)

2

 — 

Apply voltages as initial conditions (IC)

Fname

File name and directory path (248 characters maximum, including the characters needed for the directory path). An unspecified directory path defaults to the working directory; in this case, you can use all 248 characters for the file name.

The file name defaults to Jobname.

Ext

Filename extension (eight-character maximum).

The extension defaults to RST (or RMF for a static mean flow analysis) if Fname is blank.

--

Unused field.

Notes

The LDREAD command reads results data from the results file and applies them as loads.

The command can also apply results from an analysis defined with one physics environment as loads on a second analysis using a different physics environment. Results values are applied as loads for field-coupling effects (for example, output temperatures from a thermal analysis as input to a structural analysis).

The command works based on the assumption that the meshes have not changed.

Nodal loads are applied only to selected nodes. Element loads are applied only to selected elements. Element surface loads are applied only to selected elements where all face nodes for that surface are selected.

To assure proper distribution of the surface loads, select only the nodes on the element face where the surface load is to be applied.

Scaling and accumulation specifications are applied as the loads are read via the following commands:

  • BFCUM for body-force loads. (Heat-generation loads are not accumulated.)

  • SFCUM for surface loads.

  • FCUM for force loads.

List the results via the appropriate list command:

Values may be redefined after being read by issuing LDREAD again with a different load step and substep, or time value.

This command is also valid in PREP7.

Transferring Temperature Output from SHELL131 and SHELL132

If a thermal analysis uses SHELL131 or SHELL132 thermal shell elements, temperatures can be transferred as body force element loads (BFE). In most cases, only the top and bottom temperatures from SHELL131 and SHELL132 are used by the structural shell elements; any interior temperatures are ignored. However, all temperatures are used by SHELL181 having section input, and SHELL281 having section input; for these elements, therefore, the number of temperature points at a node generated in the thermal model must match the number of temperature points at a node needed by the structural model.

When using SHELL131 or SHELL132 information for the LDREAD operation, all element types should specify the same set of thermal degrees of freedom.

Transferring Temperature Output from SOLID278 and SOLID279

If a thermal analysis uses SOLID278 or SOLID279 thermal solid elements, the temperatures are available either at the nodes (KEYOPT(3) = 0) or at the nodes and layers (KEYOPT(3) = 1 or 2). Under normal circumstances, only the nodal temperatures are transferred to the structural elements.

However, if the structural elements are layered solids (KEYOPT(3) = 1 for SOLSH190, SOLID185, SOLID186) and the thermal elements have KEYOPT(3) = 1 or 2 (layered solid) and KEYOPT(8) = 1 (store data for all layers), then the layer temperatures are transferred to the structural elements. If the number of layers do not match, the algorithm reverts back to nodal temperature transfer.

Transferring Temperature Output from SHELL294

If a thermal analysis uses SHELL294 thermal shell elements, temperatures can be transferred as either the nodal body force load at the external nodes (BF) or element body force load at the layers (BFE). The destination structural shell can be SHELL181 or SHELL281.

The availability of element body force loads (BFE) is subject to the following conditions. If the structural shell has only one layer, then the temperatures from the bottom and top of SHELL294 are transferred as element body force loads. If the structural shell has more than one layer, and if the number of material layers specified by section input match between the thermal and structural shells, and if KEYOPT(8) = 1 for SHELL294, then temperatures of all layers are transferred as element body force loads. Otherwise, no temperatures are transferred as element body force loads and the algorithm reverts back to nodal temperature transfer.

Note that nodal body force loads are the temperatures at external nodes. Therefore, if the reference plane is located outside the shell thickness by SECOFFSET,USER,OFFSET, then the nodal body force loads can be noticeably different from the temperature variation through-the-thickness of the shell.

KIMG = 0 (body loads) is the only valid mode for layered temperature transfer.

Menu Paths

Main Menu>Preprocessor>Loads>Define Loads>Apply>Electric>Boundary>Temperature>From Therm Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Fluid/ANSYS>Heat Generat>From Mag Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Initial Condit'n>Temp from ANSYS
Main Menu>Preprocessor>Loads>Define Loads>Apply>Magnetic>Boundary>Temperature>From Therm Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Magnetic>Excitation>AppCurrDens>From Elec An
Main Menu>Preprocessor>Loads>Define Loads>Apply>Magnetic>Other>Electric Field>From Elec An
Main Menu>Preprocessor>Loads>Define Loads>Apply>Structural>Force/Moment>From Mag Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Structural>Force/Moment>From Reactions
Main Menu>Preprocessor>Loads>Define Loads>Apply>Structural>Pressure>From Fluid Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Structural>Temperature>From Therm Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Thermal>Convection>From Fluid Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Thermal>Heat Flux>From EMAG Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Thermal>Heat Flux>From Fluid Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Thermal>Heat Generat>From Mag Analy
Main Menu>Preprocessor>Loads>Define Loads>Apply>Thermal>Temperature>From ANSYS
Main Menu>Solution>Define Loads>Apply>Electric>Boundary>Temperature>From Therm Analy
Main Menu>Solution>Define Loads>Apply>Fluid/ANSYS>Heat Generat>From Mag Analy
Main Menu>Solution>Define Loads>Apply>Initial Condit'n>Temp from ANSYS
Main Menu>Solution>Define Loads>Apply>Magnetic>Boundary>Temperature>From Therm Analy
Main Menu>Solution>Define Loads>Apply>Magnetic>Excitation>AppCurrDens>From Elec An
Main Menu>Solution>Define Loads>Apply>Magnetic>Other>Electric Field>From Elec An
Main Menu>Solution>Define Loads>Apply>Structural>Force/Moment>From Mag Analy
Main Menu>Solution>Define Loads>Apply>Structural>Force/Moment>From Reactions
Main Menu>Solution>Define Loads>Apply>Structural>Pressure>From Fluid Analy
Main Menu>Solution>Define Loads>Apply>Structural>Temperature>From Therm Analy
Main Menu>Solution>Define Loads>Apply>Thermal>Convection>From Fluid Analy
Main Menu>Solution>Define Loads>Apply>Thermal>Heat Flux>From EMAG Analy
Main Menu>Solution>Define Loads>Apply>Thermal>Heat Flux>From Fluid Analy
Main Menu>Solution>Define Loads>Apply>Thermal>Heat Generat>From Mag Analy
Main Menu>Solution>Define Loads>Apply>Thermal>Temperature>From ANSYS