New PRM File Creation

Custom scaling factors

By default, Powder properties, shown at the bottom of the New Process Parameters dialog, are approximated in PRM generation simulations using scaling factors. The powder property scaling factors are as follows:

• Powder Thermal Conductivity = Solid Thermal Conductivity × 1E-2
• Powder Specific Heat Capacity = Solid Specific Heat Capacity × 1
• Powder Elastic Modulus = Solid Elastic Modulus × 1E-4
• Powder Thermal Emissivity = Solid Thermal Emissivity × 1.8

To directly specify the powder properties, select Custom scaling factors in the Powder field, and adjust the values shown below.

Analysis tab

On this tab, you can specify the type of analysis covered by the PRM file. Three possible types of PRM file can be created:

• Stress and distortion
• Hot spots and lack of fusion
• Both Stress and distortion and Hot spots and lack of fusion

Stress and distortion is the default setting. If you select Hot spots and lack of fusion analysis, then the three temperature fields are activated for use.

For each of the following three temperature settings, you can enter multiple temperatures, separated by semi-colons, as shown above. You must provide at least one Lack of fusion temperature, or one Hot spot temperature, and one Interlayer temperature.

Lack of fusion temperature: Specify one or more temperatures below which the powder material will not fuse.

Hot spot temperatures: Specify one or more temperatures above which the powder is considered overheated. Different temperatures can represent the points at which particular undesirable phenomena occur.

Interlayer temperatures: Specify one or more temperatures that represent the material temperature at the start of laying down a new layer. Providing more values creates a PRM with higher resolution, but increased run time.

Best practices

To determine what interlayer temperatures are necessary, it is suggested that the part level geometry or geometries of interest for that combination of processing conditions are simulated using a standard stress and distortion PRM, and choosing the Thermal Only Analysis type in the Solver Settings menu. Determine from the simulation(s) the peak temperatures that can be experienced. This should be used for the upper interlayer temperatures, rounded up to the next 100° C. The lowest temperature should be set to the ambient temperature, typically 25º C. To determine what other temperatures should be used, plot the thermal properties of the material in question with respect to temperature. Add additional interlayer temperatures where observable non-linearities occur.

Advanced tab

This tab provides options to protect the intellectual property in your PRM, or to adjust the numeric relaxation used by the solver during PRM generation.

Permanently encrypt processing parameters

By default, when a part-level simulation is run, the processing conditions used to generate the PRM file used are written to the log files. If the processing conditions are proprietary, users may want to encrypt them. Checking this box will encrypt the processing parameters in the PRM file and they will not be written to the log files. This choice is persistent, so once selected, all PRM files created will have encrypted processing parameters until this option is deselected.

Permanently encrypt material properties

By default, when a part-level simulation is run, the material properties used to generate the PRM file used are written to the log files. If the material properties are proprietary, users may want to encrypt them. Checking this box will encrypt the material properties in the PRM file and they will not be written to the log files. This choice is persistent, so once selected, all PRM files created will have encrypted material properties until this option is deselected.

Thermal model numeric relaxation and Mechanical model numeric relaxation

These options are used to control the under-relaxation of the Newton-Raphson solver during PRM generation.

• Generally, the default values above should lead to a converged solution.
• Before attempting to improve convergence using the relaxation controls, it is suggested the user increase Laser Beam Diameter input. This value has minimal impact upon the part-level stress and distortion predictions. Use a value up to twice as large as what is given by the machine.
• If the thermal or mechanical PRM generation analysis fails, it is recommended that the Relaxation iterations for that analysis type be increased to 2.
• Reducing the Relaxation scaling factor will also aid convergence, but not as effectively as increasing the iterations.
• Increasing relaxation may slow the simulation speed.
• Scaling factors below 0.1 or above 0.5 are not recommended.
• Relaxation iterations above 3 are not recommended.
• If the PRM generation does not converge using the maximum recommended relaxation, of 3 iterations and a 0.1 scaling factor, there may be problems with custom processing conditions or custom material properties.

Export PRM input files

If you want to save the new PRM thermal and mechanical input file settings for later generation, such as in batch mode from the command line, you can do so by clicking Export Files in the lower left of the New Process Parameters dialog.

The Export Files dialog opens, where you specify where to save the input files, and the proposed PRM file name.

PRM execution

After entering all required options and selecting to generate the PRM file, you are prompted to save the file to a name of your choosing, and then the PRM generation starts. The Job Manager opens when PRM generation starts, so you can check the progress of the operation and click View Logs for more detail.