Thickness analysis software is a CAD tool that facilitates the measurement and validation of wall thickness of 3-D CAD models. It accelerates the design review process for manufacturability, enabling designs to move to prototyping and production stages much faster. Unlike the traditional measurement tools, the right thickness analysis software should be fast and easy to use, while delivering savings in downstream costs through improvements at the design stage itself.
It should implement two main methods of thickness measurement: (1) normal ray and (2) rolling sphere, while providing the user the flexibility to select the analysis method based on the geometry of the part.
Thickness analysis software quickly identifies thick and thin areas on the
Design engineers need to maintain a consistent wall thickness, and any change in the wall thickness needs to be smooth, in order to ensure ease of flow and a stress-free part. Thickness analysis software that has automatic rolling sphere-based computation can help to identify regions that do not have consistent wall thickness
Thickness analysis software identifies change in thickness gradient
Molds must be provided with adequate cooling in order to take advantage of the faster cooling rates of reinforced compounds. Poor cooling rates lead to rising mold temperatures and longer cycle times. They also can result in voids, shorts and poor surface finish. So, cooling and heating channels should be located directly in the mold inserts and cores, if the mold design permits. Thickness analysis software that can automatically provide 3-D thickness on the entire model helps indentify thicker areas in the mold design, which require cooling or heating channels.
Thickness analysis software identifies heavy sections in the mold design.
It should implement two main methods of thickness measurement: (1) normal ray and (2) rolling sphere, while providing the user the flexibility to select the analysis method based on the geometry of the part.
Applications
The right thickness analysis software should be integrated within a CAD application. This helps design engineers to detect inconsistent and thick/thin wall sections automatically. The designers can then reduce the possibility of internal voids, surface sink marks, warpage, unpredictable shrink rates, unnecessary resin content, longer cycle time and increased part cost . entire model. These can be corrected at the design stage itself, and design
engineers can core out the thick regions to reduce sink marks and also
the cycle time
Consistent Wall Thickness:-
Design engineers need to maintain a consistent wall thickness, and any change in the wall thickness needs to be smooth, in order to ensure ease of flow and a stress-free part. Thickness analysis software that has automatic rolling sphere-based computation can help to identify regions that do not have consistent wall thickness
Rib Design:-
Designers follow standard design guidelines for rib design. Some of the common guidelines prevalent in the industry are:- Rib thickness should be 60 to 80 percent of nominal wall thickness
- Maximum height should not exceed three times nominal wall thickness
- Minimum spacing between ribs should be two times the nominal wall thickness
- Thick ribs should be cored out
Cooling and Ejector Pin Location:-
Molds must be provided with adequate cooling in order to take advantage of the faster cooling rates of reinforced compounds. Poor cooling rates lead to rising mold temperatures and longer cycle times. They also can result in voids, shorts and poor surface finish. So, cooling and heating channels should be located directly in the mold inserts and cores, if the mold design permits. Thickness analysis software that can automatically provide 3-D thickness on the entire model helps indentify thicker areas in the mold design, which require cooling or heating channels.
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