Ribs are often used to strengthen product mechanical properties; however, surface defects such as sink marks may occur due to uneven shrinkage caused by the varying thicknesses at the intersections of part surface and rib.

In addition to the part geometry, the occurrence of sink marks is also closely associated with the packing conditions. Prior to the application of CAE technology, obtaining a set of optimized processing conditions to reduce sink marks heavily relied on trial-and-error and the experiences of the molders.

However, with the complexity of product designs and the fierce competition in today’s manufacturing world, the old ways of product development such as trial-and-error or relying on the experiences of seasoned molders no longer support the fast turnaround time demanded by customers.

In order to tackle this sink mark issue head-on and reduce mold-trial costs, Moldex3D has introduced a useful simulation capability – Sink Mark Displacement Analysis. Moldex3D’s Sink Mark Displacement analyzes the sinking behavior in the packing stage based on the part geometry and the material used and accurately calculates the displacement values of surface sink marks. It truthfully captures the sink mark phenomenon of injection-molded parts and provides a valuable reference for product optimization and parameters adjustments prior to the actual production.

The following is a real case utilizing Moldex3D’s Sink Mark Displacement Analysis to predict the sink mark behavior.

Based on the analysis of volumetric shrinkage in the packing stage, the part’s flat surface exhibits an even distribution of volumetric shrinkage values. The volumetric shrinkage values, however, are unevenly distributed at the intersections of the part surface and rib. Thus, it is evident that the thicker the rib is, the bigger the shrinkage value will be, which further indicates a bigger chance of sink mark occurrence.

Pic shows a clear comparison of Moldex3D’s Sink Mark Displacement Analysis with the observation of sink marks on a real injection-molded part. The result from the experiment shows that when rib thickness becomes thicker, sink marks appeal to be deeper as well.

To better predict the sink mark behavior of complex part geometries, Moldex3D has continued to improve its simulation capability for Sink Mark Displacement Analysis.

The enhancement of the Sink Mark Displacement Analysis is a strong evidence of Moldex3D’s continuous efforts in improving the software capabilities and simulation accuracy. The improved software predictions will most certainly benefit users in designing their plastic products, especially for parts with complex geometries and help visualize potential problematic areas for in-time corrections and remedies to reduce costly mold tryouts and shorten product time-to-market.