Fully Automated Optimization Workflow for Injection Molding Design and Manufacturing

Edited by Jasmine Ho, Engineer at Technical Support Team, Moldex3D
Customer Profile

Alfred Kärcher SE & Co. KG https://www.kaercher.com/int/inside-kaercher/company/about-kaercher.html

  • Customer: Alfred Kärcher SE & Co. KG
  • Country: Germany
  • Industry: Consumer Products
  • Solution: Moldex3D Advanced Package, Flow, Pack, Cool, Warp, Designer BLM

Kärcher is the market leader worldwide for cleaning solutions, offering over 3000 products – almost all products include at least one molded part. (Source)

Summary

Millions of components are manufactured at Alfred Kärcher SE & Co. KG each year. While the warpage is critical for the functionality and appearance of the components, cost-effectiveness is determined by cycle time and the size of the required molding machine. Kärcher presents a workflow using Moldex3D that enables a fully automated optimization of all objectives. The main benefit of the workflow is the simultaneous parameterization of the component geometry, the process conditions, and the mold design. This enables us to consider the whole design and manufacturing process, beginning at development, to mold making, and finally production.

Challenges

  • Optimization of geometry design, mold design and process conditions
  • Component quality and production cost
  • Automation of the whole simulation process

Solutions

Using Moldex3D API to automate the simulation process

Benefits

  • Finding the global optimum of warpage, filling behavior, cycle time
  • Fully automated simulations
  • Less development time

Case Study

In this study, the target had to solve the warpage issue and reduce the cycle time of the battery slot. There are three main component quality requirements – 1.straight assembly surface, 2.straight battery slide and 3.screw dome position as shown in Fig. 1. To find the optimized solutions, the team conducted some variation setups and used Moldex3D to verify the design changes. The variation setups included the 3 steps below:

In this study, the target had to solve the warpage issue and reduce the cycle time of the battery slot. There are three main component quality requirements – 1.straight assembly surface, 2.straight battery slide and 3.screw dome position as shown in Fig. 1. To find the optimized solutions, the team conducted some variation setups and used Moldex3D to verify the design changes. The variation setups included the 3 steps below:

Fig. 1 The original design and three main quality requirements.

Step 1: Variation of the component design

There were totally 38 geometry related nondependent parameters, including the variation of the existing and additional ribs (Fig. 2).

There were totally 38 geometry related nondependent parameters, including the variation of the existing and additional ribs (Fig. 2).

Fig. 2 Parameters for geometry optimization

Step 2: Variation of the mold design

In this study, only the gate locations were varied (Fig. 3 a).

 

Step 3: Variation of the process conditions

There were 14 manufacturing process related parameters, including filling time, packing time, packing pressure, melt temperature, switch over time, temperature of the coolant (Fig. 3 b) and cooling time.

There were 14 manufacturing process related parameters, including filling time, packing time, packing pressure, melt temperature, switch over time, temperature of the coolant (Fig. 3 b) and cooling time.

Fig. 3 (a) Variation of gate locations; (b) Variation of coolant temperature

After the variation setups, they proceeded the verifications through Moldex3D API (Fig. 4). Over 200 simulations were performed in the following application and calculation time was less than one week on a single computer using 12 cores. Parallel execution of multiple simulations could further decrease the simulation time.

After the variation setups, they proceeded the verifications through Moldex3D API (Fig. 4). Over 200 simulations were performed in the following application and calculation time was less than one week on a single computer using 12 cores. Parallel execution of multiple simulations could further decrease the simulation time.

Fig. 4 Moldex3D API sketch chart

To get flexible and individual response values for the optimizations, they added probe nodes in the compelling areas. The warpage was probed at 32 locations and optimization was done by root mean square of five groups (Fig. 5).

To get flexible and individual response values for the optimizations, they added probe nodes in the compelling areas. The warpage was probed at 32 locations and optimization was done by root mean square of five groups (Fig. 5).

Fig. 5 The optimization areas for warpage reduction

Two optimized designs were chosen to observe the warpage and cycle time results. If optimization was focused on warpage, the warpage was strongly reduced while maintaining cycle time at an economically viable level (Fig. 6). In addition, if the optimization is focused on cycle time, the cycle time was shortened while the warpage was reduced significantly (Fig. 7). Moreover, Moldex3D simulation results shows a strong correlation with the real part (Fig. 8).

Two optimized designs were chosen to observe the warpage and cycle time results. If optimization was focused on warpage, the warpage was strongly reduced while maintaining cycle time at an economically viable level (Fig. 6). In addition, if the optimization is focused on cycle time, the cycle time was shortened while the warpage was reduced significantly (Fig. 7). Moreover, Moldex3D simulation results shows a strong correlation with the real part (Fig. 8).

Fig. 6 Comparison between original design and revised design (Optimization focus on warpage)

Two optimized designs were chosen to observe the warpage and cycle time results. If optimization was focused on warpage, the warpage was strongly reduced while maintaining cycle time at an economically viable level (Fig. 6). In addition, if the optimization is focused on cycle time, the cycle time was shortened while the warpage was reduced significantly (Fig. 7). Moreover, Moldex3D simulation results shows a strong correlation with the real part (Fig. 8).

Fig. 7 Comparison between original design and revised design (Optimization focused on cycle time)

Two optimized designs were chosen to observe the warpage and cycle time results. If optimization was focused on warpage, the warpage was strongly reduced while maintaining cycle time at an economically viable level (Fig. 6). In addition, if the optimization is focused on cycle time, the cycle time was shortened while the warpage was reduced significantly (Fig. 7). Moreover, Moldex3D simulation results shows a strong correlation with the real part (Fig. 8).

Fig. 8 Validation on the simulation results

In conclusion, Moldex3D brought a great level of automatization and customization to simulation workflow. The component geometry, mold design as well as the molding process could be varied in one workflow, and reliable simulation results could be obtained with small error discrepancy.

Results

In this study, Moldex3D API helped the Alfred Kärcher team reduce warpage by more than 70% as well as the cycle time. With the automated simulation process provided by Moldex3D API, no user input was required to run a complete simulation. Furthermore, other functionality could be integrated as well. Using a CAD system to automatically create and vary the component geometry. Apart from the component geometry, the software allows users to vary many parameters related to the mold design and the molding process. It also helps users to find the global optimum of warpage, filling behavior, cycle time and other target metrics, while reducing development time significantly.


#75 Ferro silicon

Ferro Silicon is mainly used as a deoxidizer in the steel making industry, in order to obtain chemical composition of qualified steel and to improve the quality of steel.Also used as inoculants and nodulizers in the cast iron industry and reducing agent in ferro alloy production. And used as welding electrode coating in the electrode manufacturing industry.

Fesi 75Silicon Alloy,Ferrosilicon 75 Fesi,Ferrosilicon75 Silicon Alloy,75 Silicon Fesi Alloy

ANYANG GUOQI SILICON INDUSTRY CO.,LTD , https://www.siliconxg.com