Effectiveness of Conformal Cooling for a V-Shaped Plate and its Influence on Warpage

Silicone rubber mold (SRM) is capable of reducing the cost and time in a new product development phase and has many applications for the pilot runs. Unfortunately, the SRM after injection molding has a poor cooling efficiency due to its low thermal conductivity. To improve the cooling efficiency, the thermal conductivity of the SRM was improved by adding fillers into the SRM. An optimal recipe for fabricating a high cooling efficiency low-pressure injection mold with conformal cooling channel fabricated by fused deposition modeling technology was proposed and implemented. This study proposes a recipe combining 52.6 wt.% aluminum powder, 5.3 wt.% graphite powder, and 42.1 wt.% liquid silicon rubber can be used to make SRM with excellent cooling efficiency. The price–performance ratio of this SRM made by the proposed recipe is around 55. The thermal conductivity of the SRM made by the proposed recipe can be increased by up to 77.6% compared with convention SRM. In addition, the actual cooling time of the injection molded product can be shortened up to 69.1% compared with the conventional SRM. The actual cooling time obtained by the experiment is in good agreement with the simulation results with the relative error rate about 20%.

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Design and fabrication of conformal cooling channels in molds: Review and progress updates

International Journal of Heat and Mass Transfer ◽

10.1016/j.ijheatmasstransfer.2021.121082 ◽

2021 ◽

Vol 171 ◽

pp. 121082

Author(s):

Shaochuan Feng ◽

Amar M. Kamat ◽

Yutao Pei

Keyword(s):

Conformal Cooling ◽

Cooling Channels ◽

Conformal Cooling Channels

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On the Use of Conformal Cooling in High-Pressure Die-Casting and Semisolid Casting

Technologies ◽

10.3390/technologies9020039 ◽

2021 ◽

Vol 9 (2) ◽

pp. 39

Author(s):

Anders E. W. Jarfors ◽

Ruslan Sevastopol ◽

Karamchedu Seshendra ◽

Qing Zhang ◽

Jacob Steggo ◽

...

Keyword(s):

High Pressure ◽

Die Casting ◽

Life Extension ◽

Conformal Cooling ◽

High Pressure Die Casting ◽

Cooling Channels ◽

Die Life ◽

Die Materials ◽

Pressure Die Casting ◽

Semisolid Casting

Today, tool life in high pressure die casting (HPDC) is of growing interest. A common agreement is that die life is primarily decided by the thermal load and temperature gradients in the die materials. Conformal cooling with the growth of additive manufacturing has raised interest as a means of extending die life. In the current paper, conformal cooling channels’ performance and effect on the thermal cycle in high-pressure die casting and rheocasting are investigated for conventional HPDC and semisolid processing. It was found that conformal cooling aids die temperature reduction, and the use of die spray may be reduced and support the die-life extension. For the die filling, the increased temperature was possibly counterproductive. Instead, it was found that the main focus for conformal cooling should be focused to manage temperature around the in-let bushing and possibly the runner system. Due to the possible higher inlet pressures for semisolid casting, particular benefits could be seen.

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Fabrication of circular cooling channels by cold metal transfer based wire and arc additive manufacturing

Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture ◽

10.1177/0954405421995613 ◽

2021 ◽

pp. 095440542199561

Author(s):

Shaohua Han ◽

Zhongzhong Zhang ◽

Pengxiang Ruan ◽

Shiwen Cheng ◽

Dingqi Xue

Keyword(s):

Additive Manufacturing ◽

High Energy ◽

Cooling Effect ◽

High Deposition Rate ◽

Cooling Channel ◽

Conformal Cooling Channel ◽

Conformal Cooling ◽

Energy Beam ◽

Cooling Channels ◽

Straight Line

Additive manufacturing has been proven to be a promising technology for fabricating high-performance dies, molds, and conformal cooling channels. As one of the manufacturing methods, wire and arc additive manufacturing displays unique advantages of low cost and high deposition rate that are better than other high energy beam-based ones. This paper presents a preliminary study of fabricating integrated cooling channels by CMT-based wire and arc additive manufacturing process. The deposition strategies for fabricating circular cross-sectional cooling channels both in conformal and straight-line patterns have been investigated. It included optimizing the welding torch angle, fabricating the enclosed semicircle structure and predicting the collision between the torch and constructed part. The cooling effect test was also conducted on both the conformal cooling channel and straight-line cooling channel. The results affirmed a higher cooling efficiency and better uniform cooling effect of the conformal cooling channel than straight-line cooling channel.

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