Abstract
Conformal cooling (CC) channels are a series of cooling channels that are equidistant from the mold cavity surfaces. CC systems show great promise to substitute conventional straight-drilled cooling systems as the former can provide more uniform and efficient cooling effects and thus improve the production quality and efficiency significantly. Although the design and manufacturing of CC systems are getting increasing attention, a comprehensive and systematic classification, comparison, and evaluation are still missing. The design, manufacturing, and applications of CC channels are reviewed and evaluated systematically and comprehensively in this review paper. To achieve a uniform and rapid cooling, some key design parameters of CC channels related to shape, size, and location of the channel have to be calculated and chosen carefully taking into account the cooling performance, mechanical strength, and coolant pressure drop. CC layouts are classified into eight types. The basic type, more complex types, and hybrid straight-drilled-CC molds are suitable for simply-shaped parts, complex-shaped parts, and locally complex parts, respectively. By using CC channels, the cycle time can be reduced up to 70%, and the shape deviations can be improved significantly. Epoxy casting and laser powder bed fusion (L-PBF) show the best applicability to aluminum (Al)-epoxy molds and metal molds, respectively, because of the high forming flexibility and fidelity. Meanwhile, laser powder deposition (LPD) has an exclusive advantage to fabricate multi-materials molds although it cannot print overhang regions directly. Hybrid L-PBF/computer-numerical-control (CNC) milling pointed out the future direction for the fabrication of high dimensional-accuracy CC molds, although there is still a long way to reduce the cost and raise efficiency. CC molds are expected to substitute straight-drilled cooling molds in the future, as it can significantly improve part quality, raise production rate and reduce production cost. In addition to this, the use of CC channels can be expanded to some advanced products that require high-performance self-cooling, such as gas turbine engines, photoinjectors and gears, improving working conditions and extending lifetime.
Highlights
The thermoforming process plays a key role in manufacturing, where a molten or thermally softened material is injected/compressed into molds and cooled to resolidify in the form of the designed shape
In addition to a proper design to meet the requirement of cooling performance, there is an important concern pertaining to the Conformal cooling (CC) channel system, namely its manufacturability [66]
The removal of the master model and/or patterns of CC channels can be accomplished in two ways: (a) using acetone liquid and pressurized water to remove sand-filled epoxy master and patterns [161], or (b) heating up to melt away the patterns made of low-melting-temperature metal such as Cu [162]
Summary
The thermoforming process plays a key role in manufacturing, where a molten or thermally softened material is injected/compressed into molds and cooled to resolidify in the form of the designed shape. The distance between the straight channel and the curved surface of the cavity varies along the channel, inducing differential cooling rates at the cavity surface and a temperature nonuniformity that results in differential shrinkage and warpage in the manufactured part [5]. The parts produced by thermoforming possess a thin shell, complex curved surface, and/or deep hollow features [7] In such cases, differential shrinkage and warpage are more severe and the cooling rates are much lower, since the deep hollow feature tends to induce local heat accumulation [8]. Differential shrinkage and warpage are more severe and the cooling rates are much lower, since the deep hollow feature tends to induce local heat accumulation [8] This may require expensive rectification of the mold to ensure the dimensional accuracy of the part [9].
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