[SCIENCE CHINA Materials] Controlled length and number of thermally conductive pathways for copper wire/poly(lactic acid) composites via 3D printing
作者:Tengbo Ma, Kunpeng Ruan, Yongqiang Guo*, Yixin Han and Junwei Gu
關鍵字:thermally conductive pathways
論文來源:期刊
具體來源:SCIENCE CHINA Materials
發表時間:2024年
Tengbo Ma, Kunpeng Ruan, Yongqiang Guo*, Yixin Han and Junwei Gu*. Controlled length and number of thermally conductive pathways for copper wire/poly(lactic acid) composites via 3D printing. SCIENCE CHINA Materials, 2023, 66(10): 4012 - 4021. 2022IF=8.1.
https://www.sciengine.com/SCMs/doi/10.1007/s40843-023-2540-9
Abstract
Thermal conduction pathways play a crucial role in understanding the thermal behavior of thermally conductive polymer composites, yet there is a lack of in-depth research on the mechanism of how the properties of thermal conduction pathways (length, number) affect the thermal conductivity of polymer composites. In this study, one-dimensional copper wire/poly(lactic acid) (1D Cw/PLA) thermally conductive composites with controllable length and quantity of copper wire (Cw) thermal conduction pathways were fabricated using 3D printing technology. A thermal conduction model for polymer composites with one-dimensional thermal conduction pathways was established, elucidating the quantitative relationship between the properties of thermal conduction pathways and their thermal performance. With the same Cw content, the in-plane thermal conductivity (λ//) of 1D Cw/PLA thermally conductive composites is positively correlated with the number and length of thermal conduction pathways. When the Cw volume fraction is 25.1 vol%, the λ// of the 1D Cw/PLA thermally conductive composites containing 20 Cw intact thermal conduction pathways can reach up to 4.23 W/(m·K), which is 87.2% higher than the λ// of the 1D Cw/PLA thermally conductive composites without Cw intact thermal conduction pathways (2.26 W/(m·K)), 72.0% higher than the λ// of the 1D Cw/PLA thermally conductive composites containing short Cw (2 intact Cw, 18 broken at 1/2 point Cw) (2.46 W/(m·K)), and 1527% higher than the λ// of the pure PLA matrix (0.26 W/(m·K)). Using the thermal conduction model and empirical equations constructed in this study, the thermal conductivity of 1D Cw/PLA composites was predicted, and it was found that there was no significant difference between the predicted values and the measured values at a 95% confidence level.
導熱通路對理解導熱高分子復合材料的導熱行為至關重要,但目前有關導熱通路屬性(長度、數量)對高分子復合材料導熱系數的影響機制缺乏深入的研究。本文采用3D打印技術制備了銅線(Cw)導熱通路長度和數量可控的一維銅線/聚乳酸(1D Cw/PLA)導熱復合材料,建立了針對一維導熱通路的高分子復合材料的導熱模型,明晰了其導熱通路屬性與其導熱性能的定量關系。相同Cw用量下,1D Cw/PLA導熱復合材料的面內導熱系數(λ//)與導熱通路的數量和長度成正相關。當Cw體積分數為25.1 vol%時,含20根Cw貫穿導熱通路的1D Cw/PLA導熱復合材料的λ//最高可達4.23 W/(m·K),比相同Cw用量下不含Cw貫穿導熱通路的1D Cw/PLA導熱復合材料λ//(2.26 W/(m·K))高87.2%,比相同Cw用量下含短Cw(2根貫穿的Cw,18根在1/2處被打斷的Cw)的1D Cw/PLA導熱復合材料的λ//(2.46 W/(m·K))高72.0%,較純PLA基體的λ//(0.26 W/(m·K))提高了1527%。采用本文構建的導熱模型和經驗方程對1D Cw/PLA復合材料的導熱系數進行預測,95%的置信度認為預測值與實測值無顯著差異。