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[1]于天驕,宋 偉,李琳,等.復合導熱硅橡膠研究進展[J].中國材料進展,2025,44(12):020-29.
 YU Tianjiao,SONG Wei,LI Lin,et al.Research progress of composite thermally conductive silicone rubber[J].MATERIALS CHINA,2025,44(12):020-29.
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復合導熱硅橡膠研究進展()
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中國材料進展[ISSN:1674-3962/CN:61-1473/TG]

卷:
44
期數:
2025年12
頁碼:
020-29
欄目:
出版日期:
2025-12-30

文章信息/Info

Title:
Research progress of composite thermally conductive silicone rubber
作者:
于天驕1宋 偉1李琳2宋文宏1孫 宇1
哈爾濱理工大學 工程電介質及其應用教育部重點實驗室,黑龍江省 哈爾濱市 150000
Author(s):
YU Tianjiao1SONG Wei1LI Lin2SONG Wenhong1SUN Yu1
1. Key Laboratory of Engineering Dielectrics and Their Applications, Ministry of Education, Harbin University of Science and Technology, Harbin, Heilongjiang 150000 2. State Grid Heilongjiang Electric Power Company Limited Electric Power Research Institute, Harbin, Heilongjiang 150000
關鍵詞:
SR導熱機理無機填料制備方式填料取向
Keywords:
SR the thermal conductivity mechanism Inorganic fillers preparation method filler orientation
分類號:
TM215.2
文獻標志碼:
A
摘要:
隨著電氣行業的飛速發展,各類電氣設備、電子器件功率愈發增高,對絕緣散熱材料的需求也隨之增加,硅橡膠(SR)具有優越的絕緣性及穩定性,將高導熱無機填料引入到SR體系中提升其導熱性,成為導熱絕緣方向的研究熱點。本文概述了填充型高分子復合物的導熱機理及相應的導熱函數模型,結合函數模型綜述了無機填料的形狀、尺寸及界面熱阻對填充型導熱SR導熱性的影響。無機填料按照一定取向排列能夠使SR在較少的填充下獲得較高的導熱性。導熱SR的不同制備方式影響無機填料在SR中的狀態,根據固體SR和液體SR的自身特性,我們總結了能夠使無機填料按一定取向排列在SR中的制備方法。最后,我們歸納了導熱SR的研究瓶頸并對其未來的研究方向進行展望。
Abstract:
With the development of the electrical industry, the power of various electrical equipment and electronic devices is increasing. The demand for insulating materials to dissipate heat has also increased. SR has excellent insulation and stability. Adding high thermal conductivity inorganic fillers to the SR system to improve its thermal conductivity has become a research hotspot in the direction of thermal conductivity of insulation. This paper summarizes the thermal conduction mechanism of the filled composites and the corresponding thermal conduction function model. We combined the functional model to review the influence of the shape, size and interfacial thermal resistance of inorganic fillers on the thermal conductivity of SR. The oriented arrangement of inorganic fillers can make SR obtain higher thermal conductivity with less inorganic fillers. Different preparation methods of thermally conductive SR can affect the filling state of inorganic fillers in SR. According to the characteristics of solid SR and liquid SR, we summarize the preparation methods that can make inorganic fillers arranged in SR according to a certain orientation. Finally, we summarize the research bottlenecks of thermally conductive SR and prospect its future research directions.

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備注/Memo

備注/Memo:
基金項目:國家自然科學基金資助項目(51607048,51541702);國網黑龍江省電力有限公司電力科學研究院資助項目(SGHLDKOOPJJS1900143);黑龍江省自然科學基金資助項目(QC2015063) 第一作者:于天驕,男,1993年生,碩士研究生第一作者:于天驕,男,1993年生,碩士研究生
更新日期/Last Update: 2024-02-27
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