Micro nanocomposite material with high thermal conductivity and preparation method thereof

A composite material and micro-nano technology, applied in the field of thermally conductive composite materials, can solve the problems of high thermal conductivity, good comprehensive mechanical properties, easy agglomeration, etc., and achieve excellent thermal conductivity, enhanced mechanical properties, and easy heat conduction network.

Inactive Publication Date: 2014-06-04
SOUTH CHINA UNIV OF TECH
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

The main problems of composite thermally conductive materials filled with micron-scale thermally conductive fillers: (1) In the case of low filling amount of thermally conductive fillers, the thermal conductivity of the composite material is not high; (2) In the case of high filling amount (greater than 30%), although The thermal conductivity has been significantly improved, but the comprehensive mechanical properties of the material have dropped sharply and significantly, which cannot meet the requirements of engineering use at all.
In contrast, composites modified by nanoscale carbon nanotubes, graphene or nano-graphite flakes have good thermal conductivity and mechanical properties, but these nano-thermal conductive fillers are easy to agglomerate in the polymer matrix, resulting in composite materials The improvement of thermal conductivity is limited, and the preparation yield of nanofillers is low, making it difficult for industrial production
In short, the existing composite heat-conducting materials cannot achieve high thermal conductivity and good comprehensive mechanical properties at the same time, and it is difficult to meet the actual needs of performance, thus limiting the wide application of heat-conducting composite materials

Method used

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Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0024] (1) Add 1.5g of graphite to 100mL of benzylamine N,N-dimethylacetamide solution with a mass concentration of 1% under high-speed stirring, and stir at 6000rpm for 30 minutes, followed by ultrasonic stripping (ultrasonic frequency is 25KHZ, Ultrasonic power is 100W) after 1 hour, after filtering and drying, the thermally conductive filler with micro-nano structure can be obtained.

[0025] (2) Dissolve 19 g of polymethyl methacrylate (PMMA) in 100 mL of N,N-dimethylformamide under heating (50° C.) and stirring to obtain a PMMA solution.

[0026] (3) Add 1g of micro-nano structure heat-conducting filler into the PMMA solution prepared by (2) under stirring, obtain a uniformly dispersed mixed solution after stirring at a high speed of 6000rpm for 30 minutes, and slowly pour the obtained mixed solution under stirring After entering the water, the polymer mixed liquid is flocculated into a solid, and after filtering, washing 3 times, and drying, the micro-nano composite mate...

Embodiment 2

[0030] (1) Add 7.2g of expanded graphite into 120mL of N,N-dimethylformamide with a mass concentration of 3% naphthylamine under high-speed stirring, and stir at 10000rpm for 60 minutes, followed by ultrasonic stripping (ultrasonic frequency is 25KHZ, Ultrasonic power is 300W) After 8 hours, a suspension was obtained. The obtained suspension is filtered and dried to obtain the thermally conductive filler with micro-nano structure.

[0031] (2) Melting and mixing 6 g of the micro-nano structured heat-conducting filler and 14 g of polyvinyl chloride in an internal mixer to obtain a micro-nano composite material. The prepared micro-nano composite material is put into a standard mold and hot-pressed at 180° C. and 12 MPa to obtain a high thermal conductivity micro-nano composite material. The mass content of the thermally conductive filler in the composite material is 30%.

[0032] As a comparative example, a graphite-modified PVC composite (referred to as PVC‐Gn‐30) was prepare...

Embodiment 3

[0035] (1) Add 7g of expanded graphite to 350mL of naphthylamine N,N-dimethylacetamide with a mass concentration of 2% under high-speed stirring, stir at 9000rpm for 40 minutes, and then ultrasonic stripping (ultrasonic frequency is 25KHZ, ultrasonic Power is 900W) After 10 hours, a suspension was obtained. The obtained suspension is filtered and dried to obtain the thermally conductive filler with micro-nano structure.

[0036] (2) Dissolve 14g of polyvinylidene fluoride (PVDF) in 100mL of N,N-diylacetamide under heating (50°C) and stirring to obtain a PVDF solution.

[0037] (3) Add 6g of micro-nano structured filler into the PVDF solution prepared in (2), stir at 10000rpm for 40 minutes to obtain a uniformly dispersed mixed solution, slowly pour the mixed solution into water under stirring, and the polymer mixed solution flocculates into a solid , after filtering, washing with water for 3 times, and drying, the micro-nano composite material was obtained, wherein the mass c...

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PUM

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Abstract

The invention discloses a micro nanocomposite material with high thermal conductivity and a preparation method thereof. The preparation method comprises the following steps: dispersing graphite or expanded graphite into a surface modifier solution, stirring at a high speed for 30-60 minutes, then performing ultrasounic stripping on the obtained mixture for 0.5-10 hours, filtering and drying to obtain micro nano structure thermal conducting filler; mixing the micro nano structure thermal conducting filler with a thermal plasticity polymer by virtue of fusion or solution, so as to obtain a micro nanocomposite material, then placing the obtained micro nanocomposite material into a mould, and performing hot press molding at the temperature of 170-300 DEG C and the pressure of 10-18MPa, so that the micro nanocomposite material with high thermal conductivity is obtained, wherein quality content of the micro nanocomposite material in a composite material is 5-30%. The micro nanocomposite material with high thermal conductivity is prepared through ultrasonic stripping under action of surfactant while graphite or expanded graphite is taken as a raw material. The micro nancomposite material with high thermal conductivity has excellent thermal conductivity and good mechanical property and is simple to prepare and low in cost.

Description

technical field [0001] The invention relates to a thermally conductive composite material, in particular to a high thermally conductive micro-nano composite material with excellent thermal conductivity and a preparation method thereof. Background technique [0002] As a widely used material, polymer has the advantages of corrosion resistance, light weight, low price, easy processing and molding, and its mechanical properties can be compared with metal materials, so it can replace metal in chemical industry, energy, and heat dissipation of electronic devices. , electronic information, electrical engineering, aerospace and other fields have potential application prospects. However, the poor thermal conductivity of polymers cannot meet the high thermal conductivity requirements in practical engineering. Therefore, the development of composite materials with excellent thermal conductivity is the key to the large-scale application of polymers. [0003] It is an effective way to...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C08L27/16C08L33/12C08L81/06C08L77/00C08L27/18C08L69/00C08L27/06C08K9/04C08K3/04C08K7/24
Inventor 裴丽霞叶庆勤张立志
Owner SOUTH CHINA UNIV OF TECH
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