CN105131733A - High-adhesion heat-dissipating coating material and preparation method thereof - Google Patents

Abstract

The present invention discloses a high-adhesion heat-dissipating coating material, which comprises the following raw materials by weight: 3-4 parts of barium petroleum sulfonate, 12-15 parts of a styrene-maleic anhydride copolymer, 6-10 parts of propargyl alcohol, 90-100 parts of tetrahydrofuran, 4-7 parts of graphene, 16-20 parts of nanometer silica, 0.2-0.3 part of a silane coupling agent KH560, 700-800 parts of dimethylformamide, 4-5 parts of sodium nitride, 0.04-0.05 part of aluminum trichloride, 1.6-2 parts of a 2-3%sodium ascorbate solution, 1.8-2 parts of a 2-3% copper sulfate solution, 120-130 parts of high-density polyethylene, 0.6-1 part of m-dihydroxybenzene, 1-2 parts of hexadecyl trimethyl ammonium bromide, 3-4 parts of phthalic acid polyester, 0.3-0.5 part of alkenyl succinic anhydride, 0.2-0.3 part of casein, 0.7-1 part of calcium ricinoleate, and 2-4 parts of diatomite. According to the present invention, the coating material has characteristics of reasonable raw material compounding, effective coaling film surface temperature reducing, and long service life.

Description

A kind of high bonding heat radiation coating and preparation method thereof

Technical field

The present invention relates to heat radiation coating technical field, particularly relate to a kind of high bonding heat radiation coating and preparation method thereof.

Background technology

Along with the fast development of modern science and technology, intensive and the miniaturization of the high frequency of electron device, high speed and unicircuit, the overall power density of unit volume electron device and thermal value are increased by a wide margin, thus makes the cooling problem of electron device become more and more outstanding.And the cooling power that the cooling system of routine can reach is subject to great challenge, especially in fields such as the energy, automobile, air-conditioning, agricultural, chemical industry, heating, aerospace, microelectronics, information, the technology such as enhancement of heat transfer, raising radiating efficiency are had higher requirement.And heat radiation coating is a kind of body surface radiating efficiency that improves, reduce the speciality coating of system temperature, heat radiation coating is coated with the radiating efficiency that can improve electron device on the electronic devices;

Nano silicon is because having in tridimensional network, and stability, reinforcing and thickening property is superior, low price, the feature such as easily to produce, is widely used in corrosion protection coating, to improve carrying and the antiseptic power of coating.The specific surface area of nano silicon is large, and specific surface energy is high, and easily occur in the coating reunite and form offspring, cause the performance of activeness and quietness to reduce, the hydroxyl on its surface also enhances this kind of phenomenon simultaneously.Therefore, improving the dispersiveness of nanosized SiO_2 in organic coating is problem demanding prompt solution.

Summary of the invention

The object of the invention is exactly the defect in order to make up prior art, provides a kind of high bonding heat radiation coating and preparation method thereof.

The present invention is achieved by the following technical solutions:

A kind of high bonding heat radiation coating, it is made up of the raw material of following weight parts:

Barium mahogany sulfonate 3-4, styrene-maleic anhydride copolymer 12-15, propiolic alcohol 6-10, tetrahydrofuran (THF) 90-100, Graphene 4-7, nano silicon 16-20, silane coupling agent KH5600.2-0.3, dimethyl formamide 700-800, sodium nitride 4-5, aluminum chloride 0.04-0.05, 2-3% sodium ascorbate solution 1.6-2, 2-3% copper-bath 1.8-2, high density polyethylene(HDPE) 120-130, Resorcinol 0.6-1, cetyl trimethylammonium bromide 1-2, phthalic acid polyester 3-4, alkenyl succinic anhydride 0.3-0.5, casein food grade 0.2-0.3, calcium ricinoleate 0.7-1, diatomite 2-4.

A preparation method for described height bonding heat radiation coating, comprises the following steps:

(1) above-mentioned cetyl trimethylammonium bromide is joined in 17-20 times of deionized water, stir, add alkenyl succinic anhydride, diatomite, 100-200 rev/min is stirred 30-40 minute, dehydration, add calcium ricinoleate, raised temperature is 80-90 DEG C, add Graphene, insulated and stirred 10-20 minute, cooling, vacuum-drying, mix with nano silicon, ball milling 30-40 minute;

(2) by styrene-maleic anhydride copolymer, propiolic alcohol, tetrahydrofuran (THF) mixing, insulated and stirred 10-16 hour at 50-60 DEG C, underpressure distillation, removing liquid, vacuum-drying, obtains alkynyl multipolymer;

(3) get above-mentioned ball milling particle, join in 20-30 toluene doubly, ultrasonic disperse 2-3 hour, adds silane coupling agent KH560, and raised temperature is 86-90 DEG C, insulated and stirred 10-12 hour, cooling, suction filtration, and vacuum-drying, obtains silanization nanoparticle;

(4) get the 46-50% of above-mentioned dimethyl formamide weight, add silanization nanoparticle, ultrasonic disperse 2-3 hour, add sodium nitride, aluminum chloride, stir 24-25 hour, suction filtration at 30-35 DEG C, washing, vacuum-drying, obtains Sodium Azide rice corpuscles;

(5) joined in 10-17 times of dehydrated alcohol by above-mentioned barium mahogany sulfonate, stir, add the 6-10% of Resorcinol, casein food grade, above-specified high density polyethylene weight, insulated and stirred 20-30 minute at 80-90 DEG C, cooling, obtains modified poly ethylene alcoholic solution;

(6) by above-mentioned Sodium Azide rice corpuscles, the mixing of alkynyl multipolymer, join in remaining dimethyl formamide, nitrogen bubble 30-40 minute, adds 2-3% sodium ascorbate solution, 2-3% copper-bath successively, reacts 20-24 hour at being placed in 76-80 DEG C, add above-mentioned modified poly ethylene alcoholic solution, stir, suction filtration, respectively washs 2-3 time with distilled water, dimethyl formamide, acetone successively by filter cake, after vacuum-drying, obtain engrafted nanometer particle;

(7) mixed with each raw material of residue by above-mentioned engrafted nanometer particle, stir, be sent to twin screw extruder, melt extrude, cooling, pulverizes and sieves, to obtain final product.

Advantage of the present invention is:

(1) coating of the present invention has good shock resistance:

Graphene, nano silicon all have larger specific surface area, can strengthen Graphene, reactive force between nano silicon and polyvinyl resin, put forward heavily stressed transfer efficiency, and then improve its shock resistance;

(2) coating of the present invention has good erosion resistance;

Graphene, nano silicon in the medium-altitude dispersion of resin, can form fine and close film, corrosive medium is more difficult to be penetrated in coating by this interface, well improves corrosion resistance;

(3) coating of the present invention has good heat conduction and heat radiation:

First the present invention prepares the styrene-maleic anhydride copolymer containing multiple alkynyl on molecular chain, then modified Nano particle, its surface is made to introduce multiple azido-, finally utilize " click " chemical method at particle surface graftomer, polymer molecular chain has multiple point to be grafted to particle surface, molecular chain " is crouched down " at particle surface, thus it is coated what do not need to realize under the condition introducing number of polymers chain to particle, obtain grafting density high, the nanoparticle of good dispersity, strengthen its dispersiveness in resin matrix, the two-dimension plane structure of Graphene that is scattered here and there in resin and the tridimensional network of nano silicon can form stable heat conduction network, greatly improve the transmission of heat, play good heat conduction and heat radiation effect.

In coating of the present invention, each raw material is rationally composite, improves the dispersiveness of particle in resin, can form stable heat conduction and heat radiation passage, can effectively reduce film coated surface temperature, long service life.

Embodiment

A kind of high bonding heat radiation coating, it is made up of the raw material of following weight parts:

Barium mahogany sulfonate 3, Zelan 338 12, propiolic alcohol 6, tetrahydrofuran (THF) 90, Graphene 4, nano silicon 16, silane coupling agent KH5600.2, dimethyl formamide 700, sodium nitride 4, aluminum chloride 0.04, 2% sodium ascorbate solution 1.6, 2% copper-bath 1.8, high density polyethylene(HDPE) 120, Resorcinol 0.6, cetyl trimethylammonium bromide 1, phthalic acid polyester 3, alkenyl succinic anhydride 0.3, casein food grade 0.2, calcium ricinoleate 0.7, diatomite 2.

A preparation method for described height bonding heat radiation coating, comprises the following steps:

(1) above-mentioned cetyl trimethylammonium bromide is joined in 17 times of deionized waters, stir, add alkenyl succinic anhydride, diatomite, 100 revs/min are stirred 30 minutes, dehydration, add calcium ricinoleate, raised temperature is 80 DEG C, add Graphene, insulated and stirred 10 minutes, cooling, vacuum-drying, mix with nano silicon, ball milling 30 minutes;

(2) by Zelan 338, propiolic alcohol, tetrahydrofuran (THF) mixing, insulated and stirred 10 hours at 50 DEG C, underpressure distillation, removing liquid, vacuum-drying, obtains alkynyl multipolymer;

(3) get above-mentioned ball milling particle, join in the toluene of 20 times, ultrasonic disperse 2 hours, adds silane coupling agent KH560, and raised temperature is 86 DEG C, insulated and stirred 10 hours, cooling, suction filtration, and vacuum-drying, obtains silanization nanoparticle;

(4) get 46% of above-mentioned dimethyl formamide weight, add silanization nanoparticle, ultrasonic disperse 2 hours, adds sodium nitride, aluminum chloride, stirs 24 hours, suction filtration at 30 DEG C, washing, and vacuum-drying, obtains Sodium Azide rice corpuscles;

(5) above-mentioned barium mahogany sulfonate is joined in 10 times of dehydrated alcohols, stirs, add Resorcinol, casein food grade, above-specified high density polyethylene weight 6%, insulated and stirred 20 minutes at 80 DEG C, cooling, obtain modified poly ethylene alcoholic solution;

(6) by above-mentioned Sodium Azide rice corpuscles, the mixing of alkynyl multipolymer, join in remaining dimethyl formamide, nitrogen bubble 30 minutes, adds 2% sodium ascorbate solution, 2% copper-bath successively, reacts 20 hours at being placed in 76 DEG C, add above-mentioned modified poly ethylene alcoholic solution, stir, suction filtration, respectively washs 2 times with distilled water, dimethyl formamide, acetone successively by filter cake, after vacuum-drying, obtain engrafted nanometer particle;

(7) mixed with each raw material of residue by above-mentioned engrafted nanometer particle, stir, be sent to twin screw extruder, melt extrude, cooling, pulverizes and sieves, to obtain final product.

Performance test:

Appearance of film: flat smooth, without shrinkage cavity, free of pinholes;

Just recoiling test: pass through;

Pencil hardness test: 2H is without scuffing;

Sticking power and resistance to Neutral Salt Spray Corrosion grade are 2 grades;

Thermal conductivity is 0.485W/mK.

Claims (2)

1. a high bonding heat radiation coating, is characterized in that what it was made up of the raw material of following weight parts:

Barium mahogany sulfonate 3-4, styrene-maleic anhydride copolymer 12-15, propiolic alcohol 6-10, tetrahydrofuran (THF) 90-100, Graphene 4-7, nano silicon 16-20, silane coupling agent KH5600.2-0.3, dimethyl formamide 700-800, sodium nitride 4-5, aluminum chloride 0.04-0.05, 2-3% sodium ascorbate solution 1.6-2, 2-3% copper-bath 1.8-2, high density polyethylene(HDPE) 120-130, Resorcinol 0.6-1, cetyl trimethylammonium bromide 1-2, phthalic acid polyester 3-4, alkenyl succinic anhydride 0.3-0.5, casein food grade 0.2-0.3, calcium ricinoleate 0.7-1, diatomite 2-4.

2. a preparation method for high bonding heat radiation coating as claimed in claim 1, is characterized in that comprising the following steps:

(1) above-mentioned cetyl trimethylammonium bromide is joined in 17-20 times of deionized water, stir, add alkenyl succinic anhydride, diatomite, 100-200 rev/min is stirred 30-40 minute, dehydration, add calcium ricinoleate, raised temperature is 80-90 DEG C, add Graphene, insulated and stirred 10-20 minute, cooling, vacuum-drying, mix with nano silicon, ball milling 30-40 minute;

(2) by styrene-maleic anhydride copolymer, propiolic alcohol, tetrahydrofuran (THF) mixing, insulated and stirred 10-16 hour at 50-60 DEG C, underpressure distillation, removing liquid, vacuum-drying, obtains alkynyl multipolymer;

(3) get above-mentioned ball milling particle, join in 20-30 toluene doubly, ultrasonic disperse 2-3 hour, adds silane coupling agent KH560, and raised temperature is 86-90 DEG C, insulated and stirred 10-12 hour, cooling, suction filtration, and vacuum-drying, obtains silanization nanoparticle;

(4) get the 46-50% of above-mentioned dimethyl formamide weight, add silanization nanoparticle, ultrasonic disperse 2-3 hour, add sodium nitride, aluminum chloride, stir 24-25 hour, suction filtration at 30-35 DEG C, washing, vacuum-drying, obtains Sodium Azide rice corpuscles;

(5) joined in 10-17 times of dehydrated alcohol by above-mentioned barium mahogany sulfonate, stir, add the 6-10% of Resorcinol, casein food grade, above-specified high density polyethylene weight, insulated and stirred 20-30 minute at 80-90 DEG C, cooling, obtains modified poly ethylene alcoholic solution;

(6) by above-mentioned Sodium Azide rice corpuscles, the mixing of alkynyl multipolymer, join in remaining dimethyl formamide, nitrogen bubble 30-40 minute, adds 2-3% sodium ascorbate solution, 2-3% copper-bath successively, reacts 20-24 hour at being placed in 76-80 DEG C, add above-mentioned modified poly ethylene alcoholic solution, stir, suction filtration, respectively washs 2-3 time with distilled water, dimethyl formamide, acetone successively by filter cake, after vacuum-drying, obtain engrafted nanometer particle;

(7) mixed with each raw material of residue by above-mentioned engrafted nanometer particle, stir, be sent to twin screw extruder, melt extrude, cooling, pulverizes and sieves, to obtain final product.