CN1817990A - Interface paint with high hydrophobicity, heat conductivity and adhesion - Google Patents

Interface paint with high hydrophobicity, heat conductivity and adhesion Download PDF

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CN1817990A
CN1817990A CN 200610045811 CN200610045811A CN1817990A CN 1817990 A CN1817990 A CN 1817990A CN 200610045811 CN200610045811 CN 200610045811 CN 200610045811 A CN200610045811 A CN 200610045811A CN 1817990 A CN1817990 A CN 1817990A
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coating
carbon black
film
high
methyl
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CN100362067C (en
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舒毅
舒品
舒华
李跃
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舒宏纪
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Abstract

A high-hydrophobicity, heat conductivity and adhesivity pigment of interface is prepared by taking methyl chloroform and butanone as medium, liquid-phase treating ordinary carbon black by silicone oil to hydrophobic activate, forming coating into dense methyl surface by polyester modified dimethylsilicone and agitation dispersing by supersonic homogenizer. The formed coating (2) is three-dimensional cross-linking network of cured polyphenylene methyl resin, which contains nanometer carbon black and silicon dioxide, and it forms dense methyl thin layer (3) on coating surface. It can be used to treat heat exchanger surface (1) of indoor apparatus and outer tube fin of household air conditioner. It has good hardness and is non- toxic.

Description

一种高疏水性、高导热性和高粘附性界面涂料 A highly hydrophobic, high thermal conductivity and high adhesion coating interface

技术领域 FIELD

本发明涉及一种金属表面用功能涂料,特别是一种压缩式空调器的蒸发器表面用的具有高疏水性、高导热性和高粘附性的功能涂料的组成。 The present invention relates to a composition of high thermal conductivity and high adhesion of the functional coating having a highly hydrophobic surface with a functional coating of a metal, in particular a compression-type air conditioner evaporator surface used.

背景技术 Background technique

已有技术中,中国发明专利ZL 001 10559.0公开了一种高疏水性、高导热性和高粘附性界面涂料(以下简称:三性界面涂料)。 Prior art, Chinese patent ZL 001 10559.0 discloses a high hydrophobicity, high thermal conductivity and high adhesion to the interface coating material (hereinafter referred to as: three interfacial coating). 这种三性界面涂料存在三个问题,问题一,三性界面涂料中所用的分散介质为工业甲苯,按对人体健康的损害分类,甲苯属第二类,即在一定程度上有害或稍有毒害的溶剂;按在工厂使用条件下的危害性分类,甲苯属第二类,即中毒性溶剂。 This problem of three three interface coating material, a problem, three of the dispersing medium used interface coatings for industrial toluene, according to the classification of damage to human health, toluene case of a second type, i.e. a certain extent, harmful or slightly toxic solvent; hazard classification according to use conditions in the factory, toluene case of a second type, i.e., toxic solvent. 根据我国1980年颁布的TJ36-79(工业企业卫生标准),空气中甲苯蒸汽最大容许浓度(maximum allowable-concentration,MAC)为100mg/m3。 According to China in 1980 promulgated TJ36-79 (industrial enterprises hygiene standards), the maximum allowable air toluene vapor concentration (maximum allowable-concentration, MAC) was 100mg / m3. 三性界面涂料采用工业甲苯为分散介质,其原因是甲苯为成膜基料的良溶剂,以及价格便宜。 Three interfacial coating using industrial toluene as a dispersion medium, which is the reason for the film forming binder toluene good solvent, and inexpensive. 问题二,三性界面涂料中的固体微粒分为两类:一类是强化导热性*00胶体石墨粉剂,其初始平均粒径为1.5微米(μm),或通用型铝粉,铝粉微粒为微小鳞片状结构,厚度为0.1~2.0μm,直径为1~200μm;另一类是形态学效应的R202,它是经硅油处理的气相二氧化硅,初始平均粒径为12纳米(nm),是完全疏水性的。 Question two, three interfacial solid particles in the coating divided into two categories: one is to strengthen the heat conductivity * 00 colloidal graphite powders, the initial average particle size of 1.5 microns ([mu] m), or a general-purpose aluminum, aluminum fine particles scaly fine structure, having a thickness of 0.1 ~ 2.0μm, having a diameter of 1 ~ 200μm; R202 morphology is another effect, which is silicone oil-treated fumed silica, the initial average particle size of 12 nanometers (nm), It is totally hydrophobic. 这两类固体微粒的初始平均粒径相差悬殊,以*00胶体石墨粉剂与R202为例,前者与后者初始平均粒径之比为1500/12=125。 The initial average particle size of these two types of differences between the solid particulates to 00 * R202 colloidal graphite powder with an example, the average particle diameter ratio of the former to the latter initially 1500/12 = 125. 因此这种三性界面涂料的稳定性差,产生固体微粒的沉淀。 Thus the poor stability of this three interface coating, precipitation of solid particles. 问题三,原三性界面涂膜虽有成膜基料与其中固体微粒配伍好,柔韧性以及粘附力相对较强等优点,但其膜面硬度较差,疏水性不是很高。 The three, although the original three interfacial film forming binder wherein the particulate solid good compatibility, flexibility and relatively strong adhesion, etc., but its poor hardness membrane surface hydrophobic is not very high.

发明内容 SUMMARY

一种高疏水性、高导热性和高粘附性界面涂料是原三性界面涂料的继承与发展。 A highly hydrophobic, high thermal conductivity and high adhesion coating interface is the Development of three primary coating interface. 因此,本发明的目的是对人体健康和环境的污染的危害降低至尽可能低的限度;采用固体微粒的最佳搭配,使形态学效应和强化导热性有机结合;解决涂料的稳定性;改善涂膜表面的疏水性及硬度,提出一种稳定性好、对环境污染小、硬度较高、疏水性能较好的一种高疏水性、高导热性和高粘附性界面涂料(以下简称:三性界面涂料改进型)。 Accordingly, an object of the present invention is harmful to human health and environmental pollution is reduced to the lowest possible extent; best with solid particles using the morphological effects and strengthen the combination of thermal conductivity; solution coating stability; improved a hydrophobic surface coating and hardness, good in stability is proposed, for environmental pollution, high hardness, good hydrophobic properties of a high hydrophobicity, high thermal conductivity and high adhesion to the interface coating material (hereinafter referred to as: three interfacial coatings improved).

本发明是用如下方法实现的。 The present invention is achieved by the following method.

三性界面涂料改进型的组成成份包括有成膜基料、分散介质、固体微粒和助剂。 Three constituent modification of the interfacial coating comprises a film-forming binder, a dispersion medium, solid particles and auxiliaries.

1.成膜基料的选用,原三性界面涂料中的成膜基料是聚甲基苯基硅氧烷,聚甲基苯基硅氧烷与固体微粒的配伍性好、附着力和疏水性较好,本三性界面涂料改进型的成膜基料仍选用W33-15(聚甲基苯基硅氧烷的甲苯溶液,溶液中,聚甲基苯基硅氧烷与甲苯的质量比是1∶1,聚甲基苯基硅氧烷的R/Si=1.47,RC6H5/RCH3=0.48)。 1. The choice of film-forming binder, the original three interfacial coating film-forming binder is polymethyl phenyl siloxane, polymethyl phenyl siloxane compatibility with the solid particles good adhesion and hydrophobic is better, the interface coatings of the present exemplary modification of the three film-forming binder still use W33-15 (methyl phenyl polysiloxane in toluene, a solution, a poly methylphenyl siloxane mass ratio with toluene is 1:1, polymethyl phenyl siloxane R / Si = 1.47, RC6H5 / RCH3 = 0.48).

2.分散介质的选用,选用对环境污染低且能与成膜基料(聚甲基苯基硅氧烷)相溶的溶剂或它们的混合溶剂。 2. The selection of the dispersion medium, the choice of low environmental pollution and capable of film forming binder (a poly methylphenyl siloxane) or a mixed solvent compatible thereof.

在涂料工业中,溶剂是泛指那些用来溶解成膜基料、形成便于施工且在形成涂膜的过程中挥发掉的液体。 In the paint industry, refers to those solvents are used to dissolve the film-forming binder, is formed to facilitate the construction and volatilized during the formation of the liquid coating film.

溶解力,作为溶剂的主要特性之一,比较科学的方法是用“溶解度参数相近的原则”进行量化。 Dissolved, as one of the main characteristics of the solvent, more scientific approach is to quantify "the principle similar solubility parameter." 根据赫尔德布兰德(hildbrand)的定义:δ=(ΔE/V)1/2式中:δ为溶解度参数,单位(J/m3)1/2,ΔE为每摩尔物质的内聚能,V为摩尔体积。 According to the definition Herder Brand (hildbrand) is: δ = (ΔE / V) 1/2 where: δ is the solubility parameter, the unit (J / m3) 1/2, ΔE is a cohesive energy per mole of a substance , V is the molar volume. 从物理意义看,δ是单位体积内分子间作用力:当两种液体的δ相同,这两种液体可以互溶;当液体与固体颗粒的δ相同,则固体颗粒可以液解于溶液中,从热力学观点,液体与液体以及液体与固体颗粒混合,在定温定容条件,自发进行的方向是系统自由能的降低,按照这一原理,可以推导出,当两种物质(液体与液体,液体与固体颗粒)溶解度参数之差的绝对值|Δδ|<2.660×103~3.683×103(J/m3)1/2时,可认为能互溶,当然|Δδ|越小互溶性就越好。 Significance of physical, [delta] is the inter-molecular forces per unit volume: [delta] When the same two liquids, two liquids may be miscible; [delta] when the same liquid and solid particles, the solid particles may be liquid solutions in the solution, from thermodynamic point of view, the liquid and particles are mixed with the liquid in the liquid and the solid, in Wen Dingrong set conditions, the direction of spontaneous system to reduce the free energy, according to this principle can be derived, when two substances (liquid and the liquid, and the liquid solid particles) solubility parameter absolute value of difference | Δδ | <2.660 × 103 ~ 3.683 × 103 (J / m3) 1/2 time, that can be miscible, of course | Delta] [delta | miscibility smaller the better. 由于聚甲基苯基硅氧烷的溶解度参数没能查到确切数据,这里近似取其良溶剂甲苯的溶解度参数Δδ甲苯=18.21×103(J/m3)1/2为其参考值。 Since PMPS solubility parameters can be found not accurate data, where the solubility parameter approximation whichever good solvent toluene toluene Δδ = 18.21 × 103 (J / m3) 1/2 its reference value.

1,1,1-三氯乙烷(以下简称三氯乙烷),示性式为CCl3CH3,它在脂肪族卤代烃中是毒性最低的物质之一。 1,1,1-trichloroethane (hereinafter referred to as TCA), of the formula shown CCl3CH3, which is one of the lowest toxicity of substances in the aliphatic halohydrocarbons. 在工作场所最大允许浓度(MAC),在美国规定为1900mg/m3,在日本规定为1100mg/m3,比甲苯100mg/m3,高出十倍以上。 Workplace maximum allowable concentration (MAC), as specified in U.S. 1900mg / m3, it is defined as in Japan 1100mg / m3, ratio of toluene 100mg / m3, more than ten times higher. 它的溶解度参数δCl=19.64×103(J/m3)1/2,δCl-δ甲苯=19.64×103-18.21×103=1.43×103<2.66×103,可见,三氯乙烷能溶解成膜基料。 Its solubility parameter δCl = 19.64 × 103 (J / m3) 1/2, δCl-δ toluene = 19.64 × 103-18.21 × 103 = 1.43 × 103 <2.66 × 103, is visible, it can dissolve the film-forming trichloroethane material.

2-丁酮(又称甲基乙基酮、甲乙酮,以下简称丁酮),分子式为CH3COC2H5,它属于低毒类物质,在工作场所,最大允许浓度为590mg/m3,比甲苯100mg/m3,高出近五倍。 2-butanone (also known as methyl ethyl ketone, methyl ethyl ketone, hereinafter referred to as methyl ethyl ketone), formula CH3COC2H5, its low toxicity substances, in the workplace, the maximum allowable concentration of 590mg / m3, ratio of toluene 100mg / m3, nearly five times higher. 丁酮不太污染环境,因为它挥发性好,在空气中容易分解为另外的物质。 Butanone not pollute the environment, because it is good volatility, easily decomposed in air for another substance. 它的溶解度参数为δb=19.03×103(J/m3)1/2,δb-δ甲苯=0.82×103<2.66×103,可见丁酮能溶解成膜基料。 Its solubility parameter δb = 19.03 × 103 (J / m3) 1/2, δb-δ toluene = 0.82 × 103 <2.66 × 103, visible ketone capable of dissolving the film-forming binder.

粘度,分为动力粘度μ和运动粘度υ=μ/ρ,式中ρ为密度,动力粘度和运动粘度的单位分别为Pa·s和m2/s。 The viscosity, dynamic viscosity [mu] and is divided into a kinematic viscosity υ = μ / ρ, where [rho] is the density, kinematic viscosity and dynamic viscosity of the unit Pa · s, respectively, and m2 / s. 粘度也是溶剂的主要特性之一。 Viscosity is one of the main characteristics of the solvent. 按动力粘度数值大小排列,三氯乙烷、甲苯、丁酮分别为0.903mPa·s、0.5866mPa·s、0.423mPa·s。 Kinematic viscosity values ​​arranged by size, trichloroethane, toluene, methyl ethyl ketone are 0.903mPa · s, 0.5866mPa · s, 0.423mPa · s. 以体积比,丁酮二份,三氯乙烷一份组成的混合溶剂的动力粘度μmix=2×0.423/3+0.903/3=0.583mPa·s,与甲苯相接近。 Volume ratio, methyl ethyl ketone duplicate dynamic viscosity of a mixed solvent consisting of trichloroethane μmix = 2 × 0.423 / 3 + 0.903 / 3 = 0.583mPa · s, close with toluene.

挥发率,以醋酸正丁酯挥发速率为基准即取为1,按挥发速率快慢排列,丁酮、甲苯、三氯乙烷分别为4.65、1.95、1.5。 Evaporation rate, to the evaporation rate of n-butyl acetate, i.e., taken as a reference, the speed of the arrangement according to the evaporation rate, methyl ethyl ketone, toluene, trichloroethane 4.65,1.95,1.5 respectively.

表面张力,甲苯、三氯乙烷、丁酮、分别为28.53mN/m、25.56mN/m、24.60mN/m,三者相差不大。 Surface tension, toluene, trichloroethane, methyl ethyl ketone, respectively 28.53mN / m, 25.56mN / m, 24.60mN / m, three or less.

综上所述,由于丁酮挥发较快,不宜单独作三性界面涂料改进型的分散介质。 In summary, the rapid volatilization butanone, not suitable for the dispersion medium interface of the three separate coating improved. 因此,两种溶剂可选用,其一:三氯乙烷;其二:三氯乙烷和丁酮的混合溶剂。 Thus, the choice of two solvents, one of: trichloroethane; Second: a mixed solvent of methyl ethyl ketone and trichloroethane.

3.固体微粒的选用,原三性界面涂料中为了强化涂膜的导热性选用平均粒径为微米(μm)级的、导热系数很高的通用铝粉或*00胶体石墨粉剂,因而造成了三性界面涂料固体微粒的沉淀现象,涂液的稳定性不好。 3. The selection of solid particles, the original three interfacial coating in order to enhance the thermal conductivity of the coating film an average particle size selected micrometers ([mu] m) level, the high thermal conductivity of aluminum or universal * 00 colloidal graphite powder, resulting in a three phenomena precipitate solid particles of coating material interface, poor stability of the coating solution. 为解决这一问题,选用纳米级的普通色素炭黑代替它们,纳米级的普通色素炭黑初始粒径为26~37nm,比表面积为80~200m2/g,保留了原三性界面涂料中经硅油处理的气相二氧化硅R202。 To solve this problem, the choice of nano-carbon black pigment instead of their normal, ordinary carbon black pigment primary particle diameter of nanoscale 26 ~ 37nm, specific surface area of ​​80 ~ 200m2 / g, retained the original three by interfacial coatings R202 silicone oil-treated fumed silica. 普通色素炭黑初始平均粒径为26~37nm,它与硅油处理气相二氧化硅的粒径比26/12~37/12=2.17~3.08,比125小多了。 Common initial pigment carbon black of 37 nm average particle diameter of 26 ~, it is treated with the silicone oil particle diameter of the fumed silica ratio = 2.17 - 3.08 26/12 ~ 37/12, smaller than 125. 在由固体微粒与液体组成的系统中,如微粒与液体之间没有化学亲和力,即两者的溶解度参数Δδ>3.680×103(J/m3)1/2,则这种系统在热力学上是不稳定的,固体微粒就会沉淀;但是从胶体化学得知,当微粒的粒径小于100nm时,这种微粒受到周围液体分子的撞击时,由于受力面积非常小而产生不平衡力,这些微粒就产生布朗(R.Brown)运动,它是一种不规则的热运动,就会使这些微粒均匀分布在液体中,因而具有动力学的稳定性。 The system consists of solid particles in the liquid composition, as there is no chemical affinity between the particles and the liquid, i.e., the solubility parameter of both Δδ> 3.680 × 103 (J / m3) 1/2, then such a system is thermodynamically not stable, solid particles will settle; However the colloid chemistry that, when 100 nm or less than the size of the particles, such particles by the impact of the liquid molecules around, due to the very small force area unbalanced force is generated, these particles generates Brown (R. Brown) movement, which is an irregular thermal motion, will make these fine particles are uniformly distributed in the liquid, which has a kinetic stability. 通常认为粒径小于100nm的粒子称为纳米粒子。 Generally considered less than 100nm particle diameter is termed nanoparticles. 于是气相二氧化硅和普通色素炭黑属于纳米级。 Then fumed silica and carbon black pigments belonging to general nanometers. 但是,作为黑色颜料,在涂料工业,炭黑的分散是最为困难。 However, as a black pigment in the coatings industry, carbon black dispersion is the most difficult. 这是因为炭黑是一种高分散、多孔的疏水性物质,但其表面上有多种活性官能团(羧基、羟基、羰基),因而形成了炭黑也具有亲水性。 This is because carbon black is a highly dispersible, hydrophobic porous material, but a variety of reactive functional groups (carboxyl, hydroxyl, carbonyl) on the surface, thereby forming a hydrophilic carbon black also. 这样,炭黑在涂料中有形成不稳定的悬浮颗粒的自发倾向,在涂料的贮存过程中,重新聚合为絮聚体(以面相接的初始粒子团)和附聚体(以点、角相接的初始粒子团),出现返粗变稠和沉淀现象。 Thus, the carbon black has a spontaneous tendency to destabilize suspended particles in the coating, the coating during storage in the re-polymerization flocculation body (primary particles in surface contact group) and agglomerates (point angle initial contact agglomerated particles), coarse thickening occurs back and precipitation phenomena. 为解决炭黑在涂料中产生的上述问题,采用硅油对炭黑进行疏水化处理,使炭黑表面上活性官能团吸附硅油,且为防止硅油和溶剂对活性官能团的竞争吸附,所用硅油不加使之稀释的任何溶剂。 To solve the above problems of carbon black produced in the coating using a silicone oil of the carbon black subjected to a hydrophobic treatment, the surface of carbon black reactive functional group adsorbing a silicone oil, and to prevent the silicone oils and solvent absorption competition reactive functional group, the silicone oil without making any dilution of the solvent. 我国常用颜料分散设备,如三辊磨、砂磨机、高速分散机和胶体磨等,都不能使固体微粒的粒径分散至纳米级。 The pigment dispersion of conventional devices, such as a three-roll mill, a sand mill, high-speed disperser and colloid mill, do not make the dispersed particle diameter of the solid particles to nanometer. 以分散最细的胶体磨而言,其最小的分散粒径1000nm以上。 A colloid mill to disperse the smallest, the dispersed particle size of more than the minimum 1000nm. 超声波均质器(超声波同化器Supersonichomogenizen),其振子在外力(交流电)作用下产生超声振动。 An ultrasonic homogenizer (Ultrasonic device assimilation Supersonichomogenizen), which generates ultrasonic vibration transducer in an external force (alternating current) effect. 这种振动会在周围介质中向外传播。 This vibration propagates outwardly in the surrounding medium. 在液态物质中传播,在一个振动周期中有半个周期压缩半个周期膨胀。 Spread the liquid substance, there is a half cycle in a compression half period expansion vibration period. 由于振动很快,如2.5万赫兹(Hz),在膨胀半周期,液体来不及膨胀而出现气泡。 Soon vibration, such as 25,000 Hertz (Hz), the expansion half-cycle, the liquid bubbles expands too late. 在压缩半周期气泡被压缩,于是气泡急崩溃,而产生空穴现象。 In the compression half-cycle of the air bubbles are compressed, so the collapse of bubble acute, and the generation of cavitation. 在空穴消失的瞬间,此时的压力可达数百兆帕(MPa),从而起着非常复杂而强烈机械搅拌作用,使液体中固体微粒逐渐分散到胶体颗粒的范围(1~100nm)。 In transient cavitation disappears, the pressure at this time is up to hundreds of megapascals (MPa), and thus plays a very complex intense mechanical agitation, solid particles in the liquid is gradually dispersed in the colloidal range of particle (1 ~ 100nm). 对普通色素炭黑有絮聚和附聚而形成大颗粒的炭黑通过超声波均质器的分散作用,将颗粒粒径恢复接近初始粒径26~37nm是可以做到的。 There flocculation and agglomeration of carbon black pigment to form common large particles of carbon black dispersion by an ultrasonic homogenizer, the particle size diameter close to the initial recovery 26 ~ 37nm can be done. 这样炭黑上活性基团吸附硅油,形成完全疏水性的纳米粒子。 Such active groups on the carbon black adsorbed silicone oil, a completely hydrophobic nanoparticles.

综上所述,固体微粒采用R202(经硅油处理的气相二氧化硅)和经硅油处理的炭黑。 In summary, the use of solid particles of carbon black R202 (fumed silica treated with silicone oil) and treated with silicone oil.

4.助剂,原三性界面涂料中采用乙烯基三特丁基过氧硅烷作偶联剂,解决三性界面涂膜的高粘附性。 4. aid, the original three interfacial coatings using vinyl triethoxy silane as t-butylperoxy-coupling agent, to solve the three high adhesion of the coating film interface. 本三性界面涂料改进型保留了原三性界面涂料中YGO-1401(浓度是40%的乙烯基三特丁基过氧硅烷甲苯溶液)作偶联剂,原三性界面涂料的成膜基料W33-15中的聚甲基苯基硅氧烷虽有与固体微粒的配伍性好和附着力相对较好的优点,但疏水性比纯甲基硅树脂差,且涂膜表面硬度差。 This three interfacial coating retains the original three improved interfacial coatings YGO-1401 (concentration 40% vinyl tri t-butylperoxy silane solution in toluene) as the coupling agent, the original three interface coating film-forming property W33-15 material poly (methylphenyl) siloxanes, although good compatibility and adhesion of solid particles and relatively good advantage, but worse than the pure methacrylic hydrophobic silicone resin, and the coating film surface hardness difference. 为了克服这些缺点,在三性界面涂料改进型加入助剂增滑剂-聚酯改性二甲基硅氧烷BYK--310,它是德国BYK公司的成熟产品,在通常烘烤温度下很稳定,只在超过200℃时聚酯链才出现降解,它的添加量视用途而定,用量较少。 To overcome these disadvantages, an improved three interfacial coating aids slip agent added - polyester-modified polydimethylsiloxane BYK - 310, which is the German company BYK mature products, it is typically at a baking temperature stable, only present exceed 200 ℃ degradation of the polyester chain, it may be added in an amount depending on the purpose, lower dosage. 在膜面上形成厚度仅为几个低分子的密排甲基薄层,其真实接触角为103°。 A thickness of only a few low-molecular-methyl closely packed thin film surface, the true contact angle of 103 °.

综上所述,助剂采用YGO-1401(浓度是40%的乙烯基三特丁基过氧硅烷甲苯溶液)和BYK-310(聚酯改性二甲基硅氧烷)。 In summary, the use of additives YGO-1401 (concentration 40% vinyl tri t-butylperoxy silane in toluene) and BYK-310 (polyester-modified dimethyl siloxane). 上述经硅油处理的炭黑用的硅油可以是硅油201-1000,为二甲基硅油,粘度为1000mm2/s(医用卫生级,上海树脂厂生产)。 The above-described carbon black silicone may be a silicone oil-treated 201-1000 silicone oil, dimethyl silicone oil having a viscosity of 1000mm2 / s (medical sanitary, Shanghai Resin Factory).

根据上述对于涂料组成成份的选择,本发明的三性界面涂料改进型的组成成份包括有成膜基料、分散介质、固体微粒和助剂。 For the above-described coating composition components selected, the coating constituent three interfacial modification of the present invention comprises a film-forming binder, a dispersion medium, solid particles and auxiliaries.

成膜基料是W33-15(聚甲基苯基硅氧烷的甲苯溶液,溶液中,聚甲基苯基硅氧烷与甲苯的质量比是1∶1,聚甲基苯基硅氧烷的R/Si=1.47,RC6H5/RCH3=0.48),分散介质是三氯乙烷或三氯乙烷与丁酮的混合溶剂,固体微粒是R202(经硅油处理的气相二氧化硅)和经硅油处理的炭黑,助剂是YGO-1401(浓度是40%的乙烯基三特丁基过氧硅烷甲苯溶液)和BYK-310(聚酯改性二甲基硅氧烷),三性界面涂料改进型的各组成成份的体积份是:W33-15:100,三氯乙烷:100~300,丁酮:0~200,R202:200~350,炭黑:200~400,YGO-1401:8~12,BYK-310:4~6,硅油201-1000:1~2。 Film-forming binder is W33-15 (methyl phenyl polysiloxane in toluene, the solution, the mass ratio of poly (methylphenylsiloxane) and toluene is 1:1, polymethyl phenyl siloxane the R / Si = 1.47, RC6H5 / RCH3 = 0.48), the dispersion medium is a mixed solvent of methyl ethyl ketone and methyl chloroform or trichloroethane, and solid particles is R202 (fumed silica treated with silicone oil) and silicone oil carbon black processing aid is YGO-1401 (concentration 40% vinyl tri t-butylperoxy silane in toluene) and BYK-310 (polyester-modified dimethyl siloxane), three interfacial coating modified parts by volume of each constituent is: W33-15: 100, trichloroethane: 100 to 300, butanone: 0 ~ 200, R202: 200 ~ 350, carbon black: 200 ~ 400, YGO-1401: 8 ~ 12, BYK-310: 4 ~ 6, 201-1000 silicone oil: 1 ~ 2.

由于综合采用了毒性很低的有机溶剂作分散介质,涂料中的固体微粒是纳米级,超声波技术以及膜面为密排的甲基,三性界面涂料改进型比原三性界面涂料有显著的进步,表现在:1.由于采用超声波技术对涂料中的固体微粒进行分散,超声波产生空穴,周围流体对空穴强大的冲击力[数百兆帕(MPa)]很容易使固体微粒分散至初始平均粒径,气相二氧化硅的平均粒径近于12nm,普通色素炭黑平均粒径近于26~37nm。 Since using a combination of low toxicity organic solvent as dispersing medium, solid particles in the coating is a nano-scale, and ultrasonic techniques the film surface is closely spaced, trimethyl interfacial coating significantly improved over the original three interfacial coating progress, in: 1. Since the ultrasonic technique of solid particles dispersed in the coating, the ultrasonic generating holes, it is easy for a fluid around a strong impact hole [hundreds of megapascals (MPa)] dispersed solid particles the initial average particle size, the average particle diameter of 12nm near fumed silica, carbon black average particle diameter of regular color near 26 ~ 37nm. 更重要的是超声波分散是在密闭的容器中进行,因此三性界面涂料改进型的生产厂家,可以实现有机溶剂的零排放;对于三性界面涂料改进型的使用厂家,如没有机溶剂的回收循环使用的设备,由于选用的有机溶剂是低毒性,对工作场所的工作人员健康和对大气的污染也大为降低。 More importantly, the ultrasonic dispersion was carried out in a sealed container, and therefore three of the improved interface coating manufacturers can achieve zero emissions of organic solvent; three interfacial coatings for improved use of manufacturers, such as no recovery of the solvent recycling apparatus, since the choice of organic solvents are low toxicity, the staff of health in the workplace and pollution of the atmosphere is also greatly reduced.

2.由于对炭黑用硅油进行疏水性处理和随后的超声波分散,解决了原三性界面涂料中的沉淀问题。 2. Since the carbon black and the hydrophobic treatment with silicone oil followed by ultrasonic dispersion, to solve the problem of precipitation of the original three interface coating material.

3.由于采用微量的聚脂改性二甲基硅氧烷,在三性界面涂料改进型形成涂膜膜面疏水性有了改善且膜面硬度更强了。 3. As a result of a slight amount of a polyester modified polydimethylsiloxane, modified form of the three interface coating film surface hydrophobic film and the film has improved surface hardness stronger.

4.关于超声波技术应用于涂料工业,其优点可归纳如下:(1)超声波均质器能产生胶体磨和高速均质机的联合效果。 4. The ultrasonic technology is applied on the coating industry, the advantages can be summarized as follows: (1) an ultrasonic homogenizer and a colloid mill to produce the combined effect of high-speed homogenizer. 涂料不升温、不挥发、不吸入空气。 The coating did not heat up, non-volatile, does not intake air.

(2)能耗低,单位能耗仅1.5KW·h/t。 (2) low energy consumption, unit energy consumption is only 1.5KW · h / t.

(3)结构小,投资很少,几个月能回收,维修、清洗极简便。 Small (3) structure, very little investment, a few months can be recycled, maintenance, cleaning very easy. [参见SEBooth.Ultrasonicass as a Method of Mixing,Dispersion and Homogenisation.Paint&amp;Resin,1986,56(6):17~18。 [See SEBooth.Ultrasonicass as a Method of Mixing, Dispersion and Homogenisation.Paint & amp; Resin, 1986,56 (6): 17 ~ 18. 译文:SE布恩。 Translation: SE Boone. 搅拌,分散和均质的超声波法。 Stirring, ultrasonic dispersion and homogeneous method. 涂料与树脂,1986,56(6):17~18]附图说明附图是三性界面涂料改进型涂敷于换热器板片而形成的三性界面涂膜改进型示意图。 Coating with the resin, 1986,56 (6): 17 to 18] The accompanying drawings is a schematic view of three improved interfacial film of three improved interface coating is applied to the plate heat exchanger formed. 图中1为换热器板片,2为改进型三性界面涂膜,它由固化的聚甲基苯基硅树脂三维交联网络,且其中包裹胶体粒子所组成,3是涂膜表面,它由密排的甲基组成。 Figure 1 is a plate heat exchanger 2 for the modified three interfacial coating, a silicone resin which three dimensional crosslinked network of the cured polymethyl phenyl, and wherein the colloidal particles are composed of wrapping, the coating film surface is 3, it consists of closely packed methyl.

具体实施方式 Detailed ways

关于涂膜疏水性、导热性和粘附性的测定,由本发明是原三性界面涂料的改进型,首先考虑粘附性,原三性界面涂料中应用了乙烯基三特丁基过氧硅烷作为硅偶联剂,从而取得原三性界面涂膜的高粘附性,在三性界面涂料改进型仍然采用这种硅偶联剂,而且成膜基料与它的体积比(1∶0.1)不变,因而可以推论三性界面涂料改进型的涂膜仍然保持了高粘附性;关于疏水性,将涂膜水平向上放置,用2.5ml一次性注射器吸足纯净水,缓慢从针头挤出水珠直径在1mm左右,水珠仍沾在针头上,让水珠沿涂膜面缓慢移动,如水珠不沾膜面,稍稍提起针头,使水珠增大至2mm,水珠落在膜面上不能停留,即涂膜稍有倾斜或振动,水珠立即从膜面脱落,则可以为涂膜保持高疏水性,此法可称为注射器挤水珠法;关于导热性,应用电热类比,应用数字万用表(DT9203型),其电 And determining the thermal conductivity of the hydrophobic coating on adhesion, the present invention is a modification of the original three interface coating, first consider the adhesiveness, the original three interfacial coatings applied vinyltriethoxysilane t-butylperoxy silane as the silane coupling agent, to obtain high adhesion to the original three interfacial coating film, a silane coupling agent still using this coating material in the third modification of the interface, and a film forming binder and its volume ratio (1:0.1 ) constant, it is possible to infer the three interfacial coating film improved adhesion remains high; on hydrophobic, the coating film upward horizontally, with 2.5ml disposable syringe suck enough pure water, was slowly squeezed out of the needle It drops the diameter of about 1mm, water droplets still stick to the needle, so that drops slowly moved along the coated surface, such as non-stick film surface drops, the needle is slightly lifted, so that drops of water is increased to 2mm, drops falling film can not stay surface, i.e., the coating is slightly inclined or vibration, immediately drops off from the membrane surface, the coating that can maintain high hydrophobicity, this method may be referred to the syringe drops extrusion method; on thermal conductivity, electrothermal analogy , the application of digital multimeter (DT9203 type), electrical 阻为200、2k、20k、200k、2M和20M六档,将该万用两条测量导线前的尖形探头改为两片紫铜板,板宽12mm、长14mm,将这两片紫铜用胶粘在一平整电木板上,两紫铜板间的间隙为0.5mm,两板的另一侧用锡焊连接测量导线。 Resistance to 200,2k, 20k, 200k, 2M and 20M sixth gear, the two universal probes before measurements pointed to two wire copper plate, sheet width 12mm, length 14mm, glue the two sheets of copper stuck on a flat wood, the gap between the two copper plates of 0.5mm, the other two side plates measuring lead is connected by soldering. 使用时,将两紫铜板紧贴于涂膜膜面,测量其电阻值,电阻越小,则涂膜导电性越好,也表征涂膜导热性越好,此法可称为测电阻法。 In use, the two copper plates close contact with the coating film surface, to measure the resistance value, the smaller the resistance, the better the conductivity of the coating film, the coating film is also characterized by better thermal conductivity, this method may be referred to measure resistance method.

实施例1:在专利ZL 001 10559.0实施例4中,将WGS-0310应用于捷达汽车空调器的蒸发器,该蒸发器单体性能试验检测数据表明有WGS-0310涂膜较之无涂膜,空气侧能力提高了3.4%。 Example 1: In the patent ZL 001 10559.0 Example 4, applied to the WGS-0310 Jetta air conditioner evaporator, the evaporator monomer detecting performance test data showed that compared with a WGS-0310 without film coating, air side capacity increased by 3.4%. 在本发明中,将聚酯改性的二甲基硅氧烷(BYK-310)加入WGS-0310中,加入的量按为WGS-0310中成膜基料(按体积比为5%),将加有助剂BYK-310的涂液应用于郑州日产汽车空调器中的蒸发器,在同一试验台上,蒸发器单体性能试验检测数据表明有这种涂膜较之无涂膜,空气侧能力提高了9.02%>3.4%。 In the present invention, the polyester-modified polydimethylsiloxane (BYK-310) was added in WGS-0310, is added in an amount according to WGS-0310 in the film-forming binder (volume ratio of 5%), the added auxiliaries BYK-310 was applied to the coating Zhengzhourichan car air conditioner evaporator, in the same test bench, monomer evaporator detection performance test data showed that there is no coating film than air side capacity increased by 9.02%> 3.4%. 可能有其他的因素,但三性界面涂料改进型中的助剂加入BYK-310,效果是正面的。 There may be other factors, but three in the improved interfacial coating aid was added BYK-310, the effect is positive.

实施例2:为了从实验上验证经硅油处理气相二氧化硅(R202,初始平均粒径12nm,白色无定形粉末)所配置的涂液的分散稳定性,是本实施例的目的。 Example 2: In order to verify the dispersion stability of the silicone oil-treated fumed silica (R202, the initial average particle diameter of 12nm, white, amorphous powder) which is arranged from the coating liquid experimentally, it is the purpose of the present embodiment.

成膜基料为W33-15,其体积以VW表示;分散介质(1)三氯乙烷,其体积以VCl表示,分散介质(2)丁酮,其体积以Vb表示;固体微粒为R202,其体积以VS表示;助剂为YGO-1401,其体积以Vv表示。 Film-forming binder as W33-15, expressed in volume VW; dispersion medium (1) trichloroethane, VCl volume in said dispersion medium (2) butanone, expressed in volume Vb; solid fine particles R202, volume represented by VS; auxiliaries, the volume Vv expressed as YGO-1401. 这一组合物各组分的体积比为:VW∶Vv∶VCl∶Vb∶VS=1∶0.1∶1.5∶1.5∶5.5上述混合物配制好后,在超声波均质器中分散1小时。 The volume ratio of the components of the composition: VW:Vv:VCl:Vb:VS = 1:0.1:1.5:1.5:5.5 the above mixture formulated, dispersed in an ultrasonic homogenizer for 1 hour. 涂液粘度,涂-4杯13.6秒。 The viscosity of the coating liquid, Tu -4 cup 13.6 seconds. 将载玻片[25.4×76.2mm(1″×3″),厚1mm]浸入该涂液中,停留20秒,缓慢取出,室温晾干,放入远红外线烤箱内,在150℃时烘烤,固化成膜40分钟。 The slides [25.4 × 76.2mm (1 "× 3"), 1mm thick] was immersed in the coating solution, the residence for 20 seconds, slowly removed, dried at room temperature, into the far-infrared oven, baking at 150 ℃ , cured film formation for 40 minutes. 涂膜的疏水性用注射器挤出水珠法,测得涂膜达到高疏水性要求;用测电阻法,测得电阻为无穷大,说明涂膜导热性很差。 Hydrophobic coating film drops with a syringe extrusion method, a coating film was measured to achieve high hydrophobicity requirements; by resistance measurement method, the measured resistance is infinite, indicating poor thermal conductivity coating.

将该涂液放置在500ml,广口磨砂透明玻璃瓶中,遮光静置15个月,未发现沉淀。 This coating solution is placed in a 500ml, wide-mouth clear glass frosted, the light shielding for 15 months, the precipitate was not found. 从这个实施例中,可见完全疏水化初始粒径12nm的气相二氧化硅,在疏水的涂液中,由布朗运动而形成的胶体动力学稳定性能好,且在涂膜表面形态学效应显著。 In this embodiment, the visible primary particle size of 12nm completely hydrophobized fumed silica, a hydrophobic liquid in the coating, the good colloidal stability of Brownian motion dynamics is formed, and the coating surface morphology significant effect.

实施例3:成膜基料W33-15,其体积以VW表示;分散介质为三氯乙烷,其体积以VCl表示;固体微粒(1)R202,其体积以VS表示,固体微粒(2)普通色素炭黑,其体积以VC表示;助剂(1)YGO-1401,其体积以Vv表示,助剂(2)BYK-310,其体积以V310表示,(3)炭黑上活性基团吸附用硅油201-1000,为二甲基硅油,粘度为1000mm2/s(医用卫生级,上海树脂厂生产),其体积以V201表示。 Example 3: film-forming binder W33-15, expressed in volume VW; trichloroethane dispersion medium, expressed as the volume of VCl; solid particles (1) R202, in which the volume VS said solid particles (2) ordinary carbon black pigment, which represents the volume to the VC; aid (1) YGO-1401, the volume Vv to said adjuvant (2) BYK-310, which represents the volume to V310, (3) carbon black reactive group 201-1000 adsorption silicone, dimethyl silicone oil having a viscosity of 1000mm2 / s (medical sanitary, Shanghai resin factory), which is expressed in the volume V201.

这一组合物各组分的体积比为:VW∶Vv∶V201∶V310∶VCl∶VC∶VS=1∶0.1∶0.01∶0.05∶3∶2∶3.5经硅油处理的炭黑是将炭黑与二甲基硅油混合,放在超声波均质器中,将炭黑微粒分散,且炭黑微粒上的活性基团吸附硅油分子,使炭黑完全疏水化。 The volume ratio of the components of the composition: VW:Vv:V201:V310:VCl:VC:VS = 1:0.1:0.01:0.05:3:2:3.5 silicone oil-treated carbon black is a carbon black and dimethicone were mixed in an ultrasonic homogenizer, the dispersion of the carbon black particles, and the reactive groups on the silicone molecule to adsorb soot particles, carbon black completely hydrophobic. 超声波均质器工作1小时。 Working ultrasonic homogenizer for 1 hour. 然后将W33-15,YGO-1401以及BYK-310和三氯乙烷缓慢地注入,最后将R202加入超声波均质器中。 Then W33-15, YGO-1401 and BYK-310 and slowly adding trichloroethane, R202 and finally added in an ultrasonic homogenizer. 超声波均质器工作2小时。 Ultrasonic homogenizer 2 hours of work. 将载玻片浸入该涂液中,缓慢取出,室温晾干,放入远红外线烤箱内,在150℃时烘烤,固化成膜40分钟。 The slides were dipped into the coating solution, withdrawn slowly, dried at room temperature, into the far-infrared oven, baking at 150 deg.] C, forming a cured for 40 minutes. 用注射器挤出水珠法,测得涂膜达到高疏水性要求;用测电阻法,测得电阻为60K,比专利ZL 00 1 10559.0实施例4,WGS-0310涂膜的电阻65K要小,说明本实施例的涂膜导热性有微小改进。 Syringe drops extrusion method, a coating film was measured to achieve high hydrophobicity requirements; by resistance measurement method, the measured resistance of 60K, for specific embodiments Patent ZL 00 1 10559.0 4, resistor 65K WGS-0310 film is smaller, description of the present embodiment has a thermally conductive coating minor modifications.

实施例4:成膜基料W33-15,其体积以VW表示;分散介质(1)三氯乙烷,其体积以VCl表示,分散介质(2)丁酮,其体积以Vb表示;固体微粒(1)R202,以体积VS表示,固体微粒(2)普通色素炭黑,其体积以VC表示;助剂(1)YGO-1401,其体积以Vv表示,助剂(2)BYK-310,其体积以V310表示,助剂(3)炭黑活性基团吸附用硅油201-1000,为二甲基硅油,粘度为1000mm2/s(医用卫生级,上海树脂厂生产),其体积以V201表示。 Example 4: film-forming binder W33-15, expressed in volume VW; dispersion medium (1) trichloroethane, VCl volume in said dispersion medium (2) butanone, expressed in volume Vb; solid particles (1) R202, VS represents a volume, solid particles (2) ordinary carbon black pigment, which represents the volume to the VC; aid (1) YGO-1401, the volume Vv to said adjuvant (2) BYK-310, in the volume V310 said additives (3) Carbon black reactive group adsorption 201-1000 silicone, dimethyl silicone oil having a viscosity of 1000mm2 / s (medical sanitary, Shanghai resin factory), expressed as the volume V201 . 这一组合物各组分的体积比为:VW∶Vv∶V201∶V310∶VCl∶Vb∶VC∶VS=1∶0.1∶0.02∶0.05∶1∶2∶4∶2首先,将炭黑与二甲基硅油混合,放入超声波均质器中,将炭黑微粒分散,且炭黑微粒上的活性基团吸附硅油分子,使炭黑完全疏水化。 The volume ratio of the components of the composition: VW:Vv:V201:V310:VCl:Vb:VC:VS = 1:0.1:0.02:0.05:1:2:4:2 First, carbon black and two methyl silicone oil were mixed in an ultrasonic homogenizer, the dispersion of the carbon black particles, and the reactive groups on the silicone molecule to adsorb soot particles, carbon black completely hydrophobic. 超声波均质器工作1小时。 Working ultrasonic homogenizer for 1 hour. 然后将W33-15、YGO-1401、BYK-310以及三氯乙烷、丁酮缓慢地注入,最后将R202加入超声波均质器。 Then W33-15, YGO-1401, BYK-310 and trichloroethane, methyl ethyl ketone was slowly injected, and finally the addition of R202 ultrasonic homogenizer. 超声波均质器工作2小时。 Ultrasonic homogenizer 2 hours of work. 涂液粘度,涂-4杯15.6秒。 The viscosity of the coating liquid, Tu -4 cup 15.6 seconds. 将载玻片浸入该涂液中,缓慢取出,室温晾干,放入远红外箱烤箱内,在180℃时烘烤,固化成膜40分钟。 The slides were dipped into the coating solution, withdrawn slowly, dried at room temperature, into the far-infrared oven box, when baked at 180 ℃, film curing for 40 minutes. 用注射器挤出水珠法,测得该涂膜达到高疏水性要求;用测电阻法,测得电阻为2.8K,远小于原WGS-0310涂膜的65K,说明本实施例的涂膜导热性有显著的改进,其原因本实施例中炭黑与成膜基料的体积比为4∶1,而实施例3中炭黑与成膜基料的体积为2∶1,即涂膜中炭黑所占的份额提高了一倍。 Syringe drops extrusion method, the coating film was measured to achieve a high hydrophobicity requirements; by resistance measurement method, the measured resistance is 2.8K, 65K is much less than the original WGS-0310 coating film, thermally conductive coating film according to the present embodiment described embodiment of significant improvement, the present embodiment, the reason the volume ratio of carbon black and a film forming binder was 4 to 1 and the volume of carbon black in Example 3 is 2:1 film-forming binder, i.e., the coating film carbon black share doubled.

由于此涂液显示了三性界面涂料改进型的优点,故命名为WCS-05。 Because of the advantages of the coating liquid shows a modification of the three interfacial coating, so named for the WCS-05. 附图是WCS-05涂敷于板片而生成的涂膜,图中1表示板片,2表示改进型三性界面涂膜,它是固化的聚甲基苯基硅树脂三维交联网络,且其中包裹完全疏水化的二氧化硅和炭黑的胶体粒子,3表示涂膜表面,它是密排的甲基组成。 BRIEF WCS-05 was applied to the plate to generate a coating film, plate represented in FIG. 1, 2 denotes three improved interfacial film, which is a cured poly methylphenyl silicone three dimensional crosslinked network, and wherein the colloidal particles wrapped completely hydrophobized silica and carbon black, and 3 denotes a surface coating, which is composed of closely packed methyl. 涂膜及其表面是完全无毒性的。 And the surface coating film is completely non-toxic.

实施例5:将WCS-05涂敷于50×50mm的试件(用1000号砂纸打磨,再用二甲苯除油脂的PS板)上,烘干成膜,用导热硅胶粘附半导体冷台的冷端,垂直放置,启动半导体冷台,使之在结露工况运行,连续运行8个月,运行时间为8×30×24=5760h。 Example 5: Move WCS-05 was applied to the test piece of 50 × 50mm (No. 1000 with a sandpaper, and then degreasing the PS plate xylene), and drying the film formation, a semiconductor with a thermally conductive silicone adhesive cold station cold end, vertically, starting semiconductor cooling stage, so that it runs in condensation conditions, continuous operation for 8 months, running time of 8 × 30 × 24 = 5760h.

按生产厂家对家用空调规定的使用寿命为10年,每年工作180天,每天工作6小时,对冷、暖空调而言,夏季室内换热器为蒸发器(送冷风),冬季则为冷凝器(送热风),因此10年寿命对室内、外作为蒸发器累积工作时间应乘以0.5,即10×180×6×0.5=5400h。 By the manufacturer of household air conditioners specified life of 10 years, working 180 days a year, working six hours a day, cold, warm in terms of air conditioning in summer indoor heat exchanger to the evaporator (send cold air), compared with the condenser winter (send hot air), thus lifetime of 10 years for interior and exterior as an evaporator cumulative operation time should be multiplied by 0.5, i.e., 10 × 180 × 6 × 0.5 = 5400h.

当半导体冷台运行结束时,观察涂膜未见剥落、裂纹等问题,且试件上水珠的形态与刚结露时,目测未见变化。 When the semiconductor cold running, no peeling of the coating film was observed, and cracks, the morphology and the dew condensation water droplets, no change was observed visually and the specimen immediately. 由于5760>5400,且为连续运行,所以改进型三性界面涂膜寿命与整机寿命相匹配。 Since 5760> 5400, and is a continuous operation, the three interfacial coating film improved life and whole life match. 而且,从实验上使具体实施方式第一段中关于涂膜高粘附性的推论得以验证。 Furthermore, experimentally DETAILED DESCRIPTION make inferences about the first section of high adhesion to a coating film can be verified.

Claims (3)

1.一种高疏水性、高导热性和高粘附性界面涂料,其组成成份包括有成膜基料、分散介质、固体微粒和助剂,成膜基料是W33-15,固体微粒有R202,助剂有YGO-1401,其特征在于:其组成成份中分散介质是三氯乙烷或三氯乙烷与丁酮的混合溶剂,固体微粒有经二甲基硅油处理的炭黑,助剂有BYK-310,各组成成份的体积份是:W33-15:100,三氯乙烷:100~300,丁酮:0~200,R202:200~350,炭黑:200~400,YGO-1401:8~12,BYK-310:4~6,二甲基硅油201-1000:1~2。 A high hydrophobicity, high thermal conductivity and high adhesion interface coating which comprises a constituent film-forming binder, dispersion media, adjuvants and solid particles, a film-forming binder W33-15, solid particles have R202, adjuvants have YGO-1401, comprising: a dispersion medium which is a constituent of a mixed solvent of methyl ethyl ketone and methyl chloroform or trichloroethane, and carbon black solid particles treated by dimethylsilicone oil, help agents include BYK-310, parts by volume of each constituent is: W33-15: 100, trichloroethane: 100 to 300, butanone: 0 ~ 200, R202: 200 ~ 350, carbon black: 200 ~ 400, YGO -1401: 8 ~ 12, BYK-310: 4 ~ 6, dimethicone 201-1000: 1 ~ 2.
2.根据权利要求1所述的高疏水性、高导热性和高粘附性界面涂料,其特征是:所述的各组成成份的体积份是:W33-15:100,三氯乙烷:300,R202:350,炭黑:200,YGO-1401:10,BYK-310:5,硅油201-1000:1。 The high hydrophobicity according to claim 1, high thermal conductivity and high adhesion interface coating, characterized in that: parts of the volume of each constituent is: W33-15: 100, trichloroethane: 300, R202: 350, Carbon Black: 200, YGO-1401: 10, BYK-310: 5, 201-1000 silicone oil: 1.
3.根据权利要求1所述的高疏水性、高导热性和高粘附性界面涂料,其特征是:所述的各组成成份的体积份是:W33-15:100,三氯乙烷:100,丁酮:200,R202:200,炭黑:400,YGO-1401:10,BYK-310:5,硅油201-1000:2。 The high hydrophobicity according to claim 1, high thermal conductivity and high adhesion interface coating, characterized in that: parts of the volume of each constituent is: W33-15: 100, trichloroethane: 100, butanone: 200, R202: 200, Carbon Black: 400, YGO-1401: 10, BYK-310: 5, silicone 201-1000: 2.
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