CN109943167A - A kind of high reflection insulating moulding coating - Google Patents

Abstract

The invention discloses a kind of high reflection insulating moulding coatings, including prime coat and top coat layer, the prime coat is made of following components (parts by weight): average grain diameter 300nm rutile titanium white powder 10%~15%, average grain diameter 300nm hollow glass micropearl 10%~20%, average grain diameter 200nm talcum powder 5%~10%, ferrous chloride 0.5%~1.5%, organosilicon-modified acrylic 40%~50%, pure water 15%~20%, the top coat layer is made of following components (parts by weight): 10 μm of kaolin 3%~12% of average grain diameter, 10 μm of rutile titanium white powder 3%~12% of average grain diameter, 20 μm of hollow glass micropearl groups 10%~25% of average grain diameter, 20 μm of talcum powder 5%~10% of average grain diameter, ferrous chloride 0.5% ~1.5%, organosilicon-modified acrylic 40%~50%, pure water 15%~20%.The present invention is intended to provide a kind of high reflection insulating moulding coating, which includes that thermal coefficient is ultralow, heat-proof quality is good, flexible, durable, stain resistant, the convenient and fast effect of construction safety.

Description

A kind of high reflection insulating moulding coating

Technical field

The present invention relates to water paint fields, in particular to arriving a kind of high reflection insulating moulding coating.

Background technique

Solar energy reflective insulation coating for construction is to contain using in coating constituent to the radiation wave spectrum from the sun Middle major part wavelength has the performance of high reflectivity to reduce the temperature of exterior walls of buildings wall, reduces the temperature difference of indoor and outdoor, from And lower heat transfer motive force, so that room temperature is reduced refrigeration lower than the room temperature of cement wall surface or common coating metope Equipment electric consumption reaches energy-efficient effect.

The energy of sunlight is concentrated mainly on visible light and near infrared ray part, this two parts account for the 90% of solar energy with On.When sunray projects body surface, it then follows visible light rule has reflection, absorbs, through property, reflectivity (a), absorptivity (p), transmitance (r) meet following rule: a+p+r=1, and the heat ray of the opaque body sun cannot be led to It crosses, therefore transmitance (r) is 0, therefore above-mentioned formula becomes a+p=1, from the above equation, we can see that, object its surface reflectivity height is inhaled Yield will be low.

Due to constituting the difference of material, the absorption of solar rays is different, if certain material is to solar spectrum Middle major part wavelength does not absorb, and is reflected, then obtained energy is just few, and temperature is also with regard to low, vice versa.It is applied in production When material, material selection is selectively carried out, so that it may so that coating surface has high reflectivity to sunlight, to effectively drop Low surface temperature, when material has high radiant emissivity for the heat absorbed again, so that it may again by the heat of absorption It radiate well, at common temperature, object radiation is in infrared band, can use atmospheric window and is emitted to building Beyond the region of objective existence.

Currently, we retrieve the open source literature of some antiradiation insulating moulding coatings, such as:

1. Chinese Patent Application No. CN201310655260.8, publication date on April 23rd, 2014, this application discloses A kind of high-performance building reflective heat-insulation paint and its preparation method and application, the reflective heat-insulation paint include it is following by weight The raw material of calculation: film forming matter: 40-50 parts, rutile type titanium white: 15-25 parts, functional filler: 5-15 parts, infra-red radiation Powder: 5-15 parts, kaolin: 5-10 parts, talcum powder: 5-10 parts, defoaming agent: 0.2-0.5 parts, wetting agent: 0.2-0.4 parts, dispersion Agent: 0.2-0.4 parts, 0.3-0.6 parts, 1-3 parts, 100 deionized water: coalescing agent: thickener: are added to.Its intermediate infrared radiation Powder is the superfines of the high radiant rate obtained by several metal oxides by high temperature sintering.Disadvantage is that: it is right The albedo of nanoscale visible light and infrared light is weak.

2. Chinese Patent Application No. CN201710163313.2, publication date on July 7th, 2017, this application discloses one Kind insulating mold coating composite integrated plate and preparation method thereof, it is by acrylic emulsion, silicone acrylic emulsion, silica dioxide gel, gas Gel, hollow glass micropearl, poly- third fiber, hydroxyethyl cellulose (HEC) are applied to alkali-resistant glass fiber mesh preparation after being prepared into rubber cement It is micro- at insulating mold coating layer, and by acrylic emulsion, silicone acrylic emulsion, heat-insulated pigment, protective glue, aeroge, hollow glass Heat-insulated coating material is sprayed on insulating mold coating layer and is made by the heat-insulated coating material that pearl, multifunctional assistant are prepared Heat-insulated coating material layer obtains insulating mold coating composite integrated plate.Disadvantage is that: to nanoscale 700nm~150nm The albedo of infrared light is weak.

Summary of the invention

The present invention provides a kind of high reflection insulating moulding coating in view of the above technical problems, the coating include thermal coefficient it is ultralow, Heat-proof quality is good, flexible, durable, stain resistant, the convenient and fast effect of construction safety.

To achieve the above object the present invention adopts the following technical scheme:

A kind of high reflection insulating moulding coating, including prime coat and top coat layer, the prime coat is by following components (parts by weight) group At: average grain diameter 300nm rutile titanium white powder 10%~15%, average grain diameter 300nm hollow glass micropearl 10%~20% are put down Equal partial size 200nm talcum powder 5%~10%, ferrous chloride 0.5%~1.5%, organosilicon-modified acrylic 40%~50%, Pure water 15%~20%.

The top coat layer is made of following components (parts by weight): 10 μm of kaolin 3%~12% of average grain diameter, average grain 10 μm of rutile titanium white powder 3%~12% of diameter, 20 μm of hollow glass micropearl groups 10%~25% of average grain diameter, 20 μ of average grain diameter M talcum powder 5%~10%, ferrous chloride 0.5%~1.5%, organosilicon-modified acrylic 40%~50%, pure water 15%~ 20%.

Mass fraction shared by each raw material of the prime coat is best are as follows: average grain diameter 300nm rutile titanium white powder 13% is put down Equal partial size 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organic-silicon-modified third Olefin(e) acid 46%, pure water 17%.

Mass fraction shared by each raw material of the top coat layer is best are as follows: 10 μm of kaolin 5% of average grain diameter, average grain diameter 10 μm rutile titanium white powder 10%, 20 μm of hollow glass micropearl groups 18% of average grain diameter, 20 μm of talcum powder 8% of average grain diameter, dichloro Change iron 1%, organosilicon-modified acrylic 42%, pure water 16%.

The coating thickness of the prime coat is 70~90 μm；The coating thickness of the top coat layer is 90~120 μm.

The optical principle that the present invention applies:

The sunlight of earth surface is irradiated to containing 53% infrared ray, 44% visible light, 3% ultraviolet light.From heat transfer theory Known to: there are three types of thermaltransmission modes: conducting, radiates, convection current.The design principle of insulating moulding coating uses reflecting material pair The sunray of 400nm--2500nm range carries out high reflection, does not allow the heat of the sun to carry out accumulation heating in body surface, again Heat heat loss through radiation cooling can be carried out automatically, and the heat of body surface is radiated in space, the temperature of object is reduced.

Found through numerous studies, the ratio between the partial size of emissivity and reflecting material and wavelength of light α are related, α 0.1~1 it Between there is reflex, heat insulation is best；It is diffusing reflection when α < 0.1, heat insulation is poor.

Secondly different colours are not also identical to the reflection of light, for example white or grey are to visible reflectance height, black pair The absorption of light is strong, and emissivity is low.

Finally be divided into two kinds from coating every thermal property principle: 1, completely cut off conduction type: pyroconductivity is extremely low, passes thermal energy It leads and almost completely cuts off, temperature difference environment is isolated；2, reflect thermal-optical type: to infrared ray and hot visible light, (sunray generates heat Major part) effective reflection, achieve the purpose that heat-insulated.

The present invention compared with prior art the utility model has the advantages that

1. the light of the raw material reflection different wave length of different-grain diameter, small but if the raw material of different-grain diameter is put together The raw material of partial size can occupy the space that big partial size is originally defined, and be unfavorable for the reflection to light, therefore prime coat in the present invention instead It is inconsistent with the raw material particle size of top coat layer addition, separate the functional area for reflecting visible light and infrared light, prime coat is mainly anti- Penetrate visible light, top coat layer key reflections infrared light, comprehensive reflection efficiency height.

2. containing thin gas inside the hollow glass micropearl that the present invention adds, thermal coefficient is low, has coating Extraordinary heat insulation and preservation effect.

3. the present invention substitutes titanium dioxide using the cheap kaolin in part, reflecting effect is constant, reduce manufacture at This.

4. the organosilicon-modified acrylic that the present invention uses possesses excellent adhesive force, impact resistance and flexibility, brilliance Weatherability and Bao Se gloss retention, feel is smooth, stain resistant, and scratch resistance is good, heat resistance outstanding, can be subjected to 200 DEG C for a long time Operating temperature.

Specific embodiment

Below in conjunction with specific embodiment, present invention is further described in detail, but does not limit the scope of the invention And application range:

Embodiment 1:

The present embodiment includes prime coat and top coat layer, and prime coat is made of following components (parts by weight): the prime coat Mass fraction shared by each raw material are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

Mass fraction shared by each raw material of top coat layer are as follows: 10 μm of kaolin 5% of average grain diameter, 10 μm of rutile of average grain diameter Titanium dioxide 10%, 20 μm of hollow glass micropearl groups 18% of average grain diameter, 20 μm of talcum powder 8% of average grain diameter, ferrous chloride 1%, Organosilicon-modified acrylic 42%, pure water 16%.

When spraying, the coating thickness of prime coat is 80 μm, and the coating thickness of top coat layer is 100 μm.

Embodiment 2:

The present embodiment includes prime coat and top coat layer, and prime coat is made of following components (parts by weight): the prime coat Mass fraction shared by each raw material are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

Mass fraction shared by each raw material of top coat layer are as follows: 10 μm of kaolin 8% of average grain diameter, 10 μm of rutile of average grain diameter Titanium dioxide 7%, 20 μm of hollow glass micropearl groups 18% of average grain diameter, 20 μm of talcum powder 8% of average grain diameter, ferrous chloride 1%, Organosilicon-modified acrylic 42%, pure water 16%.

When spraying, the coating thickness of prime coat is 80 μm, and the coating thickness of top coat layer is 100 μm.

Embodiment 3:

The present embodiment includes prime coat and top coat layer, and prime coat is made of following components (parts by weight): the prime coat Mass fraction shared by each raw material are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

Mass fraction shared by each raw material of top coat layer are as follows: 10 μm of kaolin 11% of average grain diameter, 10 μm of golden red of average grain diameter Stone titanium dioxide 4%, 20 μm of hollow glass micropearl groups 18% of average grain diameter, 20 μm of talcum powder 8% of average grain diameter, ferrous chloride 1%, organosilicon-modified acrylic 42%, pure water 16%.

When spraying, the coating thickness of prime coat is 80 μm, and the coating thickness of top coat layer is 100 μm.

Experiment 1:

Coating is prepared in the ratio of raw material in each embodiment 1-3, after shining spraying by coating thickness on scraper plate, is placed on too The lower straight solarization of sun, measures the temperature of different time scraper plate.

As can be seen from the above table, the specific gravity being added with kaolin is increasing, and heat-proof quality of the present invention gradually decreases.

Embodiment 4:

The present embodiment includes prime coat and top coat layer, and prime coat is made of following components (parts by weight): the prime coat Mass fraction shared by each raw material are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

Mass fraction shared by each raw material of top coat layer are as follows: 10 μm of kaolin 5% of average grain diameter, 10 μm of rutile of average grain diameter Titanium dioxide 10%, 20 μm of hollow glass micropearl groups 18% of average grain diameter, 20 μm of talcum powder 8% of average grain diameter, ferrous chloride 1%, Organosilicon-modified acrylic 42%, pure water 16%.

When spraying, the coating thickness of prime coat is 80 μm, and the coating thickness of top coat layer is 100 μm.

Embodiment 5:

The present embodiment includes prime coat and top coat layer, and prime coat is made of following components (parts by weight): the prime coat Mass fraction shared by each raw material are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

Mass fraction shared by each raw material of top coat layer are as follows: 10 μm of kaolin 5% of average grain diameter, 10 μm of rutile of average grain diameter Titanium dioxide 10%, 20 μm of hollow glass micropearl groups 14% of average grain diameter, 20 μm of talcum powder 10% of average grain diameter, ferrous chloride 1%, Organosilicon-modified acrylic 44%, pure water 16%.

When spraying, the coating thickness of prime coat is 80 μm, and the coating thickness of top coat layer is 100 μm.

Embodiment 3:

The present embodiment includes prime coat and top coat layer, and prime coat is made of following components (parts by weight): the prime coat Mass fraction shared by each raw material are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

Mass fraction shared by each raw material of top coat layer are as follows: 10 μm of kaolin 5% of average grain diameter, 10 μm of rutile of average grain diameter Titanium dioxide 10%, 20 μm of hollow glass micropearl groups 22% of average grain diameter, 20 μm of talcum powder 7% of average grain diameter, ferrous chloride 1%, Organosilicon-modified acrylic 40%, pure water 15%.

When spraying, the coating thickness of prime coat is 80 μm, and the coating thickness of top coat layer is 100 μm.

Experiment 2:

Coating is prepared in the ratio of raw material in each embodiment 4-6, after shining spraying by coating thickness on scraper plate, is placed on too The lower straight solarization of sun, measures the temperature of different time scraper plate.

As can be seen from the above table, it is fixed in titanium dioxide and kaolin adding proportion, only changes the additive amount of glass microballoon, The heat-proof quality variation of coating is little.

Embodiment 7:

The present embodiment includes prime coat and top coat layer, and prime coat is made of following components (parts by weight): the prime coat Mass fraction shared by each raw material are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

Mass fraction shared by each raw material of top coat layer are as follows: 10 μm of kaolin 5% of average grain diameter, 10 μm of rutile of average grain diameter Titanium dioxide 10%, 20 μm of hollow glass micropearl groups 18% of average grain diameter, 20 μm of talcum powder 8% of average grain diameter, ferrous chloride 1%, Organosilicon-modified acrylic 42%, pure water 16%.

When spraying, the coating thickness of prime coat is 80 μm, and the coating thickness of top coat layer is 100 μm.

Embodiment 8:

The present embodiment includes prime coat and top coat layer, and prime coat is made of following components (parts by weight): the prime coat Mass fraction shared by each raw material are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

Mass fraction shared by each raw material of top coat layer are as follows: 10 μm of kaolin 5% of average grain diameter, 10 μm of rutile of average grain diameter Titanium dioxide 10%, 20 μm of hollow glass micropearl groups 18% of average grain diameter, 20 μm of talcum powder 8% of average grain diameter, ferrous chloride 1%, Organosilicon-modified acrylic 42%, pure water 16%.

When spraying, the coating thickness of prime coat is 70 μm, and the coating thickness of top coat layer is 90 μm.

Embodiment 9:

The present embodiment includes prime coat and top coat layer, and prime coat is made of following components (parts by weight): the prime coat Mass fraction shared by each raw material are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

Mass fraction shared by each raw material of top coat layer are as follows: 10 μm of kaolin 5% of average grain diameter, 10 μm of rutile of average grain diameter Titanium dioxide 10%, 20 μm of hollow glass micropearl groups 18% of average grain diameter, 20 μm of talcum powder 8% of average grain diameter, ferrous chloride 1%, Organosilicon-modified acrylic 42%, pure water 16%.

When spraying, the coating thickness of prime coat is 90 μm, and the coating thickness of top coat layer is 110 μm.

Experiment 3:

Coating is prepared in the ratio of raw material in each embodiment 7-9, presses after spraying different thickness, is placed on too on scraper plate The lower straight solarization of sun, measures the temperature of different time scraper plate.

As can be seen from the above table, fixed in titanium dioxide and kaolin adding proportion, only change coating thickness, coating every Hot property variation is little.

In addition, through detecting, the contrast ratio (hiding rare) >=0.96 for the coating that embodiment 1 provides, stain resistance≤8% is resistance to Artificial weathering aging (>=600h), water resistance (>=96h), alkali resistance (>=48h), abrasion resistance (>=2000 times) meet GB/T9755-2014 " exterior wall coating material of synthetic resin emulsion " " high-class product " requirement.

Claims (4)

1. a kind of high reflection insulating moulding coating, it is characterised in that: including prime coat and top coat layer, the prime coat is by following components (parts by weight) composition: average grain diameter 300nm rutile titanium white powder 10%~15%, average grain diameter 300nm hollow glass micropearl 10%~20%, average grain diameter 200nm talcum powder 5%~10%, ferrous chloride 0.5%~1.5%, organosilicon-modified acrylic 40%~50%, pure water 15%~20%.

The top coat layer is made of following components (parts by weight): 10 μm of kaolin 3%~12% of average grain diameter, and 10 μm of average grain diameter Rutile titanium white powder 3%~12%, 20 μm of hollow glass micropearl groups 10%~25% of average grain diameter, 20 μm of talcum powder of average grain diameter 5%~10%, ferrous chloride 0.5%~1.5%, organosilicon-modified acrylic 40%~50%, pure water 15%~20%.

2. high reflection insulating moulding coating according to claim 1, it is characterised in that: quality shared by each raw material of the prime coat Number is best are as follows: average grain diameter 300nm rutile titanium white powder 13%, average grain diameter 300nm hollow glass micropearl 16%, average grain Diameter 200nm talcum powder 7%, ferrous chloride 1%, organosilicon-modified acrylic 46%, pure water 17%.

3. high reflection insulating moulding coating according to claim 1, it is characterised in that: quality shared by each raw material of the top coat layer Number is best are as follows: 10 μm of kaolin 5% of average grain diameter, 10 μm of rutile titanium white powder 10% of average grain diameter, 20 μm of skies of average grain diameter Heart glass microballoon group 18%, 20 μm of talcum powder 8% of average grain diameter, ferrous chloride 1%, organosilicon-modified acrylic 42% are pure Water 16%.

4. high reflection insulating moulding coating according to claim 1 to 3, it is characterised in that: the coating thickness of the prime coat It is 70~90 μm；The coating thickness of the top coat layer is 90~120 μm.