KR20190130087A - Method for coating on construction surface of solar module for reducing radiant heat - Google Patents

Abstract

The present invention relates to a coating construction method for an installation surface, on which a photovoltaic module is installed, to increase both the power generation efficiency of the photovoltaic module and the energy efficiency of a building by reducing solar radiation. The construction method for coating the installation surface of a photovoltaic module to reduce radiant heat comprises: a first coating layer forming step of forming a first coating layer having excellent penetration and water resistance with an elastic coating by applying, on the installation surface of the upper part of a building, water-soluble acrylic resin paint with high elasticity and low viscosity including 60 to 70 wt% of low viscosity acrylic resin, 25 to 35 wt% of water, 0.1 to 2.5 wt% of aqueous ammonia solution, and 0.1 to 2.5 wt% of elongation additives; a second coating layer forming step of forming a second coating layer to reduce radiant heat by applying, on the first coating layer, a water-soluble acrylic polymer paint including 50 to 55 wt% of acrylic polymer, 20 to 30 wt% of calcium carbonate, 10 to 20 wt% of aluminum trihydroxide, 0.1 to 2.5 wt% of aqueous ammonia solution, and 0.1 to 2.5 wt% of elongation additives; and a third coating layer forming step of forming a third coating layer with excellent pollution resistance and adhesion by applying, on the second coating layer, an acrylic silicone composite paint including 55 to 60 wt% of acrylic silicone, 30 to 35 wt% of crystalline silica, 1 to 10 wt% of titanium dioxide, 1 to 10 wt% of methyl oximinosilane, and 0.1 to 0.5 wt% of pigment.

Description

Method of painting installation surface of photovoltaic module for reducing radiant heat {METHOD FOR COATING ON CONSTRUCTION SURFACE OF SOLAR MODULE FOR REDUCING RADIANT HEAT}

The present invention relates to a method for painting a building, and more particularly, an installation surface on which a solar module is installed to increase the power generation efficiency of the solar module and the energy efficiency of the building at the same time by reducing solar radiation to the upper part of the building. It relates to a coating method for.

Generally, a plurality of solar modules are installed to face sunlight while being supported on a support on a concrete or prefabricated panel on a roof or a roof of a building. The solar modules are converted into electrical energy by using such solar modules. The solar power generation is no pollution, such as air pollution, noise, vibration, easy to maintain and manage, and as fossil energy is gradually exhausted, its demand is gradually increasing.

Since the solar power generation device is capable of small-scale power generation, even non-governmental or corporate individuals are installing and generating power. Usually, the solar power generation device can be installed on the roof or roof of a building, or on an outdoor mountainside or open ground. In the case of the rooftop, it is installed because of good sunlight and high space utilization.

In the related art, Patent Document 1 discloses a transparent substrate, an upper buffer member provided on the lower surface of the transparent substrate, a solar cell provided on the lower surface of the upper buffer member, a lower buffer member provided on the lower surface of the cell, and a lower buffer member provided on the lower substrate. It provides a photovoltaic module comprising a graphite sheet, and a coating layer provided on one or both sides of the graphite sheet to increase the durability of the graphite sheet, and can extend the life of the solar cell by excellent moisture permeation prevention function and heat dissipation. The technology is open to the public.

However, in the above-described conventional technology, the anchor work for installing the support on the concrete installation surface of the upper part of the building in order to stably support the solar module, or the crack occurs in the concrete installation surface itself, the leakage may occur inside the building. And, due to the solar radiation of the installation surface the temperature of the solar module is greatly increased, the solar power generation efficiency is lowered, there is a problem that the energy efficiency of the building is lowered.

Even when the solar module is installed on the roof of the prefabricated panel, anchor work for installing the support on the mounting surface or play may occur in the seams between the panels, and water leakage may occur inside the building. Due to the radiant heat, the temperature of the photovoltaic module is greatly increased, which lowers the photovoltaic power generation efficiency and lowers the energy efficiency of the building.

Republic of Korea Patent Publication No. 10-1090119 (published Dec. 7, 2011)

The present invention has been made to solve all the above problems, by installing a triple coating layer having a high elongation on the photovoltaic module mounting surface of the upper part of the building to reduce the solar radiation heat of the installation surface, lowering the temperature of the solar module The purpose of the present invention is to provide a method of painting the installation surface of the solar module for reducing radiant heat, which increases the energy efficiency of the building by lowering the indoor temperature by blocking the inflow of heat from the upper part of the building to the inside of the building. There is this.

In order to solve the above problems the present invention is to reduce the solar radiation to the upper part of the building in the coating construction method for the installation surface on which the solar module is installed to increase the power generation efficiency of the solar module and the energy efficiency of the building at the same time Water-soluble acrylic having high elasticity and low viscosity, including 60 to 70% of low viscosity acrylic resin, 25 to 35% of water, 0.1 to 2.5% of aqueous ammonia solution and 0.1 to 2.5% of elongation additive on the installation surface of the upper part of the building. A primary coating layer forming step of forming a primary coating layer excellent in penetration and waterproofing property having an elastic coating film by applying a resin paint; Water-soluble, comprising 50 to 55% acrylic polymer, 20 to 30% calcium carbonate, 10 to 20% aluminum trihydroxide, 0.1 to 2.5% aqueous ammonia solution and 0.1 to 2.5% elongation additive on the primary coating layer Forming a secondary coating layer for reducing radiant heat by applying an acrylic polymer paint; And acrylic silicone including 55 to 60% of acrylic silicone, 30 to 35% of crystalline silica, 1 to 10% of titanium dioxide, 1 to 10% of methyl oxymino silane, and 0.1 to 0.5% of pigment on the secondary coating layer. The present invention provides a method of coating the installation surface of a photovoltaic module for reducing radiant heat consisting of a third coating layer forming step having excellent stain resistance and adhesion by applying a composite paint.

According to the present invention, by installing a triple coating layer having a high elongation on the solar module mounting surface of the upper part of the building to reduce the solar radiation heat of the mounting surface, the temperature of the solar module is lowered to increase the photovoltaic power generation efficiency and It blocks the inflow of heat from the upper part and lowers the indoor temperature to increase the energy efficiency of the building, and it prevents water from penetrating into the building and prevents water from penetrating into the building.It has excellent elongation, pollution resistance and adhesion to The coating is maintained without affecting, the coating performance lasts for a long time, and has the effect of being integrated with the mother surface.

Figure 1a is a picture showing the generation of solar radiation heat on the installation surface of the upper part of the building, Figure 1b is a photograph of a non-woven fabric sheet on the upper part of the building.
Figure 2 is a flowchart of the installation surface coating method of the solar module for reducing radiant heat according to an embodiment of the present invention.
3 is a cross-sectional view showing the configuration of an application layer according to an embodiment of the present invention.
Figure 4 is a photograph showing the elongation of the primary coating layer according to an embodiment of the present invention.
5 is a picture of completing the 1, 2, 3 coating layer construction according to an embodiment of the present invention.
6 is a photograph of the temperature of the installation surface before and after the 1, 2, 3 coating layer construction.

Hereinafter, with reference to the drawings will be described in detail with respect to the specific content for carrying out the installation surface coating method of the solar module for reducing radiant heat according to the present invention.

In general, the generation efficiency of the solar module is known to be 14 to 15%, the solar module is very sensitive to heat, when heat is accumulated in the solar module, the power generation efficiency may be lowered to 10% or less. Referring to FIG. 1A, heat generated from the solar module itself and heat such as solar radiant heat of the installation surface may reduce the electrical energy conversion efficiency of the solar module. In addition, once the solar module is installed for more than 10 years, it is very important to prevent the reduction of power generation efficiency.

In order to reduce the solar radiation of the upper part of the building, such as a roof or roof as shown in Figure 1b can be constructed non-woven sheet on the upper surface of the building, this construction method takes a lot of construction period, the pre-treatment work is inconvenient to lift the phenomenon There is a problem that the defect rate is high, and the repair cost increases.

However, the method of painting the installation surface of the solar module for reducing radiant heat according to the present invention is to reduce the solar radiant heat to the upper part of the building to increase the power generation efficiency of the solar module and the energy efficiency of the building at the same time It relates to a coating method for the installation surface to be installed, referring to Figure 2, including the first coating layer forming step (S10), the second coating layer forming step (S20) and the third coating layer forming step (S30) Is done.

The primary coating layer forming step (S10) is a primary coating layer having excellent penetration and water resistance having an elastic coating film by applying a water-soluble acrylic resin paint having high elasticity and low viscosity to the installation surface (S) of the upper part of the building, such as a roof or roof It is a process of forming (10).

To this end, the primary coating layer 10 may include a low viscosity acrylic resin 60 to 70%, water 25 to 35%, aqueous ammonia solution 0.1 to 2.5% and elongation additive 0.1 to 2.5% by weight.

Low-viscosity acrylic resin is a highly elastic low-viscosity water-soluble acrylic resin with low molecular weight, and becomes a basic base raw material for paints, and has high elasticity, which gives elasticity to the coating film. Form.

Ammonia aqueous solution contains 0.1 to 2.5% to function as a solvent.

Elongation additive is included in the 0.1 to 2.5% to increase the elongation, silicone rubber, silica, carbon black and the like can be used.

The primary coating layer 10 is formed by applying a water-soluble acrylic resin composite paint to the mounting surface (S) with a thickness of 0.1 to 0.3mm using a roller of wool material.

If the installation surface (S) is concrete, check cracks carefully with a roller of 8 inches of soft and fine wool, and apply water-soluble acrylic resin paint, and if there are many cracks, work again. In the case of a dent or a severe crack in the installation surface S, it is applied with a high elastic fast curing urethane sealant before the application of the primary coating layer 10.

When the mounting surface (S) is a prefabricated panel, the groove of the anchor part or the joint part of the prefabricated panel is constructed with a high elastic fast curing urethane sealant, and then the sealant is worked, and then the water-soluble acrylic resin paint is applied to the joint part with a roller.

The coated surface of the primary coating layer 10 dried as described above forms a waterproof layer of an elastic coating film having a high elongation of 200% or more as shown in FIG. 4 to block leakage to prevent moisture from penetrating into the interior of the building. The film is maintained without season influences and the film performance is long-term.

The secondary coating layer forming step (S20) is a process of forming a secondary coating layer 20 to reduce radiant heat by applying a water-soluble acrylic polymer paint on the primary coating layer 10.

To this end, the secondary coating layer 20 by weight 50% to 55% acrylic polymer, 20 to 30% calcium carbonate, 10 to 20% aluminum trihydroxide, 0.1 to 2.5% aqueous ammonia solution and 0.1 to 10% elongation additive May contain 2.5%.

Acrylic polymer is a water-soluble acrylic molomer containing 50 to 55% of elasticity, which is a basic base material of the coating material, elasticity is given to the coating film, and has waterproof performance.

Calcium carbonate is contained 20 to 30% to increase the strength of the coating film.

Aluminum trihydroxide increases the thermal performance, reducing the sun's radiant heat as much as possible, reducing the ambient temperature.

Ammonia aqueous solution contains 0.1 to 2.5% to function as a solvent.

Elongation additive is included in the 0.1 to 2.5% to increase the elongation, silicone rubber, silica, carbon black and the like can be used.

The secondary coating layer 20 is coated on the primary coating layer 10 to a thickness of 400 to 800㎛ using a roller or an air spray gun. When the coating area is small, use a roller. When the coating area is large, use an air spray gun. When using an air spray gun, the distance from the installation surface is discharged at a discharge pressure of 100 to 110 kgf / cm 2 while maintaining a constant distance of 40 to 50 cm, the coating amount is applied at 0.4 L / m 2, and the thickness of the coating film is 400 to 800 μm. To be At this time, the motor of the air spray gun is more than 4HP is suitable.

The coated surface of the dried second coating layer 20 forms a waterproof layer of an elastic coating film having a high elongation of 200% or more to block leakage and prevent water from penetrating into the building, without affecting temperature or season. The coating is maintained and the coating performance is long-term. In addition, solar radiation is blocked as much as possible to lower the temperature of the solar module to increase the efficiency of photovoltaic power generation at the same time to block the heat from entering the interior of the building to lower the indoor temperature to increase the energy efficiency of the building.

The tertiary coating layer forming step (S30) is a process of increasing the life of the coating film by forming a tertiary coating layer 30 excellent in fouling resistance and adhesion by applying an acrylic silicone composite paint on the secondary coating layer 20. .

To this end, the tertiary coating layer 30 is 55% to 60% acrylic silicone, 30 to 35% crystalline silica, 1 to 10% titanium dioxide, 1 to 10% methyl oxymino silane, and 0.1 to 0.5% pigment. It is made, including.

Acrylic silicone contains 55 to 60% to become a basic base material of the paint, and has a stain resistance to maintain the cleanness of the coating film to increase the long-term life.

Crystalline silica (Crytalline Silica) is a silica having a structure uniformly arranged in a regular repeating pattern, 30 to 35% is included to increase the strength of the coating film.

Titanium dioxide is contained 1 to 10% to block ultraviolet rays, increase the heat shielding performance to reduce the radiant heat of the sun to lower the ambient temperature.

Methyl Oximino Silane contains 1-10% to reflect sunlight and increase pollution resistance.

The tertiary coating layer 30 is formed by applying a thickness of 400 to 800㎛ on the secondary coating layer 20 using a roller or an air spray gun. When using an air spray gun, the distance from the installation surface is discharged at a discharge pressure of 100 to 110 kgf / cm 2 while maintaining a constant distance of 40 to 50 cm, the coating amount is applied at 0.3 to 0.4 l / m 2, and the thickness of the coating film is 400 to 800 μm. It should be the thickness of.

Thus dried tertiary coating layer 30 is shown in Figure 5, the coating surface forms an elastic coating layer having a high elongation of 200% or more, the effect of temperature or season with excellent elongation, fouling resistance and adhesion The coating film can be maintained continuously, greatly increasing the life of the coating film, long-term coating performance, and integral with the mother surface. In addition, solar radiation is blocked as much as possible to lower the temperature of the solar module to increase the efficiency of photovoltaic power generation at the same time to block the heat from entering the interior of the building to lower the indoor temperature to increase the energy efficiency of the building.

Referring to FIG. 6 (a), when the temperature of the installation surface S was measured by a thermometer at 12 am on the roof of the building on a clear day before the 1, 2, 3 coating layers, the temperature was 81.6 degrees Fahrenheit. Referring to (b), after the first and second application layers were installed on the roof of the same building the next day, when the temperature of the installation surface (S) was measured at 12 am on a clear day, the temperature was 69.8 degrees Fahrenheit. Therefore, it could be confirmed that the temperature of about 12 degrees Fahrenheit is reduced and the temperature of about 7 degrees Fahrenheit is reduced.

In addition, it is possible to reduce the energy efficiency by maintaining the excellent cooling efficiency by lowering the internal temperature of the building 3 to 5 ℃ in summer.

After all, the installation surface coating method of the photovoltaic module for reducing radiant heat according to the present invention by constructing a triple coating layer having a high elongation on the photovoltaic module mounting surface of the upper part of the building by applying the coating layer is the mother surface and temperature By all the movements such as expansion and contraction according to the season, it is possible to solve the basic problems that can occur in the installation surface, reduce the solar radiation of the installation surface, increase the power generation efficiency and energy efficiency simultaneously, and greatly increase the film life. . In addition, it prevents water from penetrating inside the building by blocking leakage, and with excellent elongation, pollution resistance, and adhesion, the film is maintained without affecting temperature or season, and the film performance lasts for a long time and is integrated with the mother surface.

In the present invention, the above embodiment is an example, and the present invention is not limited thereto. Anything that has substantially the same configuration as the technical idea described in the claims of the present invention and achieves the same working effects is included in the technical scope of the present invention.

S. Mounting surface
10. Primary coating layer
20. Second coating layer
30. 3rd application layer

Claims (5)

In the coating method for the installation surface on which the solar module is installed to reduce the solar radiation to the upper part of the building to increase the power generation efficiency of the solar module and the energy efficiency of the building at the same time,
Water-soluble acrylic resin having high elasticity and low viscosity, including 60 to 70% of low viscosity acrylic resin, 25 to 35% of water, 0.1 to 2.5% of aqueous ammonia solution and 0.1 to 2.5% of elongation additive on the installation surface of the upper part of the building. A primary coating layer forming step of forming a primary coating layer having excellent penetration force and waterproofness by applying a coating material;
Aqueous water-soluble solution comprising 50-55% acrylic polymer, 20-30% calcium carbonate, 10-20% aluminum trihydroxide, 0.1-2.5% aqueous ammonia solution and 0.1-2.5% elongation additive on the primary coating layer. Forming a secondary coating layer for reducing radiant heat by applying an acrylic polymer paint; And
Acrylic silicone composite comprising 55 to 60% of acrylic silicone, 30 to 35% of crystalline silica, 1 to 10% of titanium dioxide, 1 to 10% of methyl oxymino silane, and 0.1 to 0.5% of pigment on the secondary coating layer by weight. Method of coating the installation surface of the photovoltaic module for reducing radiant heat consisting of the third coating layer forming step excellent in fouling resistance and adhesion by applying paint.
The method of claim 1,
The primary coating layer forming step,
Installation of cracks or seams of the mounting surface with high elastic fast curing urethane sealant, and then using a roller to apply a water-soluble acrylic resin paint to the mounting surface with a thickness of 0.1 to 0.3mm, installation of a solar module for reducing radiant heat Cotton coating construction method.
The method of claim 1,
The secondary coating layer forming step,
Method of coating the installation surface of the photovoltaic module for reducing radiant heat, characterized in that the coating using a roller or an air spray gun with a thickness of 400 to 800㎛ on the primary coating layer.
The method of claim 1,
The third coating layer forming step,
Method of coating the installation surface of the photovoltaic module for reducing radiant heat, characterized in that to apply a thickness of 400 to 800㎛ on the secondary coating layer using a roller or an air spray gun.
The method according to any one of claims 1 to 4,
Installation surface coating method of the solar module for reducing the radiant heat to reduce the temperature of the installation surface 5 to 15 ℃.

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