KR102439608B1 - PVT Panel having Deformation-Resistant Structure - Google Patents

Abstract

The present invention provides a PVT unit including a PV panel that generates electric energy by receiving sunlight and a solar heat absorption plate provided under the PV panel to absorb thermal energy, and a panel case having a structure that surrounds the edge of the PVT unit as a whole. , provided between the lower end in the longitudinal direction of the PVT unit and the panel case, a sag prevention pin for preventing deformation or sagging due to the weight of the PVT unit, and both ends in the width direction of the PVT unit and the panel case , It relates to a PVT panel having a deformation preventing structure including a PVT unit fixing block for preventing contact or close contact between the PVT unit and the case cover.
According to the present invention, by installing the anti-sag pin and the PVT unit fixing block between the PVT unit and the panel case in the PVT panel, it is possible to prevent sagging and deformation of the PVT unit, thereby improving the durability and stability of the PVT panel as a whole, and the PVT panel has the effect of facilitating the maintenance of

Description

PVT Panel having Deformation-Resistant Structure

The present invention relates to a PVT panel having a deformation-resistant structure, and more particularly, by installing an anti-sag pin and a PVT unit fixing block between the PVT unit and the panel case, sagging and deformation of the PVT unit are prevented and thus the overall durability of the PVT panel It relates to a PVT panel having an anti-deformation structure that can improve the stability of the PVT panel and facilitate maintenance of the PVT panel.

In general, power generation using solar energy includes solar power generation that converts sunlight or solar heat into electrical energy, and solar thermal power generation that collects solar heat from a solar light source and uses it for heating or hot water. Various types of photovoltaic (PV; photovoltaic) modules have been developed and used with the power generation structure of living energy.

However, since the photovoltaic module generates heat in the process of generating electricity to raise its own temperature, there is a disadvantage in that the efficiency of electricity production cannot rise above a certain level. In other words, in the case of crystalline solar power modules, only about 12 to 16% of the energy incident from the sun is used for power generation, so the solar energy use efficiency is quite low, and the rest of the energy is consumed as heat. As the temperature of the cell increases, the performance and durability of the cell are affected, and there is a problem in that the electrical conversion efficiency decreases when converting electrical energy due to the temperature increase due to the characteristics of the cell.

Therefore, in the case of a photovoltaic module, waste heat is discharged after installing a configuration for ventilating heat on the rear side, and the electrical performance of the system is improved by lowering the temperature of the photovoltaic module.

In this background, a photovoltaic/thermal (PVT; photohvoltaic-thermal) power generation module that can be used for hot water supply or heating by efficiently using the heat generated during the electricity production process of the photovoltaic power module so that both solar power and solar heat can be used at the same time developed and used.

As a technology related to such a photovoltaic/thermal power generation module, for example, a photovoltaic power module installed on the roof or an outer wall of a building that absorbs solar energy and converts it into electric energy to generate electricity, and a plurality of cells are connected; An outer frame attached to the outside of the back surface of the photovoltaic module and spaced apart from the photovoltaic module and the roof or outer wall of the building to form an accommodating space for accommodating air therebetween, and an outer frame provided with an air inlet; A heat conductive adhesive applied to the rear surface, a heat sink attached to the photovoltaic module by the heat conductive adhesive and radiating heat generated from the photovoltaic module to the air accommodated in the accommodation space, and on the back surface of the heat sink A plurality of heat-dissipating fins attached to facilitate the discharge of heat radiated from the heat sink, and an air collector that is accommodated in the accommodation space and collects heated air so as to be used for hot water supply or heating, wherein the outer frame is the sun Air-collecting solar that is configured to have a height such that the rear surface of the photovoltaic module is spaced 10 to 15 cm from the outer surface of the building roof or the outer wall of the building, and can obtain a high heat source with the cooling effect of the photovoltaic module A technology for a photovoltaic device has been disclosed.

However, this conventional solar/thermal power generation module-related technology applies a plurality of cells to the entire area of the photovoltaic module, so the electric power generation efficiency according to the photovoltaic power generation is high, whereas the electricity generated during the electric power generation process in the photovoltaic module is high. Since only the heat source is conducted, the heat source production efficiency for heat use is insignificant, and since a heat sink with a plurality of heat sink fins is used for heat dissipation, the weight and volume of the solar module increase, so that the load according to the large weight is applied and the sagging phenomenon is reduced. There is a problem in that durability is lowered.

In addition, when the panel sag occurs in the conventional solar/thermal power module, not only the structure of the panel is weakened, but also the heat energy distribution inside the panel becomes non-uniform, so that thermal deformation easily occurs, and the light collecting efficiency of the solar module is significantly lowered. There is a problem being

Korean Patent Registration No. 10-1745902 (Registration Date: 2017.06.05) Korean Patent No. 10-1742248 (Registration Date: 2017.05.25)

An object of the present invention is to prevent sagging and deformation of the PVT unit by installing an anti-sag pin and a PVT unit fixing block between the PVT unit and the panel case, thereby improving the durability and stability of the PVT panel as a whole, and maintaining the PVT panel It is to provide a PVT panel having a deformation-resistant structure that facilitates the

In order to achieve this object, the PVT panel having a deformation preventing structure according to the present invention is a PVT comprising a PV panel that generates electric energy by receiving sunlight and a solar heat absorption plate provided under the PV panel to absorb thermal energy unit; a panel case having a structure surrounding the rim of the PVT unit as a whole; a sag prevention pin provided between the lower end in the longitudinal direction of the PVT unit and the panel case, and to prevent deformation or sagging due to the weight of the PVT unit; and a PVT unit fixing block provided between both ends of the PVT unit in the width direction and the panel case and preventing contact or close contact between the PVT unit and the case cover.

The panel case may be formed in a 'C'-shaped structure in which the inner direction is opened in cross-section.

At least two or more of the anti-sag pins may be provided between the lower end in the longitudinal direction of the PVT unit and the panel case.

The anti-sag pins extend obliquely bent at a predetermined angle in the inner direction of the panel case from one side of the case fixing part and the case fixing part having a rectangular shape with an open lower part in cross section, inside the outer wall of the panel case It may be formed to have a constant distance from the surface and may be formed of a PVT unit accommodating part for accommodating the PVT unit.

Two or more of the PVT unit fixing blocks may be provided between both ends of the PVT unit in the width direction and the panel case, respectively.

The PVT unit fixing block may be formed in a 'L' shape in cross section, and installed in the panel case in a structure in which a lower portion extends in the inner direction of the panel case.

The PVT unit fixing block may have a fixing slit formed thereon and be fixed to the top in the structure on the cross-section of the panel case by the fixing slit.

The PVT panel having a deformation-resistant structure according to the present invention prevents sagging and deformation of the PVT unit by installing an anti-sag pin and a PVT unit fixing block between the PVT unit and the panel case, thereby improving the durability and stability of the PVT panel as a whole. There is an effect of facilitating the maintenance of the PVT panel.

1 is a schematic diagram showing an overall plan view of a PVT panel having a deformation preventing structure according to an embodiment of the present invention.
Figure 2 is a schematic diagram showing a cross-sectional view of a state in which the anti-sag pin is installed between the PVT unit and the panel case of the PVT panel having a deformation preventing structure according to an embodiment of the present invention.
3 is a photograph showing the overall appearance of the anti-sag fins of the PVT panel having a deformation preventing structure according to an embodiment of the present invention.
4 is a photograph showing a state in which the anti-sag pin is installed on the PVT panel having a deformation preventing structure according to an embodiment of the present invention.
5 is a schematic diagram showing an overall plan view showing a position where a PVT unit fixing block is installed on a PVT panel having a deformation preventing structure according to an embodiment of the present invention.
6 is a schematic diagram illustrating a cross-sectional view of a PVT unit fixing block installed between a PVT unit and a panel case of a PVT panel having a deformation preventing structure according to an embodiment of the present invention.
7 is a photograph showing the overall appearance of the PVT unit fixing block of the PVT panel having a deformation preventing structure according to an embodiment of the present invention.
8 is a photograph showing a state in which a PVT unit fixing block is installed on a PVT panel having a deformation preventing structure according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, in describing the embodiments of the present invention, specific numerical values are merely examples.

1 is a schematic diagram showing an overall plan view of a PVT panel having a deformation preventing structure according to an embodiment of the present invention, and in FIG. 2 is a PVT of a PVT panel having a deformation preventing structure according to an embodiment of the present invention. A schematic diagram showing a cross-sectional view of a state in which the anti-sag pin is installed between the unit and the panel case is shown. A photograph is disclosed.

4 is a photograph showing a state in which the anti-sag pin is installed on the PVT panel having a deformation preventing structure according to an embodiment of the present invention, and FIG. 5 is a deformation preventing according to an embodiment of the present invention. A schematic diagram showing the overall plan view showing the position where the PVT unit fixing block is installed on the PVT panel having a structure is shown, and in FIG. A schematic diagram showing a cross-sectional view of a state in which the PVT unit fixing block is installed between the cases is shown.

7 is a picture showing the overall appearance of the PVT unit fixing block of the PVT panel having a deformation preventing structure according to an embodiment of the present invention is disclosed, in FIG. 8 having a deformation preventing structure according to an embodiment of the present invention A photo showing a state in which the PVT unit fixing block is installed on the PVT panel is disclosed.

Referring to these drawings, the PVT panel 100 having a deformation prevention structure according to the present invention is provided under the PV panel 111 to generate electric energy by receiving sunlight and the PV panel 111 to provide thermal energy. A PVT unit 110 including a solar heat absorption plate 112 to absorb, a panel case 120 having a structure surrounding the rim of the PVT unit 110 as a whole, a longitudinal lower end of the PVT unit 110 and the panel A sag prevention pin 160 provided between the case 120 and preventing deformation or sagging due to the weight of the PVT unit 110, and both ends in the width direction of the PVT unit 110 and the panel case 120 ) is provided between, and is configured to include a PVT unit fixing block 170 for preventing contact or close contact between the PVT unit 110 and the case cover 130 .

That is, the PVT panel 110 having a deformation-resistant structure according to the present invention by installing the anti-sag pin 160 between the PVT unit 110 and the panel case 120, the PVT unit ( It is possible to prevent deformation (Deformation) such as bending or bending the PVT unit 110 by its own weight by its own weight, and the PVT unit fixing block 170 between the PVT unit 110 and the panel case 120 . ), to provide a spaced space between the PVT unit 110 and the case cover 130 at a predetermined interval and at the same time stably fix the PVT unit 110 to the panel case 120 so that the PVT unit 110 is the case. Heat energy is concentrated by being in contact with or in close contact with the cover 130 , thereby preventing thermal deformation or damage to the contact or contact portion that may occur.

Preferably, the solar heat absorption plate 112 is formed to have an area approximately equal to that of the PV panel 111 so as to be in contact with the entire lower area of the PVT panel 100 to evenly conduct the heat source. In addition, it is preferable that the absorber plate is made of an aluminum (Al) material instead of the copper (Cu) material that has been used instead of the conventional solar heat absorber. That is, the conventional absorber plate made of copper (Cu) has a high specific gravity as 8.9, but in the case of an absorber plate made of aluminum (Al), the specific gravity is 2.6, so the solar heat absorber 112 is made of aluminum. When composed of (Al) material, it is possible to reduce the overall weight of the PVT panel 100 to achieve weight reduction and to reduce the manufacturing cost.

The PVT unit 110 may be laminated to the PV panel 111 and the solar heat absorption plate 112 insulated from each other by an insulating film. In this case, the insulating film is, for example, excellent in transparency, impact resistance, cold resistance, chemical resistance, electrical insulation, etc. polyethylene (Polyethylene), polypropylene (polypropylene), polyurethane (Polyurethane) and ethylene-vinyl acetate (Ethylene-Vinyl Acetate) ), an insulating film made of a resin selected from the group consisting of may be used.

In addition, the PVT unit 110 may be formed in a structure in which a transparent film 113a is laminated on an upper surface thereof. That is, by laminating and bonding, for example, a transparent film 113a such as vacuum glass or a special film strong against UV light as a transparent protective cover on the upper surface of the PVT lamination unit 110, the weight of the PVT panel 100 is 30% as a whole It is possible to significantly reduce the above, and it is possible to further improve the energy production efficiency by maximizing the effect of reducing the thermal resistance. Here, the material of the transparent film 113a is, for example, low iron tempered glass, polycarbonate transparent sheet, acrylic transparent sheet, PVC (Poly Vinyl Chloride) transparent sheet, ABS (Acrylonitrile-Butadiene-Styrene) transparent A sheet or the like can be used, and the specific gravity is preferably 1.2, which has a very low specific gravity, and has excellent durability and moldability so that the PVT panel 100 can exhibit high durability and insulation performance while reducing the weight of the panel itself. It is possible to use a polycarbonate transparent sheet that can maximize the

The transparent film 113a may be further provided at a location other than the top surface of the PVT unit 110 . That is, the transparent film 113a may be applied in the form of, for example, an upper transparent film 113a on an upper surface of the PVT unit 110 and a lower transparent film 113b on a lower surface of the PVT unit 110 . At this time, the upper transparent film 113a and the lower transparent film 113b are respectively formed on the outer peripheral surface of the insulating film of the PVT unit 110 , and a lower insulating film is formed between the lower transparent film 113b and the solar heat absorption plate 112 . This can be further formed.

As such, the PVT unit 110 to which the upper transparent film 113a and the lower transparent film 113b are applied has further improved insulation and heat durability, so that even when a high voltage of 3000V or more is formed in the PV panel 111, the PVT unit ( 110) has the advantage of providing a stable bonding state and insulation performance.

In the lower portion of the PVT unit 110, a heat energy transfer means 141 may be formed in the form of a liquid flow path or an air flow path on the upper surface of the insulating material, and specifically, in the form of a circular or semi-circular flow path with an open top surface, the open top surface The heat energy transfer means 141 formed in a structure in close contact with the lower portion of the solar heat absorbing plate 112 or an air pocket having an inverted trapezoidal cross-section, wherein the long side of the inverted trapezoid is in close contact with the lower portion of the solar heat absorbing plate 112 It may be formed in the form of a heat energy transfer means 141 formed in a structure.

Specifically, the heat energy transfer means 141 is installed under the solar heat absorption plate 112 so as to circulate therein a heating medium to which the heat energy of the solar heat absorption plate 112 can be transmitted. At this time, since the heating medium circulates the heat energy of the solar heat absorption plate 112 to be transferred and utilized as a living energy source, the heat energy transfer means 141 has a structure extending toward a heating facility or a hot water facility. It is preferably configured to achieve this.

In addition, the heat energy transfer means 141 may be formed as a heat energy transfer means having a complex structure in which both the circular or semi-circular flow path heat energy transfer means and the heat energy transfer means having an inverted trapezoidal air pocket shape in cross section are provided. .

In addition, the heat energy transmitting means 141 is configured to be alternately disposed with each other in a state in which circular heat energy transmitting means are embedded inside the heat insulating material between the heat energy transmitting means having an inverted trapezoidal air pocket shape in cross section, so that the PVT panel ( 100) can be formed in a structure capable of simultaneously improving the heat energy transfer efficiency and heat dissipation characteristics.

The panel case 120 may be formed in a 'C'-shaped structure in which the inner direction is opened in cross-section. The panel case 120 formed in a 'C'-shaped structure with an open inner direction in this cross-section provides a space for the thermal energy generated from the PVT unit 110 to circulate as a whole for the PVT panel 100, so that the PVT panel 100 ) to improve the heat dissipation performance and provide excellent durability to achieve stable energy production efficiency.

At least two or more of the anti-sag pins 160 may be provided between the lower end in the longitudinal direction of the PVT unit 110 and the panel case 120 . That is, the anti-sag pin 160 is manufactured by installing at least two or more between the longitudinal lower end of the PVT unit 110 and the panel case 120 in consideration of the manufacturing cost of the PVT panel 100 . While reducing costs, it is possible to manufacture the PVT panel 100 having a stable structure. At this time, if the installed number of the anti-sag pin 160 is two or more, there is no special limitation, such as an odd number or an even number, and can be installed in various numbers up to 2, 3, 4, 5, and 6 can

In addition, the anti-sag pin 160 has a case fixing part 161 having a rectangular shape with an open lower part in cross section, and a predetermined angle from one side of the case fixing part 161 in the inner direction of the panel case 120 . The PVT unit accommodating part 162 for accommodating the PVT unit 110 may be formed to be obliquely bent and extended to have a predetermined distance from the inner surface of the outer wall 121 of the panel case 120 .

As described above, the case fixing part 161 having a rectangular shape with an open lower part in cross section and the outer wall 121 of the panel case 120 and the inner surface of the outer wall 121 are formed to have a constant distance to accommodate the PVT unit 110 . The anti-sag pin 160 made of the part 162 forms, for example, a rectangular fixing groove for fixing the case fixing unit 161 in the upper portion of the cross-section of the panel case 120 to form the anti-sag pin. 160 can be conveniently and stably fixed to the panel case 120, and the PVT unit accommodating part 162 is bent obliquely at a predetermined angle in the inner direction of the panel case 120 and extended, the outer wall 121 It is formed to have a constant distance from the inner surface, so that, when installed in the panel case 120 , it is possible to secure a free space for elastic deformation of the sagging prevention pin 160 due to the weight of the PVT unit 110 , and PVT By elastically supporting the unit 110, there is an advantage that the PVT unit 110 can be supported more effectively in a stable state so that it does not sag downward.

The number of installation of the PVT unit fixing block 170 is not limited, and two or more may be provided between both ends of the PVT unit 110 in the width direction and the panel case 120 , respectively. That is, the PVT unit fixing block 170 may be installed one by one between both ends of the PVT unit 110 in the width direction and the panel case 120 in consideration of the manufacturing cost of the PVT panel 100 , In consideration of the size of the PVT panel 100 and the weight of the PVT unit 110 , preferably, two or more may be provided between both ends of the PVT unit 110 in the width direction and the panel case 120 . As such, the PVT unit fixing block 170 provided with two or more more stably fixes the PVT unit 110 to the panel case 120 so that the PVT unit 110 is in contact with or in close contact with the case cover 130 . Thermal energy is concentrated, and thermal deformation or damage to the contact or close contact area that may be caused by this can be more effectively prevented.

The PVT unit fixing block 170 is formed in a 'L' shape in cross section, and the lower part 171 may be installed in the panel case 120 in a structure that extends in the inner direction of the panel case 120 . . As described above, the PVT unit fixing block 170 having a structure in which the lower part 171 extends in the inner direction of the panel case 120 is formed in a 'L' shape in cross-section as a simple and stable structure, and the panel case 120 has a simple and stable structure. ), easy installation, excellent space utilization, and more stably maintaining the separation state between the PVT unit 110 and the case cover 130 .

In addition, the method of installing the PVT unit fixing block 170 to the panel case 120 is not particularly limited, and for example, the use of an adhesive, the use of a coupling structure such as a bolt nut, a fitting structure such as an interference fit, etc. Preferably, a fitting pin 122 is formed on the upper portion of the cross-sectional structure of the panel case 120 , and a fixing slit 172 is formed on the upper portion of the PVT unit fixing block 170 to fix the fixing. The slit 172 may be formed to be fixed to the upper portion of the cross-sectional structure of the panel case 120 .

Here, the material of the PVT unit fixing block 170 is made of elastic plastic resin or rubber, so that the spaced state between the PVT unit 110 and the case cover 130 can be maintained more stably.

As described above, in the present invention, specific matters such as specific components, etc., and limited embodiments and drawings have been described, but these are only provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , various modifications and variations are possible from these descriptions by those of ordinary skill in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims will be said to belong to the scope of the spirit of the present invention. .

100: PVT panel with anti-deformation structure
110: PVT unit
120: panel case
130: anti-sag pin
140: PVT unit fixing block

Claims (7)

a PVT unit including a PV panel for generating electric energy by receiving sunlight and a solar heat absorption plate provided under the PV panel to absorb thermal energy;
a panel case having a structure surrounding the rim of the PVT unit as a whole;
It is provided between the lower end in the longitudinal direction of the PVT unit and the panel case,
Deflection prevention pin for preventing deformation or deflection due to its own weight of the PVT unit; and between both ends of the PVT unit in the width direction and the panel case,
Includes; PVT unit fixing block for preventing contact or close contact between the PVT unit and the case cover;
The anti-sag pin is a case having a rectangular shape with an open bottom in cross-section
One side of the fixing part and the case fixing part in the inner direction of the panel case
Doedoe bent obliquely at a predetermined angle and extended, the inner surface of the outer wall of the panel case and
It is formed to have a constant interval and consists of a PVT unit accommodating part for accommodating the PVT unit,
A rectangular fixing groove for fixing the case fixing part is formed on the upper part on the cross-section of the panel case,
A PVT panel having a deformation preventing structure, characterized in that when the anti-sag pin is elastically deformed by the weight of the PVT unit, the gap with the inner surface of the outer wall is filled by the anti-sag pin.
The method of claim 1,
The panel case is a PVT panel having a deformation preventing structure formed in a 'C'-shaped structure with an open inner direction in cross-section.
The method of claim 1,
The anti-sag pin is a PVT panel having a deformation preventing structure provided at least two or more between the lower end in the longitudinal direction of the PVT unit and the panel case.
delete The method of claim 1,
The PVT unit fixing block is a PVT panel having a deformation preventing structure provided in each of two or more between the width direction both ends of the PVT unit and the panel case.
The method of claim 1,
The PVT unit fixing block is formed in a 'L' shape in cross section, the PVT panel having a deformation preventing structure that is installed in the panel case in a structure in which the lower portion extends in the inner direction of the panel case.
7. The method of claim 6,
The PVT unit fixing block is a PVT panel having a deformation-resistant structure in which a fixing slit is formed at an upper portion and fixed to the upper portion in a structure on a cross-section of the panel case by the fixing slit.

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