KR20140130278A - Building Integrated Photovoltaic Module and Curtain-wall having the Same - Google Patents

Abstract

The present invention relates to a technology for a building integrated photovoltaic module applied to an outer wall panel of a building and a curtain wall including the same and, more specifically, to a building integrated photovoltaic module which has a ventilation and insulation structure for the inner temperature of the building not to increase by heat collection of the photovoltaic module and to a curtain wall including the same.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a building integrated photovoltaic module and a curtain wall including the same,

The present invention relates to a building integrated solar power generation module applied to an outer wall panel of a building and a curtain wall including the same, and more particularly, to a ventilation and insulation structure And a curtain wall including the same.

The curtain wall technique is to prevent the outside of the structure made up of pillars, beams and decks in the vertical structure of the space with metal or inorganic material from the structure to the non-proof outer circumferential wall, the reinforced concrete structure, the steel structure, and the steel reinforced concrete structure. Stand is a non-bearing wall. In recent years, curtain wall, which is a lightweight outer wall body, has been applied in place of the existing masonry and reinforced concrete structure weight wall in many buildings. In addition, with the development of architectural technology, building integrated photovoltaic module (PV module), which replaces photovoltaic module (PV module) with exterior material of building, Hereinafter, the BIPV module) is getting more attention. The BIPV module is generally applied to the G-to-G type BIPV module that uses a glazing type glass method and an anchor system together with a curtain wall stick method. On the other hand, the curtain wall made of glass on the front caused an increase in the heating and cooling load of the building, and it affected the comfort of the occupant. Especially, in the case of curtain wall, securing the insulation performance of the span part is very important in terms of energy saving in accordance with the structural characteristics of connecting the outer wall body and the indoor side slab. However, the application of BIPV module by the existing curtain wall type glass technique does not solve this problem.

In the curtain wall unit system, since the spindle portion of the vision portion and the spindle portion of the vision portion are manufactured as a single unit, they are manufactured in a factory. Therefore, the above-described thermal insulation problem can be solved through the thermal insulation design of the span portion.

However, strengthening the insulation performance of the curtain wall span part causes a rise in the temperature of the rear surface of the PV module, thereby reducing efficiency. In addition, if overheating is not considered due to the back insulation, thermal deformation of the building envelope itself may occur, and the life of the PV module itself may be degraded. Therefore, consideration should be given to the rear ventilation to prevent overheating and to minimize the efficiency reduction. In order to commercialize the curtain wall including the BIPV module, the PV module should be easily detached and attached to the curtain wall frame for easy maintenance. Be able to.

Korean Patent Publication No. 2012-0031778

SUMMARY OF THE INVENTION It is an object of the present invention to provide a PV module having a ventilation structure for protecting a PV module from being heated due to heat collection of the PV module, And a ventilation space formed between the heat insulating materials, and a curtain wall including the same.

In addition, a PV module and a frame are coupled to each other through a hook type coupling member so as to facilitate the maintenance of the PV module, and a curtain wall including the same.

A building integrated photovoltaic power generation module of the present invention is a building integrated photovoltaic power generation module comprising a solar cell module for forming an outer wall of a building and converting solar energy into electric energy and a solar cell module comprising a solar cell module upper and lower battery brackets ; A first module bracket on the lower side of which the upper side of the solar cell module is fitted; And a second module bracket on the upper side of which the lower side of the solar cell module is fitted; And a plurality of ventilation portions penetrating the battery bracket from the outside to the inside of the building are formed.

At this time, the battery bracket includes an outer plate formed in an outer direction of the building so that a first ventilation space is formed therein, and an inner plate hysteresis formed in the inner direction of the building in the outer plate, And the first ventilation part formed on the outside sheathing is formed at a lower position than the second ventilation part formed on the inside plate.

The solar power generation module may include a thermal insulation member disposed inside the building of the solar power generation module and having an upper side coupled to the first module bracket and a lower side coupled to the second module bracket; .

The heat insulating member is spaced apart from the solar cell module in an inward direction of the building so that a second ventilation space is formed in an inner side of the building of the solar cell module.

In addition, on the second module bracket, a coupling member may be provided to facilitate lower coupling of the solar cell module. Wherein the coupling member comprises: an engaging body having a hollow portion formed therein; A hook formed at an outer end of the building body of the coupling body so as to be coupled with a lower side of the solar power generation module, And a fixing member that is fitted in the hollow outside of the building of the coupling body so as to firmly engage the hook portion and the solar power generation module; .

In addition, the solar cell module is a thin film solar cell (Copper Indium Gallium Selenide, CIGS).

The curtain wall including the building integrated photovoltaic module of the present invention comprises a transparent member; And

A pair of solar modules; The upper side of the transparent member is coupled to a lower side of the first solar power generation module disposed on the upper side of the solar power generation module, and the lower side of the transparent member is connected to the lower side of the first solar power generation module, And is coupled to the upper side of the second solar photovoltaic module disposed below the solar photovoltaic module.

Since the heat of the PV module is not transmitted to the inside of the building, the heating and cooling load of the building is reduced and the energy efficiency of the building is increased . In addition, there is an effect of preventing performance degradation due to overheating of the PV module.

In addition, it is easy to install and detach the PV module, which saves time and cost for maintenance of the PV module.

1 is a sectional view of a BIPV module according to a first embodiment of the present invention;
2 is a sectional view of a solar cell module according to the first and second embodiments of the present invention;
3 is a sectional view of the curtain wall according to the first embodiment of the present invention
4 is a cross-sectional view of a BIPV module according to a second embodiment of the present invention
5 is a cross-sectional view of a coupling member according to a second embodiment of the present invention
6 is a sectional view of a curtain wall according to a second embodiment of the present invention

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

- BIPV Module Example 1 (Fixed Type)

1 is a cross-sectional view of a building-integrated photovoltaic module 100 (hereinafter referred to as a BIPV module) according to a first embodiment of the present invention. The BIPV module 100 includes a first module bracket 110, a second module bracket 120, a heat insulating member 150, and a solar module 500.

The first module bracket 110 of the BIPV module disposed on the lower side of the curtain wall is disposed on the upper side of the BIPV module 100 and the first module bracket 110 of the BIPV module disposed on the upper side of the curtain wall is disposed on the BIPV module 100 100, respectively. FIG. 1 shows a configuration of a BIPV module 100 disposed on a lower side of a curtain wall. Hereinafter, a first module bracket 110 is disposed on the upper side of the BIPV module 100. FIG.

The first module bracket 110 is disposed on the upper side of the BIPV module 100. A first member 111 is formed on the upper side of the outer end of the first module bracket 110 and a lower side of the first module bracket 110 is coupled with the upper side of the solar power module 500. A second engaging portion 112 for engaging the upper side of the heat insulating member 150 is formed on the lower side of the inside end of the first module bracket 110.

The second module bracket 120 is disposed below the BIPV module 100. A third coupling part 121 is formed on the upper side of the outside of the building of the second module bracket 120 so that the lower side of the solar power generation module 500 is fitted. A fourth engaging portion 122 for engaging the lower side of the heat insulating member 150 is formed on the upper side of the inside end of the building of the second module bracket 120.

The upper side of the solar power generation module 500 is fitted and fixed to the first coupling part 111 of the first module bracket 110 and the lower side is fitted and fixed to the third coupling part 121 of the second module bracket 120 do. The detailed structure of the solar cell module 500 will be described later with reference to FIG.

The heat insulating member 150 may be formed of a conventional heat insulating material to prevent the heat generated from the solar power generating module 500 from being transmitted to the inside of the building. The heat insulating member 150 may be spaced apart from the solar power generating module 500 to the inside of the building so that the second ventilation space 130 is formed inside the building of the solar power generating module 500. The upper side of the heat insulating member 150 is fixed to the second engaging portion 112 of the first module bracket 110 and the lower side thereof is fixedly engaged with the fourth engaging portion 122 of the second module bracket 120.

Hereinafter, the detailed structure of the solar cell module 500, which is a core structure of the present invention for efficiently discharging the heat of the solar cell module 500 to the outside of the building, will be described in detail with reference to the drawings.

2 is a cross-sectional view of a solar cell module 500 according to a first embodiment of the present invention. As shown in the figure, the photovoltaic power generation module 500 includes a solar cell module 510 and battery brackets 520 and 530. The solar cell module 510 may be a thin film solar cell (CIGS) module that converts solar energy into electrical energy and is applicable to an outer wall of a building. The battery brackets 520 and 530 include a first battery bracket 520 on which the upper side of the solar cell module 510 is fixed and a second battery bracket 520 on which the lower side is fixed.

The first battery bracket 520 has a first fitting groove 521 formed at a lower end thereof so that the upper side of the solar cell module 510 is fitted therebetween. The first battery bracket 520 includes a first outside sheath formed on the outside of the building, And a first inner plate spaced apart from the first outer sheath so as to form a ventilation space (52). The first outside plate is formed with a 1-1 vent portion 523 passing through the first outside plate, and the first inside plate is formed with a 1-2 vent portion 524 passing through the first inside plate. Accordingly, the first 1-1 ventilation space 522 is configured to communicate with the outside of the building and the second ventilation space 130 (see FIG. 1) to cool the solar cell module 510 by the flow of air.

In order to prevent rainwater, washing water, and the like from being introduced into the inside of the building through the 1-1 vent portion 523 and the 1-2 vent portion 524, 1-2 vent portion 524 of the first embodiment.

The second battery bracket 530 has a second fitting groove 531 formed at an upper end thereof so that the lower side of the solar cell module 510 is fitted thereinto. The second battery bracket 530 includes a second outside plate formed on the outside of the building, And a second inner plate spaced inward from the second outside sheathing so as to form the first and second ventilation spaces 532. The second outer plate is provided with a second-1 vent portion 533 passing through the second outer plate, and the second inner plate is provided with a second-second vent portion 534 penetrating the second inner plate. Accordingly, the first-second ventilation space 532 is configured to communicate with the outside of the building and the second ventilation space 130 to cool the solar cell module 510 by the flow of air.

At this time, in order to prevent rainwater, washing water, and the like from being introduced into the building through the second-1 vent 533 and the second -2 vent 534, the second- 2-2 may be formed at a lower position than the vent portion 534.

- Curtain wall Example 1 (Fixed type)

3 is a cross-sectional view of a curtain wall 1000 including a BIPV module 100 according to the first embodiment described above. As shown in the figure, the curtain wall 1000 includes a transparent member G disposed at the center in the vertical direction and a 1-1 BIPV module 100 disposed at the lower side of the transparent member G, And a first 1-2 BIPV module 100 'disposed on the upper side. The transparent member G may be generally made of glass, and any material that transmits light and has rigidity may be used. The lower side of the transparent member G is fixedly coupled to the first module bracket of the 1-1 BIPV module 100 and the upper side of the transparent member G is fixed to the first module bracket 100 ' Respectively.

Example 2 (Detachable)

4 is a cross-sectional view of a building integrated photovoltaic module 200 (hereinafter referred to as a BIPV module) according to a second embodiment of the present invention. The BIPV module 200 includes a first module bracket 210, a second module bracket 220, a heat insulating member 250, a solar module 500, and a coupling member 600, do.

The first module bracket 210 of the BIPV module disposed on the lower side of the curtain wall is disposed on the upper side of the BIPV module 200 and the first module bracket 210 of the BIPV module disposed on the upper side of the curtain wall is disposed on the BIPV module 200 200, respectively. 4 shows a configuration of the BIPV module 200 disposed on the lower side of the curtain wall. Hereinafter, the first module bracket 210 is disposed on the upper side of the BIPV module 200. FIG.

The first module bracket 210 is disposed on the upper side of the BIPV module 200. At the outer end of the building of the first module bracket 210, a coupling frame 211 for coupling the transparent member of the curtain wall and the solar module 500 is formed. That is, the transparent member is coupled to the upper side of the first coupling frame 211, and the solar battery module 500 is coupled to the lower side of the first coupling frame 211. A first engaging portion 212 for engaging the heat insulating member 250 is formed on the lower side of the inside end of the first module bracket 210.

The second module bracket 220 is disposed on the lower side of the BIPV module 200. A second engaging portion 222 for engaging the heat insulating member 250 is formed on the upper side of the inside end of the building of the second module bracket 220. The second module bracket 220 is provided with a coupling member 600 for fixing the solar cell module 500 to the lower side. The coupling member 600 is installed and fixed to the second module bracket 220 such that the outer end of the building protrudes outward from the outer end of the building of the second module bracket 220. The coupling member 600 is configured to facilitate detachment of the solar cell module 500, and the detailed configuration thereof will be described later with reference to FIG.

The PV module 500 is fixed to the coupling frame 211 of the first module bracket 210 and the lower side of the PV module 500 is detached and attached to the outer end of the coupling member 600 installed on the second module bracket 220 As shown in FIG. Hereinafter, the detailed configuration of the solar cell module 500 is the same as that of the solar cell module 500 according to the first embodiment described above, and thus a duplicate description thereof will be omitted.

The heat insulating member 250 may be formed of a conventional heat insulating material to prevent the heat generated from the solar cell module 500 from being transmitted to the inside of the building. The heat insulating member 250 may be spaced apart from the solar power generating module 500 to the inside of the building so that the second ventilation space 230 is formed inside the solar power generating module 500. The upper side of the heat insulating member 250 is fitted into the first engaging portion 212 of the first module bracket 210 and the lower side of the heat insulating member 250 is fitted into the second engaging portion 222 of the second module bracket 220.

Hereinafter, the detailed configuration of the coupling member 600, which is a core configuration of the second embodiment of the present invention for facilitating the attachment / detachment of the solar cell module 500, will be described in detail with reference to the drawings.

5 is a cross-sectional view of a coupling member 600 according to a second embodiment of the present invention. The coupling member 600 includes a hollow coupling body 610 having a hollow interior, a hook 611 formed at an outer end of the coupling body 610, a first fixing protrusion 610 protruding upward and downward from the center of the coupling body 610, A second fixing protrusion 613 protruding upward and downward from a building inner side end of the coupling body 610 and a fixing member 650 fitted to the outer end end hollow portion of the coupling body 610 . The hook 611 protrudes outside the building of the second module bracket 220 when the coupling member 600 is fitted to the second module bracket 220 It is flexible. Therefore, when the lower end of the solar cell module 500 (see FIG. 4) is fitted into the hook 611, the lower end thereof is easily attached and detached. After the lower end of the photovoltaic power generation module 500 is fitted to the hook 611 in order to firmly couple the photovoltaic power generation module 500 through the hook 611, the fixing member 650 is fixed to the coupling body 610, So that the rotation of the hook 611 is restricted. The first fixing protrusion 612 and the second fixing protrusion 613 prevent the coupling body 610 from being detached from the second module bracket 220 in the outer direction of the building, (220).

- Curtain wall Embodiment 2 (detachable type)

6 is a cross-sectional view of a curtain wall 2000 including a BIPV module 200 according to the second embodiment described above. As shown in the figure, the curtain wall 2000 includes a transparent member G disposed at the center in the vertical direction and a 2-1 BIPV module 200 disposed at the lower side of the transparent member G, And a 2-2 BIPV module 200 'disposed on the upper side. The transparent member G may be generally made of glass, and any material that transmits light and has rigidity may be used. The lower side of the transparent member G is fixedly coupled to the first module bracket of the 2-1 BIPV module 100 and the upper side of the transparent member G is fixed to the first module bracket 100 ' Respectively.

The technical idea should not be construed as being limited to the above-described embodiment of the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, such modifications and changes are within the scope of protection of the present invention as long as it is obvious to those skilled in the art.

1000, 2000: Curtain wall
100, 200: BIPV module
110, 210: a first module bracket
120, 220: second module bracket
130, 230: second ventilation space
150, 250:
500: solar cell module 510: solar cell module
520: first battery bracket 523: first-
524: first-second vent portion 530: second battery bracket
533: the 2-1 vent section 534: the 2-2 vent section
600: coupling member 610: coupling body
611: Hook 650: Fixing member

Claims (7)

A photovoltaic module including a solar cell module for forming an outer wall of a building and converting solar energy into electric energy, and a battery bracket having an upper side and a lower side of the solar cell module interposed therebetween;
A first module bracket on the lower side of which the upper side of the solar cell module is fitted; And
A second module bracket on the upper side of which the lower side of the solar cell module is fitted; / RTI >
Wherein a plurality or a plurality of ventilation portions penetrating the battery bracket from the outside to the inside of the building is formed.
The method according to claim 1,
The battery bracket includes:
An outer plate formed in an outer direction of the building so that a first ventilation space is formed inside the inner plate and an inner plate hysteresis formed in the inner direction of the building in the outer plate;
Wherein the ventilation part is formed on each of the outer and inner plates, and the first ventilation part formed on the outer plate is formed at a lower position than the second ventilation part formed on the inner plate.
3. The method according to claim 1 or 2,
In the solar power generation module,
A heat insulating member disposed inside the building of the photovoltaic power generation module and having an upper side coupled to the first module bracket and a lower side coupled to the second module bracket; And a solar cell module.
The method of claim 3,
Wherein the heat insulating member is spaced apart from the solar power generating module in an inward direction of the building so that a second ventilation space is formed in an inner side of the building of the solar power generating module.
The method according to claim 1,
On the second module bracket,
A coupling member to facilitate lower coupling of the solar cell module; Further,
The coupling member
A coupling body having a hollow portion formed therein;
A hook formed at an outer end of the building body of the coupling body so as to be coupled with a lower side of the solar power generation module, And
A fixing member that is fitted in the hollow outside of the building body of the coupling body so as to firmly couple the hook portion and the solar power generation module;
And a plurality of photovoltaic modules.
The method according to claim 1,
In the solar cell module,
Integrated photovoltaic power generation module that is made of thin film solar cell (Copper Indium Gallium Selenide, CIGS).
7. A curtain wall comprising a building-integrated photovoltaic module according to any one of claims 1 to 6,
The curtain wall,
A transparent member; And
A pair of solar modules; / RTI >
Wherein the solar cell module is vertically disposed and the upper side of the transparent member is coupled to a lower side of the first solar cell module disposed on the upper side of the solar cell module, And a solar cell module connected to an upper portion of the second solar cell module disposed below the first solar cell module.

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