KR102728559B1 - Building-integrated photovoltaic module fixing device - Google Patents

Abstract

The present invention relates to a building-integrated photovoltaic module fixing device, which is configured to be fixedly installed on an outer wall (W) of a building or a roof floor or a roof sandwich panel or panel in a distance-compensable manner so that a building-integrated photovoltaic module (BIPV) can be horizontally controlled with respect to the outer wall (W) or roof floor of a building, thereby enabling simple installation of the building-integrated photovoltaic module (BIPV), and is configured to be installed horizontally without a step between the building-integrated photovoltaic modules.

Description

{Building-integrated photovoltaic module fixing device}

The present invention relates to a building-integrated photovoltaic module fixing device, and more specifically, to a building-integrated photovoltaic module fixing device that is configured to be fixedly installed on an outer wall (W) of a building or a roof floor or a roof sandwich panel or panel in a distance-compensable manner so that a building-integrated photovoltaic module (BIPV) (10) can be horizontally controlled with respect to the outer wall (W) or roof floor of a building, thereby enabling simple installation of the building-integrated photovoltaic module (BIPV), and also enabling horizontal installation without a step between the building-integrated photovoltaic modules.

Recently, the need to discover alternative energy sources has increased in response to the global rise in oil prices and depletion of fossil fuels.

In addition, following the entry into force of the climate treaty to prevent global warming, Korea is also required to prepare government-level response measures to resolve air pollution and reduce carbon dioxide gas emissions based on the post-Kyoto international agreement starting in 2013.

Solar energy is the most abundant, clean, and pollution-free energy source on Earth, with the total solar energy supplied to Earth reaching approximately 120,000 terawatts (120×1015 TW) per second.

This is equivalent to 10,000 times the total energy used by humanity on Earth, and developing technology to utilize this solar energy will be a powerful way to solve the country's current energy and environmental problems, and research and development on solar cells is currently being actively conducted.

A solar cell is a device that converts light energy into electrical energy using the photovoltaic effect. It has the advantages of being pollution-free, having unlimited resources, and having a semi-permanent lifespan, and is expected to be an energy source that can ultimately solve humanity's energy problems, aside from environmental issues.

Additionally, solar cells are classified into silicon solar cells, thin-film solar cells, dye-sensitized solar cells, and organic polymer solar cells depending on their constituent materials.

Bi-crystalline silicon solar cells account for the majority of total solar cell production worldwide, and are the most popular type of solar cell because their photoelectric conversion efficiency is higher than that of other cells and technologies that continuously reduce their manufacturing costs are being developed.

Such solar cells are generally manufactured to include a pn junction interface by forming an n-type semiconductor layer on the front side of a silicon substrate and a p-type semiconductor layer on the back side. The n-type semiconductor layer on the front side acts as an emitter, and an anti-reflection film layer is applied to minimize reflection of irradiated light, and then electrodes are wired.

These solar panels can generally be divided into fixed-position and variable-position types.

In the case of the fixed-position method, the solar panels are installed and fixed on the ground or the rooftop of a building so that they face the location where the sunlight is the most intense. In the case of the variable-position method, the solar panels are installed on the ground or the rooftop of a building just like the fixed-position method, but they move according to the direction of the sun's movement.

In both the variable-location and fixed-location methods, solar panels are installed on a certain structure and their position can be varied or fixed to the ground or a building.

However, the above method had the disadvantage of taking a considerable amount of time to assemble the solar panel because it involved attaching the structure to the solar panel frame one by one using bolts.

In addition, compared to conventional systems with complex installation structures, solar panels are relatively vulnerable to wind and other factors, and there are frequent problems with solar panels being damaged by strong winds.

In particular, in the case of general solar panel structures, the interconnection structure is complex compared to its size, but there are problems such as weak bonding and long installation times.

In addition, there was a problem that the size of the solar cell module installation was greatly restricted because it was impossible to install solar cell modules continuously due to the complex structure when installing the roof of the building.

Taking these points into consideration, a solar cell module fixing device was disclosed in patent application number 10-2012-0020355.

In view of the above, a conventional general solar cell module fixing device is a solar cell module fixing device for fixing a solar cell module installed on a roof of a building with its surface facing the sun, comprising: a fixing part including a lower part on which the solar cell module is fixed; a pair of vertical parts extending upward from an upper surface of the lower part; a support part horizontally connecting the vertical parts; and a step formed in a direction facing each other from the upper end of the vertical part so that a fastening groove is formed on the upper end of the support part; a support part that enables the solar cell module fixed to the fixing part to be fixed to the roof of the building; and a support member including a fixing bracket that is fixed on the step and pressurizes and fixes the solar cell module fixed to the lower part using a bolt; a base frame that is installed at equal intervals on the roof of the building and supports the lower surface of the support member; and a support member for fixing the support member to the base frame, wherein a bracket that supports a side surface of the solar cell module is used on the lower surface of the lower part to fix the solar cell module. It is characterized by having a further formed fastening projection with a fastening groove formed so that it can be fixed.

However, the conventional general solar cell module fixing device made in this way has the effect of allowing the solar panels to be installed on the roof of a building simply due to the above-mentioned configurations, while at the same time having a relatively strong bonding force compared to the installation structure, thereby reducing the installation cost and minimizing damage to the solar cells due to wind, etc., and freely adjusting the installation interval of the profiles, so that solar cells of various sizes can be installed continuously regardless of the size of the roof. However, if the outer wall or the surface of the roof of the building is not uniform, that is, if installed in a convexly protruding or concave part, there is a disadvantage in that the solar cells cannot help but be installed with a step relative to each other.

Patent application number 10-2012-0020355, application date; February 28, 2012

Accordingly, the present invention has been made to solve the above-described problems, and the purpose of the present invention is to provide a building-integrated photovoltaic module fixing device that enables simple installation of a building-integrated photovoltaic module (BIPV) by fixing the BIPV to the outer wall (W) or roof surface or roof sandwich panel or panel in a distance-compensable manner and configuring the BIPV to be horizontally controllable with respect to the outer wall (W) or roof surface of the building, and also enables horizontal installation without a step between the BIPV modules.

Other objects of the present invention will become clear as the technology progresses.

In order to achieve the above-described purpose, the present invention provides a building-integrated photovoltaic module fixing device that is fixedly installed on the outer wall (W) or roof surface of a building in a distance-compensable manner and has a fixed frame so that a building-integrated photovoltaic module (BIPV) (10) can be horizontally controlled with respect to the outer wall (W) or roof surface of the building, comprising: a plurality of fixing means (110) provided at a predetermined interval in a vertical or horizontal direction on the outer wall (W) or roof surface of the building by fixing one end thereof to the outer wall (W) or roof surface of the building; a plurality of distance correction means (120) each of which is fixed by welding to the other end of the fixing means (110) and the other end is provided so that the distance can be variably spaced toward the outer wall (W) or roof surface of the building; and a bar-shaped installation means provided so that the building-integrated photovoltaic module (BIPV) (10) can be fixed by fixing one end thereof to the other end of the distance correction means (120) and is installed vertically or horizontally spaced apart from the outer wall (W) or roof surface of the building and the other end is provided so as to be able to fix the building-integrated photovoltaic module (BIPV) (10). It is characterized by including a bar (130) and a plurality of support bars (150) each of which is fixedly and detachably connected at a set interval to both sides of the installation bar (130) via fixed connection members (140) so as to be capable of supporting the side surface of the installation bar (130).

Here, the distance correction means (120) is characterized by comprising a distance correction fixing member (121) formed as a hollow tube that is fixed to the other end of the fixing means (110) by welding and has a distance correction fixing screw portion (121a) formed on the inner surface thereof, and a distance correction rotating member (122) having a distance correction moving screw portion (122a) formed on the outer surface thereof so as to be screw-connected to the distance correction fixing screw portion (121a) of the distance correction fixing member (121) by passing through the installation bar (130) at one end thereof, and the other end thereof being hooked to the installation bar (130), and having a tool receiving groove formed on the upper surface thereof so as to be able to rotate using a tool.

As described above, according to the building-integrated photovoltaic module fixing device according to the present invention, the building-integrated photovoltaic module (BIPV) is configured to be horizontally controllable with respect to the building's outer wall (W) or roof bottom surface or roof sandwich panel or panel by being fixedly installed in a distance-compensable manner, so that the building-integrated photovoltaic module (BIPV) can be installed simply and horizontally without a step between the building-integrated photovoltaic modules.

FIG. 1 is a cross-sectional view showing a state in which a building-integrated solar module fixing device according to a first embodiment of the present invention is installed.
FIG. 2 is a perspective view illustrating an installation bar of a building-integrated solar module fixing device according to the first embodiment of the present invention.
FIG. 3 is a perspective view illustrating a support bar of a building-integrated solar module fixing device according to the first embodiment of the present invention.
FIG. 4 is a drawing illustrating a fixing means according to a modified example of a first embodiment of a building-integrated solar module fixing device according to the first embodiment of the present invention.
FIG. 5 is a cross-sectional view showing a state in which a building-integrated solar module fixing device according to a second embodiment of the present invention is installed.
FIG. 6 is a cross-sectional view showing a state in which a building-integrated solar module fixing device is installed according to a modified example of the second embodiment of the present invention.
FIG. 7 is a cross-sectional view illustrating a building-integrated solar module fixing device according to a third embodiment of the present invention.
FIG. 8 is a cross-sectional view illustrating a building-integrated solar module fixing device according to a fourth embodiment of the present invention.

Hereinafter, an exemplary embodiment of a building-integrated solar module fixing device according to the present invention will be described in detail.

First, it should be noted that among the drawings, identical components or parts are indicated by the same reference numerals as much as possible. In describing the present invention, specific descriptions of related known functions or configurations are omitted in order to avoid obscuring the gist of the invention.

As described above, the present invention provides a building-integrated photovoltaic module fixing device (100) that is fixedly installed on the outer wall (W) or roof of a building in a distance-compensable manner and has a fixed frame so that a building-integrated photovoltaic module (BIPV) (10) can be horizontally controlled with respect to the outer wall (W) or roof of a building, comprising: a fixing means (110) provided at a predetermined interval in a vertical or horizontal direction on the outer wall (W) or roof of a building by fixing one end thereof to the outer wall (W) or roof of a building; a plurality of distance correction means (120) each of which is fixed by welding to the other end of the fixing means (110) and the other end is provided so that the distance can be variably spaced toward the outer wall (W) or roof of a building; and a bar-shaped installation device provided so that the building-integrated photovoltaic module (BIPV) (10) can be fixed by fixing one end thereof to the other end of the distance correction means (120) and is installed vertically or horizontally spaced apart from the outer wall (W) or roof of a building and the other end is provided so that the building-integrated photovoltaic module (BIPV) (10) can be fixed. It is composed of a bar (130) and a plurality of support bars (150) each of which is fixedly and detachably connected at a set interval to both sides of the installation bar (130) via fixed connection members (140) so as to be capable of supporting the side surface of the installation bar (130).

(First embodiment)

Hereinafter, the building-integrated solar module fixing device according to the first embodiment of the present invention will be described in more detail with reference to the attached drawings.

First, the fixing means (110) of the building-integrated solar module fixing device according to the present invention described above is provided in multiple numbers at regular intervals in the vertical or horizontal direction on the exterior wall (W) or roof of the building by fixing one end to the exterior wall (W) or roof of the building.

That is, the above-described fixing means (110) is provided with a fixing member (112) comprising an anchor bolt (111) that is provided so as to be fixable to the outer wall (W) or roof surface of a building, a fixing plate (112a) that is formed in a plate shape so as to be closely fixed to the outer wall (W) or roof surface of a building by having one end fixed to the anchor bolt (111), and a fixing connection plate (112b) that is formed so as to be bent in one direction and extend from one end of the fixing plate (112a) so that one end of the distance correction means (120) can be fixedly connected by welding.

Meanwhile, the above-mentioned fixing means (110) is composed of an anchor bolt (111) that is provided so as to be fixed to the outer wall (W) or roof surface of the building as described above, and a fixing member (112) whose end is fixed to the anchor bolt (111), but is not limited thereto, and may be configured in a modified manner as illustrated in FIG. 4.

That is, in the above modified example, the fixing means (1110) may be configured such that one end is fixed by being driven into the outer wall (W) of the building or the roof floor, and the other end is formed with a pointed attachment (1111) so that one end of the distance correction means (120) can be connected in a screw manner, and a connecting screw portion (1113) is formed on the outer surface of the other end.

In addition, a plurality of detachment prevention stone pieces (113) are further formed and provided on one outer surface of the above-mentioned fixing means (1110) to prevent it from being easily detached by being driven into the outer wall (W) or roof floor of the building by an attachment (1111).

The above-mentioned distance correction means (120) is provided such that each end is fixed by welding to a fixed connection plate (112b) included in a fixed member (112) of the above-mentioned fixing means (110), and the other end is provided so as to be distance-variable toward the outer wall (W) or roof bottom surface of the building.

That is, the above-described distance correction means (120) is formed as a hollow tube that is fixed to the other end of the fixing means (110) by welding, and has a distance correction fixing screw portion (121a) formed on the inner surface thereof, and a distance correction rotating member (122) that has a distance correction moving screw portion (122a) formed on the outer surface thereof so as to be screw-connected to the distance correction fixing screw portion (121a) of the distance correction fixing member (121) by penetrating the lower surface of the installation bar (130) with a washer interposed at one end thereof, and has a tool receiving groove (not shown) formed on the upper surface thereof so as to be rotated by a tool, and is provided by screw-connecting the installation bar (130) with a washer interposed at the other end thereof. It is composed of a distance correction movement prevention (123) that is provided to pressurize and fix the lower surface of the bar (130) to prevent the distance correction rotation member (122) from moving from the installation bar (130).

The above-mentioned installation bar (130) is installed vertically or horizontally apart from the outer wall (W) or roof of a building by having one end fixed to the other end of the distance correction means (120), and the other end is provided so as to be able to fix a building-integrated photovoltaic module (BIPV).

That is, the above-described installation bar (130) is formed as a hollow rectangular cross-section so that it can be installed vertically or horizontally apart from the outer wall (W) or roof of a building by having one end fixed to the other end of the distance correction means (130), and a pair of fixing pieces (132) are formed so that a fixing frame of the building-integrated solar module (10) can be fixed by means of a plurality of fixing screws or fixing bolts by forming a cutting hole (131) cut lengthwise in the center of the upper surface, and through holes (133) are formed at regular intervals on the lower surface so that one end of the distance correction rotating member (122) of the distance correction means (120) can pass through and the other end can be caught, and both sides are provided with a slide groove (134) so that one end of the fixing connection member (140) provided to fixally connect the support bar (150) can be slidably inserted and caught.

In addition, on each bottom surface of the above-mentioned fixed member (132), a fixing force increasing member (135) is further formed and provided so that the building-integrated solar module (10) can be secured to the fixed member (132) and fixed using a plurality of fixing screws or fixing bolts by having one end extending in one direction and the other end being connected to each other, thereby increasing the fixing force.

In addition, a plurality of fixing screw holes (132a) and fixing reinforcement screw holes (135a) are formed at regular intervals on the bottom surface of the fixing member (132) and the fixing force increasing member (135) of the above-mentioned installation bar (130) so that the building-integrated solar module (10) can be fixedly connected to the fixing member (132) by means of a plurality of fixing screws or fixing bolts.

The above-mentioned support bar (150) is provided so that each end is fixedly and detachably connected at a set interval to both sides of the installation bar (130) via fixed connection members (140) so as to be able to support the side surface of the installation bar (130).

That is, the above-described support bar (150) is formed as a hollow square bar-shaped cross-section with both ends closed so that each end can be fixedly and detachably connected at a set interval to both sides of the installation bar (130) via fixed connection members (140) so as to support the side surface of the installation bar (130), and a support connection hole (151) is formed on each end surface so that one end of the fixed connection member can pass through it, and an installation cutout (152) is formed in the center of the upper surface so that the fixed connection member (140) can be fixedly installed inwardly.

Here, the above-described fixed connection member (140) is composed of a fixed connection bar (141) having a fixed connection screw portion formed on one end of an outer surface thereof so that one end passes through the support connection hole (151) of the support bar (150) and the other end is slidably inserted into the slide groove (134) of the installation bar (130) for connection, and a nut member (143) that is provided to be fixed to both sides of the support bar (150) by interposing a spring washer (142) in the fixed connection screw portion of the fixed connection bar (141) and joining it in a screw manner.

(Second implementation example)

Meanwhile, the attached drawing Fig. 5 is a building-integrated photovoltaic module fixing device (200) according to the second embodiment of the present invention that enables horizontal control of a building-integrated photovoltaic module (BIPV) (10) having a fixing frame corresponding to the cross-sectional shape of the sandwich panel (P) formed when the building-integrated photovoltaic module (10) is installed on the sandwich panel (P) forming the roof of the building, and is formed as a hollow tube that is fixed to the sandwich panel (P) by welding by including holes (drawing symbols omitted) perforated at regular intervals in the vertical and horizontal directions at one end, and has a distance-adjusting screw portion (210a) formed on the inner circumference, and a distance-correcting moving screw portion (220a) formed on the outer circumference at one end so as to be screw-connected to the distance-adjusting screw portion (210a) of the distance-adjusting fixing member (210) in a screw manner, and a tool is formed on the upper surface of the other end. The present invention comprises a distance correction rotating member (220) provided with a tool receiving groove (not shown) formed therein so as to be rotatable therethrough, an installation bar (230) having a shape of a bar, one end of which is fixed to the other end of the distance correction rotating member (220) so as to be installed vertically or horizontally spaced apart from the surface of a sandwich panel (P) and the other end is provided so as to be able to fix a building-integrated photovoltaic module (BIPV) (10), and a plurality of support bars (250) provided so as to be able to support and connect one side and the other side of the installation fixing bar (230) by fixing and connecting members (240) at regular intervals on both sides of the installation bar (230), respectively.

Here, the above-mentioned installation bar (230), support bar (250), and fixed connection member (240) are configured in the same manner as the installation bar (130), support bar (150), and fixed connection member (140) of the first embodiment, and a detailed description thereof will be omitted below.

And, the attached drawing Figure 6 is a building-integrated solar module fixing device (300) according to a modified example of the second embodiment of the present invention that enables horizontal control of a building-integrated solar module (10) having a fixing frame corresponding to the cross-sectional shape of the panel (N) when the building-integrated solar module (10) is installed on the panel (N) forming the roof of the building, and is formed as a hollow tube having a polygonal cross-section corresponding to the fixing hole (drawing symbol omitted) perforated at a certain interval in the vertical and horizontal directions in the panel (N) so that one end is inserted, and a distance-variable fixing member (310) formed with a distance-variable screw portion (310a) on the inner circumference and a hooking piece (311) formed on the outer circumference so as to be hooked to the front surface of the panel (N), and a distance-variable fixing member (310) having a distance-variable screw portion (310a) of the distance-variable fixing member (310) formed on one end of the outer circumference so as to be screw-coupled to the distance-variable screw portion (310a) of the distance-variable fixing member (310) in a screw manner. A variable distance rotating member (320) formed with a moving screw portion (320a) and a tool receiving groove (not shown) formed on the upper surface of the other end so that it can be rotated using a tool, and a fixed screw portion (drawing symbol omitted) formed on the outer surface so that one end is screw-coupled to the inside of the variable distance fixed member (310) inserted into the fixing hole from the rear of the panel (N) and the other end is formed with a head portion (330a) so that it can be rotated using a tool, and a pressure fixing member (330) formed between the head portion (330a) and the fixed screw portion so that the rear of the panel (N) can be pressurized, and a pressure fixing member (331) formed so that the rear of the panel (N) can be pressurized, and a pressure fixing member (330) provided with one end fixed to the other end of the variable distance rotating member (320) so that it is installed vertically or horizontally spaced apart from the front of the panel (N) and the other end is provided so that a building-integrated solar module (10) can be fixed. It is composed of a bar-shaped installation bar (340) and a plurality of support bars (360) each of which is fixed and detachably connected at a set interval to both sides of the installation bar (340) via fixed connection members (350) so that one side and the other side of the installation fixing bar (340) can be supported and connected, respectively.

Here, the above-mentioned installation bar (340), support bar (360), and fixed connection member (360) are configured in the same manner as the installation bar (130), support bar (150), and fixed connection member (140) of the first embodiment, and a detailed description thereof will be omitted below.

(Example 3)

According to the third embodiment of the present invention, the building-integrated solar module fixing device can be configured to protect the building-integrated solar module by enabling the installation bar (130) to roll in response to vibration or strong wind of the building, as illustrated in FIG. 7.

That is, a building-integrated photovoltaic module fixing device (100) that is fixedly installed on the outer wall (W) or roof surface of a building so as to be distance-compensable and horizontally controllable with respect to the outer wall (W) or roof surface of a building, comprises: a plurality of fixing means (110) provided at regular intervals vertically or horizontally on the outer wall (W) or roof surface of a building by fixing one end thereof to the outer wall (W) or roof surface of a building; a plurality of distance correction means (120) each of which is fixed by welding to the other end of the fixing means (110) and the other end is provided so as to be distance-variable toward the outer wall (W) or roof surface of the building; and a bar-shaped installation device that is provided so as to be able to fix the building-integrated photovoltaic module (BIPV) (10) by fixing one end thereof to the other end of the distance correction means (120) and is installed vertically or horizontally spaced apart from the outer wall (W) or roof surface of a building; A bar (130') and a plurality of support bars (150) each of which is fixedly and detachably connected at a set interval to both sides of the installation bar (130') via fixed connection members (140) so as to be capable of supporting the side surface of the installation bar (130'), wherein the lower surface (130a) of the installation bar (130') is formed as a curved surface so as to protect the building-integrated solar module (10) by rolling the installation bar (130') in response to the vibration of the building or strong wind.

(Example 4)

The building-integrated solar module fixing device according to the fourth embodiment of the present invention can be configured to quickly dissipate heat generated from the building-integrated solar module, as illustrated in FIG. 8.

That is, a building-integrated photovoltaic module fixing device (100) that is fixedly installed on the outer wall (W) or roof surface of a building so as to be distance-compensable and horizontally controllable with respect to the outer wall (W) or roof surface of a building, comprises: a plurality of fixing means (110) provided at regular intervals vertically or horizontally on the outer wall (W) or roof surface of a building by fixing one end thereof to the outer wall (W) or roof surface of a building; a plurality of distance correction means (120) each of which is fixed by welding to the other end of the fixing means (110) and the other end is provided so as to be distance-variable toward the outer wall (W) or roof surface of the building; and a bar-shaped installation device that is provided so as to be able to fix the building-integrated photovoltaic module (BIPV) (10) by fixing one end thereof to the other end of the distance correction means (120) and is installed vertically or horizontally spaced apart from the outer wall (W) or roof surface of a building; A bar (130) and a plurality of support bars (150) each of which is fixedly and detachably connected at a set interval to both sides of the installation bar (130) via fixed connection members (140) so as to be capable of supporting the side surface of the installation bar (130), wherein a heat dissipation member (160) is further provided so as to be located between the installation bars (130) and the installation bars (130) so as to have one end fixed to the back surface of the building-integrated solar module (10) and the other end supported by the support bars so as to be capable of rapidly dissipating heat generated from the building-integrated solar module (10).

In the case where a building-integrated solar module is fixedly installed on the outer wall surface of a building through a building-integrated solar module fixing device according to the present invention, as illustrated in the attached drawings 1 to 3, the distance correction fixing member (121) of the distance correction means (120) is fixedly installed longitudinally at a predetermined interval on the outer wall surface by means of an anchor bolt (111) to the fixing member (112) of the fixing means (110) to which the distance correction means (120) is welded.

As described above, when the distance correction fixing member (121) of the distance correction means (120) is fixedly installed at a predetermined interval in the longitudinal direction on the outer wall surface by welding the fixing member (110), the distance correction rotating member (122) of the distance correction means (120) is passed through the through hole (133) of the installation bar (130) and then connected to the distance correction fixing member (121) in a screw manner.

Due to this, the above installation bars (130) are fixedly installed on the outer wall so as to be spaced apart from each other in the longitudinal direction.

As described above, when the installation bars (130) are each fixedly installed, the support bars (150) with fixed connection members (140) fixedly installed at both ends are slidably connected to both sides of the installation bars (130) to support the installation bars (130).

That is, when the above-mentioned installation bars (130) are fixedly installed on the outer wall with a longitudinal distance from each other by the distance correction means (120), the other end of the fixed connection bar (141) of the fixed connection member (140) fixed to each side of the support bar (150) is slid and inserted into the slide groove (134) of the above-mentioned installation bar (130).

Due to this, both sides of the installation bar (130) are each supported by the support bar (150).

As described above, the installation bar (130) is supported on both sides by the support bar (150), and the fixing frame of the building-integrated solar module (10) is secured to the fixing piece (132) of the installation bar (130) and fixed with a fixing bolt, thereby completing the installation of the building-integrated solar module (10).

Meanwhile, when the fixed frame of the above-mentioned building-integrated solar module (10) is fixed to the fixed piece (132) of the installation bar (130), if one side protrudes more than the other side, or if it goes in more and is inclined, the distance correction rotating member (122) of the distance correction means (120) is rotated clockwise or counterclockwise using a tool.

Due to this, the building-integrated solar modules (10) can be fixed horizontally to each other without a protruding portion by moving the installation bar (130) toward the outer wall or to the opposite side of the outer wall.

As described above, the present invention can easily and quickly align and fix a building-integrated solar module (10) horizontally using a building-integrated solar module fixing device.

The above description is merely an illustrative description of the technical idea of the present invention, and those skilled in the art will appreciate that various modifications and variations may be made without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to explain it, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within a scope equivalent thereto should be interpreted as being included in the scope of the rights of the present invention.

100; Building-integrated solar module fixing device 110; Fixing means
120; Distance correction means 130; Installation bar
140 ; Fixed connecting member 150 ; Supporting bar
160 ; Heat dissipation member

Claims (10)

A building-integrated photovoltaic module fixing device that enables horizontal control of a building-integrated photovoltaic module (BIPV) (10) having a fixed frame and fixedly installed on the exterior wall (W) or roof surface of a building so that the module can be horizontally controlled relative to the exterior wall (W) or roof surface of a building.
A plurality of fixing means (110) provided at regular intervals in a vertical or horizontal direction on the exterior wall (W) or roof surface of the building by fixing one end to the exterior wall (W) or roof surface of the building;
A plurality of distance correction means (120) each having one end fixed by welding to the other end of the above fixing means (110) and the other end provided with a variable distance toward the outer wall (W) or roof bottom surface of the building;
An installation bar (130) having a shape of a bar, which is installed vertically or horizontally apart from the outer wall (W) or roof surface of a building by having one end fixed to the other end of the above distance correction means (120), and the other end is provided so as to be able to fix a building-integrated photovoltaic module (BIPV) (10);
A plurality of support bars (150) are provided so that each end is fixedly and detachably connected at a certain interval to both sides of the installation bar (130) via fixed connection members (140) so as to be able to support the side surface of the installation bar (130).
The above distance correction means (120) is formed as a hollow tube that is fixed to the other end of the fixing means (110) by welding, and has a distance correction fixing screw portion (121a) formed on the inner surface thereof, and a distance correction fixing member (121) that has a distance correction moving screw portion (122a) formed on the outer surface thereof so as to be screw-connected to the distance correction fixing screw portion (121a) of the distance correction fixing member (121) by penetrating the lower surface of the installation bar (130) with a washer interposed at one end thereof, and a distance correction rotating member (122) that has a tool receiving groove formed on the upper surface thereof so as to be able to rotate by means of a tool, and is screw-connected to the lower surface of the installation bar (130) with a washer interposed therebetween. A building-integrated solar module fixing device characterized by comprising a distance correction movement prevention (123) provided to prevent the distance correction rotation member (122) from moving from the installation bar (130) by pressurizing and fixing the bottom surface.
delete delete delete In the first paragraph,
The above-mentioned installation bar is formed as a bar having a hollow rectangular cross-section, and a pair of fixing pieces are formed so that a fixing frame of the building-integrated solar module can be fixed by means of a plurality of fixing screws or fixing bolts by forming a longitudinally cut hole in the center of the upper surface thereof, through holes are formed at regular intervals on the lower surface, and a sliding groove is formed on both sides so that one end of the fixing connection member provided to fixally connect the support bar can be slidably inserted and caught. A building-integrated solar module fixing device characterized in that it is provided. In the first paragraph,
The above-mentioned support bar is formed as a hollow square bar-shaped cross-section with both ends blocked so that each end can support the side surface of the above-mentioned installation bar by being fixedly and detachably connected at a set interval via fixed connection members on both sides of the above-mentioned installation bar, and a support connection hole is formed on each of the two end surfaces so that one end of the above-mentioned fixed connection member can pass through it, and an installation cut-out portion cut lengthwise so that the above-mentioned fixed connection member can be fixedly installed inward is formed and provided at the center of the upper surface. A building-integrated solar module fixing device characterized in that it is provided.
In the first paragraph,
A building-integrated solar module fixing device characterized in that the lower surface of the above-mentioned installation bar is formed into a curved surface so as to protect the building-integrated solar module by rolling the installation bar in response to the shaking of the building-integrated solar module in response to vibration of the building or strong wind.
In the first paragraph,
A building-integrated solar module fixing device characterized in that it further comprises a heat dissipation member positioned between the installation bar and the installation bar, one end of which is fixed to the back surface of the building-integrated solar module, and the other end of which is supported by the support bar so as to quickly dissipate heat generated from the building-integrated solar module.
In paragraph 5,
A building-integrated solar module fixing device characterized in that a fixing force increasing member is further formed on each bottom surface of the fixing member so that the building-integrated solar module can be fixed by fixing it to the fixing member by a plurality of fixing screws or fixing bolts by having each end extending in one direction and each end connected to each other, and a plurality of fixing screw holes and fixing increase screw holes are further formed at regular intervals on the bottom surfaces of the fixing member and the fixing force increasing member of the installation bar so that the building-integrated solar module can be fixedly connected by a plurality of fixing screws or fixing bolts by being fixedly installed to the fixing member.
In Article 6,
The above-mentioned fixed connection member is characterized by comprising a fixed connection bar having a fixed connection screw portion formed on one end of an outer surface so that one end passes through the support connection hole of the above-mentioned support bar and the other end can be connected by sliding into a slide groove of the installation bar, and a nut member provided so as to be fixed to both sides of the above-mentioned support bar by screwing together a spring washer by interposing the fixed connection screw portion of the above-mentioned fixed connection bar. The above-mentioned building-integrated solar module fixing device is characterized by comprising:

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