KR102438188B1 - Building integrated photo voltaic roof system without bolts - Google Patents

Abstract

The present invention relates to a roof-integrated solar photovoltaic power generation system installed on a roof support structure to form a roof of a building structure. The roof-integrated solar photovoltaic power generation system has an elastic combination frame deformed by one end of a solar panel while the one end rotates around the other end to move after the other end of each solar panel is mounted on an inclined panel supporting part of a fixing supporting member. If the one end of the solar panel is mounted on a horizontal panel supporting part after the completion of the rotating movement of the solar panel, the elastic combination frame is restored and is arranged on the upper surface of the one end of the solar panel to fix the one end of the solar panel to the horizontal panel supporting part, thereby dispensing with screw coupling in the assembly of a solar panel to facilitate installation, maintenance and repairs thereof.

Description

TECHNICAL FIELD [0002] Building integrated photo voltaic roof system without bolts}

The present invention relates to a roof-integrated photovoltaic system installed on a roof support structure to form a roof of a building structure.

Recently, interest in solar power generation as an alternative energy source according to the depletion of resources is increasing. Solar power generation is an integrated technology that converts sunlight incident on the earth into electrical energy. Not only is it eco-friendly, but once the device is installed and operated, even if there is no separate energy input, it can produce electricity if only sunlight exists. There is a trend that the scope of its application is gradually expanding.

In general, photovoltaic power generation is a unit photovoltaic module (photovoltanic module) consisting of a plurality of solar cells, a wire electrically connecting the solar cells, and a film or protective glass that protects the solar cells from the external environment in series. Alternatively, it is operated using a solar panel configured by connecting in parallel. In order to apply such a solar panel to a building, the most commonly used method from the past to the present is a method of mounting a solar panel on the roof of an existing building.

This method has the advantage that there is no need to dismantle an existing building or construct a new structure for the installation of a solar panel in that it can be implemented by simply fixing the solar panel to the roof. However, this method has a disadvantage in that the appearance of the building deteriorates in that the solar panel is installed on the roof of the existing building.

In order to solve the problem of the method of installing solar panels using the finishing frame as described above, a method that is currently being widely studied is Building Integrated Photovoltaic (BIPV), which consists of the solar panel itself as the roof of the building. is the system As an example of such a building-integrated photovoltaic system, there is Republic of Korea Patent Registration No. 10-1959075 “Building-integrated photovoltaic roof system and construction method thereof”. According to Patent Registration No. 10-1959075, when two or more gutter panels are installed to correspond to the width of the solar panel between the support members installed on the upper part of the roof support structure, the width of the supplied solar panel is changed or When the width of the gutter panel is changed and a gap occurs between the facing gutter panels located between the supporting members, the auxiliary gutter panel is installed to cross the gap between the facing gutter panels along the longitudinal direction of the gutter panel. A building-integrated photovoltaic power generation roof system, which allows rainwater flowing through the gap between the photovoltaic panels to not flow into the interior, but to be effectively drained to the outside through the auxiliary gutter panel and the gutter panel to enhance the construction perfection of the building-integrated photovoltaic roof system. start

However, according to Patent Registration No. 10-1959075, as the auxiliary gutter panel is used, the drainage property is improved and the construction completeness is increased. When installing and maintaining a solar panel, it takes a long time to install and maintain the solar panel, which reduces the working efficiency. As it is exposed to the outside, there is a problem that harms the aesthetics. In addition, in fixing the solar panel using bolts, the bolt for fixing the solar panel may be loosened by a continuous external force caused by wind, etc., and there is a risk of a safety accident.

An object of the present invention is to provide a roof-integrated photovoltaic power generation system that is efficient in operation by reducing work time during installation and maintenance by using a boltless assembly method in fixing the photovoltaic panel on the roof support structure. In addition, to provide a roof-integrated photovoltaic system that can be stably fixed so that the photovoltaic panel does not deviate from the roof support structure while fixing the photovoltaic panel on the roof support structure using a boltless assembly method have. It is not limited to the technical problems as described above, and another technical problem may be derived from the following description.

A photovoltaic power generation system according to an aspect of the present invention is a roof-integrated photovoltaic power generation system installed on a roof support structure to form a roof of a building structure, and includes an inclined panel support unit corresponding to a plane parallel to the roof support structure. and a plurality of fixed support members installed at predetermined intervals on the roof support structure; a plurality of elastic support members including a horizontal panel support part corresponding to a plane parallel to the roof support structure and installed in parallel between the plurality of fixed support members; The horizontal panel of the elastic support member is formed in the shape of a square plate, each end is mounted on the inclined panel support of the fixed support member, and then the other end is rotated from the upper side to the lower side of the elastic support member around the one end. Consists of a plurality of photovoltaic panels mounted on a support, wherein each elastic support member is deformed by the other end of each photovoltaic panel while the respective photovoltaic panels are rotated and moved, and the other end after completion of the rotational movement When it is mounted on the horizontal panel support, it is restored by a change in the position of the other end and is disposed on the upper surface of the other end, and includes an elastic coupling frame for fixing the other end on the horizontal panel support.

Each elastic coupling frame is made of an elastic body, and each elastic coupling frame is separated from the rotational movement path of the other end by being deformed in the horizontal direction away from the other end by elasticity when in contact with the other end of each solar panel during the rotational movement. And, as each elastic coupling frame departs from the rotational movement path of the other end, the other end of each solar panel is rotationally moved along the rotational movement path to be mounted on the horizontal panel support.

The elastic coupling frame is a bottom plate formed in the shape of a plate; two side plates formed in a rectangular plate shape and vertically coupled to both ends of the bottom plate; Two triangular elastic parts coupled to the upper end of each of the side plates and disposed on the rotational movement path of the other end of each solar panel and deformed by the other end of each solar panel during the rotational movement; and a coupling protrusion vertically protruding from the lower surface of the bottom plate to the bottom plate, wherein each side plate moves away from the other end of each solar panel when the triangular elastic part coupled to the upper end of each side plate is deformed. By moving together with the triangular elastic part, it is possible to increase the horizontal movement distance of the triangular elastic part.

Each of the triangular elastic parts is formed in a triangular tube shape having a right-angled triangular cross section, and the height surface is coupled toward each side plate so that the inclined plane faces upward, and the other end of each solar panel during the rotational movement is the inclined surface of each triangular elastic part and It descends along the inclined plane in a contacting state and deforms each of the triangular elastic parts, and when the other end passes the inclined plane of each of the triangular elastic parts, each of the triangular elastic parts is restored and the bottom is placed on the upper surface of the other end mounted on the horizontal panel support part By doing so, it is possible to prevent upward departure of the other end.

The lower surface of each of the triangular elastic parts is disposed to be spaced apart from the height surface, and the lower surface of each triangular elastic part is inserted between the inclined surface and the height surface when the inclined surface is pressed by the other end of each solar panel during the rotational movement, the inclined surface By folding in the direction, it is possible to increase the horizontal movement distance of the triangular elastic part.

Each of the elastic support members is formed in the shape of a square tube with an open bottom and is fitted along the longitudinal direction between the two side plates of the elastic coupling frame, thereby preventing the horizontal movement of the triangular elastic part coupled to each side plate. It may further include a cap.

The elastic support member is formed in the shape of a square column having a groove along the longitudinal center line on its upper surface, and includes a coupling frame installation part installed on the horizontal panel support part, and the groove formed in the coupling frame installation part goes down from top to bottom. There is at least one section in which the width is widened as it goes, and the coupling protrusion of the elastic coupling frame is formed in a shape corresponding to the groove formed in the coupling frame installation part, and the coupling is performed by horizontally fitting the coupling frame installation part into the groove. Deviation from the groove of the frame mounting portion in the vertical direction can be prevented.

Each of the fixed support members is formed in the shape of a square plate, the first bottom portion is installed on the roof support structure; two first standing parts each formed in a square plate shape and obliquely standing on the first bottom part with respect to the first bottom part; an inclined panel support part formed in a rectangular plate shape, the lower surface of which is supported by the two first standing parts, thereby connecting the two first standing parts to each other, and having one end of each solar panel mounted on the upper surface; and a separation prevention part including a surface parallel to the inclined panel support part and disposed on the upper end of the inclined panel support part to prevent the solar panel mounted on the inclined panel support part from departing upward, the first bottom part; The two first standing parts, the inclined panel support part, and the separation preventing part may all be integrally coupled.

The inclined panel support portion of the fixed support member includes two contact support portions forming both ends of the inclined panel support portion and parallel to the roof support structure; and two rectangular plates extending downward at a predetermined angle from one end of each contact support part toward the longitudinal center of the inclined panel support part, and an inclined converging part formed by contacting each other at the longitudinal center of the inclined panel support part, wherein each One end of the solar panel is inclined along the inclination formed in the inclination converging part so that the other end of the solar panel can be rotated downward from a higher place.

After one end of each photovoltaic panel is mounted on the inclined panel support of the fixed support member, the elastic coupling frame is deformed by the other end of the photovoltaic panel while the other end is rotated around one end, and the photovoltaic panel is rotated After completion, when the other end of the solar panel is mounted on the horizontal panel support, the elastic coupling frame is restored and placed on the upper surface of the other end of the solar panel, and the other end of the solar panel is fixed on the horizontal panel support, thereby screwing into the solar panel assembly. Installation and maintenance are easy as no fastening is required. In addition, since the bolt loosening problem due to continuous external force such as wind does not occur, even if the solar panel vibrates due to continuous external force such as wind, it may be firmly fixed on the roof support structure.

1 is a view showing a building to which a roof-integrated photovoltaic system according to an embodiment of the present invention is applied.
FIG. 2 is a view illustrating the roof-integrated photovoltaic system shown in FIG. 1 .
3 is a view showing a fixed support member of the roof-integrated photovoltaic system according to an embodiment of the present invention.
4 is a view showing an elastic support member of the roof-integrated photovoltaic system according to an embodiment of the present invention.
5 is a view showing each configuration of the elastic support member shown in FIG.
6 is a view showing a part of the assembly process of the roof-integrated photovoltaic system according to an embodiment of the present invention.
7 is a schematic perspective view of an assembly process of a roof-integrated photovoltaic system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiment of the present invention described below relates to a roof-integrated photovoltaic power generation system 100 in which work efficiency is improved by boltless assembly, and may be simply referred to as a 'solar power generation system'. The photovoltaic power generation system 100 according to an embodiment of the present invention is installed on a support structure of a roof in which a frame 1, a lower panel 3 and an insulation board 5 are sequentially stacked to form a photovoltaic panel. By fixing it on the supporting structure of the roof, the photovoltaic panel can serve as the roof of the building.

1 is a view showing a building in which a photovoltaic power generation system according to an embodiment of the present invention is installed, and FIG. 2 is a view showing the photovoltaic power generation system shown in FIG. 1 . Referring to FIGS. 1 and 2 , the photovoltaic power generation system 100 according to an embodiment of the present invention includes a plurality of fixed support members 210 , a plurality of elastic support members 220 , and a plurality of photovoltaic panels 230 . ) and a plurality of fire resistant panels 240 .

In the photovoltaic system 100 according to an embodiment of the present invention, a plurality of fixed support members 210 and a plurality of elastic support members 220 are alternately arranged in parallel to each other on a roof support structure, and a plurality of sunlight Each one end of the panel 230 is coupled to any one fixed support member 210, and the other end is coupled to any one fixed support member 210 and any one elastic support member 220 adjacent to the roof of the building. to form Each configuration of the photovoltaic system according to an embodiment of the present invention will be described in more detail below.

The plurality of fixed support members 210 include a surface parallel to the support structure of the roof, and are installed parallel to each other at predetermined intervals on the roof support structure to fix the plurality of solar panels 230 at the top. A plurality of photovoltaic panels 230 fixed at a predetermined height on the roof support structure by a plurality of fixed support members 210 are spaced apart from the fireproof panel 240 installed under each photovoltaic panel 230 by a certain distance. It is convenient for ventilation or rainwater discharge. Hereinafter, unless otherwise specified, the term 'fixed support member 210' refers to each of the fixed support members 210 constituting the plurality of fixed support members 210 .

Referring to FIG. 3 showing a fixed support member 210 according to an embodiment of the present invention, the fixed support member 210 includes a first bottom portion 310, two first standing portions 320, and a first 1 is composed of an intermediate support part 330 , an inclined panel support part 340 , a separation prevention part 350 , two first panel seating parts 360 , and a first support part 370 . The first bottom part 310, two first standing parts 320, the first intermediate support part 330, the inclined panel support part 340, the separation prevention part 350, the two first panel seating parts 360. And the first support portion 370 are all integrally coupled, and each configuration of the fixed support member 210 is named by dividing the integral fixed support member 210 arbitrarily for convenience of description.

The first bottom part 310 is formed in a square plate shape and is seated on the roof support structure so that the fixed support member 210 is supported by the roof support structure.

In one embodiment of the present invention, the first bottom portion 310 is composed of a floor fixing portion 311 and a spaced support portion (312). The floor fixing part 311 forms both ends of the first bottom part 310 , and the lower surface thereof is fixed while being in contact with the roof support structure to fix the fixing support member 210 to the roof support structure.

The spaced support part 312 is formed by bending the central part of the first bottom part 310 upward along the longitudinal direction of the first bottom part 310 . More specifically, the spaced support part 312 is a central part of the first bottom part 310 and is disposed between the bottom fixing parts 311 forming both ends of the first bottom part 310 , and the first bottom part 310 . ), the bottom fixing parts 311 forming both ends are connected to each other. The spaced support part 312 is positioned at a position higher than the floor fixing part 311 and includes a plane parallel to the floor fixing part 311 .

In one embodiment of the present invention, the spaced support portion 312 is composed of a protruding plate (312a) and an inclined portion (312b). The protruding plate 312a is a rectangular plate parallel to the roof support structure and the floor fixing part 311 while a certain area on both sides of the first floor part 310 protrudes upwardly and is spaced apart from the roof support structure. And, the inclined portion 312b is a square plate inclined with respect to the bottom fixing portion 311 connecting both ends of the protruding plate 312a and the bottom fixing portion 311 forming both ends of the first bottom portion 310 . corresponds to

In the first floor portion 310 according to the embodiment of the present invention, the floor fixing portions 311 forming both ends of the first floor portion 310 are in close contact with the roof support structure, and the spaced support portion 312 is bent upward. As the fixed support member 210 is firmly fixed on the roof support structure as it is spaced apart from the roof support structure, a force applied in the direction of the roof support structure near the longitudinal center of the fixed support member 210 (for example, When the solar panel 230 is inserted, the force acting on the fixed support member 210) is more flexible by bending toward the space S between the spaced support part 312 of the first floor part 310 and the roof support structure. In addition to being able to move efficiently, there is an effect of buffering the impact applied to the solar panel 230 mounted on the fixed support member 210 .

On the other hand, in one embodiment of the present invention, both ends of the first bottom portion 310, that is, each end of the floor fixing portion 311 may be vertically bent to form the auxiliary panel support portion 311a. The auxiliary panel supporting part 311a supports the fire resistant panel 240 supported by the first panel mounting part 360 once again at a position spaced apart from the first panel mounting part 360, so that the fire resistant panel 240 is more stable. to be coupled to the fixed support member 210 .

The two first standing parts 320 are each formed in a rectangular plate shape, and by standing on the first bottom part 310 obliquely with respect to the first bottom part 310 along the longitudinal direction of the first bottom part 310 . The solar panel 230 seated on the inclined panel support 340 is supported. One end of each first standing part 320 is fixed to the upper surface of the first bottom part 310 and the other end is arranged to face upward, and the other end facing upward of each first standing part 320 is an inclined panel support part ( 340) are connected to each other. Hereinafter, unless otherwise specified, the 'first standing part 320' refers to each of the first standing parts 320 constituting the two first standing parts 320 .

In an embodiment of the present invention, one end of the first standing part 320 may be fixed to the spaced apart support part 312 of the first bottom part 310 . More specifically, one end of the first standing part 320 may be fixed on the protruding plate 312a of the spaced support part 312 , and each first standing part may more stably support the inclined panel support part 340 . One end of the 320 is preferably fixed as far as possible from the longitudinal centerline of the protruding plate 312a, that is, close to both ends.

When the first standing part 320 is fixed on the spaced support part 312 of the first bottom part 310, a force in the direction of the roof support structure is applied to the first standing part 320 when the solar panel 230 is coupled. Even if it is, the first standing part 320 can move flexibly in the vertical direction by the space S formed under the spaced support part 312 , so that the solar panel 230 can be easily coupled.

The first standing part 320 according to the embodiment of the present invention may stand while forming an outward inclination with respect to the first bottom part 310 . Accordingly, the distance between the two first standing parts 320 facing each other gradually increases from bottom to top. As described above, as the distance between the two first standing parts 320 facing each other increases toward the top of the two first standing parts 320 , the two first standing parts 320 on the two first standing parts 320 . The area of the inclined panel support part 340 connecting the standing part 320 is also increased, and accordingly, the area supporting the solar panel 230 is increased, so that the solar panel 230 can be supported more stably.

The first intermediate support part 330 is formed in a square plate shape, and is vertically fixed with respect to the first bottom part 310 between the two first standing parts 320 . The first intermediate support part 330 is coupled to the lower surface of the inclined panel support part 340 with one end on the upper surface of the first bottom part 310 between the two first standing parts 320 and the inclined panel support part 340 . support the

As the first intermediate support part 330 is positioned between the two first standing parts 320 , the two first standing parts 320 installed to be inclined with respect to the first bottom part 310 shake or move in the horizontal direction. is prevented, and also the first intermediate support part 330 distributes the weight of the solar panel 230 to prevent the fixing support member 210 from being crushed downward by the solar panel 230, so that the fixing support member The structural stability of 210 is improved. It is preferable that the first intermediate support part 330 be installed in the center between the two first standing parts 320 to evenly distribute the force applied to the two first standing parts 320 .

The inclined panel support part 340 is formed in a square plate shape and connects the two first standing parts 320 to each other by coupling them on the two first standing parts 320 facing each other. One end of each solar panel 230 is mounted on the upper surface of the inclined panel support 340 .

The inclined panel support part 340 according to the embodiment of the present invention may include a contact support part 341 and an inclined convergence part 342 . The contact support part 341 is a square plate forming both ends of the inclined panel support part 340 and is parallel to the protruding plate 312a of the first bottom part 310, and the upper surface is the lower surface of one end of the solar panel 230. It directly supports each solar panel 230 in contact with.

The inclined convergence part 342 forms the longitudinal central part of the inclined panel support part 340 and extends downward at a predetermined angle with respect to each of the contact support parts 341 forming both ends of the inclined panel support part 340 . The square plate corresponds to a groove formed by contacting each other at the longitudinal center line of the inclined panel support 340 . The slope convergence part 342 is inevitably inevitably mounted in the process of mounting one end of the solar panel 230 on the fixed support member 210 first, and then mounting the other end of the solar panel 230 on the elastic support member 220 . One end of the solar panel 230 inclined downward of the fixed support member 210 is inserted into the inclination convergence part 342 to be inclined downward, so that the other end of the solar panel 230 is higher from a higher place. Rotational movement is possible so that the operator can fix the solar panel 230 more conveniently.

The separation prevention part 350 is disposed on the upper surface of one end of the solar panel 230 supported by the inclined panel support part 340 of the fixed support member 210 so that the solar panel 230 is separated from the inclined panel support part 340 . make sure it doesn't come off. The separation prevention part 350 is composed of a cover part 351 and a panel separation part 352 .

The cover part 351 is formed in a square plate shape and is disposed on the upper surface of one end of two neighboring solar panels 230 supported by the inclined panel support part 340 and is seated on the inclined panel support part 340. By blocking the upward movement path of the two solar panels 230 , each solar panel 230 seated on the inclined panel support 340 is prevented from being separated upward.

The cover part 351 is disposed above the gap to cover the gap between the two photovoltaic panels 230 adjacent to each other, thereby preventing rainwater from flowing through the gap between the photovoltaic panels 230 adjacent to each other.

When the width of the cover part 351 is formed too wide, rainwater inflow prevention effect is excellent, but it can reduce the power generation efficiency by covering the solar panel 230 too much, and the solar panel seated on the inclined panel support part 340 . Since the 230 limits the inclination, it interferes with assembling the solar panel 230 . On the other hand, when the width of the cover portion 351 is formed to be too narrow, rainwater can easily flow between the neighboring solar panels 230 , and the effect of preventing the separation of the solar panel 230 is low, so the cover The width of the part 351 is preferably set to a size that can adequately block the gap between the adjacent solar panels 230 without significantly interfering when assembling the solar panel 230 .

In one embodiment of the present invention, a slope may be formed at both ends of the cover part 351 in the width direction so that the lower surface has a wider width than the upper surface. The slope formed from the top to the bottom in this way prevents rainwater from flowing into the gap between the neighboring solar panels 230 by allowing rainwater to naturally flow down along the slope.

The panel separation part 352 is formed in a square plate shape and is vertically coupled to the lower surface of the cover part 351 . Accordingly, the separation preventing part 350 is formed in an approximately 'T' shape in cross section. The panel spacer 352 is disposed between two solar panels 230 adjacent to each other by being fixed so that the distal end is positioned on the longitudinal centerline of the inclined panel support 340 .

The panel separation part 352 is fixed so that one end is located on the lower surface of the cover part 351 and the other end is located on the longitudinal center line of the inclined panel support part 340 , so that the cover part 351 is formed by the inclined panel support part 340 . It is supported so as to be positioned on the supported solar panel 230 . When the length of the panel separation part 352 is too long, the distance between the cover part 351 and the photovoltaic panel 230 is increased so that the cover part 351 cannot fix the photovoltaic panel 230 and is too short. Since there is no space for the solar panel 230 to be mounted on the inclined panel support 340 , the length of the panel spacer 352 is determined by the length of the solar panel 230 mounted on the inclined panel support 340 . In this state, it is preferable that the cover part 351 is set to be in close contact with the solar panel 230 , for example, the upper surfaces of the cover part 351 and the solar panel 230 are spaced apart by about 2 to 5 mm.

The panel spacer 352 is disposed between one end of two neighboring solar panels 230 so that one end of each of the neighboring solar panels 230 supported by the inclined panel support unit 340 collides with each other. The adjacent solar panels 230 are spaced apart so as not to be damaged.

The two first panel seating parts 360 protrude from the upper surface of the first bottom part 310 along the longitudinal direction of the first bottom part 310 to the outside of the two first standing parts 320, respectively, to seat the first panel. A gap M is formed between the part 360 and the first standing part 320 through which the fireproof panel 240 is fitted. Hereinafter, unless otherwise specified, the 'first panel seating part 360' refers to each of the first panel seating parts 360 constituting the two first panel seating parts 360 .

In one embodiment of the present invention, the first panel seating part 360 is formed in a shape in which a square plate is bent twice. One end of the first panel seating part 360 is fixed to the bottom fixing part 311 of the first bottom part 310 and vertically extending upward, so that the first surface 360a perpendicular to the bottom fixing part 311 is vertical. ) to form The first panel seating part 360 extending upward by a predetermined length with respect to the bottom fixing part 311 is bent vertically to form a second surface 360b parallel to the bottom fixing part 311, and then forms an obtuse angle again. It is bent so as to form a third surface 360c that is obliquely inclined with respect to the bottom fixing part 311 , and the other end is fixed to the spaced support part 312 .

The third surface 360c of the first panel seating portion 360 is disposed parallel to the first standing portion 320 facing each other, and between the third surface 360c and the facing first standing portion 320 is A gap M is formed through which one end of the fireproof panel 240 can be fitted. At this time, when the gap M formed by the first standing part 320 facing the third surface 360c of the first panel seating part 360 is too shallow, the fireproof panel 240 fitted in the gap M is Since this can be easily removed, the height of the first panel seating part 360 is a fireproof panel fitted in the gap M between the third surface 360c of the first panel seating part 360 and the first standing part 320 facing each other ( 240) is preferably formed to such an extent that it cannot easily fall out.

The second surface 360b of the first panel seating part 360 parallel to the bottom fixing part 311 has a first standing part ( Supports the lower surface of the fireproof panel 240 fitted in the gap (M) formed by the 320). In this way, the lower surface of the fire resistant panel 240 is supported by the second surface 360b, so that the fire resistant panel 240 can be more stably coupled to the first panel seating part 360 .

According to the first panel seating part 360 according to the embodiment of the present invention, a gap (M) formed between the third surface 360c of the first panel seating part 360 and the first standing part 320 facing each other. By inserting one end of the fire-resistant panel 240 into the fire-resistant panel 240 can be fixed to the fixed support member 210, the installation of the fire-resistant panel 240 is convenient, and the Since the second surface 360b supports the lower surface of the fire resistant panel 240 , the fire resistant panel 240 may be more stably fixed to the fixing support member 210 .

In addition, the first surface 360a of the first panel seating part 360 is vertically coupled to the bottom fixing part 311 , and the third surface 360c is fixed to the spaced support part 312 , so that the first panel When the fireproof panel 240 is inserted into the gap M formed between the third surface 360c of the seating portion 360 and the first standing portion 320 facing each other, the third surface 360c is spaced apart from the support portion 312 ) It can move more flexibly in the vertical direction by the space (S) formed below, so it is convenient to install the fireproof panel 240, and after the fireproof panel 240 is installed, it is vertically fixed to the first floor fixing part 311 The fireproof panel 240 is more stably fixed and supported by the support member 210 by the first surface 360a firmly supporting the second surface 360b of the first panel seating part 360 on which the fireproof panel 240 is seated. ) can be combined.

The first supporting part 370 protrudes from the lower surface of the spaced support part 312 of the first bottom part 310 and comes in contact with the roof support structure to support the spaced support part 312 . The first support part 370 supports the spaced support part 312 that is spaced apart on the roof support structure and floats on the roof support structure due to the structure in which the central part is bent, so that the fixed support member 210 is more stably fixed on the roof support structure. The space (S) formed on both sides of the first support part 370 allows it to move flexibly with the force applied in the direction of the roof support structure in the vicinity of the central portion in the longitudinal direction of the fixed support member 210 . The first support portion 370 is preferably formed on the lower surface of the central portion of the protruding plate 312a of the spaced support portion 312 to stably support the fixed support member 210 .

The fixed support member 210 according to an embodiment of the present invention includes a first bottom part 310 and two first standing parts 320 constituting the fixed support member 210 for structural stability and convenience of manufacture and installation. , it is preferable that the inclined panel support part 340 , the separation prevention part 350 and the first panel seating part 360 are formed symmetrically with respect to the first intermediate support part 330 .

The plurality of elastic support members 220 are spaced apart from each other on the support structure of the roof and installed in parallel to fix the plurality of solar panels 230 on the upper end. More specifically, the plurality of elastic support members 220 are installed in parallel between the plurality of fixed support members 210 . A plurality of solar panels 230 fixed at a predetermined height on the roof support structure by a plurality of elastic support members 220 are spaced apart from the fireproof panel 240 installed under each solar panel 230 by a predetermined distance. It is convenient for ventilation or rainwater discharge. Hereinafter, unless otherwise specified, the term 'elastic support member 220' refers to each of the elastic support members 220 constituting the plurality of elastic support members 220 .

Referring to FIG. 4 showing an elastic support member 220 according to an embodiment of the present invention, the elastic support member 220 includes a support frame 410 , an elastic coupling frame 420 and an elastic suppression cap 430 . is composed of

The support frame 410 is fixedly installed on the roof support structure and one end of each photovoltaic panel 230 is seated, thereby directly receiving the load of the photovoltaic panel 230 and supporting the photovoltaic panel 230 . 5A is a view showing the support frame 410 of the elastic support member 220 according to an embodiment of the present invention. Referring to FIG. 5A, the support frame 410 includes a second bottom part 411, two second standing parts 412, a horizontal panel support part 413, a second intermediate support part 414, and a coupling frame installation part. 415 , a second panel seating part 416 , and a second support part 417 .

The second bottom portion 411, the two second standing portions 412, the second panel seating portion 416, and the second support portion 417 of the support frame 410 are the first of the fixed support members 210, respectively. 1 As a configuration corresponding to the bottom part 310, the two first standing parts 320, the first panel seating part 360 and the first support part 370, the configuration and the role are substantially the same, the description Description of the second bottom part 411, the two second standing parts 412, the second panel seating part 416, and the second support part 417 of the support frame 410 to prevent this from being tedious. will be replaced with the description of the first bottom portion 310 , the two first standing portions 320 , the first panel seating portion 360 , and the first support portion 370 of the fixed support member 210 .

The horizontal panel support part 413 is formed in a square plate shape and connects the two second standing parts 412 to each other by coupling them on the two second standing parts 412 facing each other. The other end of each solar panel 230 mounted on the inclined panel support 340 of the fixed support member 210 is seated on the upper surface of the horizontal panel support 413 . The horizontal panel support part 413 is parallel to the protruding plate 411a of the second bottom part 411 , and the upper surface is in direct contact with the lower surface of each solar panel 230 and supports each solar panel 230 .

The second intermediate support part 414 is formed in the shape of a square plate, and is vertically fixed with respect to the second bottom part 411 between the two second standing parts 412 . The second intermediate support part 414 is coupled to the bottom plate 421 of one end and the other end of the horizontal panel support part 413 between the two second standing parts 412 to support the horizontal panel support part 413 .

As the second intermediate support part 414 is positioned between the two second standing parts 412, the two second standing parts 412 installed to be inclined with respect to the second bottom part 411 shake or move in the horizontal direction. is prevented, and the second intermediate support part 414 distributes the weight of the solar panel 230 so that the fixed support member 210 is prevented from being crushed downward by the solar panel 230, resulting in structural stability. is improved It is preferable that the second intermediate support part 414 be installed in the center between the two second standing parts 412 to evenly distribute the force applied to the two second standing parts 412 .

The coupling frame installation part 415 is formed in a rectangular column shape and is fixed to the upper surface of the horizontal panel support part 413 along the longitudinal direction of the horizontal panel support part 413, and the upper surface of the coupling frame installation part 415 has an elastic coupling frame. 420 is installed.

The upper surface of the coupling frame installation part 415 according to an embodiment of the present invention may be formed with a groove (D) capable of fitting with the elastic coupling frame 420 . The groove (D) formed on the upper surface of the coupling frame installation part 415 is formed along the longitudinal centerline of the upper surface of the coupling frame installation part 415 . The groove (D) of the coupling frame installation part 415 according to the embodiment of the present invention has at least one section in which the width is widened while going down from the top.

In one embodiment of the present invention, the groove (D) of the coupling frame installation part 415 has a predetermined width and a predetermined depth with respect to the longitudinal center line on the upper surface of the coupling frame installation part 415, and then gradually increases in width. It may be formed in a shape that widens and then narrows again. Due to the shape of the groove (D) of the coupling frame installation part 415 , the elastic coupling frame 420 can be firmly fixed to the support frame 410 without using a bolt. The coupling of the coupling frame installation part 415 and the elastic coupling frame 420 will be described in more detail below.

The elastic coupling frame 420 is formed in a rectangular tube shape with an open upper surface, is installed on the coupling frame installation part 415 of the support frame 410, and is seated on the horizontal panel support part 413 of the support frame 410. By blocking the upper end of each photovoltaic panel 230, each photovoltaic panel 230 seated on the support frame 410 is prevented from departing upward.

More specifically, the elastic coupling frame 420 according to the embodiment of the present invention has one end mounted on the inclined panel support 340 of the fixed support member 210, and then each solar panel 230 rotating around one end. ), and when the other end of the photovoltaic panel 230 is mounted on the horizontal panel support 413 after the rotational movement of the photovoltaic panel 230 is completed, it is restored by a change in the position of the other end of the photovoltaic panel 230 . The other end of the solar panel 230 is fixed on the horizontal panel support 413 by being disposed on the upper surface of the other end of the solar panel 230 .

5B is a view showing the support frame 410 of the elastic support member 220 according to an embodiment of the present invention. Referring to FIG. 5B , the elastic coupling frame 420 includes a bottom plate 421 , a coupling protrusion 422 , two side plates 423 , and two triangular elastic parts 424 .

The bottom plate 421 is formed in a square plate shape, and has the same width and length as the width and length of the upper surface of the coupling frame installation part 415 . The lower surface of the bottom plate 421 is supported by the coupling frame installation part 415 by being placed in contact with the upper surface of the coupling frame installation part 415 .

The coupling protrusion 422 protrudes vertically along the longitudinal centerline of the bottom plate 421 from the lower surface of the bottom plate 421 and is fitted into the groove D formed in the coupling frame installation part 415, thereby elastically coupling the frame ( 420 is fixed to the coupling frame installation part 415 . In the coupling protrusion 422 according to an embodiment of the present invention, there is at least one section in which the width is widened while going down from the top. In one embodiment of the present invention, the coupling protrusion 422 is formed in a shape corresponding to the groove (D) formed in the coupling frame installation portion (415).

As both the coupling protrusion 422 and the groove D formed in the coupling frame installation part 415 have a wider portion at the bottom than the top, the coupling protrusion 422 is a groove (D) of the coupling frame installation part 415. ) cannot be fitted from the upper side, and after fitting the coupling protrusion 422 into the groove (D) of the coupling frame installation part 415 at the longitudinal end of the coupling frame installation part 415, the coupling frame installation part 415 ) by pushing along the longitudinal direction of the elastic coupling frame 420 can be coupled to the coupling frame installation portion (415). That is, the elastic coupling frame 420 according to the embodiment of the present invention is fixed to the coupling frame installation unit 415 using a horizontal movement rather than a vertical movement.

As such, since the coupling protrusion 422 has a lower width wider than the upper portion, the coupling protrusion 422 fitted in the groove D of the coupling frame installation part 415 moves upward as well as in the left and right directions. limited to Accordingly, the elastic coupling frame 420 can be firmly fixed to the support frame 410, and without screwing the coupling frame installation part 415 of the support frame 410 by pushing the elastic coupling frame 420 in the horizontal direction. It can be fixed to the support frame 410 just by putting it in, so the operation is very fast and simple.

In one embodiment of the present invention, the coupling protrusion 422 may be formed integrally with the bottom plate 421 by bending the bottom plate 421 .

The two side plates 423 of the elastic coupling frame 420 are each formed in a square plate shape, and one end is vertically coupled to both ends of the bottom plate 421 .

The two triangular elastic parts 424 are made of an elastic body and are formed in a triangular tube shape. The two triangular elastic parts 424 are fixed to the upper ends of the two side plates 423 along the longitudinal direction of the two side plates 423 of the elastic coupling frame 420 and mounted on the horizontal panel support part 413. Block the upper end of the panel 230 to prevent the solar panel 230 from being separated from the horizontal panel support 413 . In one embodiment of the present invention, each triangular elastic portion 424 may be formed of a leaf spring.

Each solar panel 230 according to an embodiment of the present invention has one end mounted on the inclined panel support 340 of the fixed support member 210 and the other end is mounted on the inclined panel support 340 of the center of the one end. It is mounted on the horizontal panel support part 413 of the elastic support member 220 by rotating from the upper side to the lower side of the elastic support member 220 as a result. At this time, the triangular elastic part 424 is disposed on the rotational movement path of the other end of each photovoltaic panel 230 and deformed by the other end of each photovoltaic panel 230 moving downward. Allows movement of the other end downward.

Each of the triangular elastic parts 424 according to an embodiment of the present invention is formed in a triangular tube shape having a cross section of a right-angled triangle, and the bottom surface forming the bottom of the triangular tube faces the horizontal panel support 413, and of the triangular tube. The height surface forming the height is fixed to face each side plate 423 of the elastic coupling frame 420, so that the side is located on the upper surface of the other end of the solar panel 230 mounted on the horizontal panel support 413. The 230 prevents the horizontal panel support 413 from leaving upward.

On the other hand, each of the triangular elastic parts 424 according to the embodiment of the present invention is disposed so that the inclined plane faces upward, so that when each solar panel 230 is inserted from above, it is in contact with the inclined plane of each triangular elastic part 424. It is deformed in a direction toward each side plate 423 by the pressure from each solar panel 230, and accordingly, each solar panel 230 passes through each triangular elastic part while pressing the inclined surface of each triangular elastic part 424. It may be mounted on the horizontal panel support 413 .

Each triangular elastic part 424 is restored in shape by elasticity again when each solar panel 230 is mounted on the horizontal panel support part 413, that is, when released from the pressure applied by the solar panel 230. The bottom surface is disposed on the upper surface of the photovoltaic panel 230 in parallel to the photovoltaic panel 230 to prevent upward separation of the photovoltaic panel 230 .

In one embodiment of the present invention, the triangular elastic portion 424 may be spaced apart from the bottom surface and the height surface by a predetermined interval. As the lower surface and the height surface of the triangular elastic part 424 are spaced apart, when the inclined surface of the triangular elastic part 424 is pressed by the other end of the solar panel 230, the lower surface is inserted between the height surface and the inclined surface by pressing the inclined surface downward. By folding in the inclined plane direction, the triangular elastic part 424 is more deformed along with it, so that the horizontal movement distance of the triangular elastic part 424 may be increased.

In one embodiment of the present invention, the elastic coupling frame 420 is a single plate spring with one plate spring forming a bottom plate 421, a coupling protrusion 422, two side plates 423 and two triangular elastic parts 424. can be formed with That is, the longitudinal central area of one leaf spring forms the coupling protrusion 422 , the area on both sides forms the bottom plate 421 , and the area on both sides forms the two side plates 423 , and both ends These two triangular elastic portions 424 may be formed. In this way, when the entire elastic coupling frame 420 is composed of a leaf spring, when each solar panel 230 is inserted from above, not only the two triangular elastic parts 424 but also the two side plates 423 are also As each solar panel 230 is bent and moved toward the outside (that is, the inside of the elastic coupling frame 420), the horizontal movement distance of each triangular elastic part 424 increases, so that each solar panel 230 ) is convenient to fix.

The elastic suppression cap 430 has an empty interior, is formed in a square tube shape with an open lower surface, and suppresses the movement due to elasticity of the elastic coupling frame 420 to prevent the solar panel mounted on the horizontal panel support 413 ( 413 ). 230) is prevented from escaping.

The elastic suppression cap 430 has the same length as the elastically coupled frame 420, and has the same width as the distance between the two side plates of the elastically coupled frame 420 between the two side plates of the elastically coupled frame 420. is plugged in In this way, the inward movement of the two side plates 423 of the elastic coupling frame 420 is limited by the elastic restraining cap 430 being fitted between the two side plates of the elastic coupling frame 420 . As described above, the solar panel 230 installed on the horizontal panel support 413 by the elastic restraining cap 430 restricts the movement due to the elasticity of the elastically coupled frame 420 is a horizontal panel by the elasticity of the elastically coupled frame 420 . It is prevented from being separated from the support 413 .

The elastic suppression cap 430 according to the embodiment of the present invention is difficult to suppress the movement of the two side plates 423 and the two triangular elastic parts 424 when the height is too low, and when the height is too high, it is elastic Since it protrudes onto the coupling frame 420 and may damage the aesthetics, the height of the elastic suppression cap 430 is preferably set to be the same as the two side plates 423 of the elastic coupling frame 420 .

6 is a view showing a state in which the solar panel 230 is coupled to the fixed support member 210 and the elastic support member 220 according to an embodiment of the present invention. Referring to FIG. 6 , one end of the solar panel 230 is sandwiched between the inclined panel support part 340 of the fixed support member 210 and the cover part 351 of the panel separation part 352 , and the other end is elastic It is disposed above the support member 220 (FIG. 6a). The other end of the solar panel 230 disposed above the elastic support member 220 is rotated downward and deformed by pressing the inclined surface of the triangular elastic part 424 of the elastic support member 220 (FIG. 6b).

The other end of the solar panel 230 that deforms the inclined plane of the triangular elastic part 424 and rotates downward along the inclined plane of the triangular elastic part 424 passes the triangular elastic part 424 and is on the horizontal panel support part 413. The triangular elastic part 424 from which the pressure from the solar panel 230 has been removed is returned to the triangular tube shape again on the upper surface of the other end of the solar panel 230 seated on the horizontal panel support 413 as the bottom surface. position to prevent separation of the solar panel 230 (FIG. 6c). When the solar panel 230 is seated on the horizontal panel support 413, the elastic suppression cap 430 is sandwiched between the two side plates 423 of the elastic coupling frame 420, so that of the two side plates 423 By restricting movement, the solar panel 230 is more stably fixed on the horizontal panel support 413 .

In this way, the triangular elastic portions 424 formed on both sides of the elastic coupling frame 420 are deformed by the force from the top to the bottom applied to the inclined surface to form a space through which the solar panel 230 can pass, and applied to the inclined surface. When the force is removed, it is restored to its original shape by elasticity, thereby preventing the solar panel 230 mounted on the horizontal panel support 413 using the bottom surface from escaping upward. Accordingly, the operator can fit the solar panel 230 on the horizontal panel support 413 only by pressing the solar panel 230 down, so that screw fastening is unnecessary, which is the efficiency of installation and maintenance On the other hand, since the screw is not fastened, there is an excellent effect of aesthetics, and since the screw is not tightened, there is no problem that the bonding strength is weakened even when continuously exposed to wind, etc., and the bonding stability is improved.

The plurality of solar panels 230 is a device for converting sunlight incident on the roof direction of the building into electrical energy and is formed in a rectangular plate shape. Each photovoltaic panel may include a plurality of photovoltaic cells, a wire electrically connecting the photovoltaic cells, and a film or protective glass that protects the photovoltaic cells from the external environment, and each outer rim is made of a metal material. It is finished by a finishing frame made of

A plurality of fire resistant panels 240 are formed in the shape of a square plate, and between the adjacent fixed support members 210 and the elastic support members 220, the bottom surface of the fire resistant panel 240 is an insulation board that is a support structure of the roof ( 5) by being installed in contact with the fireproof panel 240, even if rainwater is introduced between the plurality of photovoltaic panels 230 that are sequentially installed from the upper side, it is not introduced into the room but is discharged to the outside.

Each fire resistant panel 240 according to an embodiment of the present invention has one end between the adjacent fixed support member 210 and the elastic support member 220, the first panel seating part 360 and the second end of the fixed support member 210. 1 It is fitted in the gap M formed between the standing parts 320 , and the other end is inserted into the gap M formed between the second panel seating part 416 and the second standing part 412 of the elastic support member 220 . It is installed by fitting.

In one embodiment of the present invention, at both ends of each fireproof panel 240, a panel protrusion 241 protruding toward the top is formed, and the lower surface of each panel protrusion 241 has a first panel seating part 360 and It is installed more stably by being respectively mounted and supported on the second surface of the second panel seating part 416 . In one embodiment of the present invention, the fire resistant panel 10 may be manufactured using a galvanized steel sheet to ensure fire resistance.

7 is a schematic perspective view of an assembly process of a roof-integrated photovoltaic system according to an embodiment of the present invention. In order to prevent unnecessary repetition of the drawings, only one fixed support member 210 and two elastic support members 220 are illustrated in FIG. 7 , but in actual installation, a plurality of fixed support members according to the area of the roof support structure It will be apparent to those skilled in the art that the 210 and the plurality of elastic support members 220 will be installed on the roof support structure. Referring to FIG. 7 , first, the support frames 410 of the plurality of fixed support members 210 and the plurality of elastic support members 220 are alternately arranged parallel to each other and fixed on the roof support structure (not shown). (Fig. 7a).

Thereafter, each fire resistant panel 240 is installed between the adjacent support frame 410 and the fixed support member 210 (FIG. 7b). At this time, both ends of each fireproof panel 240 have one end between the fixed support member 210 and the elastic support member 220 adjacent to each other. It is fitted in the gap M formed between the parts 320 , and the other end is fitted in the gap M formed between the second panel seating part 416 and the second standing part 412 of the elastic support member 220 . is installed as

After the plurality of fireproof panels 240 are installed, the coupling protrusion 422 of the elastic coupling frame 420 is inserted into the groove D formed in the coupling frame installation part 415 of each support frame 410 and coupled (Fig. 7c). At this time, as the groove D and the coupling protrusion 422 formed in the coupling frame installation part 415 have a wider portion at the lower side than the upper side, the coupling protrusion 422 is a groove of the coupling frame installation part 415 . It should be inserted along the longitudinal direction of the groove (D) from the side other than the upper side of (D). As such, the coupling protrusion 422 of the elastic coupling frame 420 fitted into the groove D of the coupling frame installation part 415 is wider at the bottom than at the top so that the upward movement is restricted, so that the elastic coupling frame 420 without screws is fastened. ) to be more firmly fixed to the coupling frame installation part 415 .

After fixing the elastic coupling frame 420 to the support frame 410, the solar panel 230 is installed between the adjacent fixing support members 210 and the support frame 410 of the elastic coupling frame 420. (Fig. 7d). The solar panel 230 has one end sandwiched between the inclined panel support part 340 of the fixed support member 210 and the cover part 351 of the panel spacer 352, and the other end is sandwiched between the inclined panel support part 340 of the fixed support member 210 . After rotating around one end, it comes down from the upper side of the elastic support member 220 and moves in contact with the inclined surface of the one triangular elastic part 424 of the elastic support member 220, and then one triangular elastic part 424. It is installed by being mounted on the horizontal panel support 413 passing through. At this time, the triangular elastic portion 424 of the elastic coupling frame 420 is deformed by the pressure from the solar panel 230 in contact with the inclined surface of the triangular elastic portion 424, and accordingly the solar panel 230 is It may be mounted on the horizontal panel support part 413 past the triangular elastic part 424 .

The triangular elastic part 424 from which the pressure from the solar panel 230 is removed returns to the triangular tube shape again and is located on the upper surface of the other end of the solar panel 230 seated on the horizontal panel support 413 as the bottom surface. The separation of the optical panel 230 is prevented.

When the solar panel 230 is seated on the horizontal panel support 413 , the elastic suppression cap 430 is sandwiched between the two side plates 423 of the elastic coupling frame 420 ( FIG. 7e ). The elastic suppression cap 430 is fitted between the two side plates of the elastic coupling frame 420 to limit the horizontal movement of the two side plates 423 so that the solar panel 230 is more stably the horizontal panel support 413 . ) to be fixed on the

According to the photovoltaic system 100 according to the embodiment of the present invention, the coupling protrusion 422 formed at the lower end of the elastic coupling frame 420 of the elastic support member 220 is coupled to the coupling frame installation. Since the elastic coupling frame 420 can be firmly installed in the support frame 410 without screw fastening by installing it in a manner that is inserted into the groove D formed in the portion 415, installation and maintenance work can be performed efficiently.

In addition, the triangular elastic portions 424 formed on both sides of the elastic coupling frame 420 are deformed by the force from the top to the bottom applied to the inclined plane to form a space through which the solar panel 230 can pass, and the sun When the force applied to the slope by the light panel 230 is removed, it is restored to its original shape by elasticity, thereby preventing the solar panel 230 mounted on the horizontal panel support 413 using the bottom surface from escaping upward. By doing so, the operator can fix the photovoltaic panel 230 on the horizontal panel support 413 only by pressing the photovoltaic panel 230 down, so that screw fastening is unnecessary, which promotes the efficiency of installation and maintenance. On the other hand, there is an effect of excellent aesthetics because the screw is not fastened.

So far, preferred embodiments of the present invention have been mainly looked at. Those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments are to be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated in the claims rather than the foregoing description, and all differences within the scope equivalent thereto should be construed as being included in the present invention.

100: solar power system
210: fixed support member
220: elastic support member
230: solar panel
240: fireproof panel
310: first bottom part
320: first standing unit
330: first intermediate support
340: inclined panel support
350: escape prevention unit
360: first panel seating part
370: first support
410: support frame
420: elastic coupling frame
430: elastic suppression cap
413: horizontal panel support
422: coupling protrusion
424: triangular elastic part

Claims (9)

A roof-integrated photovoltaic power generation system installed on a roof support structure to form a roof of a building structure,
a plurality of fixed support members 210 including inclined panel support parts 340 corresponding to a plane parallel to the roof support structure and installed at predetermined intervals on the roof support structure;
a plurality of elastic support members 220 including a horizontal panel support part 413 corresponding to a plane parallel to the roof support structure and installed in parallel between the plurality of fixed support members 210;
It is formed in a square plate shape, and after each end is mounted on the inclined panel support part 340 of the fixed support member 210 , the other end rotates from the upper side to the lower side of the elastic support member 220 around the one end. A plurality of solar panels 230 mounted on the horizontal panel support 413 of the elastic support member 220 by being moved; and
Each of which is formed in a square plate shape, and includes a plurality of fire resistant panels 240 installed between the adjacent fixed support members 210 and the elastic support members 220 so that the bottom surface is in contact with the roof support structure,
Each of the elastic support members 220 is deformed by the other end of each photovoltaic panel 230 while the respective photovoltaic panels 230 are rotationally moved, and after the rotational movement is completed, the other end is the horizontal panel support part When mounted on (413), it is restored by a change in the position of the other end and is disposed on the upper surface of the other end to include an elastic coupling frame 420 for fixing the other end on the horizontal panel support part 413,
Each of the fixed support members 210 is
a first bottom portion 310 formed in a square plate shape and installed on the roof support structure;
two first standing parts 320 each formed in a rectangular plate shape and obliquely standing on the first bottom part 310 with respect to the first bottom part 310;
Each of the two first standing parts 320 in the longitudinal direction of the first bottom part 310 from the upper surface of the first bottom part 310 protrudes outside the bottom surface of each fire resistant panel 240 . Includes two first panel seating parts 360 to support,
Each of the first panel seating parts 360 has a surface 360c facing parallel to each of the first standing parts 320 and a surface parallel to the roof support structure at a position higher than the first floor part 310 . 360b, wherein one end of each fireproof panel 240 is fitted into the gap M formed between each of the first standing portions 320 and the surface 360c, and the lower surface is the surface 360b. Roof integrated solar power system, characterized in that supported by. The method of claim 1,
Each elastic coupling frame 420 is made of an elastic body,
When each elastic coupling frame 420 is in contact with the other end of each solar panel 230 during the rotational movement, it is deformed in the horizontal direction away from the other end by elasticity, thereby departing from the rotational movement path of the other end,
As each elastic coupling frame 420 departs from the rotational movement path of the other end, the other end of each solar panel 230 is rotated along the rotational movement path and mounted on the horizontal panel support 413 . A roof-integrated photovoltaic system, characterized in that. 3. The method of claim 2,
The elastic coupling frame 420 is
Bottom plate 421 formed in the shape of a square plate;
two side plates 423 formed in a rectangular plate shape and vertically coupled to both ends of the bottom plate 421;
Two triangles coupled to the upper end of each of the side plates 423 and disposed on the rotational movement path of the other end of each solar panel 230 and deformed by the other end of each solar panel 230 during the rotational movement. elastic part 424; and
and a coupling protrusion 422 vertically protruding from the lower surface of the bottom plate 421 to the bottom plate 421,
Each side plate 423 is a triangular elastic part 424 in a direction away from the other end of each solar panel 230 when the triangular elastic part 424 coupled to the upper end of each side plate 423 is deformed. A roof-integrated photovoltaic power generation system, characterized in that it increases the horizontal movement distance of the triangular elastic part (424) by moving it. 4. The method of claim 3,
Each of the triangular elastic parts 424 is formed in a triangular tube shape having a right-angled triangular cross section, and the height surface is coupled toward each side plate 423 so that the inclined plane faces upward,
During the rotational movement, the other end of each solar panel 230 descends along the inclined surface in a state in contact with the inclined surface of each of the triangular elastic portions 424 to deform each of the triangular elastic portions 424, and the other end is the angle When passing through the inclined surface of the triangular elastic part 424, each of the triangular elastic parts 424 is restored and the bottom surface is disposed on the upper surface of the other end mounted on the horizontal panel support part 413, thereby preventing the upper departure of the other end. A roof-integrated solar power system. 5. The method of claim 4,
The bottom surface of each of the triangular elastic parts 424 is disposed to be spaced apart from the height surface,
When the lower surface of each of the triangular elastic parts 424 is pressed by the other end of each solar panel 230 during the rotational movement, the lower surface of each of the triangular elastic parts 424 is inserted between the inclined plane and the height surface and folded in the inclined plane direction, whereby the triangular elastic part is folded in the inclined plane direction. Roof-integrated solar power generation system, characterized in that increasing the horizontal movement distance of (424). 6. The method of claim 5,
Each of the elastic support members 220 is
The bottom surface is formed in an open square tube shape and is fitted along the longitudinal direction between the two side plates 423 of the elastic coupling frame 420, so that the horizontal of the triangular elastic part 424 coupled to each side plate 423. Roof-integrated photovoltaic system, characterized in that it further comprises an elastic restraining cap (430) to prevent the direction movement. 4. The method of claim 3,
The elastic support member 220 is
It is formed in the shape of a square column having a groove (D) along the longitudinal center line on the upper surface, and includes a coupling frame installation part 415 installed on the horizontal panel support part 413,
The groove (D) formed in the coupling frame installation part 415 has at least one section in which the width is widened while going down from top to bottom,
The coupling protrusion 422 of the elastic coupling frame 420 is formed in a shape corresponding to the groove D formed in the coupling frame installation part 415, and is horizontal to the groove D of the coupling frame installation part 415. A roof-integrated photovoltaic system, characterized in that it is prevented from departing from the groove (D) of the coupling frame installation part (415) in the vertical direction by fitting in the direction. The method of claim 1,
Each of the fixed support members 210 is
Formed in the shape of a square plate, the lower surface is supported by the two first standing parts 320 to connect the two first standing parts to each other, and the slope at which one end of each solar panel 230 is mounted on the upper surface. panel support 340; and
Deviation to prevent the solar panel 230 mounted on the inclined panel support part 340 from departing upward by including a surface parallel to the inclined panel support part 340 and disposed on the upper end of the inclined panel support part 340 . It further comprises a prevention part 350,
The first floor part 310, the two first standing parts 320, the inclined panel support part 340 and the separation preventing part 350 are all integrally coupled to the roof solar power generation, characterized in that system. 9. The method of claim 8,
The inclined panel support part 340 of the fixed support member 210 is
two contact support parts 341 forming both ends of the inclined panel support part 340 and parallel to the roof support structure; and
Two square plates extending downward at a predetermined angle from one end of each contact support part 341 toward the longitudinal center of the inclined panel support part 340 are formed by contacting each other at the longitudinal center of the inclined panel support part 340 . Including a gradient convergence part 342,
One end of each solar panel 230 is inclined along the slope formed in the inclination converging part 342, so that the other end of the solar panel 230 can be rotated downward from a higher place. roof-integrated solar power system.

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