KR101368923B1 - A roof panel which using photovoltanic modules as a closing means - Google Patents

Abstract

The present invention provides a roof panel using photovoltaic modules as finishing materials, the roof panel comprising: a base panel fixed on the upper parts of fixing bars spaced apart at constant intervals from each other; multiple supporting bars spaced apart at constant intervals from each other and disposed on the upper part of the base panel; fillers filled in gaps between the supporting bars; multiple first guide rails which are fixed on the supporting bar and disposed on the upper parts of the fillers while being spaced apart at constant intervals from each other; multiple second guide rails which have both ends vertically connecting spaces between the first guide rails by being fixed one side of the neighboring first guide rail; a pair of third guard rails which are mutually faced and which are horizontally disposed on the neighboring first guide rail; multiple photovoltaic modules sealing spaces respectively which are partitioned by the first and second guard rails; and an operational plate sealing which has both ends combined with the upper part of the third guide rails and which seals a space between the third guide rails.

Description

A roof panel which using photovoltanic modules as a closing means}

The present invention relates to a roof panel, and more particularly, the roof of the building is composed of a solar cell module with no fear of leakage at all, the roof between the solar cell module is provided with a mobile passage for replacement or repair of the solar cell module It is about the panel.

There is a growing interest in solar power as an alternative energy source due to the depletion of near-by resources. Photovoltaic power generation is an integrated technology that converts sunlight entering the earth into electrical energy. It is not only eco-friendly, but once the device is installed and operated, it can produce electricity without the need for energy input. There is an advantage, and the application range is gradually increasing.

In general, photovoltaic power generation is a unit photovoltaic module including a plurality of solar cells, a wire electrically connecting the solar cells, and a film or protective glass to protect the solar cells from the external environment. Operate in series or parallel connection. In order to apply such a solar cell module to a building, the most widely used from the past to the present is a method of mounting a solar cell module on a roof of an existing building.

This method can be implemented by simply fixing the finishing frame that tightly constrains the solar cell module to the roof, which means that there is no need to dismantle the existing building or newly construct a new structure for installing the solar cell module. have. However, this method has a disadvantage in that the appearance of the building becomes bad in that the solar cell module assembly is installed on the existing building roof. In addition, this method is to fix the finishing frame to the roof using a fastening means, such as bolts, there is a problem that leaks into the building through the through hole of the fastening means formed in the fixing process.

On the other hand, in order to solve the problem of the method of installing the solar cell module using the finishing frame as described above, the currently widely studied method is to configure the solar cell module itself as the roof of the building. Republic of Korea Patent No. 0989599 uses this approach and an embodiment thereof is disclosed in FIG. As can be seen in the drawing, this method has the advantage of not only reducing the cost for roof construction but also maintaining the exterior of the building as originally intended by constructing the roof itself of the building as a solar cell module assembly.

However, this method does not fundamentally solve the problem of water leakage into the building due to rainfall in that a roof is formed by interconnecting a plurality of solar cell modules that operate independently of each other. In addition, most of these methods currently proposed are composed only of the solar cell module itself, so that if the repair and replacement of a specific solar cell module is required after construction, there is no proper way to deal with it. There is this.

Republic of Korea Patent No.0989599

The present invention has been proposed to solve the above problems, an object of the present invention is to provide a roof panel using a solar cell module as a finishing material that can completely block leakage into the interior of the building.

Another object of the present invention to provide a roof panel that can be very easy to repair or replace the solar cell module constituting the roof after the construction is completed.

Still another object of the present invention is to provide a roof panel which can easily remove heat generated from a solar cell module using external air.

The present invention and the base panel 10 is fixed to the upper fixed bar (b) installed to be spaced apart from each other in order to achieve the above object; A plurality of support bars 20 installed on the base panel 10 at predetermined intervals from each other; Filler 30 is filled in the space between the support bar 20; N first guide rails 40 which are spaced apart from each other by a predetermined interval and are fixed at right angles to the support bar 20 and are installed on the filler 30; (1, 2, 3), (4, 5, 6), which are installed adjacent to each other among the n first guide rails (40). . , (n-2, n-1, n) is fixedly installed to divide each inner space formed by each pair, and in the (1, 2, 3) pairs (1, 2) and (2, 3) ) Is fixedly installed between the (4, 5, 6) pair is fixed between (4, 5) and (5, 6). . In the (n-2, n-1, n) pair, a plurality of second guide rails 50 fixedly installed between (n-2, n-1) and (n-1, n); (3, 4), which are installed adjacent to each other among the n first guide rails (40). . (n-3, n-2) third guide rails 60 installed in parallel with each other in contact with each pair of first guide rails; (1, 2, 3), (4, 5, 6), among the n first guide rails 40. . and (n-2, n-1, n) a plurality of solar cell modules 70 for enclosing each space partitioned by second guide rails 50 coupled to each pair; (3, 4) out of the n first guide rails 40; . (n-3, n-2) Both ends of the third guide rail 60 installed in parallel and in contact with each pair of first guide rails are coupled to each other so that the solar cell module 70 is not mounted. Work plate 80 for sealing the unopened space; And the present invention is characterized in that it includes the technical features.

The first guide rail 40 has a central support wall 41 with horizontal left and right horizontal ends 415 and 417 formed at an upper portion thereof, and protrudes vertically to the left and right with respect to the central support wall 41. The first drainage channels 433 and 435 may be formed in the interspace, but may include the first drainage walls 43 and 45 having the settled ends 435 and 455 at each upper portion thereof.

One side of each of the first drainage walls 43 and 45 may be provided with second drainage walls 47 and 49 protruding vertically to form second drainage passages 473 and 493 in the space therebetween.

In addition, a leakage preventing rail 1 bent at both ends of the first guide rail 40 may be installed vertically.

The second guide rail 50 has a central support wall 52 having left and right horizontal ends 525 and 527 at an upper portion thereof, and protrudes vertically to the left and right with respect to the central support wall 52. In the interspace, drainage passages 563 and 583 communicating with the first drainage passages 433 and 435 of the first guide rail 40 are formed, respectively, and the drainage walls 56 having upper and lower ends 565 and 585 are provided. 58).

The third guide rail 60 includes a support end 612, a horizontal end 614 provided on an upper portion of the support end 612, and in close contact with a bottom surface of the working plate 80, and the support end 612. It may be provided at the lower end of the extension end 61 is placed on the upper end of the settle end (435, 455) of the first guide rail (40).

A space of a predetermined interval may be formed between the solar cell module 70 and the filler 30.

The support member 90 may be filled in the lower space of the working plate 80.

According to the present invention, the first guide rail and the second guide rail each having a drainage path are vertically coupled to each other to partition a space, and the first guide rail and the second guide rail are coupled to communicate with each other. By mounting a plurality of solar cell modules used as finishing materials in their respective spaces, if rainwater flows through the space between the guide rail and the solar cell module, they are discharged to the outside to prevent rainwater from seeping into the building. It becomes possible.

In addition, the present invention by placing the work plate between the plurality of solar cell modules used as the finishing material of the roof and guides the drainage of rainwater that can flow through the end of the work board properly, after the roof construction is completed Not only can the repair and replacement of the battery module be made very easy, but it also prevents water from leaking through incoming connections at the end of the working plate.

In addition, the present invention by placing a predetermined interval so that the outside air can flow freely between the solar cell module and the filling material constituting the roof, to quickly remove a large amount of heat generated during the operation of the solar cell module rapid rapid inside the roof It is possible to prevent the temperature rise, as well as to prevent overheating of the solar cell module device according to the temperature rise.

In addition, the present invention proposes a configuration for filling the support material in the space formed in the lower portion of the working plate to properly absorb the noise generated during the repair or replacement of the solar cell module, as well as the space portion It allows to adequately block the heat from going outside.

1 is a schematic appearance configuration diagram of a roof panel according to the present invention.
Figure 2 is a schematic view of the combined structure of the solar cell module in the roof panel according to the present invention as a detailed view of the portion A of FIG.
Figure 3 is a schematic view of the combined structure of the work plate portion in the roof panel according to the present invention as a detailed view of the portion B of FIG.
4A and 4B are schematic construction flowcharts of the solar cell module unit according to the present invention;
5a and 5b is a schematic construction sequence diagram of the working plate portion in the present invention.
Figure 6 is a configuration of a conventional roof made using a solar cell module as a finishing material.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the technical features of the present invention, A detailed description thereof will be omitted.

1 is a schematic external configuration diagram of a roof panel according to the present invention, Figure 2 is a schematic view of the combined structure of the solar cell module in the roof panel according to the present invention as a detailed view of the portion A of FIG. 3 is a detailed view of the portion B of Figure 1 shows a schematic coupling configuration of the working plate in the roof panel according to the present invention. 4A and 4B each show a schematic construction diagram of the solar cell module unit, and FIGS. 5A and 5B each show a schematic construction diagram of the working plate unit.

The roof panel according to the present invention has a basic feature in that it consists of a solar cell module part and a working plate part, and includes the base panel 10, the support bar 20, the filler material 30, and the first, second, and third parts. The technical features of the guide rails 40, 50, 60, including the solar cell module 70 and the working plate 80. The technical features of the present invention will be described in order.

The base panel 10 is a part fixedly installed on the fixing bar (b). It is preferable that the material is made of a metal, and as shown in the drawings, a plurality of through holes may be formed, or a stepped portion protruding downwardly spaced apart from each other through a molding operation may be formed in the longitudinal direction. The through hole is for enhancing the sound absorbing function, and the stepped portion is for enhancing the rigidity of the base panel.

When the stepped portion is provided in the base panel, each stepped portion of the adjacent base panel 10 overlaps each other and is placed on the fixing bar (b) as shown in FIG. 4A. Fixing bar (b) in the present invention as a configuration for reinforcing the lower transverse bearing capacity of the building roof, a plurality of spaced apart from each other in the form of a horizontal bar is installed. The fixing bar may be made of C-shaped steel.

The support bar 20 is provided to support the first, second, and third guide rails 40, 50, and 60, the filler 30, and the solar cell module 70, which will be described later. The base panel 10 is installed above the spaced apart state. The number to be installed is preferably determined in consideration of the thickness and length of the support bar and the thickness and width of the filler 30 to be described later. As shown in Figure 4a, the support bar may be made of a Z bar that is widely used in the industry. The support bar 20 may be fixedly coupled to the fixed bar b together with the base panel 10 by a fastening means such as a bolt.

The filler 30 is a part that performs insulation and sound absorption in the roof panel according to the present invention, and fills the space partitioned by the support bar 10 as shown in FIG. 4A. The filler may be arbitrarily selected from materials well known in the related art, and its thickness and width may be variously changed according to the characteristics and structure of the building.

The first guide rail 40 is a rail on which the solar cell module 70 and the working plate 80 are mounted and supported, and at the same time, guides the flow of rain water. The first guide rail 40 may be formed of a plurality (n) spaced apart from each other by a predetermined interval, and is fixed to the support bar 20, as shown in Figure 4b is installed above the filler 30 . The first guide rail is preferably arranged in a direction perpendicular to the support bar.

On the other hand, in the present invention, as shown in the drawings, the first guide rail 40 has a left and right horizontal ends (415, 417) is provided on the upper and the center support wall 41, and the left and right of the central support wall 41; It is proposed that the case is formed to include a first drainage wall (43, 45) is provided on each upper end is provided with a settled end (435, 455). First drain paths 433 and 453 are formed between the central support wall and the first drain wall by the first drain walls 43 and 45, respectively.

Each of the left and right horizontal ends 415 and 417 is a portion in which the end of the solar cell module 70 or the end of the working plate 80 is supported. Each of the settled ends 435 and 455 is a portion in which an end of the second guide rail 50 to be described below is mounted and supported. Each of the first drainage channels 433 and 453 induces a flow when rainwater flows through an end of the solar cell module 70 or an end of the working plate 80 and each of the second guide rails 50. It acts as a drainage path.

In addition, the present invention does not exclude a case in which the second drain walls 47 and 49 protruding perpendicularly to one side of the first drain walls 43 and 45 are provided. Second drainage passages 473 and 493 are formed between the first drainage wall and the second drainage wall by the second drainage walls 47 and 49. In each of the second drainage channels 473 and 493, rainwater overflows the space of the first drainage channels 433 and 453, or rainwater flowing through the end of the solar cell module 70 or the end of the working plate 80 is formed. It is an auxiliary drainage route in case it is not guided by 1 drainage.

Unexplained reference numerals 3 and 5 are water leakage preventing members through the ends of the solar cell modules 70 mounted on the left and right horizontal ends 415 and 417, respectively, in opposing states. The cover for sealing the upper portion of the preventing member 5, and reference numeral 416 is a through hole through which the fastening means for pressing and fixing the leak preventing member (3, 5) and the cover (7).

Furthermore, the present invention does not exclude the case where the water leakage prevention rail is provided under the first guide rail 40. The leakage preventing rail is to prevent leakage through the connection portion of the unit first guide rail having a predetermined length. The water leak-proof rail 1 is located above the support bar 20 and is disposed in the longitudinal direction of the first guide rail 40, and it is preferable that both ends are bent in the vertical direction as shown in FIG. 4B. . 4B, insertion grooves (not shown) are formed in the second drainage walls 47 and 49 of the first guide rail 40, and each bent portion of the leakage preventing rail 1 is inserted into the insertion grooves. The configuration is disclosed, the insertion groove may alternatively be formed in the first drain wall (43, 45).

The second guide rail 50 is a rail on which one end of the solar cell module 70 is mounted and supported, and similarly to the first guide rail 40 described above, the second guide rail 50 simultaneously guides the flow of rain water. The second guide rails 50 are formed of a plurality of spaced apart from each other by a predetermined interval and each end is preferably fixed to one side of the adjacent first guide rail 40, the first guide rail 40 A) is composed of a plurality of n guide rails, and (1, 2, 3), (4, 5, 6),. . and (n-2, n-1, n) guide rails are fixedly coupled to each side of the first guide rails facing each other.
That is, in the first guide rail pair consisting of (1, 2, 3), it is fixedly installed between (1, 2) and (2, 3), and is attached to the first guide rail pair consisting of (4, 5, 6). In this case, it is fixedly installed between (4, 5) and (5, 6). . In the first pair of guide rails consisting of (n-2, n-1, n), it is fixedly installed between (n-2, n-1) and (n-1, n). According to this combination, each inner space formed by the pair of first guide rails is divided into a plurality. In FIG. 1, n first guide rails (1, 2, 3), (4, 5, 6),. . , divided into (n-2, n-1, n) pairs, and a plurality of second guide rails 50 coupled to each of the pair of first guide rails 40 are disclosed to divide a space. . Attached 4b also shows a construction diagram assuming this coupling configuration.
However, the spatial division using the first guide rail combination may be determined in consideration of the structure and size of the building and the size of the solar cell module to be described later. That is, the second guide rails are fixedly coupled to each side of the first guide rails facing each other in the pair so that the second guide rails are mutually opposed and adjacent to each other. will be.

According to the present invention, the second guide rail 50 has a central support wall 52 having left and right horizontal ends 525 and 527 formed thereon, and a settled end 565 and 585 formed at each top thereof. The case where the drainage walls 56 and 58 which protrude perpendicularly from left and right with respect to the wall 52 is provided. Each of the left and right horizontal ends 525 and 527 is a portion where the end of the solar cell module 70 is mounted. The drainage passages 563 and 583 are formed between the central support wall and the drainage wall by the drainage walls 56 and 58 protruding vertically.

In the case where the second guide rail 50 is configured as described above, when both ends of the second guide rail 50 are mounted on the settled ends 435 and 455 of the first guide rail 40, the drainage guideway The drainage passages 563 and 583 which act as the first drainage passages 433 and 583 communicate with any one of the first drainage passages 433 and 453 of the first guide rail 40. That is, rainwater introduced through one end portion of the solar cell module 70 is led to the drainage passages 563 and 583 of the second guide rail 50 and then to the first drainage passages 433 and 533 of the first guide rail 40. ) Is discharged to the outside.

The solar cell module 70 is a device for converting sunlight incident to the roof of the building into electrical energy, a plurality of solar cells, wires for electrically connecting the solar cells as known in the art, and It may be made of a film or a protective glass to protect the solar cells from the external environment, detailed description thereof will be omitted.

In installing the solar cell module 70, it is preferable that a predetermined interval is formed between the solar cell module 70 and the filler 30. In addition, the solar cell module 70 may be mounted in a plurality of spaces partitioned by the first guide rail 40 and the second guide rail 50 by the finishing frame 72. The plurality of spaces in which the solar cell module is mounted may be formed in any one of the above-described configurations formed by the combination of the first guide rail 40 and the second guide rail 50. At this time, each end 74 of the finishing frame 72, as shown in Figure 4b, any one of the left and right locking end (415, 417) of the first guide rail 40, and the second guide rail 50 It is mounted on any one of the left and right horizontal ends 525 and 527. Finishing frame for mounting the solar cell module 70 is a configuration that can be applied in a variety of changes different from that shown in the drawings.

As described above, the present invention uses a method of mounting each solar cell module on a first guide rail and a second guide rail that vertically connect each solar cell module to each other in order to use a plurality of solar cell modules as a roof finishing material. It can respond appropriately to harsh external environments such as strong winds and snowfalls. In addition, the first guide rail and the second guide rail supporting each solar cell module communicate with each other to induce rainwater flowing through the connection part of the solar cell module to drain the inside of the building fundamentally. have. In addition, the present invention forms a space of a predetermined interval between the solar cell module and the filler material, the heat generated according to the operation of the solar cell module can be easily discharged to the outside.

In addition, as described above, the present invention does not exclude a case where the end portion of the solar cell module is mounted and supported is isolated from the outside by using a leakage preventing member and a cover. At this time, the leak-proof member may be interposed between any one or both selected between the left and right horizontal ends (415, 417) and the end 74 of the finishing frame, and the top of the end 74 of the finishing frame, Each end 74 portion of the mutually opposite finishing frame can be closed as a lid 7.

The third guide rail 60 is a rail on which each end 82 of the working plate 80 is mounted and supported. The third guide rail 60, like the aforementioned first and second guide rails 40 and 50, simultaneously guides the flow of rainwater. There is a characteristic to. The third guide rail 60 is formed in a pair of opposite to each other, it is preferable to be installed in parallel to each of the adjacent first guide rails 40. As described above, a case where n first guide rails 40 are formed will be described.
First, the first guide rail 40 is composed of n, and the second guide rail 50 is opposed to each other among the n first guide rails 40 and adjacent to (1, 2, 3), (4, 5, 6),. . , when combined with each pair of (n-2, n-1, n), the third guide rail 60 is (3, 4),. . , (n-3, n-2) It is preferable to be provided in parallel with the first guide rail in a state in contact with each of the first guide rail 40 of each pair. In FIG. 1, an example of a coupling configuration of such a third guide rail is disclosed. However, the specific coupling configuration of the third guide rail is determined in consideration of the structure of the building, the size of the solar cell module, the width and the length of the working plate to be described later, as in the case of the second guide rail 50 described above. It's work.
5A is a detailed construction diagram of such a configuration, when the filler 30 is filled between the support bars 20, and then the first guide rail 40 and the second guide rail 50 are installed in sequence, A configuration is provided in which a third guide rail 60 is provided in each of the first guide rails 40 facing each other. Obviously, the previous step of FIG. 5A is identical to the construction step disclosed in FIG. 4A.

In the present invention, the third guide rail 60 may include a support end 612, a horizontal end 614 formed on the support end 612, and an extension formed on the support end 612. The case which consists of stage 61 is proposed. In this case, the third guide rail is placed on the upper ends of the settled ends 435 and 455 of the first guide rail 40 using the extension end 61, and the end 82 of the working plate 80 is mounted to allow the third guide rail to be mounted thereon. The load acting on the plate 614 is supported by the support end 612.

Unexplained reference numeral 618 may be an end portion which is bent upward and protrudes on one side as a drain induction end. The protruding end is configured for engagement with any one selected from the left and right horizontal ends 415 and 417 of the first guide rail 40, and the rainwater flowing through the coupling site acts as a drainage guide. It is discharged to the outside through the space of the drain induction stage to prevent leakage into the interior of the building. The specific configuration of the drainage induction stage is not limited to this form and may be variously applied in various ways.

The working plate 80 is a passage through which the worker moves when it is necessary to repair or replace the solar cell module after the roof panel according to the present invention is completed. Both ends of the working plate 80 are coupled to an upper portion of the third guide rail 60 to seal a space between adjacent third guide rails 60. For example, (3, 4) out of n said first guide rails 40. . , (n-3, n-2) is coupled to the upper portion of the third guide rail 60 provided in the first guide rail 40 of each pair. Accordingly, the space in which the solar cell module 70 is not mounted is completely sealed by the working plate 80. It is preferable that the working plate 80 is made of a material capable of supporting a constant load such as metal.

The working plate according to the present invention is preferably disposed between a plurality of solar cell modules because the purpose is to repair and replace the solar cell module. The drawings disclose a configuration in which a working plate is disposed in a space between two rows of solar cell modules, but this is merely an example and may be configured in various various combinations. However, it will be necessary to consider whether the work is easy when determining the layout of the working plate.

On the other hand, the present invention does not exclude that the support member 90 is filled in the lower space of the drawing work plate 80. The support member 90 is a means for preventing the working plate 80 from being deformed due to the weight of the worker. At the same time, the support member 90 may function as an insulation and sound absorbing body in the lower space of the working plate 80. The support material can be arbitrarily selected from a variety of materials exhibiting heat insulation and sound absorption functions. 5B shows the schematic construction of the working plate 80 in the case where the support material 90 is mediated.

As in the case of the solar cell module 70 described above, the end portion of the working plate 80 mounted on the upper part of the first guide rail 40 may be sealed using a leak preventing member. In the drawings, reference numerals 2 and 4 are respectively prevented from leaking through the respective ends of the solar cell module 70 and the working plate 80 mounted on the left and right horizontal ends 415 and 417, respectively. Reference numeral 6 is a cover for sealing the top of the leak-proof member (4).

As described above, the present invention provides a case in which a repair or replacement of the solar cell module is required after construction by mediating the working plate between the solar cell modules, and in addition to this, suggesting a configuration in which the support material is filled in the lower part of the working plate. Of course, it is expected that the additional insulation and sound absorption effect of the support material as well as the deformation prevention of the.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be apparent that the present invention can be practiced with added features.

1: fixing bar 10: base panel
20: support bar 30: filler
40: first guide rail 50: second guide rail
60: third guide rail 70: solar cell module
80: working board

Claims (8)

A base panel 10 fixed to an upper portion of the fixing bar (b) installed spaced apart from each other;
A plurality of support bars 20 installed on the base panel 10 at predetermined intervals from each other;
Filler 30 is filled in the space between the support bar 20;
N first guide rails 40 which are spaced apart from each other by a predetermined interval and are fixed at right angles to the support bar 20 and are installed on the filler 30;
(1, 2, 3), (4, 5, 6), which are installed adjacent to each other among the n first guide rails (40). . , (n-2, n-1, n) is fixedly installed to divide each inner space formed by each pair, and in the (1, 2, 3) pairs (1, 2) and (2, 3) ) Is fixedly installed between the (4, 5, 6) pair is fixed between (4, 5) and (5, 6). . In the (n-2, n-1, n) pair, a plurality of second guide rails 50 fixedly installed between (n-2, n-1) and (n-1, n);
(3, 4), which are installed adjacent to each other among the n first guide rails (40). . (n-3, n-2) third guide rails 60 installed in parallel with each other in contact with each pair of first guide rails;
(1, 2, 3), (4, 5, 6), among the n first guide rails 40. . and (n-2, n-1, n) a plurality of solar cell modules 70 for enclosing each space partitioned by second guide rails 50 coupled to each pair;
(3, 4) out of the n first guide rails 40; . (n-3, n-2) Both ends of the third guide rail 60 installed in parallel and in contact with each pair of first guide rails are coupled to each other so that the solar cell module 70 is not mounted. Work plate 80 for sealing the unopened space;
Roof panel using a solar cell module, characterized in that made as a finishing material. The method of claim 1,
The first guide rail 40 has a central support wall 41 with horizontal left and right horizontal ends 415 and 417 formed at an upper portion thereof, and protrudes vertically to the left and right with respect to the central support wall 41. Forming the first drainage channels (433, 453) in the interspace, each upper end of the solar cell module characterized in that it comprises a first drainage wall (43, 45) is provided with a settled end (435, 455) Roof panel used as 3. The method of claim 2,
On one side of each of the first drainage wall (43, 45) is characterized in that it is provided with a second drainage wall (47, 49) protruding vertically to form the second drainage (473, 493) in the space therebetween Roof panel that uses battery module as finishing material. The method of claim 3,
The roof panel using the solar cell module as a finishing material, characterized in that the leak-proof rail (1) is bent at both ends vertically beneath the first guide rail (40). 3. The method of claim 2,
The second guide rail 50 has a central support wall 52 having left and right horizontal ends 525 and 527 at an upper portion thereof, and protrudes vertically to the left and right with respect to the central support wall 52. In the interspace, drainage passages 563 and 583 communicating with the first drainage passages 433 and 435 of the first guide rail 40 are formed, respectively, and the drainage walls 56 having upper and lower ends 565 and 585 are provided. 58) Roof panel using a solar cell module, characterized in that consisting of the finishing material. 3. The method of claim 2,
The third guide rail 60 includes a support end 612, a horizontal end 614 provided on an upper portion of the support end 612, and in close contact with a bottom surface of the working plate 80, and the support end 612. The roof panel using a solar cell module as a finishing material, characterized in that the lower end is provided on the lower end (61, 455) of the extension end 61 is provided on the upper end of the settle end (435, 455). The method of claim 1,
The roof panel using the solar cell module as a finishing material, characterized in that the support member 90 is filled in the lower space of the working plate (80). The method of claim 1,
Roof panel using a solar cell module as a finishing material, characterized in that a space of a predetermined interval is formed between the solar cell module 70 and the filler (30).

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