KR102467930B1 - A Building-integrated photovoltaic power generation system and method for its construction - Google Patents

Abstract

A photovoltaic power generation system integrated with a building, according to the present invention, comprises: a base panel unit including a lower panel and an upper panel seated on an upper end of a building to constitute a roof and a connection structure connecting the lower panel with the upper panel; at least one panel-shaped photovoltaic power generation module provided to carry out photovoltaic power generation; and a connection unit which is fastened to an upper end of the base panel unit and provided to support the photovoltaic power generation module. The connection unit includes: at least one pair of fastening blocks provided to support the photovoltaic power generation module; at least one pair of fastening guide members seated on an upper surface of the base panel unit and provided to guide positions of the fastening blocks; and a drainage guide member which is disposed on a lower end of the photovoltaic power generation module and provided to collect water flowing in from the outside and discharge the collected water to the outside of the building. According to the present invention, it is possible to prevent the drainage guide member from sagging.

Description

A Building-integrated photovoltaic power generation system and method for its construction}

The present invention relates to a building-integrated photovoltaic power generation system and a construction method thereof, and more particularly, to prevent a phenomenon in which rainwater from outside penetrates through a roof of a building and leaks, while maintaining improved ease of construction, It relates to a building-integrated photovoltaic power generation system capable of monitoring the operation status during operation of the power generation system and a construction method thereof.

The electricity production method using solar panels is in the limelight as a new energy source, but since solar panels require a considerable area for installation, it is burdensome to install while damaging farmland or forests. Even when installed in the form of covering the upper part, desired power generation is achieved while minimizing damage to the natural environment, while solar panels are installed on the roof to avoid restrictions in the installation location.

The method of installing a solar panel on an open or closed roof is to install a separate structure on the upper side of the roof to fix the solar panel. After fixing the frame to the upper side of the roof, solar panels are installed using the frame.

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, a method that is currently being widely studied is a building integrated solar power generation roof (Building Integrated Photovoltaic Power Generation Roof) in which the solar cell module itself constitutes the roof of the building. Photovoltaic, BIPV). This method has an advantage in that the roof of the building itself is composed of a solar cell module assembly, so that the cost for roof construction can be reduced and the exterior of the building can be maintained as originally intended.

However, in the case of the building-integrated solar power generation roof, rainwater penetrating through gaps formed between the solar panels flows directly into the lower part of the solar panel, and rainwater flowing into the lower part of the solar panel penetrates into the interior of the building As such problems still exist, a solution to the above problems is required.

In addition, in the construction of the conventional building-integrated photovoltaic power generation roof, it is configured to proceed with bolting for each part through a separate bolt member in order to proceed with solid fastening of each part, not only construction but also maintenance There is also a problem that requires a lot of work time in progress.

KR 10-1405555 B1 (2014.06.02) 'Building Integrated Photovoltaic Exterior Structure'

The present invention was created to solve the above-mentioned problems, and more specifically, while preventing external rainwater flowing in between gaps in photovoltaic modules from flowing directly along the roof surface of the building, the leakage caused by the rainwater It is intended to provide a building-integrated photovoltaic power generation system that can be minimized and a construction method thereof.

In addition, by combining each part mainly in a fit-to-fit combination method, it is possible to proceed with simpler parts fastening, so that compared to the conventional building-integrated solar power generation roof, building-integrated solar power generation with remarkably excellent workability and high maintenance efficiency It is an object to provide a system and its construction method.

A building-integrated photovoltaic power generation system according to the present invention includes a base panel portion including a lower panel and an upper panel that are seated on top of a building to form a roof and a connection structure connecting the lower panel and the upper panel; At least one photovoltaic module having a panel shape and provided to generate photovoltaic power; and a connection part fastened to an upper end of the base panel part and provided to support the photovoltaic module, wherein the connection part includes: at least one pair of fastening blocks provided to support the photovoltaic module; at least one pair of fastening guide members seated on an upper surface of the base panel unit and provided to guide a position of the fastening block; and a drainage guide member disposed at a lower end of the photovoltaic module to collect water flowing in from the outside and discharge it toward the outside of the building.

More specifically, at least one of the fastening blocks is provided so as to be slid and coupled to the fastening guide member, and the drain guide member is provided to be seated on the fastening block or the upper part of the base panel unit, and extends a predetermined length. At least one main drainage guide member formed; and at least one auxiliary drainage guide member coupled to the fastening block, extending a predetermined length, collecting water introduced from the outside and discharging it toward the main drainage guide member.

More specifically, the main drainage guide member is disposed between a pair of fastening blocks disposed to face each other, and both side ends are supported by the fastening guide member, and the auxiliary drainage guide member is Disposed at the upper end of the main drainage guide member, provided to extend in a direction transverse to the extension direction of the main drainage guide member, characterized in that the end is provided to be disposed within the main drainage guide member formation area.

More specifically, the auxiliary drainage guide member is disposed at the lower end of an area where a plurality of photovoltaic modules come into contact with each other, collects water flowing between the plurality of photovoltaic modules, and guides it to the main drainage guide member. It is characterized in that it is formed to.

More specifically, the fastening block includes an auxiliary drainage guide member fastening groove provided so that both ends of the auxiliary drainage guide member are inserted and fastened; a drainage guide member mounting portion formed to seat the auxiliary drainage guide member; and a photovoltaic module coupling groove formed at an upper end of the auxiliary drainage guide member coupling groove and into which an end portion of the photovoltaic module is inserted.

More specifically, the fastening block is characterized in that the fastening block is provided to support the corner of the photovoltaic module.

More specifically, the fastening block is characterized in that the fastening block is provided so as to be mutually divisible, and the fastening body includes: a first fastening body including a block fastening groove formed at a lower end of a predetermined depth; And a second fastening body provided to be separable from the first fastening body, formed to be formed to be fitted with the block fastening groove, and having a block fastener having a shape corresponding to the shape of the block fastening groove; It is characterized in that it includes.

More specifically, the fastening guide members are each installed at mutually symmetrical positions with respect to the main drainage guide member, and the fastening blocks have at least one fastening block installed on different fastening guide members. In this case, it is characterized in that the fastening blocks installed on the other fastening guide member face each other while being adjacent to the fastening block installed on one fastening guide member.

More specifically, the connection unit may further include at least one spacer member provided at a lower end of the main drainage guide member to prevent sagging of the main drainage guide member.

More specifically, at least one or more of the spacer members are disposed while maintaining a predetermined interval along the extension direction of the main drainage guide member, and the side end is fastened to the fastening guide member in a shape-fitting manner. .

In addition, the building-integrated photovoltaic power generation system of the present invention includes an inverter module assembly including at least one inverter module provided to convert the power generated in direct current through the photovoltaic module into alternating current and provide the power to a place of use; It is communicatively connected with the inverter module assembly to generate at least one generation amount monitoring information that is information representing the amount of power generated through the photovoltaic power generation module, and when the amount of power generation in the amount of power generation monitoring information is less than a preset standard amount of power generation, an abnormal situation a service server provided to generate alarm information notifying that it is; and a user terminal configured to be communicatively connected to the service server and output at least one or more pieces of information selected from among the power amount monitoring information and the alarm information.

More specifically, the photovoltaic assembly is installed so that at least one photovoltaic module is grouped by section having an arbitrary area, and the inverter module includes at least one photovoltaic module forming one group. While being connected to, it is provided to classify and collect the amount of power generation acquired through the photovoltaic power generation module by the group unit, and the service server monitors the monitoring information based on the amount of power generation of the photovoltaic power generation module collected in the group unit It is characterized in that it is provided to generate at least one or more and provide them to the user terminal.

More specifically, the user terminal is provided with the monitoring information, and based on the monitoring information, it is characterized in that it is provided to generate and output a monitoring screen representing the amount of power generation of the photovoltaic modules grouped by section.

And, in the construction method of the building-integrated photovoltaic power generation system including a building-integrated photovoltaic power generation system including a photovoltaic module according to the present invention, the construction method is seated on the top of the building to cover the roof. a roof structure forming step of forming a roof structure of a building through a constituting base panel; After the roof structure forming step, assembling a fastening guide member for determining a location of a drain guide member formed to collect water introduced from the outside on an upper end of the base panel unit; After the fastening guide member assembling step, a main drainage guide member coupling step of seating and fastening the main drainage guide member constituting the drain guide member to an upper end of the fastening guide member; After the main drainage guide member coupling step, a fastening block coupling step in which an fastening block provided to support the photovoltaic module is slid along the fastening guide member to be inserted into and fastened to the fastening guide member; an auxiliary drainage guide member coupling step of fitting and coupling an auxiliary drainage guide member constituting the drainage guide member to the fastening block while the fastening block coupling step proceeds; After the step of assembling the auxiliary drainage guide member, a photovoltaic module coupling step of fitting and coupling the photovoltaic module to the fastening block; characterized in that it comprises a.

More specifically, at least one of the fastening blocks is provided to be coupled to each other by sliding on the fastening guide member, and fastening bodies constituting the fastening block are provided to be mutually divisible, and the fastening bodies are provided at the lower end. A first fastening body including a block fastening groove formed to a predetermined depth; And a second fastening body provided to be separable from the first fastening body, formed to enable a shape fit with the block fastening groove, and having a block fastener having a shape corresponding to the shape of the block fastening groove; Including, the coupling block coupling step, the first coupling step of inserting the first coupling body into the coupling guide member to slide and then fastening at an arbitrary position through a separate coupling member; and after the first coupling step, inserting the second coupling body into the coupling guide member to slide and move the coupling body, and then shape-fitting the second coupling body to the first coupling body coupled with the coupling guide member. It is characterized in that it includes; a second combining step of combining in a customized manner.

More specifically, in the assembling of the coupling guide members, a spacer member provided to support the drain guide member from below is coupled with the pair of coupling guide members while maintaining a distance between the pair of coupling guide members. It is characterized by progressing to

A building-integrated photovoltaic power generation system and a construction method thereof according to the present invention include a drainage guide member to guide rainwater flowing in from the outside toward the drainage guide member and to prevent rainwater from penetrating under the roof. It can be discharged by guiding it in the direction, so it can secure more improved waterproof performance.

In addition, by providing not only the main drainage guide member but also the auxiliary drainage guide member, rainwater flowing in from the outside is guided toward the drainage guide member, and guided toward the outside of the photovoltaic module to prevent rainwater from penetrating under the roof and discharged. This can ensure better waterproofing performance.

In addition, it is possible to provide more improved construction convenience by performing simple fitting through the fastening block to fasten and support the drainage guide member and the photovoltaic module.

In addition, the effect of maintaining high drainage performance by preventing the sagging of the main drainage guide member extending a predetermined length through the spacer member so that the rainwater does not accumulate in a specific area when rainwater is collected. can provide

And, it is possible to provide an effect capable of preventing sagging of the main drainage guide member while proceeding with simpler construction through a spacer member fastened in a form-fitting coupling method.

In addition, by allowing the amount of power generated through the photovoltaic power generation module to be monitored from a remote location, it is possible to more easily grasp the amount of power generated by the photovoltaic power generation module and assist in responding more quickly when a problem occurs.

In addition, by collecting the amount of power generation of the photovoltaic module in a group unit to generate monitoring information and provide it to the user terminal, it is possible to more intuitively provide related information to the user, thereby providing improved usability.

1 is a perspective view showing a building-integrated photovoltaic power generation system of the present invention.
Figure 2 is a perspective view showing a state in which some areas of the building-integrated photovoltaic power generation system of the present invention are disassembled.
FIG. 3 is an enlarged view illustrating area I of FIG. 2 .
4 is a plan view showing the building-integrated photovoltaic power generation system of the present invention from above.
5 is a plan view illustrating a state in which a photovoltaic module is separated from a building-integrated photovoltaic power generation system according to the present invention.
6 is an enlarged perspective view of a connecting portion of a building-integrated photovoltaic power generation system according to the present invention.
7 is a front view showing the front of the building-integrated photovoltaic power generation system of the present invention.
FIG. 8 is an enlarged view illustrating area G of FIG. 8 .
9 is a side view showing the front of the building-integrated photovoltaic power generation system of the present invention.
FIG. 10 is an enlarged view of area H of FIG. 10 .
11 is a perspective view showing a state in which fastening blocks constituting the building-integrated photovoltaic power generation system of the present invention are separated.
12 is a perspective view showing a state in which fastening blocks constituting the building-integrated photovoltaic power generation system of the present invention are coupled.
FIG. 13 is a cross-sectional view showing a cross section taken along the EF region of FIG. 1 in the longitudinal direction.
14 is a schematic configuration diagram of a building-integrated photovoltaic power generation system according to an additional embodiment of the present invention.
15 is a use state diagram illustrating a monitoring screen output through a user terminal constituting a building-integrated photovoltaic power generation system according to an additional embodiment of the present invention.
FIG. 16 is a block flow chart showing the progress sequence of the construction method of the building-integrated photovoltaic power generation system according to the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below and can be implemented in various different forms, only these embodiments are intended to complete the disclosure of the present invention, and are common in the art to which the present invention belongs. It is provided to fully inform the knowledgeable person of the scope of the invention, and the invention is only defined by the scope of the claims.

Also, terms used in this specification are for describing the embodiments and are not intended to limit the present invention.

In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. As used herein, "comprises" and/or "comprising" does not exclude the presence or addition of other components than the recited components.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used in a meaning commonly understood by those of ordinary skill in the art to which the present invention belongs.

First, with reference to FIGS. 1 to 5, the building-integrated photovoltaic power generation system of the present invention will be described in more detail.

1 is a perspective view showing a building-integrated photovoltaic power generation system of the present invention, FIG. 2 is a perspective view showing a partially disassembled state of the building-integrated photovoltaic power generation system of the present invention, and FIG. 3 is I of FIG. 4 is a plan view showing the building-integrated photovoltaic power generation system of the present invention from the top, and FIG. 5 is a state in which the photovoltaic power generation module is separated from the building-integrated photovoltaic power generation system of the present invention. It is a plan view showing

As shown in FIGS. 1 to 5 , the building-integrated solar power generation system of the present invention includes a base panel unit 100 , a solar power module 200 and a connection unit 300 .

First, the base panel unit 100 is provided to form a roof by being seated on the top of a building, and includes a lower panel 110, an upper panel 120, and a connection structure 160.

The lower panel 110 is supported by a rigid body 1 having a predetermined shape constituting a building, and at least one connection structure 160 may be seated on an upper portion of the lower panel 110 . In addition, the upper panel 120 is seated on top of the connection structure 130, and the installation angles 140 for supporting the upper panel 120 intersect with each other to be installed on top of the connection structure 160. can

In addition, as shown, the lower panel 110 may be perforated to improve sound absorption performance.

In addition, in the space formed between the lower panel 110 and the installation angle 140 by the connection structure 160, the structure does not change in case of fire, a predetermined strength is maintained, and fire resistance is provided by providing a non-combustible property. A fireproof member 150 having a predetermined thickness to secure may be filled.

Also, before installing the upper panel 120 , a waterproof sheet 160 having a predetermined area may be provided to prevent moisture from penetrating under the base panel unit 100 .

Next, the solar power module 200 has a panel shape and is provided to generate solar power, and at least one or more are provided to be supported by the connection part 300 to be described later.

In addition, the connection part 300 is provided to support and fix the photovoltaic module 200, and at least one is provided, and between the base panel part 100 and the photovoltaic module 200 It is characterized in that provided in.

More specifically, the connection part 300 may include a fastening block 310, a fastening guide member 320, and a drainage guide member 330.

The fastening block 310 is provided to support the photovoltaic module, and at least one pair is provided.

In addition, at least one or more of the fastening blocks 310 are coupled to each other by sliding on the fastening guide member, and the fastening block 310 will be described in more detail below.

In addition, the fastening guide member 320 is provided to determine the position of the fastening block 310 and the position of the drainage guide member 330 to be described later, and is seated on the upper surface of the base panel unit 100. It is provided to guide the positions of the fastening block 310 and the drainage guide member 330.

At this time, the fastening guide member 320 may extend from one end of the upper surface of the base panel unit 100 to the other end, and may be provided in a bar shape having a groove of a predetermined depth.

In addition, at least one pair of coupling guide members 320 are disposed to be spaced apart from each other by a predetermined distance, and the main drainage guide of the drainage guide member 330 to be described later is placed on the space formed by the pair of coupling guide members 320. The member 331 may be provided to be seated.

In addition, the drain guide member 330 is disposed at the lower end of the photovoltaic module 200 to collect water introduced from the outside and discharge it toward the outside of the building.

Here, the drainage guide member 330 may include a main drainage guide member 331 and an auxiliary drainage guide member 332 .

In particular, the main drainage guide member 331 is provided to be seated on the fastening block or the upper part of the base panel part, and is formed to extend a predetermined length.

In addition, the main drainage guide member 331 is disposed between a pair of fastening blocks 310 disposed to face each other, and both side ends are supported by the fastening guide member 320.

At this time, the fastening guide member 320 may be installed at mutually symmetrical positions based on the main drainage guide member 331.

In addition, at least one auxiliary drainage guide member 332 is provided, is coupled to the fastening block, extends a predetermined length, and is provided to collect water introduced from the outside and discharge it toward the main drainage guide member. .

In particular, the auxiliary drainage guide member 332 is provided to extend in a direction transverse to the extension direction of the main drainage guide member 332 while being disposed on the upper end of the main drainage guide member 332 .

In addition, the auxiliary drainage guide member 332 is disposed at the lower end of an area where the plurality of photovoltaic modules 200 come into contact with each other, and collects water introduced between the plurality of photovoltaic modules 200 to collect the main water. It is formed to lead to the drainage guide member 331.

At this time, one end of the auxiliary drainage guide member 332 is provided to be disposed within the main drainage guide member formation area so that the water collected along the auxiliary drainage guide member 332 can flow toward the main drainage guide member 331. there will be

As described above, by providing the auxiliary drainage guide member 332 as well as the main drainage guide member 331, rainwater flowing in from the outside is guided toward the drainage guide member 330, and rainwater flows under the roof. It can be discharged by guiding it toward the outside of the photovoltaic module 200 so as not to penetrate toward the outside, so that more improved waterproof performance can be secured.

In addition, the building-integrated photovoltaic power generation system may be provided with a cover body (V) along an extended area of the main drainage guide member 331 while being seated on an upper end of the fastening block 310 .

In particular, through the cover body (V), foreign matter introduced from the outside is deposited on the side of the main drainage guide member to block the drain formed based on the main drainage guide member 331 to prevent a phenomenon in which waterproof performance is lowered. can do.

At this time, although not particularly shown in the drawing, a plurality of heat dissipation holes may be additionally formed to dissipate heat generated when the photovoltaic module 200 is operated through the cover body (V).

Next, with reference to FIGS. 6 to 10 , the connection unit 300 constituting the building-integrated photovoltaic power generation system of the present invention will be described in more detail.

6 is a perspective view showing an enlarged connection of the building-integrated solar power generation system of the present invention, FIG. 7 is a front view showing the front of the building-integrated solar power generation system of the present invention, and FIG. 8 is a section G of FIG. 9 is a side view showing the front of the building-integrated photovoltaic power generation system of the present invention, and FIG. 10 is an enlarged view showing area H of FIG. 9 .

As shown in FIG. 6, the connection part 300 is provided to support and fix the photovoltaic module 200, and at least one is provided, and the base panel part ( 100) and the photovoltaic module 200, and may include a fastening block 310, fastening guide member 320, and drainage guide member 330.

In particular, while determining the positions of the fastening block 310 and the drainage guide member 330 through the fastening guide member 320, the fastening block is slidably fastened so that it can be aligned in a more accurate position. constructability can be provided.

In addition, the coupling block 310 slidingly coupled to the coupling guide member 320 is any one coupling guide member when at least one coupling block 310 is installed in each other coupling guide member 320. It is characterized in that it is disposed to face each other with the fastening block 310 installed on the other fastening guide member 320 while being in a position adjacent to the fastening block 310 installed in the state 320.

At this time, when the fastening blocks 310 are installed on the same fastening guide member 320, each fastening block 310 is installed to have the same distance from each other, and by proceeding with the above-described arrangement, the fastening Blocks 310 support each corner of the photovoltaic module 200 .

In addition, at least one spacer member 340 may be coupled in a shape-fitting manner between the pair of coupling guide members 320 spaced apart by a predetermined distance.

More specifically, at least one of the spacer members 340 is disposed while maintaining a predetermined interval along the extension direction of the main drainage guide member 331, and both ends are shaped with the fastening guide members 320. It is fastened by the fitting method.

In this way, through the spacer member 340 fastened in a form-fitting manner, it is possible to provide an effect of preventing sagging of the main drainage guide member 331 while performing simpler construction.

Next, with reference to FIGS. 11 and 12, the fastening block constituting the building-integrated photovoltaic power generation system of the present invention will be described in more detail.

11 is a perspective view showing a state in which the fastening blocks constituting the building-integrated photovoltaic power generation system of the present invention are separated, and FIG. 12 shows a state in which the fastening blocks constituting the building-integrated solar power generation system of the present invention are coupled. It is a perspective view.

As shown in FIGS. 11 and 12, the fastening block 310 includes a fastening body 311, an auxiliary drainage guide member fastening groove 312, a drainage guide member mounting portion 313, and a photovoltaic module fastening groove ( 314) and a photovoltaic module mounting portion 315.

First, the fastening body 311 is provided to be mutually divisible, and may be provided to have a shape extending a predetermined height toward the top.

In particular, the fastening body 311 may include a first fastening body 311a and a second fastening body 311b.

Here, the first fastening body 311a has a block fastening groove bg formed at a predetermined depth at the lower end.

At this time, at least one pair of block fastening grooves (bg) may be formed at a predetermined depth on both side surfaces of the first fastening body 311a with the direction of extension of the drainage guide member seating part 313 as a central axis. have.

In addition, the block fastening grooves (bg) may be formed such that the pair is symmetrical to each other with respect to the extension direction of the drain guide member seating portion 313 as a central axis, and between the block fastening grooves (bg) by a predetermined thickness The area of the first fastening body 311a can be maintained.

In addition, the block fastening groove (bg) is formed at a position spaced apart from the lower end of the fastening body 311 upward by a predetermined distance so that the fastening body 311 can smoothly fasten with the fastening guide member described above. can

The second fastening body 311b is provided to be separable from the first fastening body, and is formed to enable a form-fitting connection with the block fastening groove bg, and corresponds to the shape of the block fastening groove bg. A block fastener (bp) having a shape is formed.

At this time, the block fasteners (bp) may be formed to correspond to the number of formations of the block fastening grooves (bg).

In addition, the block fastener (bp) is formed at a position spaced apart from the lower end of the coupling body 311 upward by a predetermined distance so that the coupling body 311 can be smoothly coupled with the coupling guide member described above. can

In addition, the auxiliary drainage guide member fastening groove 312 is provided so that both ends of the auxiliary drainage guide member are inserted and fastened, and is formed at a position spaced a predetermined distance from the lower end of the fastening body 311 toward the upper end. .

In addition, the drainage guide member seating portion 313 is formed to seat the auxiliary drainage guide member, and is formed at the lower end of the auxiliary drainage guide member fastening groove 312, so that the auxiliary drainage guide member fastening groove 312 It is formed to stably support the bottom surface of the auxiliary drainage guide member in a fitted state by.

In addition, the photovoltaic module fastening groove 314 is provided to proceed with the fastening of the photovoltaic module, and is formed at the upper end of the auxiliary drainage guide member fastening groove 312, and the photovoltaic module It is characterized in that the end is formed to be inserted.

In addition, although not particularly shown in the drawings, in order to maintain a more robust coupling state, it is formed on the inner wall surface of the photovoltaic module fastening groove and may further include a coupling force enhancing member made of an elastically deformable material.

In addition, the photovoltaic module mounting portion 315 is formed at the top of the fastening body to firmly support the lower surface of the photovoltaic module.

At this time, the photovoltaic module mounting portion 315 may be formed to be orthogonal to the extending direction of the drainage guide member mounting portion 313 .

In addition, although not particularly shown in the drawings, in order to couple the first fastening body 311a to the aforementioned fastening guide member, on the side of the drainage guide member seating part 313, the pair of block fastening grooves bg A separate screw member may be introduced to penetrate the space between them, and the fastening guide member and the screw member may be fastened so that the first fastening body 311a and the drainage guide member are more firmly coupled to each other.

Thereafter, the above-described second fastening body 311b and the first fastening body 311a are formed and mutually fastened by mutual fastening, thereby firmly coupling the auxiliary drainage guide member and simultaneously combining different photovoltaic modules. will make

As described above, by performing simple fitting through the fastening block 311 to fasten and support the drainage guide member and the photovoltaic module, it is possible to provide more improved construction convenience.

Next, with reference to FIG. 13, the spacer member constituting the connection part of the building-integrated photovoltaic power generation system of the present invention will be described in more detail.

FIG. 13 is a cross-sectional view showing a cross section cut in the longitudinal direction along the area E-F of FIG. 1;

As shown in FIG. 13, at least one spacer member 340 is disposed while maintaining a predetermined interval along the extension direction of the main drainage guide member 331.

At this time, by providing the spacer member 340, it is possible to prevent sagging of the main drainage guide member 331 disposed between the fastening guide members 320.

In this way, through the spacer member 340, the main drainage guide member 331 extending a predetermined length is prevented from drooping, so that when rainwater is collected, the rainwater does not accumulate in a specific area, so that the high It is possible to provide an effect capable of maintaining drainage performance.

Next, referring to FIG. 14, a building-integrated photovoltaic power generation system according to an additional embodiment of the present invention will be described in more detail.

14 is a schematic configuration diagram of a building-integrated photovoltaic power generation system according to an additional embodiment of the present invention.

As shown in FIG. 14, the building-integrated solar power generation system according to an additional embodiment of the present invention includes a base panel unit 100, a solar power module 200, a connection unit 300, and an inverter module assembly 400. , It is characterized in that it further includes a gateway 500, a service server 600 and a user terminal 700.

Prior to a detailed description of the base panel unit 100 and the connection unit 300, detailed descriptions of the base panel unit 100 and connection unit 300 will be omitted in order to avoid overlapping descriptions with those described above.

The photovoltaic module 200 is installed such that at least one photovoltaic module is grouped by section having an arbitrary area.

In addition, the inverter module assembly 400 includes at least one inverter module provided to convert the DC power generated through the photovoltaic module 200 described above into AC and provide the power to a place of use.

In addition, the inverter module may be connected to at least one photovoltaic module forming one group, and may be configured to classify and collect the amount of power generated through the photovoltaic module 200 by the group unit.

And, the gateway 500 is provided for communication connection between the inverter module assembly 400 and the service server 600.

And, the service server 600 is provided to be communicatively connected to the inverter module assembly 400 through the gateway 500 .

In addition, the service server 600 generates at least one piece of generation amount monitoring information, which is information indicating the amount of power generated through the photovoltaic power generation module 200 .

More specifically, the service server 600 is provided to generate at least one piece of monitoring information based on the amount of power generation of the photovoltaic module 200 collected in units of groups and provide the monitoring information to the user terminal 700. do.

In addition, the service server 600 is provided to generate alarm information indicating an abnormal situation when the generation amount of the generation amount monitoring information is less than a predetermined reference generation amount.

And, the user terminal 700 is connected to the service server 600 in communication and is provided to output at least one or more information selected from among the power amount monitoring information and the alarm information.

In this way, by allowing the amount of power generation generated through the photovoltaic power generation module 200 to be monitored from a remote location, the amount of power generation of the photovoltaic power generation module 200 can be grasped more easily, and through the coupling part having the above-described coupling structure Maintenance can be carried out more conveniently, and it can help to proceed with a quicker response when a problem occurs.

As described above, by collecting the amount of power generation of the photovoltaic module 200 in a group unit to generate monitoring information and providing it to the user terminal 700, it is possible to more intuitively provide related information to the user. , it is possible to provide more improved usability.

Next, referring to FIG. 15 , a monitoring screen MD output through a user terminal constituting a building-integrated photovoltaic power generation system according to an additional embodiment of the present invention will be described.

15 is a use state diagram illustrating a monitoring screen output through a user terminal constituting a building-integrated photovoltaic power generation system according to an additional embodiment of the present invention.

As shown in FIG. 15, the user terminal 700 receives the monitoring information, and based on the monitoring information, generates a monitoring screen (MD) indicating the amount of power generation of the photovoltaic module grouped by section, provided for output.

At this time, on the monitoring screen (MD), the contents of the collection of the amount of power generation of the photovoltaic module in group units are output so that the photovoltaic module is actually installed in the same shape, and a separate monitoring section is provided to indicate the amount of power generation for each group ( MS) can be formed and output.

At this time, when the amount of power generation of photovoltaic modules installed in a specific group and set in a certain area is lower than the average of the amount of power generation of photovoltaic modules set in other groups installed in other areas, the monitoring screen ( It can be constructed to output the above-described alarm information through an alarm section (AS) formed in the MD).

As described above, by collecting the generation amount of the photovoltaic module in a group unit to generate monitoring information and provide it to the user terminal, it is possible to more intuitively provide related information to the user, thereby providing more improved convenience of use. can

Next, with reference to FIG. 16, a construction method of the building-integrated photovoltaic power generation system according to the present invention will be described in more detail.

FIG. 16 is a block flow chart showing the progress sequence of the construction method of the building-integrated photovoltaic power generation system according to the present invention.

As shown in FIG. 16, the construction method of the building-integrated photovoltaic power generation system according to the present invention includes a roof structure forming step (S100), an assembly guide member assembly step (S200), a main drainage guide member coupling step (S300), It is characterized in that it includes a fastening block coupling step (S400), an auxiliary drainage guide member coupling step (S500), and a photovoltaic module coupling step (S600).

First, the roof structure forming step (S100) is a step of forming the roof structure of the building through a base panel portion seated on the upper end of the building and constituting the roof.

In addition, the assembling of the fastening guide member step (S200) is a step that proceeds after the roof structure forming step, and the fastening guide member for determining the location of the drain guide member formed to collect water flowing in from the outside at the top of the base panel part. is the stage of assembling.

In particular, in the assembling step of the coupling guide member (S200), a spacer member provided to support the drain guide member from below is coupled with the pair of coupling guide members while maintaining a distance between the pair of coupling guide members. is going on.

In addition, through the spacer member coupled in the fastening guide member assembling step (S200), the main drainage guide member coupled by extending a predetermined length in the main drainage guide member coupling step (S300) to be described later is prevented from sagging, When the collection of the rainwater is in progress, it is possible to provide an effect capable of maintaining high drainage performance by preventing the rainwater from pooling in a specific area.

In addition, the main drainage guide member coupling step (S300) is a step that proceeds after the fastening guide member assembling step, and is a step of seating and fastening the main drainage guide member constituting the drain guide member to the upper end of the fastening guide member.

And, the fastening block coupling step (S400) is a step that proceeds after the main drainage guide member coupling step.

More specifically, the coupling block coupling step (S400) is a step in which the coupling block provided to support the photovoltaic module is slid along the coupling guide member to be inserted into and fastened to the coupling guide member.

In particular, the coupling block coupling step may include a first coupling stage and a second coupling stage.

At this time, the fastening block includes a first fastening body and a second fastening body which are divided from each other.

Again, the first coupling step constituting the fastening block coupling step proceeds to insert the first fastening body into the fastening guide member, slide it, and fasten it at an arbitrary position through a separate fastening member.

And, the second combining step proceeds after the first combining step.

More specifically, in the second coupling step, the second coupling body is inserted into the coupling guide member to slide.

At this time, the grooves formed in the first fastening body and the grooves formed in the second fastening body are inserted and moved in a direction in which the grooves are spaced apart from each other and face each other.

Thereafter, the second fastening body is coupled to the first fastening body coupled to the fastening guide member in a form-fitting manner.

As described above, it is possible to provide more improved construction convenience by enabling fastening and supporting the drainage guide member and the photovoltaic module by proceeding with fitting through the fastening blocks that are divided and formed.

Next, the auxiliary drainage guide member coupling step (S500) is a step of fitting and coupling the auxiliary drainage guide member constituting the drainage guide member to the fastening block while proceeding with the fastening block coupling step.

At this time, the auxiliary drainage guide member coupling step (S500) may proceed before the fastening block coupling step (S400) is completed, and after the fastening block coupling step (S400) is completed, the auxiliary drainage guide member coupling step ( S500) may proceed to completion.

Next, the photovoltaic module coupling step (S600) is a step that proceeds after the auxiliary drainage guide member coupling step, and proceeds to fit and couple the photovoltaic module to the fastening block.

As described above, it is possible to provide more improved construction convenience by performing simple fitting through the fastening block to fasten and support the drainage guide member and the photovoltaic module.

By providing not only the main drainage guide member, but also the auxiliary drainage guide member, rainwater flowing in from the outside can be guided toward the drainage guide member and guided outside the photovoltaic module to prevent rainwater from penetrating under the roof to be discharged. It can ensure better waterproofing performance.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but this is only for explaining the present invention, and those skilled in the art to which the present invention belongs may make various modifications or equivalents from the detailed description of the present invention. It will be appreciated that one embodiment is possible.

Therefore, the true scope of the present invention should be determined by the technical spirit of the claims.

100: base panel part
200: solar power module
300: connection part
310: fastening block
311: fastening body
311a: first fastening body
311b: second fastening body
312: auxiliary drainage guide member fastening groove
313: auxiliary drainage guide member seating part
314: solar power module fastening home
315: solar power module seating part
320: fastening guide member
330: drainage guide member
331: main drainage guide member
332: auxiliary drainage guide member
340: spacer member
400: inverter module assembly
500: Gateway
600: service server
700: user terminal
MD: monitoring screen
MS: Monitoring section
AS: Alarm section
S100: roof structure formation step
S200: Fastening guide member assembly step
S300: Main drainage guide member coupling step
S400: Fastening Block Combination Step
S500: Secondary drainage guide member coupling step
S600: Photovoltaic module coupling step

Claims (15)

A base panel unit 100 that is seated on top of a building and includes a lower panel and an upper panel constituting a roof and a connection structure connecting the lower panel and the upper panel;
At least one photovoltaic power generation module 200 having a panel shape and provided to generate solar power; and
A connection part 300 fastened to an upper end of the base panel part and provided to support the photovoltaic module;
The connection part 300,
At least one pair of fastening blocks 310 provided to support the photovoltaic module; at least one pair of fastening guide members 320 seated on an upper surface of the base panel unit and provided to guide a position of the fastening block; And a drain guide member 330 disposed at the lower end of the photovoltaic module to collect water flowing in from the outside and discharge it toward the outside of the building; includes,
The fastening block 310,
At least one of them is slid on the fastening guide member and is provided to be coupled to each other, and the fastening body 311 constituting the fastening block is provided to be mutually divisible,
The fastening body 311,
A first fastening body (311a) including a block fastening groove formed at a predetermined depth at the bottom; and
The second fastening body 311b is provided to be separable from the first fastening body, is formed to enable a shape fit with the block fastening groove, and has a block fastener having a shape corresponding to the shape of the block fastening groove. ); Building-integrated photovoltaic power generation system comprising a. According to claim 1,
The drainage guide member 330,
At least one main drainage guide member 331 provided to be seated on a fastening block or an upper portion of the base panel unit and extending a predetermined length; and
At least one auxiliary drainage guide member 332 coupled to the fastening block, extending a predetermined length, and collecting water flowing in from the outside and discharging it toward the main drainage guide member; characterized in that it comprises a building integrated sun photovoltaic system. According to claim 2,
The main drainage guide member 331,
Disposed between a pair of the fastening blocks disposed to face each other, provided so that both side ends are supported by the fastening guide member,
The auxiliary drainage guide member 332,
Disposed at the upper end of the main drainage guide member, provided to extend in a direction transverse to the extension direction of the main drainage guide member, and an end portion disposed within the main drainage guide member formation area. solar power system. According to claim 3,
The auxiliary drainage guide member 332,
Building-integrated photovoltaic power generation, characterized in that the plurality of photovoltaic modules are disposed at the lower end of the area in contact with each other to collect water flowing between the plurality of photovoltaic modules and guide it to the main drainage guide member. system. According to claim 2,
The fastening block 310,
fastening body(311)
auxiliary drainage guide member fastening grooves 312 provided so that both ends of the auxiliary drainage guide member are inserted and fastened;
a drainage guide member mounting portion 313 formed to seat the auxiliary drainage guide member; and
A building-integrated photovoltaic power generation system comprising: a photovoltaic module fastening groove 314 formed at an upper end of the auxiliary drainage guide member fastening groove and into which an end portion of the photovoltaic module is inserted. delete According to claim 2,
The fastening guide member 320,
They are installed at mutually symmetrical positions based on the main drainage guide member,
The fastening block 310,
When at least one fastening block is installed on different fastening guide members, the fastening blocks installed on one fastening guide member face each other while being adjacent to the fastening block installed on one fastening guide member. A building-integrated photovoltaic power generation system, characterized in that disposed. According to claim 2,
The connection part 300,
Building-integrated photovoltaic power generation system further comprising: at least one spacer member 340 provided at the bottom of the main drainage guide member to prevent sagging of the main drainage guide member. According to claim 8,
The spacer member 340,
Building-integrated solar power generation system, characterized in that at least one or more are disposed while maintaining a certain interval along the extension direction of the main drainage guide member, and the side end is fastened with the fastening guide member in a form-fitting coupling method. The method of any one of claims 1 to 5 and 7 to 9,
An inverter module assembly 400 including at least one inverter module provided to convert the power generated by the photovoltaic power generation module into alternating current into alternating current and provide it to a place where power is used;
It is communicatively connected with the inverter module assembly to generate at least one generation amount monitoring information that is information representing the amount of power generated through the photovoltaic power generation module, and when the amount of power generation in the amount of power generation monitoring information is less than a preset standard amount of power generation, an abnormal situation a service server 600 provided to generate alarm information notifying that it is; and
A building-integrated photovoltaic power generation system further comprising a user terminal 700 configured to be communicatively connected to the service server and output at least one selected from among the generation amount monitoring information and the alarm information. According to claim 10,
The solar power module 200,
At least one photovoltaic module is installed to be grouped by section having an arbitrary area,
The inverter module 410,
While being connected to at least one photovoltaic module forming one group, it is provided to classify and collect the amount of power generation obtained through the photovoltaic module by the group unit,
The service server 600,
The building-integrated solar power generation system, characterized in that provided to generate at least one monitoring information based on the amount of power generation of the photovoltaic module collected in units of groups and provide it to the user terminal. According to claim 11,
The user terminal 700,
The building-integrated photovoltaic power generation system, characterized in that provided to receive the monitoring information and generate and output a monitoring screen indicating the amount of power generation of the photovoltaic modules grouped by section based on the monitoring information. In the construction method of a building-integrated photovoltaic power generation system including a photovoltaic module,
The construction method,
A roof structure forming step of forming a roof structure of a building through a base panel portion seated on top of the building and constituting the roof;
After the roof structure forming step, assembling a coupling guide member assembly step for determining the location of a drainage guide member formed to collect water introduced from the outside at an upper end of the base panel unit;
After the fastening guide member assembling step, the main drainage guide member coupling step of fastening the main drainage guide member constituting the drain guide member by seating it on top of the fastening guide member;
After the main drainage guide member coupling step, the fastening block coupling step proceeding to slide the fastening block provided to support the photovoltaic module along the fastening guide member, and insert and fasten the fastening guide member to the fastening guide member;
An auxiliary drainage guide member coupling step of fitting and coupling an auxiliary drainage guide member constituting the drainage guide member to the fastening block while performing the fastening block coupling step;
After the auxiliary drain guide member coupling step, a photovoltaic module coupling step of fitting and coupling the photovoltaic module to the fastening block; includes,
The fastening block,
At least one or more slidably coupled to the fastening guide member, and fastening bodies constituting the fastening block are provided so as to be mutually divisible;
The fastening body,
A first fastening body including a block fastening groove formed at a predetermined depth at the bottom; and
A second fastening body that is provided to be separable from the first fastening body, is formed to enable a shape fit with the block fastening groove, and has a block fastener having a shape corresponding to the shape of the block fastening groove; include,
The fastening block coupling step,
A first coupling step of inserting the first fastening body into the fastening guide member to slide and fasten the first fastening body to an arbitrary position through a separate fastening member; and
After the first coupling step, the second coupling body is inserted into the coupling guide member to slide and move, and then the second coupling body is shape-fitted to the first coupling body coupled to the coupling guide member. A construction method of a building-integrated photovoltaic power generation system comprising a; second coupling step of coupling in a manner. delete According to claim 13,
The fastening guide member assembling step,
Building-integrated photovoltaic power generation, characterized in that proceeding to combine a spacer member provided to support the drainage guide member from below with the pair of fastening guide members while maintaining a distance between the at least one pair of fastening guide members How the system is constructed.

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