KR102538642B1 - Building Integrated Photovoltaic System with improved heat radiation efficiency and safety and drainage - Google Patents

Abstract

The present invention relates to a building-integrated photovoltaic power generation system that generates electricity by itself by installing solar panels (SP) on the exterior of a window, balcony, roof, or rooftop building, with a set front-to-back interval on the exterior of the building and horizontally Middle purlins 1a mounted in the direction, corrugated plates 1b mounted on top of the purlins 1a, and guide rails 1c mounted in the vertical direction at the top of the corrugated plates 1b at a set left and right interval, Level brackets 1d mounted to be slidably movable at set front and rear intervals for each guide rail 1c, angle bars 1e horizontally mounted at each upper end of the level brackets 1d, and the angle bar (1e) a foundation frame (1) composed of a heat insulating material (1f) mounted in the empty space between them and a waterproof sheet (1g) laid on the upper surface of the heat insulating material (1f); A main frame (10) mounted vertically on the top of the base frame (1) at set intervals and fixing the solar panels (SP) to be arranged and installed; Intermediate storage members 20 installed in the vertical direction at set intervals between the main frames 10 and accommodating wires connected to the solar panel SP; An intermediate support member 30 mounted to cover the upper end of the intermediate storage member 20 and supporting the lower surface of the solar panel SP so as not to droop; Reinforcement storage members 40 mounted in the horizontal direction at set intervals between the main frames 10 and accommodating wires connected to the solar panel SP; A reinforcing supporting member 50 that is mounted to cover the top of the reinforcing storage member 40 and supports the lower surface of the solar panel SP so that it does not sag; A buffer member 60 mounted to cover the upper end of the intermediate supporting member 30 and the reinforcing supporting member 50 and in close contact with the lower surface of the solar panel SP to absorb shock and block heat transfer. It is characterized in that it is made by.

Description

Building Integrated Photovoltaic System with improved heat radiation efficiency and safety and drainage}

The present invention relates to a building-integrated photovoltaic power generation system that generates electricity by itself by installing photovoltaic panels on the exterior of a building, such as a window, balcony, roof or rooftop, and more particularly, in the middle and between the solar panels Arranged in the vertical direction, it supports to prevent sagging, collects rainwater that flows in between the solar panels and delivers it to the main frame, and then absorbs the impact of the intermediate storage member or reinforcing support member and solar panel for storing the wires and transfers heat. By constructing a buffer member to block, it is possible to apply a large-sized solar panel with a relatively large area, so the power generation capacity can be greatly increased, and the solar panel is safely protected against abnormal weather such as snow, rain, and strong wind. Of course, it relates to a building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage that can increase the satisfaction of workers and users with quick and convenient workability and excellent finish due to wire storage.

In recent years, as an alternative energy source due to resource depletion, interest in photovoltaic power generation is growing. In other words, photovoltaic power generation is an integrated technology that converts sunlight incident on the earth into electrical energy. It is not only eco-friendly in itself, but also has the advantage of being able to produce electricity if only the sun exists without additional energy input, so it is gradually becoming more popular. The scope of application is expanding.

Such photovoltaic power generation is operated by connecting solar panels in series or in parallel, which include wires that electrically connect the solar panels and films or glass that protect the solar panels from the external environment.

To apply such a solar panel to a building, the most commonly used so far is to mount the solar panel on an existing building. That is, a method of simply fixing the main frame that tightly restrains the solar panel to the roof is used.

Therefore, there is an advantage in that there is no need to dismantle the existing building or construct a new structure separately for the installation of the solar panel. However, this method has a disadvantage in that the appearance of the building deteriorates in that the solar panel assembly is installed on the roof of the existing building.

Moreover, although the main frame is fixed to the roof using fastening means such as bolts, there is a problem in that water leakage occurs inside the building through the through hole of the fastening means.

In other words, a method that is currently being extensively studied to solve the problem of the solar panel installation method is the building integrated photovoltaic system (BIPV), which configures the solar panel itself as the exterior material of the building. .

This building-integrated photovoltaic power generation system has the advantage of being able to maintain the exterior of the building as originally intended as well as reducing the construction cost of the building by configuring the exterior material of the building with solar panels.

However, this method does not fundamentally solve the problem of water leakage into the building in that the exterior is configured by interconnecting a plurality of solar panels that operate independently of each other.

Moreover, solar panels generate considerable heat during their operation, and most of the methods proposed so far focus only on replacing them with simple building exterior materials, but do not properly dissipate the heat generated by the solar panels, resulting in power generation. There is a problem of reducing efficiency.

On the other hand, in recent years, solar power generation systems tend to increase the size of solar panels in order to increase power generation. For example, a panel such as 500 to 830 W has a size of 1,400 x 2,500 mm.

Therefore, due to the increase in the size of the solar panel, it does not stably withstand conditions such as snow, rain, and strong wind, and sagging occurs, resulting in a problem of reducing power generation efficiency due to damage and shortening life span.

Republic of Korea Patent Registration No. 10-1832470 (Title of Invention: Solar Integrated Roof System) Republic of Korea Patent Registration No. 10-1928534 (Title of Invention: Building-integrated Solar Power Generation Roof System and Construction Method)

The present invention has been proposed to solve the above problems, and is arranged horizontally and vertically in the middle and between the solar panels to prevent sagging and collects rainwater flowing between the solar panels and delivers it to the main frame. Next, by constructing an intermediate storage member or a reinforcing support member for storing the wires and a buffer member that absorbs the impact of the solar panel and blocks heat transfer, it is possible to apply a large solar panel with a relatively large area, thereby significantly increasing the power generation capacity. It not only protects solar panels safely against abnormal weather such as snow, rain and strong wind, but also provides quick and convenient workability due to wire storage and excellent finish to increase worker and user satisfaction. The purpose is to provide a building-integrated photovoltaic power generation system with improved drainage.

In addition, the present invention not only supports the solar panels to be installed, but also combines a drainage member for collecting rainwater inevitably leaking from the main member and discharging it to the outside along with a main member for collecting rainwater flowing in between the solar panels and discharging it to the outside. By configuring it, safety and high lifespan are ensured with excellent drainage, followed by an elastic pad that absorbs shocks acting on solar panels and blocks heat transfer, and a control member that adjusts the distance between solar panels and absorbs shocks. The purpose is to provide a building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage that can secure construction precision and seismic performance.

In addition, the present invention configures an intermediate ventilation frame that provides an inspection space as well as cooling of the solar panel together with an external ventilation frame that cools the solar panel by passing air while finishing the solar panel, so that the heat accumulated in the solar panel is removed from the outside. It is a building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage that can not only improve overall power generation efficiency as it can be discharged quickly, but also reduce the number of man-hours required for inspection due to quick and convenient maintenance. Its purpose is to provide.

The present invention relates to a building-integrated photovoltaic power generation system that generates electricity by itself by installing solar panels on the exterior of a window, balcony, roof, or rooftop building, mounted horizontally on the exterior of the building at a set front-back interval. middle purlins, corrugated plates mounted on top of the purlins, guide rails mounted vertically on the top of the corrugated plates at set left and right intervals, and level brackets mounted to be slideable at set front and back intervals for each guide rail And, a foundation frame composed of angle bars mounted in the horizontal direction at each upper end of the level brackets, an insulator mounted in an empty space between the angle bars, and a waterproof sheet installed on an upper surface of the insulator; A main frame installed vertically at an upper end of the foundation frame at set intervals and fixing the solar panels to be arranged in an array; an intermediate storage member installed in a vertical direction at set intervals between the main frames and accommodating wires connected to the solar panel; an intermediate support member mounted to cover the upper end of the intermediate storage member and supporting the lower surface of the solar panel so as not to sag; a reinforcing storage member installed in a horizontal direction at set intervals between the main frames and accommodating wires connected to the solar panel; a reinforcing supporting member that is mounted to cover the upper end of the reinforcing storage member and supports the lower surface of the solar panel so as not to sag; It is characterized in that it comprises; a buffer member that is mounted to cover the upper end of the intermediate supporting member and the reinforcing supporting member, and is in close contact with the lower surface of the solar panel to absorb shock and block heat transfer.

At this time, the main frame according to the present invention is mounted on the top of the base frame with bolts or screws, the main member for supporting the photovoltaic panels spaced apart from the floor at a predetermined height; A connecting angle member inserted into the center of the main member and connecting the main members in a row to hold each other without twisting; an elastic pad mounted on an upper end of the main member, absorbing an impact applied to the solar panel and blocking heat transfer; an adjusting member mounted on an upper end of the main member and absorbing shock while adjusting a distance between the solar panels arranged in front and rear; a drainage member mounted in a vertical direction at each lower end of the main member and collecting and discharging rainwater flowing from the main member to the outside; It is characterized in that it consists of; a fixing member mounted in a vertical direction between each of the solar panels and fastened to the main member with a ball/nut to fix the solar panel.

In addition, the main member according to the present invention, the main piece protruding horizontally with a predetermined width so as to be mounted on the upper end of the base frame; inclined pieces protruding obliquely upward toward the left and right sides at both ends of the main piece to provide a drainage space through which rainwater flows; Leg pieces protruding vertically downward at each end of the inclined piece to induce installation on the exterior of the building; Fixing pieces protruding horizontally outward at each end of the leg piece to induce mounting with bolts or screws; A pair of connection pieces protruding vertically at a set interval from the center of the main piece; A connecting hole passing through a circular or angular shape between the connecting pieces so that the connecting angle member is inserted and mounted; a connection slot for slide-accommodating a nut at an upper end of the connection hole so that the fixing member is mounted; Mounting pieces protruding horizontally toward the left and right sides of each upper end of the connection piece so that the solar panel is mounted in a state where the elastic pad is mounted; Spacer pieces protruding vertically from each end of the mounting pieces facing each other so that the solar panels are spaced apart at set intervals; It is characterized in that it is formed of; a mounting piece protruding vertically upward at each outer end of the mounting piece so that the elastic pad is inserted and mounted in a proper position.

In addition, the elastic pad according to the present invention includes a horizontal elastic piece mounted horizontally on each upper left and right side of the main member to support the left and right bottom surfaces of the solar panels; It is characterized in that the vertical elastic pieces are integrally formed with each of the upper left and right sides of the main member and vertically mounted to support the left and right side surfaces of the solar panels.

In addition, the control member according to the present invention is formed of a plate-shaped soft material having a set thickness to adjust the front and rear intervals between the solar panels and absorb shock, and is formed at a predetermined center at the bottom so as to be fitted to the top of the main member. It is characterized by the formation of a fixing groove that is recessed in height.

In addition, the drainage member according to the present invention, the drain piece disposed at the lower end of the main member to induce the flowing rainwater to flow into a set path; It is characterized in that it is formed of; wing pieces protruding obliquely upward toward the left and right sides at each end of the drainage piece to collect the inflowing rainwater so that it does not overflow.

In addition, the fixing member according to the present invention, the fixing piece fastened to the main member and the ball / nut to press and fix the upper edge of the photovoltaic panels; It is characterized in that it is formed of; a pair of alignment pieces protruding vertically from the lower end of the fixing piece at set intervals to guide the solar panels to be spaced apart.

In addition, the intermediate storage member and the intermediate support member according to the present invention, support pieces protruding horizontally on both sides so as to overlap each other at each end facing each other; It is characterized in that a locking piece is formed at one end of the support piece of the intermediate support member to sequentially bend and protrude downward inward/outward to induce detachment/attachment with the intermediate storage member.

In addition, the reinforcing supporting member according to the present invention, the supporting piece protruding horizontally with a width covering the reinforcing storage member to conceal the wire; A fitting piece protruding in an angular shape at the center of the upper end of the supporting piece to insert and mount a buffer member; A heat insulation hole penetrated in a predetermined shape at the center of the fitting piece to block heat transfer from the solar panel; It is characterized in that it is formed as; vertical pieces protruding vertically from both ends of the supporting piece to collect rainwater flowing between the solar panels and deliver it to the main frame.

In addition, the building-integrated photovoltaic power generation system according to the present invention further includes an external ventilation frame mounted horizontally on the front and rear of the main frame and cooling the solar panels by passing air through them. It is characterized by doing.

In addition, the external ventilation frame according to the present invention, the front ventilation member having an A-shaped cross-section and one or more mounted in the horizontal direction to the front of the main frame; It consists of; one or more rear ventilating members having an A-shaped cross-sectional shape mounted in the rear of the main frame in the horizontal direction; It is characterized in that a plurality of vents for inducing air circulation on the front and upper surfaces, respectively.

In addition, the building-integrated photovoltaic power generation system according to the present invention further includes an intermediate ventilation frame mounted in a horizontal direction between the main frames, cooled by passing air through the photovoltaic panels, and providing an inspection space. It is characterized by including.

In addition, the intermediate ventilation frame according to the present invention, one or more intermediate ventilation members mounted in the horizontal direction between the main frame and the solar panel, for discharging heat accumulated in the solar panel to the outside; an intermediate protection member that is slide-inserted and mounted at a lower end of the intermediate ventilation member and collects rainwater flowing into the intermediate ventilation member and transfers it to the main frame; It is characterized by consisting of; inserted and mounted on both sides of the intermediate ventilation member, and collecting rainwater flowing between the solar panel and the intermediate protective member and delivering it to the main frame.

In addition, the intermediate ventilation member according to the present invention, a plurality of ventilation holes that open toward the front at the top so as to block the inflow of rainwater flowing down along with discharging heat accumulated in the solar panel to the outside; Accommodating grooves recessed to a predetermined width and depth on both bottoms so that one end of the water tray is inserted and accommodated; Guide walls protruding vertically from both sides of the bottom surface so that rainwater or foreign substances flowing in from the ventilation hole are collected in the intermediate protective member; Characterized in that a; mounting groove cut through a circular or angular shape on the inner side surface so that the intermediate protection member is slide-inserted and mounted.

In addition, the intermediate protection member according to the present invention, the inspection hole that is opened to the side facing the front to enable visual inspection with the release of heat accumulated in the solar panel to the outside; a blocking wall protruding vertically at a position adjacent to the inspection hole to collect rainwater or foreign substances inevitably flowing in from the intermediate ventilation member and pass it to the main frame; Characterized in that; mounting protrusions protruding in a circular or angular shape at both ends so as to be slide-inserted and mounted at the lower end of the intermediate ventilation member.

First, the present invention is disposed in the horizontal and vertical directions in the middle and between the solar panels to prevent sagging, collect rainwater flowing between the solar panels and deliver it to the main frame, and then to the intermediate storage member for storing the wires. By constructing a buffer member that absorbs the shock of the reinforcement support member and the solar panel and blocks heat transfer, it is possible to apply a large-sized solar panel with a relatively large area, so that the power generation capacity can be greatly increased, as well as snow, rain and strong winds. It not only safely protects the solar panel against abnormal weather conditions, but also has the effect of increasing the satisfaction of workers and users with quick and convenient workability and excellent finish due to wire storage.

Second, the present invention not only supports the solar panels to be installed, but also combines a main member for collecting and discharging rainwater flowing between the solar panels and a drainage member for collecting and discharging rainwater that inevitably leaks from the main member and discharging it to the outside. By configuring it, safety and high lifespan are ensured with excellent drainage, followed by an elastic pad that absorbs shocks acting on solar panels and blocks heat transfer, and a control member that adjusts the distance between solar panels and absorbs shocks. It has the effect of securing the precision of construction and seismic performance.

Third, the present invention configures an intermediate ventilation frame that provides an inspection space as well as cooling of the solar panel together with an external ventilation frame that cools the solar panel by passing air while finishing the solar panel, so that the heat accumulated in the solar panel is removed from the outside. As it can be discharged quickly, the overall power generation efficiency can be improved, and the man-hours required for inspection can be shortened due to quick and convenient maintenance.

In addition to the effects described above, specific effects of the present invention will be described together while explaining specific details for carrying out the present invention.

1 is a rendering photograph showing a photovoltaic power generation system according to the present invention.
2 is an exploded view showing a separated solar power generation system according to the present invention.
3 is a cross-sectional view showing an enlarged main part of the photovoltaic power generation system according to the present invention.
4 to 6 are configuration diagrams showing in detail the main frame of the photovoltaic power generation system according to the present invention.
7 to 10 are configuration diagrams showing in detail an intermediate storage member or a buffer member of the photovoltaic power generation system according to the present invention.
11 is a configuration diagram showing in detail the external ventilation frame of the photovoltaic power generation system according to the present invention.
12 to 15 are configuration diagrams showing in detail an intermediate ventilation frame of the photovoltaic power generation system according to the present invention.
16 is a reference diagram showing a path through which the solar power generation system according to the present invention drains rainwater.

Hereinafter, various embodiments of this document will be described with reference to the accompanying drawings. However, this is not intended to limit the technology described in this document to specific embodiments, and it should be understood that it includes various modifications, equivalents, and/or alternatives of the embodiments of this document. In connection with the description of the drawings, like reference numerals may be used for like elements.

In addition, expressions such as “first,” “second,” etc. used in this document may modify various components regardless of order and/or importance, and to distinguish one component from another. It is used only and does not limit the corresponding components. For example, 'first part' and 'second part' may indicate different parts regardless of order or importance. For example, a first element may be named a second element without departing from the scope of rights described in this document, and similarly, the second element may also be renamed to the first element.

In addition, terms used in this document are only used to describe a specific embodiment, and may not be intended to limit the scope of other embodiments. Singular expressions may include plural expressions unless the context clearly dictates otherwise. Terms used herein, including technical or scientific terms, may have the same meaning as commonly understood by a person of ordinary skill in the technical field described in this document. Among the terms used in this document, terms defined in a general dictionary may be interpreted as having the same or similar meaning as the meaning in the context of the related art, and unless explicitly defined in this document, an ideal or excessively formal meaning. not be interpreted as In some cases, even terms defined in this document cannot be interpreted to exclude the embodiments of this document.

The present invention relates to a building-integrated photovoltaic power generation system that generates electricity by itself by installing solar panels (SP) on the exterior of a window, balcony, roof, or rooftop building. , heat dissipation efficiency, safety and It is a building-integrated solar power generation system with improved drainage.

First, the foundation frame 1 according to the present invention is installed at a location where the building will appear, as shown in FIGS. 1 and 2 .

The base frame 1 is composed of a middle purlin 1a, a corrugated plate 1b, a guide rail 1c, a level bracket 1d, an angle bar 1e, an insulator 1f, and a waterproof sheet 1g.

The middle purlin (1a) is mounted in the horizontal direction at intervals before and after the setting through the walls or pillars constituting the building.

The corrugated plate (1b) is a plate provided with V-shaped cross-sectional corrugations at set left and right intervals, and is mounted on the top of the middle purlins (1a).

Here, although the corrugated plate 1b is not shown as a separate drawing, a plurality of holes are formed in a regular pattern.

The guide rail 1c is formed with a slot opened in a cross-sectional shape of a ㅗ so that the level bracket 1d is slidably inserted into the upper side of the guide rail 1c.

These guide rails (1c) are inserted and mounted in the vertical direction at the top of the corrugated plate (1b) with a set left-right interval.

That is, the guide rail 1c is mounted with bolts together with the corrugated plate 1b at each point where the middle purlin 1a overlaps.

The level bracket 1d is formed in a Y-shaped or F-shaped cross-section and is slidably mounted on the upper end of the guide rail 1c.

This level bracket (1d) is to support the angle bar (1e) fixedly at a set height, the lower end is fastened with a fixing plate inserted into the slot of the guide rail (1c).

That is, the level bracket 1d is fixed to the level bracket 1d by pressing and fastening with the fixing plate in a state in which the front and rear positions of the level bracket 1d are adjusted from the guide rail 1c.

Here, an insulating block to block heat transfer may be mounted on the inner surface of the level bracket 1d in contact with the angle bar 1e.

In addition, the level bracket 1d may be divided into two or more parts so that the height of the angle bar 1e can be adjusted so as to slide up and down while being engaged with each other.

The angle bar (1e) is formed in an A-shaped cross-section, and is inserted and mounted in the horizontal direction on one surface of the upper end of the level bracket (1d).

The angle bar 1e serves to support the main frame 10, the intermediate storage member 20, and the reinforcing storage member 40 to be described later to be spaced apart from the corrugated plate 1b and fix them with bolts so that the insulation material 1f is filled. do

The insulator 1f is filled and installed in the empty space provided between the angle bars 1e to block heat transfer and noise.

The waterproof sheet 1g is a roofing sheet laid on top of the heat insulator 1f, and acts to absorb or release moisture depending on the ambient humidity while blocking water leakage.

Subsequently, the main frame 10 according to the present invention is mounted in the vertical direction at a set interval on the top of the base frame 1 as shown in FIGS. 1 to 3, and serves to fix the solar panels SP to be arranged and installed.

As shown in FIGS. 4 and 5, the main frame 10 includes a main member 11, a connecting member 12, an elastic pad 13, an adjusting member 14, a drainage member 15, a fixing member ( 16).

The main member 11 is a metal profile extruded in a cross-sectional shape of a ㅗ, and is mounted on the top of the base frame 1 with bolts or screws.

The main member 11 serves to support the solar panels SP spaced apart from the floor at a predetermined height.

That is, as shown in FIG. 6, the main member 11 includes a main piece 11a, an inclined piece 11b, a leg piece 11c, a fixing piece 11d, a connecting piece 11e, a connecting hole 11f, and a connecting slot 11g. ), a holding piece 11h, a separation piece 11i, and a mounting piece 11j.

The main piece 11a protrudes horizontally with a predetermined width and is mounted on the top of the base frame 1.

The inclined pieces 11b protrude obliquely upward toward the left and right sides at both ends of the main piece 11a to provide a drainage space through which rainwater flows to the top of the main piece 11a.

The leg piece 11c protrudes vertically downward at each end of the inclined piece 11b to induce installation on the exterior or foundation frame of the building.

The fixing piece 11d protrudes horizontally to the left and right at each end of the leg piece 11c and is coupled with a bolt or screw.

The connecting piece 11e protrudes vertically at set intervals from the center of the main piece 11a to separate the solar panels SP at a predetermined height to provide a drainage space.

The connection hole 11f is formed in a circular or angular shape between the connection pieces 11e so that the connection angle member 12 is inserted and mounted.

The connecting slot 11g has an opening formed at the upper end of the connecting hole 11f so that the nut can be slidably received so that the fixing member 16 is mounted by a bolt.

The mounting pieces 11h protrude horizontally toward the left and right sides of each upper end of the connection piece 11e, and the solar panel SP is supported while the elastic pad 13 is attached.

The spacer pieces 11i protrude vertically from each end of the mounting pieces 11h facing each other to space the solar panels SP apart at set intervals.

The mounting piece 11j protrudes vertically upward at each outer end of the mounting piece 11h and guides the elastic pad 13 to be inserted and mounted in the correct position.

The connection angle member 12 is inserted into the center of the main member 11 and serves to guide the main members 11 to be connected in a row.

That is, the connecting angle member 12 is formed of a rod having a circular or prismatic cross section that can be inserted into the connecting hole 11f of the main member 11.

These connection angle members 12 hold the main members 11 arranged in a row so as not to twist each other.

Here, it is preferable that the connection angle member 12 be formed of a hollow tube with an empty inside so as to minimize heat transfer and weight while absorbing shock from the main member 11.

The elastic pad 13 is mounted on the upper end of the main member 11 to absorb shock applied to the solar panel SP and serve to block heat transfer.

That is, the elastic pad 13 is mounted on the top of the mounting piece 11h of the main member 11 to absorb the external force transmitted to the outside while alleviating contraction and expansion of the main member 11 and the solar panel SP. It protects the solar panel (SP) safely.

The elastic pad 13 is formed in the form of a string (strap) of a soft synthetic resin material having excellent thermal insulation properties, and is composed of a horizontal elastic piece 13a and a vertical elastic piece 13b as shown in FIG. 5 .

The horizontal elastic pieces 13a are mounted horizontally at each upper end of the mounting pieces 11h of the main member 11 to support the left and right bottom surfaces of the solar panels SP.

The vertical elastic pieces 13b are vertically mounted on each side of the spacer pieces 11i of the main member 11 to support left and right side surfaces of the solar panels SP.

That is, as the elastic pad 13 absorbs both the vertical external force and the horizontal external force transmitted from the outside, excellent seismic performance can be expected.

The control member 14 is mounted on the top of the main member 11 and serves to adjust the distance between the solar panels SP arranged in front and rear and to absorb shock.

The adjusting member 14 is mounted on the top of the mounting piece 11h of the main member 11 and performs the same function as the elastic pad 13 while constantly adjusting the distance between the solar panels SP.

That is, the adjusting member 14 is formed in the form of a thin plate made of a soft synthetic resin material having excellent heat insulating properties, and has a width that embraces the mounting piece 11h as shown in FIG. 5 .

Here, the adjusting member 14 has a fixing groove 14a recessed to a predetermined height at the center of the bottom surface so as to be fitted to the spaced piece 11i of the main member 11.

Therefore, as the adjustment member 14 can be continuously maintained in the mounting position on the main member 11, the installation of the solar panel SP is provided with an easy advantage.

The drainage member 15 is mounted in the vertical direction at each lower end of the main member 11 to collect rainwater flowing from the main member 11 and discharge it to the outside.

That is, the drainage member 15 is seamlessly mounted from the rear end to the front end of the photovoltaic power generation system and discharges rainwater inevitably introduced through the main member 11 toward the drain.

As shown in FIG. 5, the drainage member 15 includes a drainage piece 15a and a wing piece 15b.

The drainage piece 15a is disposed on the bottom of the main piece 11a of the main member 11 to induce rainwater to flow into a set path.

The wing pieces 15b protrude obliquely upward toward the left and right sides at each end of each side of the drainage piece 15a and are disposed at the bottom of the inclined piece 11b of the main member 11.

These wing pieces 15b collect the inflowing rainwater so that it does not overflow and induces it to be quickly discharged toward the drain.

Therefore, by completely blocking leakage of the building due to the drainage member 15, safety and high lifespan can be guaranteed.

The fixing member 16 is mounted in the longitudinal direction between each of the solar panels SP arranged in an array on the main member 11 .

That is, the fixing member 16 is fastened with a nut and a bolt inserted into the connection slot 11g of the main member 11 and serves to fix the solar panel SP by pressure.

As shown in FIG. 5, the fixing member 16 includes a fixing piece 16a and a pair of alignment pieces 16b.

The fixing piece 16a is fastened to the main member 11 between the solar panels SP with bolts to fix the upper edge of the solar panels SP by pressing.

The alignment piece 16b protrudes vertically at a set interval from the lower end of the fixing piece 16a to guide the solar panels SP to be spaced apart.

Here, one or more connecting holes may be formed in the fixing piece 16a so that a packing member for blocking a joint between the solar panels SP may be mounted.

Subsequently, the intermediate storage member 20 according to the present invention is mounted in the vertical direction at set intervals between the main frames 10 as shown in FIGS. 1 to 3 .

As shown in FIG. 7, the intermediate storage member 20 is formed in a c-shaped cross-section and serves to accommodate wires connected to the solar panel SP.

Here, as shown in FIG. 8, the middle storage member 20 has support pieces 21 that protrude outward horizontally at each of the upper ends facing each other.

This support piece 21 induces coupling with the intermediate support member 30 and serves to distribute the transmitted load.

Subsequently, the intermediate support member 30 according to the present invention is mounted so as to cover the top of the intermediate storage member 20 as shown in FIGS. 1 to 3 .

The intermediate support member 30 is formed in a c-shaped cross-section as shown in FIG. 7 and serves to support the lower surface of the solar panel SP so as not to droop.

Here, as shown in FIG. 8, the intermediate support member 30 has support pieces 31 that protrude outward horizontally at each lower end portion facing each other.

That is, the support piece 31 of the intermediate support member 30 is closely engaged with the support piece 21 of the intermediate storage member 20 and serves to distribute the transmitted load.

At this time, one end of the support piece 31 of the intermediate support member 30 is formed with a hooking piece 32 that is sequentially bent and protruded inward and outward downward.

This locking piece 32 induces quick and convenient removal/installation to the intermediate storage member 20 without a separate fastening member, providing an advantage of easy construction and maintenance.

Subsequently, the reinforcement storage member 40 according to the present invention is mounted horizontally at set intervals between the main frame members 10 as shown in FIGS. 1 to 3.

As shown in FIG. 7, the reinforcing storage member 40 is formed in a c-shaped cross-section and serves to accommodate wires connected to the solar panel SP.

Here, as shown in FIG. 8, the reinforcement storage member 40 also has support pieces 41 protruding horizontally outward at each of the upper ends facing each other.

This support piece 41 induces coupling with the reinforcing support member 50 and serves to distribute the transmitted load.

Subsequently, the reinforcing support member 50 according to the present invention is mounted to cover the top of the reinforcing storage member 40 as shown in FIGS. 1 to 3 .

As shown in FIG. 9, the reinforcing supporting member 50 serves to support the lower surface of the solar panel SP so as not to sag.

That is, the reinforcing supporting member 50 is composed of a supporting piece 51, a fitting piece 52, an insulating hole 53, and a vertical piece 54, as shown in FIG.

The supporting piece 51 is formed to protrude horizontally with a width that covers the reinforcing storage member 40 and conceals the electric wire to be accommodated.

The fitting piece 52 protrudes in an angular shape at the top center of the supporting piece 51 so that the buffer member 60 is inserted and mounted.

The insulation hole 53 is penetrated in a predetermined shape at the center of the fitting piece 52 to block heat transfer from the solar panel SP.

The vertical pieces 54 protrude vertically from both ends of the support piece 51 to collect rainwater flowing between the solar panels SP and pass it to the main member 11 .

Subsequently, the buffer member 60 according to the present invention is mounted so as to cover the upper ends of the intermediate supporting member 30 and the reinforcing supporting member 50 as shown in FIGS. 1 to 3 and 7 to 10.

Like the elastic pad 30, the buffer member 60 is made of a soft synthetic resin material having excellent thermal insulation properties and has a C-shaped cross-section in the form of a string (strap).

That is, the buffer member 60 is in close contact with the lower surface of the solar panel SP to absorb impact and block heat transfer.

Of course, the buffer member 60 relieves the contraction and expansion of the solar panel SP to safely protect the solar panel SP.

In this way, by configuring the intermediate storage member 20 and the reinforcing storage member 40 to accommodate the wires connected to the solar panels (SP), the satisfaction of workers and users will be increased due to quick and convenient workability and excellent finish. can

Above all, the intermediate supporting member 30, the reinforcing supporting member 50, and the buffer member 60 are configured to support the solar panel SP to prevent sagging, thereby providing a large solar panel SP with a relatively large area. Since it can be applied, not only can the power generation capacity be greatly increased, but also the solar panel (SP) can be safely protected against abnormal weather such as snow, rain, and strong wind.

Meanwhile, the building-integrated photovoltaic power generation system according to the present invention may further include an external ventilation frame 70 and an intermediate ventilation frame 80.

First, the external ventilation frame 70 is mounted in the horizontal direction on the front and rear of the main frames 10, respectively, as shown in FIGS. 1 and 2.

The external ventilation frame 70 serves to cool the solar panels SP by passing air therethrough.

That is, the external ventilation frame 70 is configured to be divided into a front ventilation member 71 and a rear ventilation member 72 .

One or more front ventilation members 71 are formed in an A-shaped cross-section and are mounted on the front of the main frame 10 in a horizontal direction.

The rear ventilation member 72 is formed in an A-shaped cross-section, and one or more are mounted on the rear side of the main frame 10 in the horizontal direction.

Here, as shown in FIG. 11, the front/rear ventilation members 71 and 72 are formed with a plurality of ventilation holes 71a and 72a for inducing air circulation so that heat accumulated in the solar panel SP is released.

That is, the ventilation hole 71a of the front ventilation member 71 is formed on the front side to allow air to flow in from the outside.

In addition, a ventilation hole 72a is formed on the upper surface of the rear ventilation member 72 to discharge internal air to the outside.

Finally, the intermediate ventilation frame 80 according to the present invention is mounted horizontally between the main frames 10 as shown in FIGS. 1 to 3.

That is, the intermediate ventilation frame 80 serves to cool the air through the solar panels SP and provide an inspection space.

The intermediate ventilation frame 80 is composed of an intermediate ventilation member 81, an intermediate protective member 82, and a drip tray 83, as shown in FIGS. 12 to 14.

At least one intermediate ventilation member 81 is formed in a c-shaped cross-section and is mounted between the main member 11 and the solar panel SP in the horizontal direction.

That is, the intermediate ventilation member 81 induces cooling by passing air through the solar panels SP, and includes a plurality of ventilation holes 81a, accommodating grooves 81b, guide walls 81c, and mounting grooves ( 81d) is formed.

Ventilation holes 81a are opened in plurality toward the front at the top to block the inflow of rainwater while discharging heat accumulated in the solar panel SP to the outside.

Accommodating groove (81b) is recessed to a predetermined width and depth on both sides of the bottom to accommodate one end of the water tray (83).

The guide walls 81c protrude vertically from both sides of the bottom surface adjacent to the ventilation hole 81a, and guide rainwater or foreign matter flowing in from the ventilation hole 81a to be collected in the intermediate protective member 82.

The mounting groove 81d is cut through in a circular or angular shape on the inner side surface so that the intermediate protective member 82 is slide-inserted and mounted.

The intermediate protective member 82 is formed in a c-shaped cross-section and is slide-inserted into the mounting groove 81d.

That is, the intermediate protective member 82 collects rainwater or foreign substances flowing into the intermediate ventilation member 81 and transfers them to the main member 11, and includes the inspection hole 82a, the blocking wall 82b, and the mounting protrusion 82c. is formed

The inspection hole 82a has a plurality of openings on the side facing the front, and enables visual inspection while discharging heat accumulated in the solar panel SP to the outside.

The blocking wall (82b) protrudes vertically from the horizontal portion adjacent to the inspection hole (82a) to prevent rainwater or foreign substances inevitably flowing in from the ventilation hole (81a) from being discharged to the inspection hole (82a), thereby blocking the main member (11). forward to

The mounting protrusions 82c protrude in a circular or angular shape at both ends so that they are slide-inserted into the mounting grooves 81d.

The water tray 83 is formed in a c-shaped cross-section and is inserted and mounted on both sides of the intermediate ventilation member 81.

The drip tray 83 collects rainwater introduced between the solar panel SP and the intermediate ventilation member 81 and delivers it to the main member 11 .

That is, as shown in FIG. 15, outside air introduced from the front ventilation member 71 absorbs heat accumulated in the bottom of the solar panel SP, and then passes through the inspection hole 82a and is discharged through the ventilation hole 81a.

Therefore, the heat accumulated in the solar panel (SP) can be quickly released to the outside, which can improve the overall power generation efficiency, as well as shorten the number of man-hours required for inspection due to quick and convenient maintenance.

On the other hand, when it rains, most of the rainwater is discharged to the outside or a drain pipe while flowing down the upper surface of the solar panel (SP) forward.

At this time, rainwater flowing down may flow into an inevitable gap between the main member 11 and the solar panel SP.

As shown in FIG. 16, the rainwater is immediately discharged to the outside or to a drain pipe along the main member 11.

Here, leakage may occur through an unavoidable gap in the main member 11 due to a fastening member or the like.

In this case, it is immediately discharged to the outside or to the drain pipe by the drainage member 15 disposed at the lower end of the main member 11.

And the rainwater flowing down can also flow into the inevitable gap between the solar panels (SP) arranged in front and back.

This rainwater is transferred to the main member 11 disposed on both sides by the reinforcing support member 50.

In addition, rainwater flowing down may also flow into an unavoidable gap between the solar panel SP and the intermediate ventilation member 81.

This rainwater is delivered to the main member 11 disposed on both sides by the drip tray 83.

At this time, even if a typhoon with rain strikes and rainwater flows into the intermediate ventilation member 81, it is transferred to the main member 11 by the intermediate protective member 82.

In this way, the present invention can completely block the leakage of the building, ensuring safety and high lifespan.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and is commonly used in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible by those with knowledge of, and these modified embodiments should not be individually understood from the technical spirit or perspective of the present invention.

SP: solar panel 1: foundation frame
1a: middle purlin 1b: corrugated plate
1c: guide rail 1d: level bracket
1e: angle bar 1f: insulation
1g: waterproof sheet 10: main frame
11: main member 11a: main side
11b: inclined piece 11c: leg piece
11d: fixed piece 11e: connecting piece
11f: connection hole 11g: connection slot
11h: Departure 11i: Separation
11j: mounting piece 12: connecting angle
13: elastic pad 13a: horizontal elastic piece
13b: vertical elastic piece 14: adjusting member
14a: fixing groove 15: drainage member
15a: drainage piece 15b: wing piece
16: fixing member 16a: fixing piece
16b: Alignment piece 20: Intermediate storage member
21, 31, 42: support piece 30: intermediate support member
32: hooking piece 40: reinforcement storage member
50: reinforcing support member 51: supporting piece
52: fitting piece 53: insulation hole
54: vertical piece 60: buffer member
70: external ventilation frame 71: front ventilation member
71a, 71b: ventilation hole 72: rear ventilation member
80: intermediate ventilation frame 81: intermediate ventilation member
81a: ventilation hole 81b: receiving groove
81c: guide wall 81d: mounting groove
82: intermediate protection member 82a: inspection hole
82b: barrier wall 82c: mounting protrusion
83: drip tray

Claims (14)

In a building-integrated solar power generation system that generates electricity itself by installing a solar panel (SP) on the exterior of a window, balcony, roof, or rooftop building,
Middle purlins (1a) mounted horizontally on the exterior of the building at set front-to-back intervals, corrugated plates (1b) mounted on top of the purlins (1a), and set left-right intervals at the top of the corrugated plates (1b) A guide rail (1c) mounted in the vertical direction, a level bracket (1d) mounted to be slidably movable at a set interval before and after each guide rail (1c), and horizontally mounted at each upper end of the level bracket (1d) A foundation frame (1) composed of angle bars (1e), insulators (1f) mounted in empty spaces between the angle bars (1e), and waterproof sheets (1g) laid on the upper surface of the insulators (1f). ;
A main frame (10) mounted vertically on the top of the base frame (1) at set intervals and fixing the solar panels (SP) to be arranged and installed;
Intermediate storage members 20 installed in the vertical direction at set intervals between the main frames 10 and accommodating wires connected to the solar panel SP;
An intermediate support member 30 mounted to cover the upper end of the intermediate storage member 20 and supporting the lower surface of the solar panel SP so as not to droop;
Reinforcement storage members 40 mounted in the horizontal direction at set intervals between the main frames 10 and accommodating wires connected to the solar panel SP;
A reinforcing supporting member 50 that is mounted to cover the top of the reinforcing storage member 40 and supports the lower surface of the solar panel SP so that it does not sag;
A buffer member 60 mounted to cover the upper end of the intermediate supporting member 30 and the reinforcing supporting member 50 and in close contact with the lower surface of the solar panel SP to absorb shock and block heat transfer. So,
The intermediate storage member 20 and the intermediate supporting member 30,
Support pieces 21 and 31 protruding horizontally on both sides so as to overlap each other at each end opposite to each other;
a hooking piece 32 that sequentially bends and protrudes in/outward from one end of the support piece 31 of the intermediate supporting member 30 to induce removal/removal with the intermediate storage member 21;
A building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that it is formed.
The method of claim 1,
The main frame 10,
A main member 11 mounted on the top of the foundation frame 1 with bolts or screws and supporting the solar panels SP at a predetermined height from the floor;
A connection angle member 12 inserted into the center of the main member 11 and connecting the main members 11 in a row to hold each other without twisting;
an elastic pad 13 mounted on an upper end of the main member 11 and absorbing shock applied to the solar panel SP and blocking heat transfer;
an adjusting member 14 mounted on an upper end of the main member 11 and absorbing shock while adjusting a distance between the solar panels SP arranged in front and rear;
a drainage member (15) mounted vertically at each lower end of the main member (11) and collecting rainwater flowing from the main member (11) and discharging it to the outside;
a fixing member 16 mounted in a vertical direction between the solar panels SP and fastened to the main member 11 with a ball/nut to fix the solar panel SP;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that composed of.
The method of claim 2,
The main member 11,
A main piece 11a protruding horizontally with a predetermined width to be mounted on the upper end of the base frame 1;
Inclined pieces 11b protruding obliquely upward toward left and right at both ends of the main piece 11a to provide a drainage space through which rainwater flows;
Leg pieces (11c) protruding vertically downward at each end of the inclined piece (11b) to induce installation on the exterior of the building;
Fixing pieces (11d) protruding horizontally outward at each end of the leg piece (11c) to induce mounting with bolts or screws;
A pair of connection pieces (11e) protruding vertically at a set interval from the center of the main piece (11a);
A connecting hole 11f passing through in a circular or angular shape between the connecting pieces 11e so that the connecting angle member 12 is inserted and mounted;
a connecting slot 11g for slide-accommodating a nut at an upper end of the connecting hole 11f so that the fixing member 16 is mounted;
Mounting pieces (11h) that protrude horizontally toward the left and right sides at each upper end of the connection piece (11e) so that the solar panel (SP) is mounted in a state where the elastic pad (13) is mounted;
Spacer pieces 11i protruding vertically from each end of the mounting pieces 11h facing each other so that the solar panels SP are spaced apart at set intervals;
Mounting pieces 11j protruding vertically upward at each outer end of the mounting piece 11h so that the elastic pad 13 is inserted and mounted in a proper position;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that formed by.
The method of claim 2,
The elastic pad 13,
Horizontal elastic pieces (13a) mounted horizontally on each upper left and right side of the main member (11) to support left and right bottom surfaces of the solar panels (SP);
Vertical elastic pieces (13b) that are vertically mounted on the upper left and right sides of the main member (11) to support the left and right side surfaces of the solar panels (SP);
A building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that it is integrally formed.
The method of claim 2,
The adjusting member 14,
It is formed of a plate-shaped soft material having a set thickness to adjust the front and rear intervals between the solar panels (SP) and absorb shock, and is recessed at a predetermined height in the center of the bottom surface to be fitted to the top of the main member 11. A building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that the groove portion 14a is formed.
The method of claim 2,
The drainage member 15,
a drainage piece (15a) disposed at the lower end of the main member (11) to guide rainwater flowing into a set path;
Wing pieces (15b) protruding obliquely upward toward the left and right sides at each end of each side of the drainage piece (15a) to collect the inflowing rainwater so that it does not overflow;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that formed by.
The method of claim 2,
The fixing member 16,
A fixing piece 16a fastened to the main member 11 with a ball/nut to press and fix the upper edge of the solar panels SP;
A pair of alignment pieces 16b protruding vertically from the lower end of the fixing piece 16a at set intervals to guide the solar panels SP to be spaced apart;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that formed by.
delete The method of claim 1,
The reinforcing support member 50,
a supporting piece 51 protruding horizontally with a width covering the reinforcing storage member 40 to conceal the wire;
A fitting piece 52 protruding in an angular shape at the center of the upper end of the support piece 51 to insert and mount the buffer member 60;
A heat insulation hole 53 passing through the center of the fitting piece 52 in a predetermined shape to block heat transfer from the solar panel SP;
Vertical pieces 54 protruding vertically from both ends of the supporting piece 51 to collect rainwater flowing between the solar panels SP and pass it to the main frame 10;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that formed by.
The method of claim 1,
The building-integrated solar power generation system,
An external ventilation frame 70 installed in the front and rear of the main frame 10 in the horizontal direction, and cooling the solar panels SP by passing air through them;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that it further comprises.
The method of claim 10,
The external ventilation frame 70,
One or more front ventilation members 71 having an A-shaped cross-section and mounted horizontally on the front of the main frame 10;
At least one rear ventilation member 72 having an A-shaped cross-section mounted in the rear of the main frame 10 in a horizontal direction;
composed of,
The front and rear ventilation members 71 and 72,
a plurality of vents 71a and 72a for inducing air circulation on the front and upper surfaces of the front and rear ventilation members 71 and 72, respectively, to release heat accumulated in the solar panel SP;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that formed.
The method of claim 1,
The building-integrated solar power generation system,
Intermediate ventilation frames 80 installed in the horizontal direction between each of the main frames 10, cooling by passing air through the solar panels SP, and providing an inspection space;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that it further comprises.
The method of claim 12,
The intermediate ventilation frame 80,
At least one intermediate ventilation member 81 mounted in a horizontal direction between the main frame 10 and the solar panel SP and discharging heat accumulated in the solar panel SP to the outside;
an intermediate protective member 82 that is slide-inserted and mounted at the lower end of the intermediate ventilation member 81 and collects rainwater flowing into the intermediate ventilation member 81 and transfers it to the main frame 10;
Water trays 83 inserted into and mounted on both sides of the intermediate ventilation member 81 to collect rainwater flowing between the solar panel SP and the intermediate protective member 82 and pass it to the main frame 10;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that composed of.
The method of claim 13,
The intermediate ventilation member 81,
A plurality of ventilation holes (81a) opening toward the front at the upper end to block the inflow of rainwater while discharging heat accumulated in the solar panel (SP) to the outside;
Accommodating grooves 81b recessed to a predetermined width and depth on both bottoms so that one end of the water tray 83 is inserted and accommodated;
Guide walls 81c protruding vertically from both sides of the bottom surface so that rainwater or foreign matter flowing in from the ventilation hole 81a is collected in the intermediate protective member 82;
a mounting groove 81d cut through a circular or angular shape on an inner side surface so that the intermediate protective member 82 is slide-inserted;
Building-integrated photovoltaic power generation system with improved heat dissipation efficiency, safety and drainage, characterized in that formed.

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