KR102267727B1 - Building integrated photovoltaic module installable building exterior system for both photovoltaic module socket and building exterior panel - Google Patents

Abstract

The present invention relates to a solar power module socket and building exterior panel system and, more specifically, to a solar power module socket and building exterior panel system which combines a solar power module with a building exterior panel to form an exterior material of a building itself as an exterior material for installing a solar power module, makes a combination structure of the solar power module and the building exterior panel simple, removes the solar power module from the building exterior panel, or enables the building exterior panel to have a function of a complete building exterior panel when the solar power module is not installed.

Description

Building integrated photovoltaic module installable building exterior system for both photovoltaic module socket and building exterior panel

The present invention relates to a solar power module socket-combining building exterior panel system, and more particularly, by combining a solar power module and a building exterior panel, the exterior material of the building itself is configured as an exterior material for installing a solar power module, but the solar When the photovoltaic module and the building exterior panel have a simple coupling structure, and the solar power module is removed from the building exterior panel, or the solar power module is not installed, the building exterior panel is a complete building exterior panel. It relates to a solar power module socket-combining building exterior panel system having a function.

In general, the Building Integrated Photovoltaic System (BIPV system) is a system that can simultaneously perform the functions of building materials and power generation by installing a photovoltaic module in a building, such as windows, exterior walls, roofs, etc. It is applied in various forms.

In particular, in recent years, most of the methods of mounting solar cell modules on the roof of existing buildings have been taken up, and this method can be implemented by simply fixing the finishing frame that tightly binds the solar cell module to the roof. There is an advantage in that there is no need to dismantle or construct a new structure for solar cell module installation.

However, this method has a disadvantage in that the appearance of the building deteriorates in that the solar cell module assembly is installed on the roof of the existing building, and also in installation, the finishing frame is fixed to the roof by using a fastening means such as a bolt. , there is a problem in that leakage occurs into the building through the through hole of the fastening means formed during the fixing process.

On the other hand, in order to solve the problem of the method of installing the solar cell module using the finishing frame as described above, the method that is currently widely distributed is the building integrated solar power generation roof (Building Integrated) which consists of the solar cell module itself as the roof of the building. Photovoltaic Roof System, BIPV Roof System).

This method has the advantage of being able to reduce the cost for roof construction as well as maintaining the appearance of the building as originally intended by configuring the roof of the building itself as a solar cell module assembly.

Looking at the development technologies for the building-integrated photovoltaic roof system (BIPV Roof System), in Korea Patent Registration 10-1348089 (registration date December 30, 2013), each upper left and right are formed extending in the horizontal direction. The first and second cradles 120 and 130 are provided, and the first and second drain units 160 and 170 are provided on the lower left and right sides, and are installed at a predetermined distance from each other on the upper part of the fixing bar 1 of the building. A plurality of main drainage guide pipe 10 and; A plurality of auxiliary drainage guide pipes (20) which are arranged spaced apart from each other at regular intervals, each provided with a drainage guideway (22) and installed orthogonally to the opposite main drainage guide pipe (10); The first and second cradle ends 120 of the main drain guide pipe 10 and the auxiliary drain guide pipe 20 to seal each space partitioned by the main drain guide pipe 10 and the auxiliary drain guide pipe 20, each end of which is opposed to each other, 130) and a plurality of solar cell modules 30; The closing cap 40 is mounted on the first and second mounting ends 120 and 130 of each of the main drain guide pipe 10 and seals the interspace S formed at the opposite ends of the solar cell modules 30 . of; A building-integrated solar power generation roof, characterized in that it includes, has been developed.

In addition, Korean Patent No. 10-1823957 (registration date January 25, 2018) discloses a B.PV module in which a front frame, a rear frame, and a left and right frame are respectively coupled to the front, rear, left, and right sides of a solar cell, The front frame 20 has a step difference and a support part 21 formed in the shape of a 'L' in the longitudinal direction is formed on the front side, and the support part 21 has a plurality of modules for fixing the modules coupled back and forth to each other or for fixing to the roof. of the installation hole 22 is formed, a fixing groove 23 is formed in the longitudinal direction at the rear side of the installation hole 22, and the rear frame 30 is formed in a '┏' shape to form a plurality of installation holes 32 ) is formed, and a fixing part 31 inserted and fixed into the fixing groove 23 is formed at the lower end, and an elastic part 41 formed on the upper side of the left frame 40 and the right frame 50, respectively. Between 51 and the frame, the solar cell 10 is inserted and fixed together with the protective cover 11, and the cover frame 60 is coupled to the right frame 50 by a plurality of bolts 62, A BPV module installed on a roof is known, in which an elastic part 61 protruding upward of the module is symmetrically formed in a 'C' shape on the upper side of the cover frame 60 .

In addition, Korean Patent No. 10-1832470 (registration date February 20, 2018) discloses a plurality of roof steel frames installed across the roof of the building; a connection support body that is fixed on the roof steel frame and installed to be erected vertically; A vertical wall part installed in close proximity to both sides based on the connection support body, an upper stopping part bent outward from the upper end of the vertical wall part, and a lower stopping part bent outwardly from the lower end of the vertical wall part. Insulation panel fixing member made of; an insulating panel coupled to be fitted between the upper and lower engaging portions of the insulating panel fixing member and installed horizontally on both sides based on the connecting support; a roof plate supporting member that is fixedly installed to protrude upward from a portion of the upper surface of the heat insulating panel and functions as a space; It is supported by the roof plate support member in a state spaced apart from the upper part of the insulation panel, is installed horizontally like the insulation panel, is installed symmetrically on both sides with respect to the connection support body, and is bent upward at the end of the connection support body. a roof plate having an upward locking portion formed thereon and bent upwardly at an opposite end thereof to form a bent seating portion assembled to surround the upper end of the roof plate support member; Installed to block the penetration of rainwater by shielding the space formed between the roof plate and the roof plate at the upper portion of the connection support body, bent downwardly at both ends and formed with downward engaging portions corresponding to the upwardly engaging portions of the roof plate a first roof cover installed in such a way that the downward locking part is engaged with the upward locking part of the roof plate; a waterproof sheet attached to the upper surface of the first roof cover and having a waterproof function; The second roof installed to be seated on the roof plate so as to surround the assembly of the lower engaging portion of the first roof cover and the upper engaging portion of the roof plate from the upper portion of the first roof cover to block rainwater from penetrating into the connecting portion. cover; a photovoltaic module support beam fixedly installed on the upper surface of the second roof cover; and a photovoltaic module fixedly installed on the photovoltaic module support beam; including, the photovoltaic module is installed to be directly supported on the roof steel frame through the connecting support, and the space formed between the connecting support and the roof plate is removed It is configured to be sealed through the first roof cover and the second roof cover, and the connection support body includes a seating part fixed to the upper surface of the roof steel frame, and a fitting groove extending upward from the top surface of the seating part and extending vertically in the inside. A lower support member comprising an upper extension formed to be opened upward, a support portion fixed through a bolt and a nut to which the solar module support beam is fastened through the second roof cover and the first roof cover, and the support portion A plurality of heat-insulating spaces extending downward from the lower surface and separated by partition walls are formed in the lower edge. A connection groove is formed to open downward at the bottom, and a lower edge with a locking groove having a larger diameter than the connection groove is formed inside the connection groove. An upper support member made of a long support portion, a connecting rod portion fitted and coupled to the connection groove is formed at the upper end, and a portion of the connecting rod portion is formed with a locking projection corresponding to the locking groove and assembled to be fitted into the locking groove, and at the lower end, the There is described a solar integrated roof system, characterized in that it is composed of a connecting member having a fitting portion that is fitted and coupled to the fitting groove, and the lower support member and the upper support member are connected through a connecting member to form an integral body.

In addition, Korean Patent No. 10-1855253 (registration date April 30, 2018) discloses a plurality of main drain pipes that are provided to be inclined in the longitudinal direction to correspond to the shape of the inclined roof and are spaced apart from each other in the width direction; A plurality of module fixing members comprising a transversing member provided to cross the upper part of the main drain pipe in the width direction, and a pair of module fixing parts provided to be spaced apart from each other in the upper part of the transversing member from side to side; a plurality of solar cell modules for roofs arranged side by side so that the ends are fixed to the module fixing part of the module holder to form a roof; A first ventilation plate provided horizontally between the adjacent solar cell modules for the roof, the plurality of first ventilation holes being spaced apart from each other in the longitudinal direction, and from both sides in the width direction of the first ventilation plate to the bottom a ventilation cover extending side by side and comprising a pair of opening and closing member guides inserted and mounted between the pair of fixing modules; A second ventilation provided in a horizontal position on the lower portion of the first ventilation plate, in which a plurality of second ventilation holes for opening the first ventilation holes and second closing parts for closing the first ventilation holes are alternately formed with each other Ventilation is made including a plate and a pair of side wall plates extending side by side from both sides in the width direction of the second ventilation plate to the lower side, and guided to slide along the longitudinal direction of the ventilation cover by the ventilation cover hole opening and closing member; The second ventilation hole of the ventilation hole opening and closing member is positioned side by side with the first ventilation hole of the ventilation cover so that the first ventilation hole is opened, or the second closing part of the ventilation hole opening and closing member of the ventilation cover an opening/closing member driving source for slidingly moving the ventilation hole opening and closing member in order to close the first ventilation hole by blocking the first ventilation hole; a temperature sensing unit for sensing a temperature; Rainwater detection unit for detecting rainwater; a control unit controlling the opening and closing member driving source so that the first ventilation hole is opened only when a temperature value equal to or higher than the reference temperature is detected by the temperature sensing unit and no rain water is detected by the rain water sensing unit; A building-integrated photovoltaic roof system capable of controlling ventilation is known, characterized in that it comprises a.

In addition, in Korea Patent Registration 10-2085947 (registration date March 02, 2020) in a building-integrated photovoltaic power generation roof in which a plurality of photovoltaic modules are arranged to form the exterior of the building, the first one or more main rain pipes that are fixedly installed between the solar modules arranged along the direction, and include a guide rib for sliding movement of the module support accommodated therein; at least one auxiliary rain pipe provided above the main rain water pipe and provided between the photovoltaic modules along a second direction for arranging photovoltaic modules; A plurality of the main rain water pipes are accommodated in the main rain water pipe and are provided to be slidably moved by the protrusions seated on the guide ribs, and are configured to include a support part on which a part of the edge of the solar module is seated, and form a single row. and a module support for supporting the photovoltaic module by forming an interval from each other and spaced apart from the main rain pipe by a predetermined distance, wherein the lower space of the photovoltaic module in the state in which the photovoltaic module is arranged is completed. A building-integrated photovoltaic roof is known, characterized in that the air can flow through the installation interval.

In addition, Korean Patent No. 10-2076511 (registration date, February 06, 2020) discloses a plurality of purlins spaced apart from each other and arranged side by side; A lower horizontal surface extending in a direction perpendicular to the longitudinal direction of the furlin and having a lower surface in contact with the furin but disposed in plurality along the longitudinal direction of the furin, and extending in a direction perpendicular to the longitudinal direction of the furin, the lower surface of the furline a base panel spaced apart from the purlin and comprising an upper horizontal plane disposed between the lower horizontal planes, and an inclined plane connecting the lower horizontal plane and the upper horizontal plane; a plurality of earthquake-resistant buffers provided on the base panel; A vertical extension plate extending in a vertical direction while the lower end is coupled to the earthquake-resistant buffer unit, and a horizontal extension plate bent from the upper end of the vertical extension plate and extending in the horizontal direction, extending in parallel to the furin steel for a plurality of saddles; a heat insulating material provided between the plurality of saddle steel materials at the upper portion of the base panel; a plurality of main drain pipes fixedly provided on the upper portion of the steel material for the saddle and disposed side by side spaced apart from each other in a form orthogonal to the longitudinal direction of the steel material for the saddle; a plurality of module holder provided on the upper part of the main drain pipe; a plurality of solar cell modules fixed by the module holder to form a roof; A pair of solar cells disposed at a lower portion between a pair of solar cell modules adjacent to each other along the longitudinal direction of the main drain pipe and disposed in a shape perpendicular to the longitudinal direction of the main drain pipe and adjacent to each other along the longitudinal direction of the main drain pipe a plurality of auxiliary drain pipes for guiding the rainwater flowing between the modules to be discharged to the main drain pipe; The earthquake-resistant buffer unit includes: a lower fixing plate fixed to the lower horizontal surface of the base panel, and a pair of inclined fixing plates extending outward from both ends of the lower fixing plate and fixed to the inclined surface of the base panel. And, an upper fixing plate respectively extending outward in the horizontal direction from the upper end of the inclined fixing plate and fixed to the upper horizontal surface of the base panel, and spaced apart from the lower fixing plate to the upper part and extending in the horizontal direction, each of both ends is integrated with the inclined fixing plate a lower sliding guide plate, a pair of horizontal spring mounts that extend in the horizontal direction along the extension direction of the lower horizontal surface of the base panel between the lower fixed plate and the lower sliding guide plate and open toward the outside in the horizontal direction, the lower part An earthquake-resistant frame body comprising: a first vertical spring mounting hole formed in the upper central portion of the fixing plate and opened toward the top, and an upper sliding guide plate extending in the inner horizontal direction from each of the pair of inclined fixing plates; a vertical compression spring whose lower end is fixed to the first vertical spring mounting hole; A spring cover in the form of a cap formed with a second vertical spring mounting hole to which the upper end of the vertical compression spring is fixed, and a spring cover extending in an upward direction from the top of the spring cover are coupled to the lower end of the vertical extension plate of the saddle steel An earthquake-resistant frame upper cover comprising a pair of vertical coupling plates; a pair of horizontal compression springs having an inner end fixed to the horizontal spring mount; Between the lower sliding guide plate and the upper sliding guide plate is provided to be slidable in the horizontal direction with respect to the earthquake-resistant frame body, a central through-hole having a larger area than the spring cover of the earthquake-resistant frame upper cover is formed in the center, both sides in the longitudinal direction Sliding horizontal plate having a slot hole for a spring and a slot hole for a flat bar on the edge; a first bolt member having an upper end inserted in the vertical direction into the slot hole for the spring to be slidably provided along the slot hole for the spring and having a lower end coupled to the outer end of the compression spring in the horizontal direction; a second bolt member which is vertically inserted into the slot hole for the flat bar and slidably provided along the slot hole for the flat bar; One end is coupled to the second bolt member of the earthquake-resistant buffer unit coupled to one steel material for a saddle, and the other end is coupled to the second bolt member of the earthquake-resistant buffer unit coupled to the other steel material for saddle flat bar ( a plurality of horizontally connected flat bars in the form of flat bars; A building-integrated photovoltaic roof with an earthquake-resistant function is known, characterized in that it comprises a.

However, since the various prior arts are integrally formed with the solar cell module and the roof material in that the roof of the building itself is composed of a solar power roof, it does not damage the exterior of the building and has the effect of increasing the power generation efficiency of the solar cell module. However, when the solar cell module is removed or removed from the roofing material, the function as a roofing material is lost, and when a solar cell module is not installed, there is a problem in that a separate roofing material must be installed and constructed. The complex structure of the battery module had a very inconvenient problem in construction.

[Patent Document 001] Korean Patent Registration 10-1348089 (Registration Date December 30, 2013) [Patent Document 002] Korean Patent 10-1823957 (Registration Date January 25, 2018) [Patent Document 003] Korean Patent 10-1832470 (Registration Date: February 20, 2018) [Patent Document 004] Korean Patent No. 10-1855253 (Registration Date: April 30, 2018) [Patent Document 005] Korean Patent 10-2085947 (Registration Date March 02, 2020) [Patent Document 006] Korean Patent Registration 10-2076511 (Registration Date February 06, 2020)

The present invention is to solve the above conventional problems, but by combining the photovoltaic power module and the building exterior panel to configure the exterior material of the building itself as an exterior material for installing the solar power module, the photovoltaic module and the building exterior material panel is combined The structure is simple, and when the photovoltaic module is removed from the building exterior panel or the solar power module is not installed, the building exterior panel has the function of a complete building exterior panel. It is a problem to be solved to provide an exterior panel system.

단면형상으로 연장형성되고, 내부 측면에는 길이방향으로 하니컴 격자 형태의 보강재가 설치되며, 상부에는 태양광 발전 모듈 소켓의 절반폭이 안치되고, 나머지 절반폭은 외부로 돌출되어 형성되는 제1측면거치프레임과; 상기 하부결합요부를 제외한 상기 패널 플레이트 측변 상부 평면에서 수직으로 일정폭 및 일정 높이의

단면형상으로 연장형성되고, 내부 측면에는 길이방향으로 하니컴 격자 형태의 보강재가 설치되는 제2측면거치프레임;을 포함하여 구성되고, 상호 인접된 상기 상부결합홈부와 상기 하부결합요부가 상하 결합되며, 상기 제1측면거치프레임의 외부로 돌출된 태양광 발전 모듈 소켓의 나머지 절반폭은 상기 제2측면거치프레임 상부에 안치 결합되어 형성되는 태양광 발전 모듈 소켓 겸용 건축물 외장재 패널 시스템을 과제의 해결수단으로 한다.The present invention, in order to solve the above problems, a panel plate formed in a rectangular plate shape to a predetermined thickness and used as a building exterior panel; an upper coupling groove formed on one side of the panel plate to have a predetermined width in the longitudinal direction, the upper portion of the predetermined width being formed in a flat surface, and the lower portion having a longitudinal concave portion having a predetermined depth in the upper direction; A lower coupling recess formed with a predetermined width in the longitudinal direction on the other side opposite to one side of the panel plate, the lower portion of the constant width being formed in a plane, and the upper portion being formed with a longitudinal convex portion having a predetermined height in the upper direction; ; Vertically in the upper plane of the upper coupling groove portion of a certain width and a certain height

It is formed to extend in a cross-sectional shape, and a honeycomb grid-shaped reinforcement is installed on the inner side in the longitudinal direction, the half width of the photovoltaic module socket is placed on the upper part, and the other half width is formed by protruding to the outside. frame; Vertically of a certain width and a certain height in the upper plane of the side of the panel plate except for the lower coupling recess

It is formed to extend in a cross-sectional shape, and a second side support frame in which a reinforcing material in the form of a honeycomb lattice is installed on an inner side surface in the longitudinal direction is included, and the upper coupling groove portion and the lower coupling recess portion adjacent to each other are vertically coupled, The other half width of the photovoltaic module socket protruding to the outside of the first side mounting frame is mounted and coupled to the upper part of the second side mounting frame to form a solar power module socket combined building exterior panel system as a means of solving the problem do.

The edge frame of the photovoltaic module is mounted on each of the upper half width and the other half width of the photovoltaic module socket, and the photovoltaic module is fixedly installed by screwing it as a means of solving the problem.

In the longitudinal direction of the central portion dividing the half width and the other half width of the photovoltaic module socket, a guide rib is formed to align and guide the edge frame of the photovoltaic module in the longitudinal direction as a means of solving the problem.

As a means of solving the problem, a ventilation space formed at an interval of 10 cm or more is formed between the panel plate and the photovoltaic module to enable ventilation in order to prevent a decrease in efficiency due to a temperature increase while the photovoltaic module is generating power. do.

Each of the panel plate, the upper coupling groove, the lower coupling recess, the honeycomb lattice type reinforcement, the first side frame and the second side frame is a non-combustible material according to KS F ISO 1182 (non-combustible test method for building materials). as a solution to

The photovoltaic power module socket combined building exterior panel system of the present invention combines the photovoltaic power module and the building exterior material panel to configure the exterior material of the building itself as an exterior material for installing the solar power module, but the solar power module and the building exterior material The combination structure of the panel is simple, and when the photovoltaic power module is removed from the building exterior panel or the photovoltaic power module is not installed, the building exterior panel has the function of a complete building exterior material panel, so photovoltaic power generation When the module socket is not installed, there is an excellent effect that it is not necessary to install a separate building exterior material as in the prior art.

1 is a cross-sectional perspective view of the solar power module socket combined building exterior panel system of the present invention
Figure 2 is a cross-sectional view of the solar power module socket combined building exterior panel system of the present invention
Figure 3 is a cross-sectional left and right enlarged view of the solar power module socket combined building exterior panel system of the present invention
Figure 4 is a coupling process diagram of the solar power module socket combined building exterior panel system of the present invention
5 is a combined state diagram of a building exterior material system for installation of a building-integrated photovoltaic power module of the present invention;
Figure 6 is a cross-sectional view of the arrangement of the solar power module socket combined building exterior panel system of the present invention
7 is a combined perspective view of the solar power module socket combined building exterior panel system of the present invention
8 is a parking lot application view of the solar power module socket combined building exterior panel system of the present invention

단면형상으로 연장형성되고, 내부 측면에는 길이방향으로 하니컴 격자 형태의 보강재가 설치되며, 상부에는 태양광 발전 모듈 소켓의 절반폭이 안치되고, 나머지 절반폭은 외부로 돌출되어 형성되는 제1측면거치프레임과; 상기 하부결합요부를 제외한 상기 패널 플레이트 측변 상부 평면에서 수직으로 일정폭 및 일정 높이의

단면형상으로 연장형성되고, 내부 측면에는 길이방향으로 하니컴 격자 형태의 보강재가 설치되는 제2측면거치프레임;을 포함하여 구성되고, 상호 인접된 상기 상부결합홈부와 상기 하부결합요부가 상하 결합되며, 상기 제1측면거치프레임의 외부로 돌출된 태양광 발전 모듈 소켓의 나머지 절반폭은 상기 제2측면거치프레임 상부에 안치 결합되어 형성되는 태양광 발전 모듈 소켓 겸용 건축물 외장재 패널 시스템을 기술구성의 특징으로 한다.The present invention, a panel plate formed in a rectangular plate shape to a predetermined thickness and used as a building exterior panel; an upper coupling groove formed on one side of the panel plate to have a predetermined width in the longitudinal direction, the upper portion of the predetermined width being formed in a flat surface, and the lower portion having a longitudinal concave portion having a predetermined depth in the upper direction; A lower coupling recess formed with a predetermined width in the longitudinal direction on the other side opposite to one side of the panel plate, the lower portion of the constant width being formed in a plane, and the upper portion being formed with a longitudinal convex portion having a predetermined height in the upper direction; ; Vertically in the upper plane of the upper coupling groove portion of a certain width and a certain height

It is formed to extend in a cross-sectional shape, and a honeycomb grid-shaped reinforcement is installed on the inner side in the longitudinal direction, the half width of the photovoltaic module socket is placed on the upper part, and the other half width is formed by protruding to the outside. frame; Vertically of a certain width and a certain height in the upper plane of the side of the panel plate except for the lower coupling recess

It is formed to extend in a cross-sectional shape, and a second side support frame in which a reinforcing material in the form of a honeycomb lattice is installed on an inner side surface in the longitudinal direction is included, and the upper coupling groove portion and the lower coupling recess portion adjacent to each other are vertically coupled, The other half width of the photovoltaic module socket protruding to the outside of the first side mounting frame is mounted and coupled to the upper part of the second side mounting frame to form a photovoltaic power module socket combined building exterior panel system as a feature of the technical configuration do.

The edge frame of the photovoltaic module is mounted on each of the half width and the other half width of the photovoltaic module socket, and the photovoltaic module is fixedly installed by screwing.

It is characterized in that a guide rib is formed to align and guide the edge frame of the photovoltaic module in the longitudinal direction in the longitudinal direction of the central part that separates the half width and the other half width of the photovoltaic module socket.

It is a feature of the technical configuration that a ventilation space formed at an interval of 10 cm or more is formed between the panel plate and the photovoltaic module to enable ventilation in order to prevent a decrease in efficiency due to a temperature increase while the photovoltaic module is generating power. do.

Each of the panel plate, upper coupling groove, lower coupling recess, honeycomb lattice type reinforcement, first side mounting frame and second side mounting frame is a non-combustible material according to KS F ISO 1182 (non-combustible testing method for building materials). characteristic of the composition.

Hereinafter, embodiments and drawings of the present invention will be described in detail so that those of ordinary skill in the art can easily carry out the present invention. However, the present invention may be embodied in several different forms, and is not limited to the embodiments and drawings described herein.

단면형상으로 연장형성되고, 내부 측면에는 길이방향으로 하니컴 격자 형태의 보강재(200)가 설치되며, 상부에는 태양광 발전 모듈 소켓(300)의 절반폭(301)이 안치되고, 나머지 절반폭(302)은 외부로 돌출되어 형성되는 제1측면거치프레임(400)과; 상기 하부결합요부(104)를 제외한 상기 패널 플레이트(100) 측변 상부 평면에서 수직으로 일정폭 및 일정 높이의

단면형상으로 연장형성되고, 내부 측면에는 길이방향으로 하니컴 격자 형태의 보강재(200)가 설치되는 제2측면거치프레임(500);을 포함하여 구성되고, 상호 인접된 상기 상부결합홈부(102)와 상기 하부결합요부(104)가 상하 결합되며, 상기 제1측면거치프레임(400)의 외부로 돌출된 태양광 발전 모듈 소켓(300)의 나머지 절반폭(302)은 상기 제2측면거치프레임(500) 상부에 안치 결합되어 형성된다.First, referring to [Fig. 1] to [Fig. 8], the solar power module socket combined building exterior panel system of the present invention is formed in a rectangular plate shape with a certain thickness and used as a building exterior panel panel. (100) and; The upper coupling is formed on one side of the panel plate 100 with a predetermined width in the longitudinal direction, the upper portion of the predetermined width is formed in a flat surface, and the lower portion is formed with a longitudinal concave portion 101 having a predetermined depth in the upper direction. a groove 102; On the other side opposite to one side of the panel plate 100 is formed with a predetermined width in the longitudinal direction, the lower portion of the constant width is formed as a flat surface, and the upper portion is a longitudinal convex portion 103 having a predetermined height in the upper direction. And the lower coupling recess 104 is formed; Vertically in the upper plane of the upper coupling groove portion 102 of a certain width and a certain height

It is formed to extend in a cross-sectional shape, and the reinforcing material 200 in the form of a honeycomb grid is installed on the inner side in the longitudinal direction, the half width 301 of the solar power module socket 300 is placed on the upper part, and the other half width 302 ) is a first side mounting frame 400 and formed to protrude to the outside; In the upper plane of the side of the panel plate 100 excluding the lower coupling recess 104, the vertical width and height of the

It is formed to extend in a cross-sectional shape, and a second side mounting frame 500 in which a reinforcing material 200 in the form of a honeycomb lattice is installed on the inner side in the longitudinal direction is included, and the upper coupling groove portion 102 adjacent to each other and The lower coupling recess 104 is vertically coupled, and the other half width 302 of the photovoltaic module socket 300 protruding to the outside of the first side mounting frame 400 is the second side mounting frame 500 ) is formed by being seated on top

At this time, the edge frame 701 of the photovoltaic module 700 is placed on the upper half width 301 and the other half width 302 of the photovoltaic module socket 300, respectively, and is screwed to the photovoltaic power module 700 is fixedly installed.

In addition, in the longitudinal direction of the central part that separates the half width 301 and the other half width 302 of the photovoltaic module socket 300, the edge frame 701 of the photovoltaic module 700 is aligned in the longitudinal direction. A guide rib 600 is formed to guide.

In addition, the photovoltaic power module 700 is formed with an interval of 10 cm or more between the panel plate 100 and the photovoltaic power module 700 to enable ventilation to prevent a decrease in efficiency due to a temperature increase during power generation. A ventilation space 800 is formed.

In particular, as shown in [Fig. 8], the solar power module socket combined building exterior panel system of the present invention can be installed not only as a general building exterior material, but also as a parking lot building roof or exterior material.

In addition, the panel plate 100, the upper coupling groove portion 102, the lower coupling recessed portion 104, the reinforcing material 200 in the form of a honeycomb grid, the first side mounting frame 400 and the second side mounting frame 500, respectively It is preferable to use silver as a non-combustible material according to KS F ISO 1182 (Test method for non-combustibility of building materials).

The above description is merely illustrative of the technical idea of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments and drawings disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments and drawings. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: panel plate 101: concave
102: upper coupling groove portion 103: convex portion
104: lower coupling recess 200: reinforcing material
300: solar power module socket 301: half width
302: the other half width 400: the first side mounting frame
500: second side mounting frame 600: guide rib
700: solar power module 701: frame frame
800: ventilation space

Claims (5)

a panel plate formed in a rectangular plate shape with a predetermined thickness and used as a building exterior panel; an upper coupling groove formed on one side of the panel plate to have a predetermined width in the longitudinal direction, the upper portion of the predetermined width being formed in a flat surface, and the lower portion having a longitudinal concave portion having a predetermined depth in the upper direction; A lower coupling recess formed with a predetermined width in the longitudinal direction on the other side opposite to one side of the panel plate, the lower portion of the constant width being formed in a plane, and the upper portion being formed with a longitudinal convex portion having a predetermined height in the upper direction; ; Vertically in the upper plane of the upper coupling groove portion of a certain width and a certain height

It is formed to extend in a cross-sectional shape, and a honeycomb grid-shaped reinforcement is installed on the inner side in the longitudinal direction, the half width of the photovoltaic module socket is placed on the upper part, and the other half width is formed by protruding to the outside. frame; Vertically of a certain width and a certain height in the upper plane of the side of the panel plate except for the lower coupling recess

It is formed to extend in a cross-sectional shape, and a second side support frame in which a reinforcing material in the form of a honeycomb lattice is installed on an inner side surface in the longitudinal direction is included, and the upper coupling groove portion and the lower coupling recess portion adjacent to each other are vertically coupled, The other half width of the photovoltaic module socket protruding to the outside of the first side mounting frame is formed by being seated and coupled to the upper part of the second side mounting frame,
A guide rib is formed to align and guide the edge frame of the photovoltaic module in the longitudinal direction in the longitudinal direction of the central part dividing the half width and the other half width of the photovoltaic module socket,
Each of the panel plate, the upper coupling groove, the lower coupling recess, the honeycomb lattice type reinforcement, the first side frame and the second side frame is a non-combustible material according to KS F ISO 1182 (non-combustibility testing method for building materials). Solar power module socket combined building exterior panel system with
According to claim 1,
A photovoltaic power module socket combined building exterior panel, characterized in that the edge frame of the photovoltaic module is placed and screwed on each of the half width and the other half width of the photovoltaic module socket, and the photovoltaic module is fixedly installed system
delete 3. The method of claim 2,
Solar power, characterized in that a ventilation space formed at an interval of 10 cm or more is formed between the panel plate and the photovoltaic module to enable ventilation in order to prevent a decrease in efficiency due to a temperature increase while the photovoltaic power module is generating power Building exterior panel system for power generation module socket delete

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