KR102585355B1 - Roof panel system and construction method thereof - Google Patents

Abstract

The present invention relates to a roof panel system having a thermal break and a rotational assembly seismic isolation structure, which includes a plurality of frames, a base panel disposed on the frame and having a plurality of grooves extending in one direction, and disposed on the base panel. , a panel support bar extending parallel to the frame, a joint assembly seated in the groove and connecting the base panel and the panel support bar to form a restoring force in the height direction, and a roof panel disposed on the panel support bar.

Description

Roof panel system with rotational assembly and earthquake-resistant structure and construction method thereof {Roof panel system and construction method thereof}

The present invention relates to a roof panel system with thermal breakage and rotational assembly seismic isolation structure and a method of constructing the same. Additionally, the present invention relates to a roof panel system with integrated solar power generation equipment and a construction method thereof.

In general, the roofs of buildings are made in various forms, and recently, roof panel assemblies using panels have been widely used. These roof panel assemblies are sometimes manufactured with solar modules to produce electrical energy using solar energy. do.

A roof panel system including a solar panel or solar module may be constructed by sequentially combining a lower panel, an insulation board, and an upper panel to form an insulation assembly, and a solar module is installed on the insulation assembly.

Roof panel systems require maintenance depending on the external environment because solar panels are exposed to the outside. For example, when it rains, rainwater flows into the roof panel system, and a function is needed to quickly discharge the inflowed rainwater to the outside. Therefore, research and development on a roof panel system with rapid and large drainage capacity is needed.

Previously, solar panels were attached to the roof by placing them on the completed roof. In other words, it was constructed on the roof of the building using the PV (Photovoltaic) method, but two processes had to be carried out sequentially, and there were limits to reducing construction costs. Recently, research and development on building-integrated photovoltaic power generation continues. Building-integrated solar power generation can reduce construction costs by using solar panels as the exterior material of the building.

Building roofs are made in various shapes, and prefabricated roof panels have been widely used recently. Prefabricated roof panels are usually constructed by connecting exterior metal panels such as surface-treated steel or aluminum. When forming the roof of a building with prefabricated roof panels, the construction period is shortened, construction costs can be reduced, and the exterior of the building can be designed in more diverse ways.

Generally, a prefabricated roof panel first installs a purlin at the top of a building, and then the lower panel, upper panel, and members supporting them are placed on it, and the members are fastened to each other with clips, bolts, etc.

However, when vibration from an earthquake or strong wind is transmitted to the prefabricated roof panel, each member shakes, applying stress to the connected parts, and there is a problem that the assembled structure may be damaged.

The present invention seeks to provide a roof panel system with a thermal break and rotational assembly seismic isolation structure that improves insulation performance by blocking heat transfer and forms a stable roof structure, and a method of constructing the same.

The present invention can provide a roof panel system integrated with solar power generation equipment that forms a stable structure for buildings installed, etc. and is easy to construct and manage. Additionally, the present invention can provide a roof panel system having a structure that facilitates drainage.

One aspect of the present invention includes a plurality of frames, a base panel disposed on the frame and having a plurality of grooves extending in one direction, a panel support bar disposed on the base panel and extending parallel to the frame, A roof panel system including a joint assembly that is seated in a groove and connects the base panel and the panel support bar to form a restoring force in the height direction, and a roof panel disposed on the panel support bar, and has a thermal isolation and rotation assembly seismic isolation structure. provides.

Additionally, the joint assembly may include a mount unit seated in the groove, a saddle unit assembled to the mount unit and connected to the panel support bar, and a restoring force generating member disposed between the mount unit and the saddle unit.

Additionally, the mount unit may be mounted in a groove of the base panel and include a first mount made of an elastic material, and a second mount that is inserted into the first mount and supports the saddle unit.

Additionally, when the saddle unit is rotated after being inserted into the mount unit, a body assembled to the mount unit, a saddle extending to the body and having an insertion groove, and the panel support bar are assembled and a train inserted into the insertion groove. Only sheets can be provided.

Additionally, the saddles may have a first long hole extending in the height direction, and the heat barrier sheet may have a second long hole extending parallel to the first long hole.

Additionally, the saddle unit may have a guide groove into which a portion of the restoring force generating member is inserted, and the heat-blocking sheet may be provided with a support cover inserted into a seating groove disposed at an upper end of the saddle.

Another aspect of the present invention includes installing a plurality of frames on the upper part of a building, installing a base panel having a plurality of grooves on the plurality of frames, installing a joint assembly in the groove, and installing a joint assembly along the frame. Inserting an extending panel support bar into the joint assembly, and installing a roof panel on the panel support bar, wherein the joint assembly includes a mount unit seated in the groove, assembled to the mount unit, and the panel. A construction method of a roof panel system with a thermal bridge isolation and rotation assembly seismic isolation structure, including a saddle unit to which a support bar is connected, and a restoring force generating member disposed between the mount unit and the saddle unit to form a restoring force in the height direction. to provide.

Additionally, in the step of installing the joint assembly, the saddle unit may be inserted into the mount unit and then rotated to assemble the mount unit and the saddle unit.

The roof panel system and construction method equipped with thermal insulation and rotational assembly seismic isolation structure according to an embodiment of the present invention can reduce costs and improve efficiency by shortening the construction period of the building roof.

In addition, the roof panel system and construction method equipped with thermal insulation and rotational assembly seismic isolation structure according to an embodiment of the present invention can have seismic isolation performance by forming a restoring force against vibration transmitted according to external environments such as earthquakes or typhoons. there is.

In addition, the roof panel system and construction method equipped with thermal insulation and rotational assembly seismic isolation structure according to an embodiment of the present invention stably forms the assembly structure of each member, and allows for follow-up management through partial replacement and repair after construction. It can be easy.

The roof panel system according to the present invention provides a seismic isolation structure for solar power generation facilities installed on top, so safety can be maintained even if external earthquakes or vibrations occur. In addition, it is possible to prevent heat generated during solar power generation from being transferred internally by providing a thermal barrier structure for solar power generation facilities.

The roof panel system with integrated solar power generation equipment and its installation method according to the present invention uses solar power generation equipment or solar panels as the exterior material of the building, thereby reducing construction costs and reducing construction time.

The roof panel system with integrated solar power generation equipment and its installation method according to the present invention form a stable structure in the building where it is installed, and the roof panel system is easy to construct and manage. The roof panel system can be installed easily and simply into the insulation assembly. Additionally, the roof panel system can have a stable structure because the bracket unit, support rail, and supporter form a support structure.

The roof panel system with integrated solar power generation equipment and its installation method according to the present invention can have a structure with smooth drainage. The roof panel system distributes rainwater through a first gutter located along the solar panel and a pair of second gutters located on both sides. The drainage frame can distribute rainwater to a pair of second gutters, leading to stable drainage. In other words, the roof panel system can improve drainage by dispersing rainwater through three gutters placed below the solar panel.

Figure 1 is a perspective view showing a roof panel system according to an embodiment of the present invention.
FIG. 2 is a view showing the roof panel system of FIG. 1 viewed from the front.
Figure 3 is an enlarged view of part A of Figure 2.
Figure 4 is an exploded perspective view of the joint assembly of Figure 3.
5 and 6 are diagrams for explaining the assembly method of the joint assembly.
Figure 7 is a diagram for explaining the construction method of the roof panel system of Figure 2.
Figure 8 is a perspective view showing a roof panel system with integrated solar power generation equipment according to an embodiment of the present invention.
Figure 9 is a cross-sectional view taken along ±-± of Figure 8.
FIG. 10 is an enlarged view of area A of FIG. 9.
Figure 11 is a perspective view showing the supporter of Figure 8.
FIG. 12 is a plan view showing a partial configuration of the roof panel system of FIG. 8.
FIG. 13 is a partial cross-sectional view of the drainage frame taken along μ-μ in FIG. 12.
Figure 14 is a flowchart showing a method of installing a roof panel system with integrated solar power generation equipment according to another embodiment of the invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. The effects and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms.

Hereinafter, the following embodiments will be described in detail with reference to the accompanying drawings. When describing with reference to the drawings, identical or corresponding components will be assigned the same reference numerals and duplicate descriptions thereof will be omitted.

In the drawings, in order to clearly explain the present invention, parts not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

In the following embodiments, terms such as first and second are used not in a limiting sense but for the purpose of distinguishing one component from another component.

In the following examples, singular expressions include plural expressions, unless the context clearly dictates otherwise.

In the following embodiments, terms such as include or have mean the presence of features or components described in the specification, and do not exclude in advance the possibility of adding one or more other features or components.

In the following embodiments, when a part of a unit, area, component, etc. is said to be on or on another part, it is not only the case where it is directly on top of the other part, but also when other units, areas, components, etc. are interposed between them. Also includes cases.

In the following embodiments, terms such as connect or combine do not necessarily mean a direct and/or fixed connection or combination of two members, unless the context clearly indicates otherwise, and do not mean that another member is interposed between the two members. It's not exclusion.

In the drawings, the sizes of components may be exaggerated or reduced for convenience of explanation. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, so the following embodiments are not necessarily limited to what is shown.

Hereinafter, the roof panel system 1 may be defined as having a roof structure that covers the upper part of a building, and as a structure in which a plurality of panels can be mounted.

The roof panel system 1 according to an embodiment of the present invention may have a solar panel installed on the top so that the solar power generation equipment is integrated. The roof panel system (1) is installed outside and can produce electricity by solar panels. For example, the roof panel system 1 with integrated solar power generation equipment may be installed on the roof or wall of a building, or on a support structure for solar power generation.

The roof panel system 1 according to another embodiment of the present invention may include a roof panel including an insulating material, etc. The roof panel system 1 can be installed on the roof of a building to form the structure of the roof of the building.

1 to 7 show a roof panel system (1) having a thermal insulation and rotational assembly seismic isolation structure, which is installed in a building, and will be described focusing on the basic lower structure on which the roof panel or solar panel is supported. In addition, FIGS. 8 to 23 will focus on an embodiment in which solar power generation equipment is integrated by arranging solar panels installed on the basic lower structure. Therefore, the roof panel system 1 hereinafter may be viewed as including a lower basic structure disposed on the upper part of a building or a state in which a solar panel or roof panel is mounted on the upper part of the lower basic structure.

FIG. 1 is a perspective view showing a roof panel system according to an embodiment of the present invention, and FIG. 2 is a view showing the roof panel system of FIG. 1 viewed from the front.

According to one embodiment of the present invention, the roof panel system 1 may be installed on the top of a building. The roof panel system 1 can be installed by connecting a plurality of panels on the top of a building.

Referring to FIGS. 1 and 2 , the roof panel system 1 may include a frame 100, a base panel 200, a joint assembly 300, and a panel support bar 400. Additionally, the roof panel system 1 may include a sliding clip 500, a heat-blocking pad 600, a roof panel 700, a sound-absorbing sheet 800, and an insulation material 900.

The frame 100 is located at the top of the building and can be installed in the area where the roof is being constructed. There may be a plurality of frames 100, and a base panel 200 may be disposed on the plurality of frames 100.

The frame 100 may be formed in a shape extending in the Y-axis direction. The frame 100 may form a lateral bearing force at the lower part of the roof.

In one embodiment, the frame 100 may be formed in a tubular shape. The frame 100 may be made of C-beam steel, which is widely used in the relevant technical field. However, it is not necessarily limited to this, and the frame 100 can be used as long as it has a sufficient area to be installed in a building and has a shape that forms a predetermined height.

The base panel 200 may be disposed on a plurality of frames 100 to cover the upper part of the building.

In one embodiment, the base panel 200 has approximately the shape of a plate and may have a plurality of grooves 210. Each groove 210 may be formed to be spaced apart at a predetermined interval.

In one embodiment, the groove 210 may have a groove shape extending in the X-axis direction. The groove 210 may be provided as a step that is recessed from the upper surface of the base panel 200. The bottom of the groove 210 contacts the frame 100, and the base panel 200 may be fastened to the frame 100 by a connecting member such as a bolt.

The joint assembly 300 may be positioned on the base panel 200 and seated in the groove 210. The joint assembly 300 may extend in the Z-axis direction and may be provided to protrude beyond the upper surface of the base panel 200.

The joint assembly 300 may be connected to the panel support bar 400. The joint assembly 300 may be provided to support the panel support bar 400. Specifically, a portion of the panel support bar 400 may be inserted into the joint assembly 300.

The joint assembly 300 may be provided in plural numbers, and the plurality of joint assemblies 300 may be arranged on the base panel 200 to be spaced apart at a predetermined interval.

According to one embodiment, the plurality of joint assemblies 300 may be arranged side by side in the Y-axis direction. Each joint assembly 300 may be seated in grooves 210 spaced apart at predetermined intervals along the Y-axis direction. A panel support bar 400 may be disposed on the plurality of joint assemblies 300.

At this time, within the same groove 210 as the plurality of joint assemblies 300, other joint assemblies 300 are seated at predetermined intervals along the X-axis direction, and other panel support bars 400 are placed on them. can be placed.

However, in the plurality of panel support bars 400, as long as the spacing between them is formed appropriately for construction, the different joint assemblies 300 do not need to be arranged side by side in the X-axis direction.

The joint assembly 300 may be provided to form a restoring force. At least one portion of the joint assembly 300 may be configured to move up and down along the Z-axis.

For example, the joint assembly 300 may have a lower member and an upper member that are individually formed and have a structure in which they are assembled. In the joint assembly 300, a restoring force may be formed between the lower member and the upper member. The joint assembly 300 may be provided so that when the lower member is fixed to the groove 210, the upper member can move up and down along the Z axis, but can be restored to its original position.

The panel support bar 400 may be disposed on the base panel 200. The panel support bar 400 may be installed on the upper surface of the base panel 200 by the joint assembly 300. A plurality of panel support bars 400 may be provided, and a roof panel 700 forming the outer roof of the building may be disposed on the plurality of panel support bars 400.

The panel support bar 400 may be formed in a shape that extends parallel to the frame 100.

According to one embodiment, the panel support bar 400 may be disposed at the same position as the frame 100 with the base panel 200 interposed therebetween. At this time, the frame 100, base panel 200, and panel support bar 400 may be connected to each other by one connecting member.

The panel support bar 400 may be provided with a vertical portion 410 formed perpendicular to the base panel 200 and a parallel portion 420 formed parallel to the base panel 200. The vertical portion 410 is connected to the joint assembly 300, and the parallel portion 420 may support the roof panel 700.

Therefore, by installing the joint assembly 300 and the panel support bar 400 on the base panel 200, the base panel 200 and the roof panel 700 can be spaced apart at a predetermined height, and the base panel 200 ) A space may be formed between the roof panel 700 and the roof panel 700.

In an alternative embodiment, roof panel system 1 may include sliding clips 500 and thermal barrier pads 600.

The sliding clip 500 and the heat shield pad 600 may be disposed on the panel support bar 400. Specifically, the sliding clip 500 and the heat blocking pad 600 may be installed on the parallel portion 420.

The sliding clip 500 may extend in the Z-axis direction and be connected to a portion of the roof panel 700. The sliding clip 500 may be provided so that the side part of the roof panel 700 is inserted and slides.

A plurality of sliding clips 500 may be provided, and a plurality of sliding clips 500 may be arranged on the panel support bar 400 to be spaced apart at a predetermined interval.

A plurality of roof panels 700 can be installed by a plurality of sliding clips 500. On the panel support bar 400, a plurality of sliding clips 500 may be arranged side by side in the Y-axis direction. Each sliding clip 500 may be installed at predetermined intervals along the Y-axis direction.

For example, as shown in FIG. 2, one roof panel 700 may be disposed between two sliding clips 500. That is, the spacing between the sliding clips 500 may be determined according to the width of the roof panel 700 in the Y-axis direction.

The heat blocking pad 600 may be disposed between the parallel portion 420 and the sliding clip 500 to surround the lower portion of the sliding clip 500.

The heat-blocking pad 600 may be installed on the parallel portion 420 of the panel support bar together with the sliding clip 500 using a connecting member such as a bolt.

The heat-blocking pad 600 may be made of a material with excellent heat-blocking effect. The heat blocking pad 600 may be provided to prevent heat transfer between the sliding clip 500 and the panel support bar 400.

In the roof panel system 1, the connection portion of the sliding clip 500 and the roof panel 700 may protrude outward, and the connection portion is likely to be heated by solar heat. At this time, the heat blocking pad 600 can block the heat applied to the sliding clip 500 and reduce the temperature rise of the panel support bar 400.

As the thermal insulation pad 600 blocks heat transfer between the sliding clip 500 and the panel support bar 400, temperature changes in the internal space of the roof panel system 1 can be reduced and condensation can be prevented. The insulation of buildings can be improved.

The roof panel 700 may be supported by the panel support bar 400. The roof panel 700 may be installed on the panel support bar 400 to form the outer surface of the roof. The roof panel 700 can be installed on the panel support bar 400 using a sliding clip 500.

The roof panel 700 may be formed in a plate shape extending in the X-axis direction. A sliding connection part is formed on the side of the roof panel 700, and the sliding connection part may be provided to be inserted into the sliding clip 500.

There may be a plurality of roof panels 700. A plurality of roof panels 700 may be connected to each other by sliding clips 500 and form a roof exterior. Depending on the shape and area of the building being constructed, the number of roof panels 700 to be used may be determined.

As previously described, a space may be formed between the base panel 200 and the roof panel 700. A sound-absorbing sheet 800 and an insulating material 900 may be disposed in the space. The sound-absorbing sheet 800 may be placed on the base panel 200, and the insulation material 900 may be placed on the sound-absorbing sheet 800.

The sound-absorbing sheet 800 and the insulation material 90 are each formed in a sheet shape with a predetermined thickness, and may be disposed between a plurality of panel support bars 400 installed on the base panel 200. That is, the width of the sound-absorbing sheet 800 and the insulation material 90 in the X-axis direction may be determined by the spacing between the panel support bars 400.

The sound-absorbing sheet 800 can suppress the transmission of noise generated outside the building, noise generated from the roof structure itself, or noise generated indoors. The sound-absorbing sheet 800 may be made of fiber or other sheet material that attenuates noise transmission. For example, the sound-absorbing sheet 800 may be made of polyester wool.

The insulation material 900 blocks heat transfer by convection, conduction, and radiation that occurs between the exterior and interior through the roof panel system 1, thereby improving the insulation effect of the building. The insulation material 900 may be made of a material with excellent heat blocking effect. For example, the insulation material 900 may be made of materials such as styrofoam, extruded protective plate, glass wool, or mineral wool. Preferably, the insulation material 900 may be made of glass wool.

Figure 3 is an enlarged view of portion A of Figure 2, and Figure 4 is an exploded perspective view of the joint assembly of Figure 3.

Referring to FIGS. 3 and 4 , the joint assembly 300 may include a mount unit 310, a saddle unit 320, and a restoring force generating member 300.

The mount unit 310 may be placed on the top of the base panel 200. The mount unit 310 may be seated in the groove 210 of the base panel.

The mount unit 310 may be formed to correspond to the shape of the groove 210. However, it is not limited to this, and the mount unit 310 can be of any size and shape that can be installed in the space formed by the shape of the groove 210.

The mount unit 310 may be provided with a first mount 311 and a second mount 312. The first mount 311 and the second mount 312 may be connected to and fixed to the groove 210 of the base panel and the frame 100 by a mount connection member 313.

The first mount 311 may be located on the base panel 200, and the first mound 311 may be seated in the groove 210.

The lower part of the first mount 311 may be formed to correspond to the shape of the groove 210. The first mount 311 may be supported with its bottom and side surfaces in contact with the groove 210 . However, it is not necessarily limited to this, and depending on the shape of the first mount 311, a portion of the first mount 311 may be supported in contact with a portion of the groove 210. At this time, if the contact area between the first mount 311 and the groove 210 forms sufficient support force, any shape of the first mount 311 can be applied.

A mount groove 3111 into which the second mount 312 is inserted may be provided on the upper surface of the first mount 311. The mount groove 3111 may be formed in a shape corresponding to the shape of the lower part of the second mount 312. The mount groove 3111 may be formed to be recessed from the upper surface of the first mount 311. Specifically, the mount groove 3111 is located in the center of the upper surface of the first mount 311 and may be provided as a square groove. However, it is not necessarily limited to this.

A first connection hole 3111a penetrating in the vertical direction may be formed in the center of the mount groove 3111. The first connection hole 3111a may be provided as a through hole into which the mount connection member 313 is inserted.

Additionally, the first mount 311 may be made of an elastic material. As an example, the first mount 311 may be made of a material such as rubber or resin. Since the first mount 311 has elasticity, the first mount 311 may have a buffering effect against vibration. When vibration occurring inside and outside the building is transmitted to the frame 100 or the roof panel 700, the first mount 311 reduces the vibration transmitted between the base panel 200 and the panel support bar 400. This can prevent damage to the roof panel system (1).

The second mount 312 may be placed on the first mount 311. The second mount 312 may be supported by the first mount 311. At least a portion of the second mount 312 may be inserted into the mount groove 3111.

The lower part of the second mount 312 is formed in a shape corresponding to the upper surface of the first mount 311, and the upper part may be provided in a slit shape.

To describe the shape of the second mount 312 in detail, each part of the second mount 312 includes a first area 3121, a second area 3122, a third area 3123, and a fourth area ( 3124).

The first area 3121 corresponds to the lower part of the second mount 312, and the first area 3121 may form the bottom of the second mount 312. The first area 3121 may be seated on the first mount 311. The first area 3121 may correspond to the upper surface of the first mount 311. The first area 3121 may have a concave shape downward so that a portion of it is inserted into the mount groove 3111.

A second connection hole 3121a penetrating in the vertical direction may be formed in the center of the first area 3121. The second connection hole 3121a may be provided to overlap the first connection hole 3111a. The second connection hole 3121a may be provided as a through hole into which the mount connection member 313 is inserted.

1 to 4, when the first mount unit 311 and the second mount unit 312 are disposed in the groove 210 of the base panel, the mount connection member 313 has a first connection hole ( 3111a) and the second connection hole 3121a, and may be connected to the frame 100 disposed below the base panel 200.

The second area 3122 corresponds to a side wall of the second mount 312 and extends upward from the first area 3121 to form a predetermined height. The second area 3122 may be formed on both sides of the first area 3121 and have walls facing each other.

Inside the second mount 312, a receiving space defined by the first area 3121 and the second area 3122 may be provided. In the accommodation space of the above-described second mount 312, the mount connection member 313 can be inserted into the first connection hole 3111a and the second connection hole 3121a, and the restoring force generating member 330 is placed thereon. can be placed.

The third area 3123 corresponds to the upper part of the second mount 312, and the third area 3123 may form the upper surface of the second mount 312. The third area 3123 extends from the second areas 3122 on both sides in a direction approaching each other, and may be formed in the shape of a slit spaced apart by a predetermined width. A saddle unit 320 may be inserted between the third areas 3123.

The fourth area 3124 may be formed as a protrusion protruding downward from the third area 3123. The fourth area 3124 may support the saddle unit 320 inserted through the third area 3123. A portion of the saddle unit 320 may be assembled in the fourth area 3124. By assembling the saddle unit 320 in the fourth area 3124, the mount unit 310 and the saddle unit 320 can be firmly connected.

The lower part of the saddle unit 320 may be assembled to the mount unit 310. A panel support bar 400 can be connected to the upper part of the saddle unit 320.

The saddle unit 320 may include a body 321, a saddle 322, and a heat blocking sheet 323.

The body 321 may be a part connected to the mount unit 310. Specifically, after the body 321 is inserted into the third area 3123, it can be rotated in one direction and assembled into the fourth area 3124.

The body 321 may be formed in a plate shape forming a predetermined area. The body 321 may have a width smaller than the gap between the third areas 3123. Because of this, the body 321 can be easily inserted into the third area 3123.

A guide groove 3211 into which a portion of the restoring force generating member 330 is inserted may be formed on the bottom of the body 321. The guide groove 3211 may contact the upper part of the restoring force generating member 330 to align the position of the restoring force generating member 330. The guide groove 3211 can prevent the restoring force generating member 330 from being separated or separated.

The edges of the body 321 may be cut. As shown in FIG. 4, the body 321 may be formed in a shape in which all four corners are cut diagonally. However, it is not necessarily limited to this, and the body 321 may be formed in a shape in which four corners are rounded.

The saddle 322 may be formed extending from the body 321. The saddle 322 may be connected at least in part to the panel support bar 400.

According to one embodiment, the lower part of the saddles 322 is provided in the shape of a pillar protruding upward from the body 321, and the upper part of the saddles 322 extends from the lower part of the saddles 322 to form two plates. It can be provided. The two plates may be spaced apart by a predetermined width to form an insertion groove 3221.

The saddle 322 may be provided with a slit-shaped insertion groove 3221 that is open upward. The insertion groove 3221 may be connected to the panel support bar 400. The heat-blocking sheet 323 may be inserted into the insertion groove 3221.

The saddle 322 may have a seating groove 3222 disposed at the upper end. When the heat-blocking sheet 323 is inserted into the insertion groove 3221, a portion of the heat-blocking sheet 323 may be seated in the seating groove 3222.

The saddle 322 may be provided with a first long hole 322a extending in the height direction. The first long hole 322a may be formed as a through hole penetrating the upper part of the saddle 322. In order to connect the saddle 322a to the panel support bar 400, a saddle connection member 324 may be inserted into the first long hole 322a.

The heat-blocking sheet 323 can be inserted into the saddle 322, and the panel support bar 400 can be assembled. The heat blocking sheet 323 may be interposed between the saddle 322 and the panel support bar 400. Specifically, the heat-blocking sheet 323 may be inserted into the insertion groove 3221 of the saddle 322, and the vertical portion 410 of the panel support bar 400 may be inserted into the heat-blocking sheet 323.

The heat barrier sheet 323 may be provided in a shape corresponding to the shape of the insertion groove 3221, and a support groove 3231 may be formed.

The heat barrier sheet 323 may be provided with a slit-shaped support groove 3231 that is open upward. The support groove 3231 may support the panel support bar 400. A vertical portion 410 may be inserted into the support groove 3231.

The heat blocking sheet 323 may have a support cover 3232 disposed at the upper end. The support cover 3232 may be seated in the seating groove 3232. The support cover 3232 may be provided to correspond to the shape of the seating groove 3232 and cover the seating groove 3232.

The heat blocking sheet 323 may be provided with a second long hole 323a extending in the height direction. The second long hole 323a may be formed as a through hole penetrating the heat barrier sheet 323. The second long hole 323a may extend parallel to the first long hole 322a and overlap each other. A saddle connection member 324 may be inserted into the second long hole 323a.

As shown in FIGS. 1 to 4, with the heat barrier sheet 323 inserted into the saddle 322, the panel support bar 400 can be inserted into the support groove 3231 of the heat barrier sheet 323. there is. At this time, the panel support bar 400 may be connected to the saddle 322 and the heat shield sheet 323 by inserting the saddle connection member 324 into the first long hole 322a and the second long hole 323a.

Since the first long hole 322a and the second long hole 323a are through holes extending in the height direction, the panel support bar 400 moves up and down at a predetermined height with respect to the saddle 322 and the heat blocking sheet 323. This can possibly be connected.

Therefore, the saddle unit 320 can adjust the assembly position of the long saddle connection member 324 according to the height of the vertical portion 410 of the panel support bar 400, so that the panel support bar 400 of various sizes can be installed. It can be applied. In addition, even if vibration occurring inside and outside the building is transmitted to the saddle unit 320, the saddle connection member 324 connected to the panel support bar 400 moves up and down along the first long hole 322a and the second long hole 323a. Since it moves to , it can have a buffering effect against vibration.

The heat blocking sheet 323 may be made of a material with excellent heat blocking effect. The heat blocking sheet 323 may be provided to prevent heat transfer between the saddle 322 and the panel support bar 400.

In the roof panel system 1, panel support bars 400 are adjacent to roof panels 700, whose parallel portions 420 form the roof exterior. Because of this, heat received from the outside by the roof panel 700 can be easily transferred to the parallel portion 420, and the heat blocking sheet 323 blocks heat transfer between the saddle 322 and the panel support bar 400. As a result, temperature changes in the internal space of the roof panel system 1 can be reduced, condensation can be prevented, and the insulation of the building can be improved.

Additionally, the heat barrier sheet 323 may be made of an elastic material. As an example, the heat barrier sheet 323 may be made of a material such as rubber or resin. Since the heat-blocking sheet 323 has elasticity, the heat-blocking sheet 323 may have a buffering effect against vibration.

The restoring force generating member 330 may be disposed between the mount unit 310 and the saddle unit 320. The restoring force generating member 330 may be disposed in the inner space of the second mount 312 and supported by the first area 3121.

The restoring force generating member 330 may support the saddle unit 320. A portion of the restoring force generating member 330 may be inserted into the guide groove 3211 on the bottom of the saddle unit 320. Accordingly, the restoring force generating member 330 can stably support the saddle unit 320.

Even if a temporary change in shape occurs, the restoring force generating member 330 can be restored to its original shape. The restoring force generating member 330 may be made of a material or shape having restoring force.

As the restoring force generating member 330 restores its shape, the saddle unit 320 supported by the restoring force generating member 330 may be returned to its original position.

When vibration occurring inside and outside the building is transmitted to the frame 100 or the roof panel 700, the restoring force generating member 330 reduces the vibration transmitted between the base panel 200 and the panel support bar 400. This can prevent damage to the roof panel system (1).

In one embodiment, the restoring force generating member 330 may be provided as a normal spring. The restoring force generating member 330 may be tensioned or compressed depending on the applied force, and may be restored to its original shape when twisting occurs.

In one embodiment, the spring diameter of the restoring force generating member 330 may decrease from the bottom to the top.

5 and 6 are diagrams for explaining the assembly method of the joint assembly.

Specifically, FIG. 5 is a diagram showing the saddle unit 320 separated from the mount unit 310, and FIG. 6 is a diagram showing the saddle unit 320 coupled to the mount unit 310. Although not shown in the drawing, the mount unit 310 is mounted in the groove 210 of the base panel, and the first mount 311 and the second mount 312 are connected by a mount connection member 313 (not shown). It is fastened to the base panel 200.

Referring to FIG. 5, the saddle unit 320 is adjacent to the mount unit 310 and may be arranged to face each other in the vertical direction.

The restoring force generating member 330 may be disposed in the internal space of the second mount 312. The second mount 312 may provide a space in which the restoring force generating member 330 is accommodated as the second area 3122 forms a predetermined height.

The body 321 may be inserted into the mount unit 310 through the third area 3123. The bottom of the body 321 may be in contact with the restoring force generating member 330, and the upper portion of the restoring force generating member 330 may be inserted into the guide groove 3211 of FIG. 3.

In FIG. 5, the saddle unit 320 is shown with the heat-blocking sheet 323 inserted into the insertion groove 3221, but the heat-blocking sheet 323 is assembled to the body 321 on the second mount 312. After this, it may be inserted into the insertion groove 3221.

The heat barrier sheet 323 is provided with a support groove 3231 on the inside, and the vertical portion 410 of the panel support bar can be inserted into the support groove 3231. The support groove 3231 may have a width that increases from the bottom to the top.

Referring to the partially enlarged view of FIG. 5, the inner edge of the upper end of the heat barrier sheet 323 may be cut diagonally to form an inclined surface 323b. The inclined surface 323b may be located at the upper end of the support groove 3231 and extend from the support groove 3231.

The heat barrier sheet 323 not only has the width of the support groove 3231 wider toward the top, but also has an inclined surface 323b at the upper end, so that the width of the support groove 3231 is widest at the upper end. You can. Because of this, the vertical portion 410 can be easily inserted into the support groove 3231.

When the heat barrier sheet 323 is inserted into the insertion groove 3221, the support cover 3232 may be seated in the seating groove 3222. The seating groove 3222 may be provided at the upper end of the saddle 322 with a portion having a thinner thickness. By seating the support cover 3232 in the seating groove 3232, the heat barrier sheet 323 can be stably fixed to the saddle 322.

Referring to FIG. 6 , the saddle unit 320 may be inserted into the mount unit 310 and then rotated to be assembled to the mount unit 310 .

The saddle unit 320 applies a pressing force to the restoring force generating member 330 from the upper direction and may be inserted into the internal space of the second mount 312. Because of this, the restoring force generating member 330 may be compressed.

The restoring force generating member 330 may be accommodated in the internal space of the second mount 312 and compressed or tensioned. The second mount 312 may provide a space in which the shape of the restoring force generating member 330 changes or is restored as the second area 3122 forms a predetermined height.

Referring to the partially enlarged view of FIG. 6, the body 321 may be inserted into the third area 3123 and then rotated to be assembled in the fourth area 3124. The fourth area 3124 supports the body 321 and may be provided to assemble a portion of the body 321.

As described above, when the four corners of the body 321 are cut, the body 321 can easily rotate within the third area 3123, and the body 321 can be accurately rotated within the fourth area 3124. Can be assembled.

Figure 7 is a diagram for explaining the construction method of the roof panel system of Figure 2.

1 to 7, a construction method of a roof panel system according to an embodiment of the present invention will be described.

According to FIG. 7, the construction method of the roof panel system 1 includes the steps of installing a plurality of frames on the upper part of the building (S10), and installing a base panel having a plurality of grooves on the plurality of frames (S20). ), installing a joint assembly in the groove (S30), inserting a panel support bar extending along the frame into the joint assembly (S40), and installing a roof panel on the panel support bar (S50) ) may include.

In the step of installing a plurality of frames on the top of the building (S10), a plurality of frames 100 can be installed on the top of the building in order to construct the roof of the building.

There are a plurality of frames 100, but the number can be adjusted depending on the design of the roof being constructed or the characteristics of the building, and the spacing or arrangement method at which the frames 100 are installed can be determined.

The frame 100 may be mounted on a building using connecting members such as bolts or clips. Frame 100 may form transverse support for roof panel system 1 .

In the step (S20) of installing a base panel having a plurality of grooves on the plurality of frames, the base panel 200 is provided as a panel having a predetermined area and can cover the upper part of the plurality of frames 100. .

There are a plurality of base panels 200, and the bottom surface of the roof structure can be formed by installing each base panel 200 side by side on the plurality of frames 100.

In the step of installing the joint assembly in the groove (S30), the joint assembly 300 is seated in the groove 210 and may be connected to at least one of the frame 100 or the base panel 200.

Since the panel support bar 400 is connected to the joint assembly 300, the spacing of the panel support bar 400 can be adjusted depending on the location where the joint assembly 300 is installed.

There are a plurality of joint assemblies 300, but the number can be adjusted depending on the design of the roof being constructed or the characteristics of the building, and the spacing or arrangement method at which the joint assemblies 300 are installed can be determined.

As previously described with reference to FIGS. 3 to 6 , the joint assembly 300 may include a mount unit 310, a saddle unit 320, and a restoring force generating member 330.

According to one embodiment, the mount unit 310 and the saddle unit 320 may be assembled with each other, and a restoring force generating member 330 is interposed between the mount unit 310 and the saddle unit 320 in the height direction. resilience can be formed.

In the step of installing the joint assembly in the groove (S30), the saddle unit 320 may be rotated after being inserted into the mount unit 310 to assemble the mount unit 310 and the saddle unit 320.

According to one embodiment, the step of installing the joint assembly in the groove (S30) includes installing a mount unit in the groove, placing a restoring force generating member in the mount unit, and assembling a saddle unit in the mount unit. Steps may be provided.

In the step of installing the mount unit in the groove, the mount unit 310 may be seated in the groove 210 and connected to the frame 100 and the base panel 200 by the mount connection member 313. The mount connection member 313 may be provided as a normal bolt or other connection member.

In the step of disposing the restoring force generating member in the mount unit, the restoring force generating member 330 may be disposed inside the mount unit 310. Specifically, the restoring force generating member 330 may be disposed on the first area 3121 of the second mount 312.

In the step of assembling the saddle unit to the mount unit, the saddle unit 320 may be inserted into the mount unit 310 while pressing the restoring force generating member 330 in an upward direction. After being inserted into the mount unit 310, the saddle unit 320 can be rotated in one direction and assembled.

In the step S40 of inserting the panel support bar extending along the frame into the joint assembly, the panel support bar 400 may be inserted into the joint assembly 300.

Specifically, the panel support bar 400 may be inserted into the saddle unit 320. At this time, the panel support bar 400 is connected to the saddle unit 320 so that it can move up and down at a predetermined height by inserting the saddle connection member 324 into the first long hole 322a and the second long hole 323a. You can. The saddle connection member 324 may be provided with a conventional bolt or other connection member.

By connecting the joint assembly 300 and the panel support bar 400, the roof panel 700 can be installed at a location spaced apart from the base panel 200. Additionally, a space for accommodating the sound-absorbing sheet 800 and the insulation material 900 may be formed between the base panel 200 and the roof panel 700.

According to one embodiment, the step of inserting the panel support bar extending along the frame into the joint assembly (S40) further includes the step of placing the sound-absorbing sheet 800 and the insulation material 700 on the base panel 200. can do.

A sound-absorbing sheet 800 and an insulating material 700 are disposed in the space formed between the base panel 200 and the roof panel 700, so that the roof panel system 1 can have noise blocking and thermal insulation performance added.

In the step of installing the roof panel on the panel support bar (S50), the roof panel 700 may be installed on the panel support bar 400.

A plurality of roof panels 700 are provided, and each roof panel 700 is connected to each other, thereby forming an outer roof. The number of panels used for the roof panel 700 may be determined depending on the design of the roof being constructed or the characteristics of the building.

According to one embodiment, the step of installing the roof panel on the panel support bar (S50) may include installing a sliding clip on the panel support bar and connecting the roof panel to the sliding clip. there is.

In the step of installing the sliding clip on the panel support bar, the sliding clip 500 may be installed on the panel support bar 400. At this time, a heat-blocking pad 600 is disposed between the sliding clip 500 and the panel support bar 400 and can be installed together with the sliding clip 500.

In the step of connecting the roof panel to the sliding clip, a portion of the roof panel 700 may be connected by sliding along the sliding clip 500. In addition, the outer structure of the roof panel system 1 can be further strengthened by finishing the connection portions of the roof panel 700 and the sliding clip 500.

Figure 8 is a perspective view showing a roof panel system with integrated solar power generation equipment according to an embodiment of the present invention, Figure 9 is a cross-sectional view taken along ±-± of Figure 8, and Figure 10 is area A of Figure 9 This is an enlarged drawing.

Referring to FIGS. 8 to 10, a roof panel system 2 with integrated solar power generation facilities according to an embodiment of the present invention can be installed outside and produce electricity. For example, the roof panel system 2 with integrated solar power generation equipment may be installed on the roof or wall of a building, or on a support structure for solar power generation.

The roof panel system 2 may have the roof panel system 1 described in FIGS. 1 to 9 installed as a lower structure, and a solar power generation facility 1000 may be installed on the upper part of the lower structure. Roof panel system 2 may have a waterproofing layer 13 on top of insulation 900 .

The waterproof layer 13 is formed on the top of the insulating material 900 and can prevent rainwater, etc. from seeping into the insulating material 900. The waterproof layer 13 may be formed by coating one surface of the insulation material 900 with a waterproof material.

A portion of the panel support bar 400 is exposed above the insulation material, and a first bracket 1310, which will be described later, may be installed.

The solar power generation facility 1000 installed on the upper part of the roof panel system 2 includes a first gutter 1100, a second gutter 1200, a bracket unit 1300, a support rail 1400, a supporter 1500, It may include a drainage frame 1600, a solar panel 1700, a cover unit 1800, and a side cover 1900.

Hereinafter, the first direction will be defined as the X-axis direction in the drawings, and the second direction will be defined as the Y-axis direction in the drawings.

The first gutter 1100 may extend in a first direction and have a width in a second direction different from the first direction.

For example, a plurality of first gutters 1100 may be arranged on top of the insulating material 900 to be spaced apart from each other. The first gutter 1100 may be arranged to be spaced apart from the second gutter 1200 on both sides.

The second gutter 1200 may extend in a first direction and have a width in a second direction. The second gutter 1200 may be substantially the same as the first gutter 1100 and may be disposed on both sides of the first gutter 1100.

For example, a plurality of second gutters 1200 may be arranged on top of the insulating material 900 to be spaced apart from each other. The second gutter 1200 may be arranged to be spaced apart from the first gutter 1100 on both sides.

The first gutter 1100 and the second gutter 1200 may be formed as drainage passages of the roof panel system 2. Rainwater that has passed through the drainage frame 1600 and the cover unit 1800 may be discharged to the outside through the first gutter 1100 and the second gutter 1200.

The bracket unit 1300 may be installed on the first gutter 1100 and the second gutter 1200. The bracket unit 1300 may have a first bracket 1310 and a second bracket 1320.

The first bracket 1310 may be installed to connect the first gutter 1100 and the second gutter 1200. The first bracket 1310 is installed on the panel support bar 400 and can connect and fix the first gutter 1100 and the second gutter 1200.

The second bracket 1320 is connected to the first bracket 1310, and a supporter 1500 may be installed. The second bracket 1320 is connected to the first bracket 1310 and the second gutter 1200, and a supporter 1500 may be mounted on the top.

The support rail 1400 may be disposed along the second gutter. A pair of support rails 1400 are arranged side by side, and a supporter 1500 may be installed on the pair of support rails 1400. By the support rail 1400, the supporter 1500 can be spaced apart from the upper surface of the second gutter 1200.

Figure 11 is a perspective view showing the supporter of Figure 8.

10 and 11, the supporter 1500 may be mounted on the support rail 1400. The supporter 1500 may be placed on top of the second gutter 1200 and spaced apart from the second gutter 1200 by the bracket unit 1300 and the support rail 1400. Supporters 1500 may be provided in plural numbers and installed on a pair of support rails 1400.

In one embodiment, the supporter 1500 may include a base 1510, a first plate 1520, and a second plate 1530. Additionally, in an optional embodiment, the supporter 1500 may further include a fixing protrusion 1540.

The base 1510 extends in the height direction, and a first plate 1520 and a second plate 1530 may extend on both sides.

The first plate 1520 extends from the lower side of the base 1510 in the second direction and may be connected to the support rail 1400. The first plate 1520 extends in the second direction from both sides of the base 1510 and may have a third tip 1520T bent at the end.

The first plate 1520 may be mounted on the second end of the support rail 1400 and fixed to the second bracket 1320. The third tip 1520T is supported on the protruding wall of the support rail 1400, so that the supporter 1500 can be stably fixed to the support rail 1400.

The second plate 1530 extends from the upper side of the base 1510 in the second direction and can be connected to the solar panel 1700. The second plate 1530 extends in a second direction from both sides of the base 1510, and the edge of the solar panel 1700 may be supported on the second plate 1530.

The second plate 1530 may have a step at the top of the base 1510. Due to the step, the solar panel 1700 can be placed at a set position of the supporter 1500.

The first plate 1520 and the second plate 1530 may have different extension lengths in the second direction. The first plate 1520 may have a first length D1 in a second direction from the base 1510, and the second plate 1530 may have a second length D2 in a second direction from the base 1510. there is. Since the second plate 1530 extends shorter from the base 1510 than the first plate 1520, the first length D1 may be set to be longer than the second length D2. Due to the difference between the first length D1 and the second length D2, the end of the drainage frame 1600 may be arranged to be inserted into the supporter 1500.

The first plate 1520 and the second plate 1530 may be arranged to be spaced apart from each other at a preset height D3 in the height direction. The end of the drainage frame 1600 is inserted into the space between the first plate 1520 and the second plate 1530, and the water moving along the drainage frame 1600 flows through the first plate 1520 of the supporter 1500. It may move into the space between and the second plate 1530 and be discharged into the second gutter 1200.

The first cover 1810 can be inserted into the fixing protrusion 1540. The fixing protrusion 1540 protrudes from the top of the base 1510, so that the first cover 1810 can be inserted. The fixing protrusions 1540 may be provided in a pair so that both sides of the first cover 1810 are supported.

FIG. 12 is a plan view showing a partial configuration of the roof panel system of FIG. 8, and FIG. 13 is a cross-sectional view of a portion of the drainage frame taken along μ-μ in FIG. 12.

Referring to FIGS. 10, 12, and 13, drainage frames 1600 may be installed on supports 1500 facing each other.

The drainage frame 1600 is disposed between solar panels 1700 that are adjacent to each other in the first direction and can guide rainwater flowing between the solar panels 1700. The drainage frame 1600 may support both ends of the solar panel 1700 in the first direction.

The drain frame 1600 may have at least one drain hole 1600H. 5 illustrates an embodiment in which the drainage frame 1600 has four drainage holes 1600H, but the present invention is not limited thereto and may be set in various ways depending on the amount of rainwater flowing into the roof panel system 2.

The drain frame 1600 may be arranged so that the drain hole 1600H faces the first gutter 1100. Thus, rainwater passing through the drain hole 1600H of the drainage frame 1600 is discharged to the first gutter 1100, and rainwater moving to both ends of the drainage frame 1600 can be discharged to the second gutter 1200. there is.

The end of the drainage frame 1600 is in contact with the second plate 1530 and may be disposed to face the end of the first plate 1520. 3, the lower part of the drainage frame 1600 is supported on the protruding wall 141 of the support rail 1400, and the end of the drainage frame 1600 is in contact with the end of the second plate 1530, The end of 1600 may be inserted into the space between the first plate 1520 and the second plate 1530.

In an optional embodiment, referring to FIG. 6 , the drainage frame 1600 may further include a guide protrusion 1610.

The guide protrusion 1610 may be disposed along the edge of the drain hole 1600H. The guide protrusion 1610 is disposed on the lower surface of the drainage frame 1600 and can guide rainwater or air moving into the drainage hole 1600H.

The guide protrusion 1610 may have a predetermined protrusion height. As an example, the guide protrusion 1610 may have an annular shape along the drain hole 1600H. As another example, a plurality of guide protrusions may be provided and may be arranged to be spaced apart at predetermined intervals along the drain hole.

The guide protrusion 1610 is located below the edge of the drain hole 1600H and can guide rainwater passing through the drain hole 1600H to be discharged only to the first gutter 1100. The drain hole 160 moves only downward along the guide protrusion 160 and can be prevented from moving sideways along the bottom surface of the drain frame 1600. Rainwater passing through the drain hole 1600H due to the guide protrusion 1610 is discharged only to the first gutter 1100, thereby implementing a stable drainage function. In addition, rainwater passing through the drain hole (1600H) is discharged only to the first gutter (1100), and since rainwater does not leak to both sides of the first gutter (1100), electrical components installed next to the first gutter (1100) It can prevent short circuits and flooding.

The solar panel 1700 may be placed on the upper side of the roof panel system 2 and exposed to the outside. A plurality of solar panels 1700 are arranged side by side, and a cover unit 1800 may be placed between neighboring solar panels 1700.

The central portion of the solar panel 1700 may overlap with the first gutter 1100 , and both end portions in the second direction may overlap with the second gutter 1200 .

The solar panel 1700 may be installed so that both ends in the first direction are supported by the drainage frame 1600. Thus, rainwater that moves into the space between neighboring solar panels 1700 in the first direction flows into the drainage frame 1600, and some of the rainwater flows into the drainage hole 1600H of the drainage frame 1600. One part may be discharged to the gutter 1100, and the other part may move along both ends of the drainage frame 1600 and be discharged to the second gutter 1200.

The solar panel 1700 may be installed so that both ends in the second direction are supported by the supporter 1500. Since the edge of the solar panel 1700 is seated on the second plate 1530 of the supporter 1500, the solar panel 1700 can be stably fixed to the supporter 1500. Additionally, rainwater that moves into the space between adjacent solar panels 1700 in the second direction may be discharged into the second gutter 1200.

In an optional embodiment, at least one of the first cover 1810 and the second cover 1820 may be flame retardant or non-flammable. Flame retardant treatment or non-combustible treatment may be a commonly used flame retardant or non-combustible treatment method. At least part of the surface of the first cover 1810 or the second cover 1820 is flame retardant or non-combustible, thereby preventing the fire from spreading to other solar panels when a fire occurs in some solar panels.

Referring again to FIG. 9, side covers 1900 may be optionally installed on the edges of roof panel system 2. The side cover 1900 is disposed on the outside of the roof panel system 2 to prevent external foreign substances from entering the interior of the roof panel system 2.

Roof panel systems require maintenance depending on the external environment (especially the weather) because solar panels are exposed to the outside. For example, when it rains, rainwater flows into the roof panel system, and a function is needed to quickly discharge the inflowed rainwater to the outside.

Referring to Figures 8 and 12, the roof panel system 2 according to the present invention can have a large-capacity drainage function by dispersing the movement path of incoming rainwater.

External fluid flowing into the first through hole of the first cover 1810 is guided to the second gutter 1200. A second gutter 1200 is disposed below the first cover 1810, so that fluid flowing in through the first cover 1810 can be directly discharged into the second gutter 1200.

Part of the external fluid flowing into the second through hole of the second cover 1820 is guided to the first gutter 1100 through the drain hole 1600H of the drain frame 1600, and the other part is guided to the drain frame 1600. It can be guided to the second gutter 1200 by moving to both ends.

When the roof panel system 2 is installed in an inclined state on a roof, etc., a large amount of rainwater flows into the second cover 1820. When the roof panel system 2 is installed inclined along the first direction, rainwater flowing along the upper surface of the solar panel 1700 flows into the second cover 1820. Even if a large amount of rainwater flows in in an instant, part of the rainwater is distributed to the first gutter 1100 by the drainage frame 1600, and the other part moves along the drainage frame 1600 to form a pair of second gutters 1200. ), the roof panel system (2) can discharge a large amount of rainwater.

Meanwhile, when solar panels generate power, the surrounding temperature rises due to solar heat. A rise in temperature can cause a drop in voltage, which can reduce the power generation efficiency of the entire system. The roof panel system 2 according to the present invention can quickly remove heat generated from the solar panel 1700, thereby increasing the power generation efficiency of the roof panel system 2.

The roof panel system (2) with integrated solar power generation equipment according to the present invention uses solar power generation equipment or solar panels as the exterior material of the building, thereby reducing construction costs and reducing construction time.

The roof panel system (2) with integrated solar power generation equipment according to the present invention moves air along the through holes installed on the four sides of the solar panel (1700), strengthening the ventilation function of the roof panel system (2). , the temperature rise occurring in the solar panel 1700 is minimized, thereby increasing the power generation efficiency of the roof panel system 2. A flow of air may be formed in a space spaced apart from the solar panel 1700.

The roof panel system (2) with integrated solar power generation equipment according to the present invention forms a stable structure in the building where it is installed, and the roof panel system (2) is easy to construct and manage.

The roof panel system 2 with integrated solar power generation equipment according to the present invention may have a structure with smooth drainage. The roof panel system 2 distributes rainwater through a first gutter disposed along the solar panel and a pair of second gutters disposed on both sides. The drainage frame can distribute rainwater to a pair of second gutters, leading to stable drainage. In other words, the roof panel system can improve drainage by distributing rainwater through three gutters placed below the solar panel.

Figure 14 is a flowchart showing a method of installing a roof panel system with integrated solar power generation equipment according to another embodiment of the invention.

Referring to FIG. 14, the method of installing a roof panel system includes installing an insulation assembly on a basic structure (S100), and a first insulation material extending in a first direction and having a width in a second direction on top of the insulation assembly. A step of installing a gutter and a second gutter on both sides of the first gutter (S200), a step of installing a pair of support rails on the second gutter (S300), and between the pair of support rails. A step of installing a supporter (S400), a step of installing a drain frame having a drain hole on the supporter facing each other (S500), the center is arranged to overlap along the first gutter, and both ends in the second direction are It may include installing solar panels so that they overlap along the second gutter and are supported by the supporter (S600), and installing a cover between the solar panels (S700).

The step of installing the insulation assembly to the basic structure (S100) may include a method of constructing the roof panel system (1).

Referring to FIG. 7, the step of installing the insulation assembly in the basic structure (S100) includes installing a plurality of frames on the upper part of the building (S10), and installing a base panel having a plurality of grooves on the plurality of frames. Step (S20), installing a joint assembly in the groove (S30), inserting a panel support bar extending along the frame into the joint assembly (S40), and installing a roof panel on the panel support bar. It may include step (S50).

The roof panel system according to the present invention provides a seismic isolation structure for solar power generation facilities installed on top, so safety can be maintained even if external earthquakes or vibrations occur. In addition, it is possible to prevent heat generated during solar power generation from being transferred internally by providing a thermal barrier structure for solar power generation facilities.

The present invention has been described with reference to an embodiment shown in the attached drawings, but this is merely illustrative, and those skilled in the art will understand that various modifications and other equivalent embodiments are possible therefrom. . Therefore, the true scope of protection of the present invention should be determined only by the appended claims.

1, 2: Roof panel system
100: frame
200: Base panel
300: joint assembly
400: Panel support bar
500: sliding clip
600: Heat barrier pad
700: Roof panel
800: Sound-absorbing sheet
900: insulation
1000: Solar power generation equipment

Claims (8)

multiple frames;
a base panel disposed on the frame and having a plurality of grooves extending in one direction;
a panel support bar disposed on the base panel and extending parallel to the frame;
a joint assembly that is seated in the groove, connects the base panel and the panel support bar, and forms a restoring force in the height direction; and
It includes a roof panel disposed on the panel support bar,
The joint assembly is
a mount unit seated in the groove;
a saddle unit that is assembled to the mount unit when inserted into the mount unit and rotated, and to which the panel support bar is connected; and
A roof panel system having a rotational assembly and an earthquake-resistant structure, comprising: a restoring force generating member disposed between the mount unit and the saddle unit. According to claim 1,
The mount unit is
a first mount mounted in a groove of the base panel and made of an elastic material; and
A roof panel system having a rotational assembly and an earthquake-resistant structure, including a second mount inserted into the first mount and supporting the saddle unit. According to claim 1,
The saddle unit is
a body assembled to the mount unit when inserted into the mount unit and rotated;
Saddles extending from the body and having an insertion groove; and
A roof panel system with a rotational assembly and an earthquake-resistant structure, comprising: a heat-blocking sheet on which the panel support bar is assembled and inserted into the insertion groove. According to clause 3,
The saddles have a first elongated hole extending in the height direction,
A roof panel system with a rotational assembly and an earthquake-resistant structure, wherein the thermal barrier sheet has a second long hole extending parallel to the first long hole. According to clause 3,
The saddle unit is
Has a guide groove into which a part of the restoring force generating member is inserted,
The heat blocking sheet is
A roof panel system with a rotational assembly and an earthquake-resistant structure, including a support cover inserted into a seating groove disposed at the upper end of the saddle. Installing a plurality of frames on the upper part of the building;
Installing a base panel having a plurality of grooves on the plurality of frames;
Installing a joint assembly in the groove;
Inserting a panel support bar extending along the frame into the joint assembly; and
It includes installing a roof panel on the panel support bar,
The joint assembly is
a mount unit seated in the groove;
a saddle unit that is assembled to the mount unit when inserted into the mount unit and rotated, and to which the panel support bar is connected; and
A method of constructing a roof panel system having a rotational assembly and an earthquake-resistant structure, comprising: a restoring force generating member disposed between the mount unit and the saddle unit to form a restoring force in the height direction. According to clause 6,
The step of installing the joint assembly is
A method of constructing a roof panel system with rotational assembly and an earthquake-resistant structure, wherein the saddle unit is inserted into the mount unit and then rotated to assemble the mount unit and the saddle unit. delete

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