KR20200008833A - Solar cell module support for steel frame - Google Patents

Abstract

The present invention relates to an apparatus for fixing a solar module of a prefabricated roof, which is capable of improving the strength for a support force. The apparatus comprises: a rail frame including a base part, a partition wall part or a sidewall part, and an upper opening; and a T-bolt having a head having a narrow width and a wide width.

Description

SOLAR CELL MODULE SUPPORT FOR STEEL FRAME}

The present invention relates to a solar module fixing device of a prefabricated roof, and more specifically, can be installed directly on top of the prefabricated roof panel without dismantling the old aging prefabricated roof panel for installation of the solar module, the coupling By integrating and minimizing the construction of members, the strength of bearing capacity can be improved by reducing the connection parts between parts, and the construction is easy while greatly reducing the time required for construction by simplifying the work process. The present invention relates to a solar module fixing device of a prefabricated roof which can prevent leakage due to rainwater through a waterproof structure of a connection portion to which a bolt is fastened.

In general, when constructing a prefabricated building, the roof body is structured with a focus on several factors that can greatly insulate, absorb, leak, and support the bar. Glass wool, which is a high-insulation and sound-absorbing polyester wool or an inorganic insulating material, is constructed. Fillers, such as the back, are laid side by side with the roof panels located between the steel plates, and the ends of each roof panel are connected to each other for construction.

However, there is a disadvantage in that leakage occurs to the fastening part side of the bolt for fixing the roof panel when the roof construction of the prefabricated building as described above, in some cases by fixing the bracket at the same time by placing the bracket on the top of the joint part of the roof panel, Although the cap was inserted on the top to prevent leakage, in this case, the cap was easily separated from the bracket by external factors such as wind pressure, and thus the original purpose was not achieved.A separate cap fixing bracket, etc. It may be tightened by means of fixing, but in this case, too many structures to prevent leakage are of course, and the structure of the cap has to be changed to be able to be fastened with the cap fixing bracket, so it is very difficult to manufacture the structure to prevent leakage. Losing was a disadvantage.

On the other hand, recently, due to the depletion of fossil energy, the development of new alternative energy is required, and as a part of the demands of the times, there are many cases in which solar panels for photovoltaic power generation are additionally installed above the roof of the constructed building. It is becoming.

When installing solar panel on the roof of a general building, first, the pillars, such as angular pipes, which are hot-drilled by making holes in the roof panels forming the roof, are fixed to the roof structure by welding, etc. Fix the fasteners with bolts and nuts, and connect the solar panels to the fasteners. If the above method is followed, drilling the roof panels, welding the struts, and fastening them to the props There is a lot of work to be done, such as fastening a sphere and fixing a solar panel. Therefore, labor costs and construction costs are high, and a lot of subsidiary materials and bolts and nuts are required. As a result, construction costs also increased significantly.

In consideration of this, in recent years, the structure of the roof panel itself may be manufactured in a form that is easy to install a solar panel, but this must be done when constructing a new building or by removing an existing roof panel and constructing a new roof panel. This raises the problem of rising costs, and the difficulty of the work, which takes much time and wastes manpower.

Meanwhile, in Korean Patent Application Publication No. 10-1375896 shown in FIG. 1, end portions of each roof panel 1 are laid side by side on a support with a roof panel 1, which is bent in multiple directions, inclined in both directions in opposite directions. When the roof of the prefabricated building is connected to each other, the lower part is closed and placed in an upward direction so as to be placed above the joint part of the roof panel 1, and fixed surfaces 11 are formed on both sides of the upper part in the outward direction. A lower cap 10; A bracket 20 fixed to the support by a fixing bolt 2 together with a lower cap 10 and a joint portion of each roof panel 1 in a state inserted into the lower cap 10; It is formed in a closed shape to prevent rainwater inflow, and both end portions are formed with fixed surfaces 31 contacting the fixed surfaces of the lower cap 10, respectively. The fastener for preventing the leakage of the roof of the prefabricated building consisting of the upper cap 30 is fixed to 10).

However, in the above and the prior art, since the fastener for preventing the leakage of the roof of the prefabricated building is composed of three members, such as the lower cap, the bracket, the upper cap, the number of the members is too high, which leads to a large production cost. Since it was necessary to fix the upper cap on the upper part of the lower cap and fix it with fixing screws etc., the construction was complicated and it took a lot of time to install. Since the T-bolt for installing the solar panel was only supported by the upper cap, the bearing capacity fell and typhoons In case of strong external pressure, the T-bolt may be released from the upper cap.

In addition, in the prior art Korean Patent Publication No. 10-1403826 shown in Figure 2 "fastener for installing the solar panel on the roof of the prefabricated building" in the body 60 is placed on the roof panel 1, the body (60) Fixing the body 60 and the roof panel 1 to the support (not shown) at a time with a fixing bolt 2 through the space between each side wall portion 61 protruding upward from both sides, cap ( 70) the second locking jaw formed in the fixing groove 71 of the cap 70 by pressing the fixing groove 71 of the central portion between the first locking jaws 62 formed at the upper end of the side wall portion 61 of the body 60; The cap 70 is fixed to the upper portion of the body 60 so that the 72 is caught by the first locking jaw 62, and the T bolt 80 is fitted into the fixing groove 71 of the cap 70. The mounting bracket 81 of a multi-stage bent shape is fixed to the photovoltaic panel mounting bracket 81 is installed to fix the solar panel 3 between the mounting bracket 81 is disclosed. .

However, the above technique is configured to be complexly coupled to a plurality of members as in the former technique, and the lower cap 10, the bracket 20, the upper cap 30, etc., which are the technical components of the former, are all separately. Since the assembly is not firm because it is connected to the fitting or fastening structure, the number of members is still used a lot, the construction cost is increased, the operation is also complicated, in the latter technique, both ends of the cap 70 in the body (60) The cap 70 is disengaged from the body 60 when the air pressure acts between the side wall 61 and the cap 70 of the body 60 so as to be bent downwardly at a position extended from the support surface 63 of In addition to the possible problems, the assembly of a number of members such as the body 60, fixing bolts (2), caps (70), T bolts (80), nuts and solar panel mounting brackets (81) The process is complicated and difficult In addition to the problem, in addition, when the solar panel mounting bracket 81, which is formed in multiple stages, is coupled to the T bolt 80, the solar panel mounting bracket 81 is rotated together while the nut is tightened. It can be coupled to the fork, such that the gap has not been a problem that the rigid coupling is not achieved, such as the bracket does not accurately fix the solar panel 3 over time.

In addition, when the rainwater is leaked into the interior of the body 60, if the leakage occurs in the fastening hole of the fixing bolt (2), such a problem that the prefabricated roof panel, which is weak in durability, may be damaged.

The present invention has been made to solve the above problems, an object of the present invention, it is possible to immediately install on top of the prefabricated roof panel without dismantling the old aging prefabricated roof panel for installation of the solar module, It is to provide a prefabricated roof solar module fixing device that can improve the strength to the bearing capacity by integrating and minimizing the configuration of the coupling member to reduce the connection between the parts accordingly.

In addition, another object of the present invention, by adopting a structure that can improve the durability while minimizing the components required for assembly and fastening, simplifying the process of work, greatly reducing the time required for construction and easy construction The present invention relates to a solar module fixing device of a prefabricated roof that can improve durability at the same time.

In addition, another object of the present invention, while making it easy to construct the construction through the waterproof operation of the connection portion to which the bolt is fastened so as not to be leaked by rain water, and at the same time has a structure that can be easily made waterproof operation Even if it is not an operator, the fixing of the solar module can be easily done, and the fixing bracket for fixing between the fixing device and the solar panel can be easily combined and can be combined in a solid structure, thereby improving the durability and bonding force between the fastening parts. This is to provide a long lasting prefabricated roof solar module fixing device.

The solar module fixing device of the prefabricated roof according to the present invention in order to achieve the above object, the photovoltaic for installing the solar module on the roof of the building is constructed of a prefabricated roof panel that is repeatedly formed in the longitudinal direction of the mountain and the floor In the module fixing device, the base section is formed to extend in a long way to be coupled along the mountain portion of the roof panel, the base portion formed to be seated in contact with the upper surface of the mountain, and the base portion to form a predetermined internal space above the base portion A rail frame formed by partition walls or side walls extending upward from a predetermined height, an upper opening opened to form a predetermined locking step above the inner space, and a bolt hole vertically penetrating from the inner space to the base portion; A T-bolt having a narrow width having a width capable of passing through the upper opening and a head having a wide width caught in the locking jaw; Including, but when the fixing member is inserted into the bolt hole to be coupled to the base of the rail frame to the upper surface of the mount is sealed between the upper surface of the mount and the base portion to waterproof the bolt hole Absence; It further comprises.

In addition, the solar module fixing device of the prefabricated roof according to the present invention, the rail frame, characterized in that the wing parts in contact with both sides of the inclined side of the mountain is formed integrally extended from both sides of the base portion.

In addition, the solar module fixing device of the prefabricated roof according to the present invention, one end is fastened to the rail frame by the T-bolt so that the solar module is fixed to the rail frame, the other end is the solar module Fixing bracket for supporting the edge of the; The rail frame further includes a bracket fixing groove formed on the upper surface of the rail frame, the bracket fixing groove having a recessed depth by a predetermined depth to have the same width corresponding to the width of the fixing bracket.

In addition, the solar module fixing device of the prefabricated roof according to the present invention, the fixing bracket is formed with a fastening hole for fastening the T-bolt is inserted into the bottom surface horizontally seated in the bracket fixing groove, and the bottom A vertical surface extending vertically upward from one side of the surface to be in surface contact with the edge side surface of the solar module, and protrudingly extending from the upper end of the vertical surface to the opposite side of the bottom surface to form an upper surface of the edge of the solar module; The upper surface is formed to be formed, the upper surface is a predetermined bending angle is formed so that the distal end is inclined downward by a predetermined angle to form an acute angle with the vertical surface, the bottom surface and the vertical surface is formed to be perpendicular to each other It features.

By the above configuration, the solar module fixing device of the prefabricated roof according to the present invention can be installed directly on the prefabricated roof panel without dismantling the old aging prefabricated roof panel for installation of the solar module, By integrating and minimizing the configuration of the member, there is an advantage that the strength to the bearing force can be improved by reducing the connection between the parts.

In addition, the solar module fixing device of the prefabricated roof according to the present invention adopts a structure that can improve the durability while minimizing the components required for assembly and fastening, while greatly reducing the time required for construction by simplifying the work process Ease of construction has the advantage of improving economics and durability at the same time.

In addition, the solar module fixing device of the prefabricated roof according to the present invention is configured to prevent water leakage due to rain water, etc. through the waterproof operation of the connection portion to which the bolt is fastened and at the same time can be made waterproof easily fixed solar module The work can be easily performed, and the fastening operation of the fixing bracket for fixing between the fixing device and the solar panel can be easily combined with a solid structure, thereby improving the durability and long-term bonding force between the fastening parts. .

1 is a cross-sectional view showing an installation state of a fastener for installing a solar panel according to a conventional embodiment.
2 is a cross-sectional view showing an installation state of a fastener for installing a solar panel according to another embodiment of the prior art.
3 is a cross-sectional view showing an installation state of a solar module fixing device according to an embodiment of the present invention.
Figure 4 is a side exploded view for showing a fastening structure of the solar module fixing device according to an embodiment of the present invention.
Figure 5 is a side cross-sectional view showing a fastening process of the T-bolt in the solar module fixing device according to an embodiment of the present invention.
Figure 6 is a side view showing an installation state of the fixing bracket in the solar module fixing device according to an embodiment of the present invention.

Hereinafter, a solar module fixing device (hereinafter, referred to as a “solar module fixing device”) of a prefabricated roof according to the present invention will be described in more detail with reference to the embodiment illustrated in the drawings.

3 is a cross-sectional view showing an installation state of a solar module fixing device according to an embodiment of the present invention, Figure 4 is a side exploded view for showing a fastening structure of the solar module fixing device according to an embodiment of the present invention. 5 is a side cross-sectional view illustrating a fastening process of a T-bolt in a solar module fixing device according to an embodiment of the present invention, and FIG. 6 is a fixing bracket in the solar module fixing device according to an embodiment of the present invention. Is a side view showing the installation state of the.

Referring to the drawings, the solar module fixing device 100 according to an embodiment of the present invention, the building (1) and the floor (1b) of the building which is constructed of prefabricated roof panel (1) that is formed repeatedly in the longitudinal direction long In the solar module fixing device for installing the solar module 3 on the roof, comprising a rail frame 110, T-bolt 120, sealing member 130 and the fixing bracket 140 do.

First, the present invention, unlike the conventional techniques for assembling or fastening a separate cap to the body for fastening the body first through the fixing member 2 to the roof panel 1 and the T-bolt, etc. on the top of the existing While using the roof panel (1) as it is, one rail frame 110 is fastened to the mountain (1a) of the roof panel (1) easily to form a waterproof structure while the solar module (3) is a solid structure at the top For easy installation, as shown in FIG. 3, the solar module only by fastening the T-bolt 120 in a state where the rail frame 110 is fixed to the roof panel 1 with the fixing member 2. Characterized in that the construction of (3) can be made easily.

Accordingly, it is possible to reduce the construction cost by minimizing the parts required for the construction work of the solar module on the roof panel, and at the same time, the fastening work is easy and robust, which can improve the durability and economic efficiency as well as shorten the construction time. The effect can be exerted simultaneously.

The rail frame 110 is configured such that the solar module 3 is firmly fixed to the upper portion of the roof panel 1 through the T-bolt 120 and the fixing bracket 140 which will be described later. .

The rail frame 110 in one embodiment of the present invention is formed to extend in a long cross section so as to be seated and coupled along the protruding peak (1a) portion of the roof panel 1, the rail frame 110 The base 111, the partition 112, or the side wall 113, the bolt hole 114, the wing 115, the locking jaw 116 and the upper opening 117 may be formed.

Referring to FIGS. 3 and 4, the rail frame 110 is formed with a base portion 111 having a flat surface at a bottom thereof to be seated in contact with an upper surface of the mountain 1a, and is predetermined above the base portion 111. The partition wall part 112 and the side wall part 113 which are extended upward by a predetermined height from the base part 111 are formed to form the inner space S.

In this case, the rail frame 110 may be an embodiment in which only one of the partition wall portion 112 and the side wall portion 113 is formed. That is, the barrier rib portion 112 may be exposed to the outside, or the side wall portion 113 may serve as the barrier rib forming the inner space S.

Therefore, when the partition wall portion 112 or the side wall portion 113 is configured as described above, it is preferable to reinforce the thickness of the cross section so as not to be easily deformed by the load.

Accordingly, the rail frame 110 has a substantially rectangular cross-sectional structure formed by the base portion 111 and the partition portion 112 or the side wall portion 113 to firmly support the load of the solar panel 3. To be able.

In addition, the rail frame 110 is formed with a bolt hole 114 penetrated vertically through the base portion 111 in the internal space (S).

The bolt hole 114 is a configuration for inserting the fixing member 2, the longitudinal direction of the cross section of the rail frame 110, that is, the bottom surface of the base portion 111 of the inner space (S) The rail frame 110 is formed through the fixing member 2 in a state in which the base portion 111 is horizontally seated on the upper surface of the mountain 1a so as to be vertically penetrated at a predetermined position along a longitudinal direction. ) To be firmly fixed.

On the other hand, the rail frame 110 as described above may be fixed to the base support 111 is fastened to the upper surface of the mountain (1a) by the fixing member 2, in one embodiment of the present invention An embodiment in which the wing 115 is formed to be inclined downward from the base support 111 of the rail frame 110 is formed.

The wing portion 115 has an inclination angle corresponding to the inclined side surface so as to contact both inclined side surfaces of the mountain (1a), is formed integrally extending from both sides of the base portion 111.

Therefore, the rail frame 110 has the cross-section of the lower portion is formed by extending the wing portion 115 by a length that can cover most or the entire portion of the inclined side of the mountain (1a) portion to the The rail frame 110 may be fixed to the roof panel 1 through the fixing member 2 in a state in which the rail frame 110 is in close contact with the top surface and the inclined side surface of the mountain 1a.

In addition, the rail frame 110 is formed by the upper opening 117 is opened to form a predetermined locking step 116 above the inner space (S).

The locking jaw 116 and the upper opening 117 is a portion of the head 121 when the head 121 of the T-bolt 120, which will be described later, is inserted into the inner space S. 116, the body portion is projected upward from the upper surface of the rail frame 110 by a predetermined height to be fastened with a nut to fix the solar module 3 to the rail frame 110.

As described above, the T-bolt 120 has a width larger than the width of the upper opening 117 so that the head 121 is caught by the catching jaw 116 for installation of the solar module 3. Is formed.

At this time, in the embodiment of the present invention, the head 121 of the T-bolt 120 is caught by the narrow width Nh having the width that can pass through the upper opening 117 and the locking jaw 116. It is formed to have a wide width (Wh).

The T-bolt 120 formed as described above passes the upper opening 117 between the locking jaws 116 of the internal space S in the narrow width Nh direction of the head 121, and then the wide width Wh direction. In the head 121 is rotated to be caught by the locking step 116 is integrally coupled to the rail frame 110, the nut is bolted to the bolt portion 122 protruding upward by a predetermined length through the upper opening 117 While being fastened, the fixing bracket 140 to be described later is integrally coupled with the rail frame 110.

Meanwhile, the T-bolt 120 configured as described above may simply couple the solar module 3 to the rail frame 110 through the process illustrated in FIG. 5.

Referring to FIG. 5, the head 121 passes through the upper opening 117 through a narrow width Nh in a state in which the head 121 of the T-bolt 120 faces downward and passes through the upper opening 117. Insert into the internal space (S) of (110). (A state)

Next, in the state where the head 121 is inserted into the inner space S, the T-bolt 120 is placed so that the wide width Wh of the head 121 is caught by the locking step 116 of the inner space S. FIG. Rotate 90 degrees (b state)

Next, when the fastening hole formed at one end of the fixing bracket 140 to be described later in the state in which the head 121 is caught by the locking jaw 116 as described above to pass through the bolt portion 122 and tighten the nut The fixing bracket 140 is coupled to the rail frame 110 via the T-bolt 120, and the solar module 3 is firmly fixed by the fixing bracket 140. c state)

At this time, the fixing bracket 140 is engaged with the bracket fixing groove 118 when the nut is fastened while the one end is supported by the bracket fixing groove 118 formed on the upper surface of the rail frame 110. By being supported and constrained so as not to rotate with the nut, the coupling operation with the photovoltaic module 3 can be easily and firmly performed.

On the other hand, the solar module fixing device according to an embodiment of the present invention, the base member 111 of the rail frame 110 is fixed to the bolt hole 114 to be coupled to the upper surface of the mountain (1a) ( 2) is a large feature is configured to include a sealing member 130 is installed between the upper surface of the mountain (1a) and the base portion 111 to waterproof the bolt hole 114 when the fastening is inserted. .

In the exemplary embodiment of the present invention, the rail frame 110 includes the base part 111, the partition part 112, the side wall part 113, and the wing part 115 formed integrally with the inner space S. The T-bolt 120 and the head portion of the fixing member 2 is characterized in that it can be accommodated, so in one embodiment of the present invention the bolt hole 114 and the upper opening 17 ) Is to be formed in communication with the internal space (S).

Therefore, the solar module fixing device 100 of the present invention has a problem that rainwater or the like may be introduced into the internal space S through the upper opening 17. That is, the solar module fixing device 100 of the present invention is fastened like the T-bolt 120 and the high-end bolt 2 while forming the one-piece structure in which the rail frame 110 minimizes connection parts as described above. The fastening operation of the members can be easily performed, as well as the torsional rigidity against the load can be improved. At this time, in one embodiment of the present invention, the upper opening 117 is formed to open upward due to the structure as described above, a problem that rain water or the like may be introduced into the internal space (S).

Accordingly, in one embodiment of the present invention, the sealing member 130 is configured to waterproof around the bolt hole 114 in which the fixing member 2 is inserted at the bottom of the rail frame 110.

Thus, the sealing member 130 may be formed in a long band shape along the longitudinal direction of the base portion 111, or may be formed in plural to be provided in each location where the bolt hole 114 is formed.

In addition, in one embodiment of the present invention, the sealing member 130 can be installed very easily.

That is, at least one groove 111a having a predetermined cross-sectional shape is formed in the base 111, and the sealing member 130 is fitted with one or more fitting protrusions 131 corresponding to the groove 111a. ) Is formed to protrude, and the fitting protrusion 131 is formed in a number corresponding to the groove (111a).

At this time, since the rail frame 110 is installed to be inclined in the longitudinal direction by the inclination of the mountain (1a) of the roof panel 1, when the sealing member 130 is constructed as described above the bolt hole 114 Since water does not accumulate around the water and flows in one direction along the inner space S, sufficient waterproof may be achieved through the sealing member 130, and even a small amount of water may be provided through the bolt hole 114. Even if the sealing member 130 is introduced, the sealing member 130 may allow sufficient waterproofing to be achieved by only preventing moisture from flowing into the holes of the acid 1a generated by the fixing member 2.

Therefore, the solar module fixing device 100 of the present invention can easily fasten one rail frame 110 to the mount 1a of the roof panel 1 while using the existing roof panel as it is. As a result, a solid construction is possible, and the work for the waterproof structure is simple, and the effect of achieving a sufficient waterproof structure is generated.

One end of the fixing bracket 140 is fastened to the T-bolt 120 so that the other end of the fixing bracket 140 is fixed to the rail frame 110.

On the other hand, in one embodiment of the present invention, the fixed bracket 140 may be made of a one-way bracket 141 and a two-way bracket 142.

Referring to FIG. 6, the one-way bracket 141 is configured to be installed to the outside of the solar module 3 disposed at the outermost side when a plurality of the solar modules 3 are arranged next to each other side by side.

Thus, in one embodiment of the present invention, the one-way bracket 141 may be formed by forming a bottom surface 141a, a vertical surface 141b, and an upper surface 141c.

Referring to the drawings, the one-way bracket 141 is formed with a fastening hole (141a ') for fastening the T-bolt 120 is inserted into the bottom surface (141a), the bottom surface (141a) It is formed to form a plane to be horizontally seated on the upper surface of the rail frame (110).

In addition, the vertical surface 141b extends vertically upward from one side of the bottom surface 141a and is supported in surface contact with the edge side surface of the photovoltaic module 3 so that the solar module 3 has a rectangular frame. The side portion of is supported stably without play.

In addition, the upper surface 141c protrudes and forms a plane from the upper end of the vertical surface 141b to the opposite side of the bottom surface 141a. That is, the bottom surface 141a extends in one direction based on the vertical surface 141b and extends in the horizontal direction so as to be fastened to the T-bolt 120, and the upper surface 141c extends in the vertical surface ( 141b) is formed to protrude to the other side to support the upper edge of the edge portion of the photovoltaic module 3 downward.

Thus, the solar module 3 may be firmly fixed integrally with the rail frame 110 and the T-bolt 120 via the one-way bracket 141.

At this time, in one embodiment of the present invention, the rail frame 110 has a bracket seating groove 118 recessed by a predetermined depth so as to have the same width corresponding to the width of the bottom surface 141a of the one-way bracket 140. It is characterized by being formed on the upper surface.

The bracket seating groove 118 is a phenomenon that the inner jaw is formed in a predetermined recessed shape on the upper surface of the upper opening 117 of the rail frame 110 to flow in the one-way bracket 141 is accommodated Will be prevented.

That is, when the one-way bracket 141 is fastened to the T-bolt 120 using a tool in a state in which the one-way bracket 141 is fitted to the T-bolt 120 from the upper surface of the rail frame 110, the one-way bracket ( Due to the friction of the nut 141 is rotated, there is a problem moving together, the one-way bracket 141 is constrained by the bracket seating groove 118 rotation is constrained by the operator to the one-way bracket 141 the T- It is very easy to fasten to the bolt, thereby improving the working speed, and the phenomenon that the nut fastened to the T-bolt is not gradually released due to the flow phenomenon of the solar module 3 due to wind pressure or the like. The effect is that the coupling durability can be improved compared to the structure to simply connect the fixing bracket.

In addition, in one embodiment of the present invention, the upper surface 141c of the one-way bracket 141 is formed with a predetermined bending angle θ such that the distal end is inclined downward by a predetermined angle to form an acute angle with the vertical surface 141b. The bottom surface 141a and the vertical surface 141b are formed to be perpendicular to each other.

That is, the one-way bracket 41 extends horizontally protruding in one direction relative to the vertical surface 142, the upper surface 143 is predetermined to be inclined downward by a predetermined angle in the other direction. Bend angle θ is formed.

Accordingly, the solar module fixing device 100 of the present invention, the upper surface (141c) is the upper surface of the solar module 3 in the process of the one-way bracket 141 is fastened to the T-bolt 120. To be elastically pressurized downward.

That is, as shown in FIG. 6, the one-way bracket 141 may have the top surface 141c before the bottom surface 141a is seated in the bracket seating groove 118 having a predetermined depth in the rail frame 110. The length of the vertical surface 141b may be set to a length at which the inclined tip portion of the solar module 3 can reach the upper surface of the solar module 3 first. In this case, the bottom surface 141a is the bracket seating groove 118. When the nut is fastened to the T-bolt 120 in the non-contact state, the upper surface 141c is elastically deformed to be in surface contact with the upper surface of the photovoltaic module 3. By fixing the photovoltaic module 3 with a strong force, even if a long time passes after the installation of the photovoltaic module, the photovoltaic module 3 does not flow or a phenomenon in which the connecting parts are easily released.

The bidirectional bracket 142 may fix the solar modules 3 and 3 'of the two neighboring solar modules 3 and 3' between the solar modules 3 and 3 'which are disposed adjacent to each other. It is configured to be.

Thus, the bidirectional bracket 142 is formed of a bottom surface 142a, a vertical surface 142b and an upper surface 142c similar to the one-way bracket 141, the upper surface 142c is the one-way bracket ( It is preferable that the bending angle θ be formed in the same form as 142.

As shown in FIG. 7, the bidirectional bracket 142 may be disposed in a gap between the photovoltaic modules 3 and 3 ′ on both sides, and the bidirectional bracket 142 is disposed on the bottom surface ( The vertical surface 142b and the upper surface 142c are formed at both sides with respect to 142a so that the edges and the upper ends of the photovoltaic modules 3 and 3 'on both sides can be simultaneously supported.

The bi-directional bracket 142 formed as described above is a fastening hole 142a 'of the bottom surface 142a so that the top surface 142c is caught in the gap between the solar modules 3 and 3' on both sides. When inserted in the state inserted in the T-bolt 120, the bottom surface 142a is spaced apart from the upper surface of the rail frame 110 by a predetermined height. That is, the bidirectional bracket 142 is supported with the inclined tip portion of the upper surface 142c in contact with the upper end of the photovoltaic modules 3 and 3 ', wherein the operator is a nut of the T-bolt 120. As the fastening angle (θ) formed in the bidirectional bracket 142, the upper surface 142c elastically pressurize the solar modules (3, 3 ') of both sides so that a solid coupling operation can be made.

That is, the plurality of solar modules 3 and 3 'disposed adjacent to each other in the upper part of the prefabricated roof panel 1 can be very firmly fixed.

Accordingly, the photovoltaic module fixing device 100 of the present invention includes a photovoltaic module 3 on a roof of a building constructed with a prefabricated roof panel 1 in which a mountain 1a and a floor 1b are formed in a longitudinal direction. The installation work can be made very easy and robust, construction time can be greatly shortened, and the number of necessary parts is reduced compared to the prior art, the economic efficiency is also improved.

The solar module fixing device of the prefabricated roof described above and shown in the drawings is only one embodiment for carrying out the present invention, and should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is defined only by the matters set forth in the claims below, and the embodiments which have been improved and changed without departing from the gist of the present invention will be apparent to those skilled in the art. It will be said to belong to the protection scope of the present invention.

110 Rail frame 111 Base
112 bulkhead 113 side wall
114 Bolts 115 Wings
116 Jam Jaw 117 Upper Opening
120 T-bolt 130 Sealing member
140 Fixed Bracket 141 One-way Bracket
142 Two-way Bracket

Claims (4)

In the photovoltaic module fixing device for installing the photovoltaic module on the roof of the building is constructed of a prefabricated roof panel that is repeatedly formed in the longitudinal direction of the mountain and the floor,
A cross section is elongated and formed to be coupled along the hill portion of the roof panel. A rail frame formed with a partition wall portion or a side wall portion, an upper opening opened to form a predetermined locking step above the inner space, and a bolt hole vertically penetrating from the inner space to the base portion;
A T-bolt having a narrow width having a width capable of passing through the upper opening and a head having a wide width caught in the locking jaw; Including,
A sealing member installed between the upper surface of the mount and the base portion to waterproof the bolt hole when the fixing member is inserted into and fastened to the bolt hole so that the base portion of the rail frame is coupled to the upper surface of the mount; The solar module fixing device of the prefabricated roof further comprising. The method of claim 1,
The rail frame is a prefabricated roof solar module fixing device, characterized in that the wing parts in contact with both sides of the inclined side of the mountain formed integrally extending from both sides of the base portion. The method according to claim 1 or 2,
A fixing bracket having one end fastened to the rail frame by the T-bolt so that the solar module is fixed to the rail frame, and the other end supporting the edge of the solar module; Include more,
The rail frame is a solar module fixing device of the prefabricated roof, characterized in that the bracket fixing grooves are formed in the upper surface formed in the groove recessed by a predetermined depth to have the same width corresponding to the width of the fixing bracket. The method of claim 3,
The fixing bracket is formed with a fastening hole for fastening the T-bolt is inserted into the bottom surface is horizontally seated in the bracket fixing groove, and extends vertically upward from one side of the bottom surface of the solar module The vertical surface is supported to be in contact with the side surface, and the upper surface of the upper surface of the vertical surface protruding protruding toward the opposite side of the bottom surface to support the upper surface of the photovoltaic module is formed,
The upper surface of the prefabricated roof solar module fixing device, characterized in that a predetermined bending angle is formed to be inclined downward by a predetermined angle to the acute angle with the vertical surface, the bottom surface and the vertical surface is formed at right angles to each other. .

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