KR102647918B1 - Solar Energy Generation System - Google Patents

Abstract

The present invention relates to a solar power generation system (solar power generation device). More specifically, it is about a solar power generation system using solar power installation structures that can utilize idle space on urban buildings, such as rooftops or rooftops of general or public buildings, rest areas, and gas station canopies. At this time, in order to install a solar power generation system in an idle space or on the roof of a building, the installation structure includes a vertical support, a horizontal support, a module support, and a joint connecting them.

Description

Solar energy generation system that is easy to install

The present invention relates to a solar power generation system (solar power generation device) that is easy to install. More specifically, it is about a solar power generation system using a solar power generation device installation structure that can utilize idle space on urban buildings such as rooftops or roofs of general or public buildings, rest areas, and gas station canopies.

Regarding solar power generation systems, roof-mounted solar power generation device fixing devices and methods have been disclosed that not only improve the convenience of installation and separation of solar power installation structures, but also prevent damage from external forces such as wind pressure. It is done.

In the installation of a solar power generation system, solar power generation system solar modules usually installed on the roof of a building are installed after assembling horizontal and vertical beams in a grid shape, but the installation work is not easy due to the small work space. .

When a solar power installation structure equipped with solar power generation modules is installed in an idle space such as a building roof or rooftop, the size of the structure increases due to wind pressure, which can have a negative impact on the safety of the building structure and the working load. And the number of work processes increases, increasing installation costs.

According to the easy-to-install solar power generation system of the present invention, disassembly and assembly of the installation structure are easy, so the work load and work process due to installation and repair of the solar power generation device are reduced, and the installation structure can be partially repaired. The overall height of the solar power installation structure can be lowered by the installation structure to reduce damage caused by wind pressure and external loads, thereby increasing durability. The combined structure of the installation structure is simplified, which can reduce costs such as transportation and labor costs.

In addition, since the solar photovoltaic installation structure is fixed by an installation structure that combines horizontal supports, vertical supports, and module supports, additional costs such as site purchase costs or civil engineering costs required for installation of solar power generation devices can be reduced.

Figure 1 is a state diagram of an example in which a solar power installation structure of a solar power generation system is installed.
Figure 2 is a cross-sectional view of an example installed state seen from the front.
Figure 3 is a perspective view of an example of a fixture in an exploded state.
Figure 4 is a perspective view of the fixture in an assembled state.
Figure 5 is an example of a fixed state showing an enlarged portion.
In Figure 6, (a) is a perspective view illustrating the rear joint. (B) is a perspective view illustrating the anterior joint.
Figure 7 is an exemplary diagram illustrating the process of inserting the horizontal support into the side coupling part of the joint and an exemplary diagram of adjusting the length of the horizontal support.
Figure 8 is an example of another implementation of the part, a state diagram before binding and an assembled state diagram after binding.
Figure 9 is a full side view and partial perspective view.

The installation structure and installation method of the solar power installation structure on which the solar power generation module (Sola Panel Module) of the solar power generation system is mounted includes a plurality of vertical supports (10) and a plurality of joints respectively connected to both ends of the vertical supports (10). (30), each module support 20 is fixed to the upper coupling part of the joint 30 and is located on the upper side of the vertical support 10 and forms an inclined surface on its upper surface, and the joint 30 An installation structure (100) provided with a light weight and consisting of each horizontal support (50) fixed to the side coupling portion and positioned perpendicular to the vertical support (10),

Each solar power generation device 200 is mounted in a direction corresponding to the inclined surface of the module support 30 through a plurality of fastening means 60 fastened at regular intervals on the upper side of the installation structure 100. Thus, the solar power generation device is fixed by the installation structure.

A plurality of vertical supports (10) arranged on the rooftop of a building or in an idle space including the roof, a plurality of joints (30) respectively coupled to both ends of the vertical supports (10), and fixed to the upper coupling portion of the joints (30). Each module support 20 is located on the upper side of the vertical support 10 and forms an inclined surface on its upper surface, and is coupled to the side coupling part of the joint 30 in a direction perpendicular to the vertical support 10. An installation structure (100) consisting of a plurality of horizontal supports (50) positioned at; It consists of each solar power generation device 200 mounted in a direction corresponding to the inclined surface of the module support 30 via a plurality of fastening means 60 fastened to the upper side of the installation structure 100.

The fixing device according to the present invention is for using idle spaces on city buildings, such as rooftops or roofs of general and public buildings, or canopies of rest areas and gas stations, as solar power generation sites, and includes an installation structure (100) fixed to the idle space, and , It consists of a solar power generation device 200 that is obliquely fixed to the upper side of the installation structure 100.

The installation structure 100 is a structure in the form of a triangular pillar that is fixed outdoors, such as on a building roof, and includes a plurality of vertical supports 10 seated in the width direction at the installation location, and the joint at the top of the vertical supports 10. It consists of a plurality of module supports 20 fixed through (30) and a plurality of horizontal supports 50 fixed to the side of the vertical support 10 in the longitudinal direction through the joint 30.

It is preferable that the vertical support 10, module support 20, and horizontal support 50 are formed in the shape of a straight bar as much as possible. In particular, the module support 20 forms a right angle surface on one side and an inclined surface on the upper side. It is desirable to form.

The joint 30 not only connects the vertical support 10, the horizontal support 50, and the module support 20 to each other, but also sets the angle of the solar power generation device 200, and the vertical support is located on the lower side thereof. A lower coupling part to which (10) is connected is formed, a side coupling part to which the horizontal support 50 is connected is formed on both sides, and an upper coupling part to which the module support 20 is connected is formed on the upper side. At this time, it is desirable to use a four-way joint for the joint 30 except for the joints located at both ends of the installation structure 100, and the side coupling portions to which the horizontal supports 50 are connected are provided on both sides of the joint. As it is formed, a lower coupling part to which the vertical support 10 is connected is formed in the center, and an upper coupling part to which one end of the module support 20 is connected is formed in a direction inclined at a certain angle on the upper side.

The solar power generation device 200 is mounted on the upper surface of the installation structure 100 in an oblique direction to convert solar energy into electrical energy. The upper surface of the installation structure 100 preferably includes the module support ( It is fixed through a plurality of fastening means 60 fastened at regular intervals on the inclined surface of 20).

The installation structure 100 is installed on the roof of a building, roof, or canopy of a gas station, and then the solar power generation device 200 is placed and fixed thereon. In particular, the module support 20 of the installation structure 100 is aligned with the horizontal plane. Since it has the characteristic of being inclined at an inclination angle of 30 ± 5°, the solar power generation device 200 faces south, creating an optimal environment in which it can easily receive sunlight. Since the installation structure 100 is composed of a combination of supports 10, 20, and 50, the area is determined by adjusting the spacing of the supports 10, 20, and 50 without being limited by the area of the building rooftop, so the solar power generation device (200) can be installed at maximum.

Since the parts of the vertical support 10 and the module support 20 that meet in the right angle and diagonal directions are combined with the joint 30, the inner diameter of the joint 30 is larger than that of the vertical support 10 and the module support 20. It is desirable to form it large, which results in a shape that embraces the vertical support 10 and the module support 20.

In Figure 5, the galvanized C-beam steel fastening means 60 is screwed to the installation structure 100, and the solar power generation device 200 is screwed thereon.

In order to utilize idle space such as roofs more efficiently and adapt to the size and various shapes of the space, a means of adjusting the length of the horizontal support is needed in the installation structure.

In FIG. 6, the joint 30 interconnects the vertical support 10, the horizontal support 50, and the module support 20, and the length of the horizontal support 50 is adjusted to fit around the perimeter when the building rooftop has a complex or narrow shape. It consists of two side coupling parts (35) connecting the horizontal supports (50) so that they can be adjusted to be longer or shorter depending on the environment.

As shown in the examples of FIGS. 6 and 8, the side coupling portion 35 is provided separately by dividing it into a first side coupling portion 35a and a second side coupling portion 35b, and the two are provided by combining them. In more detail, the first side engaging portion 35a and the second side engaging portion 35b are placed in parallel (side by side) contact and then coupled to each other so that their bodies are in close contact with each other. This will be called ‘lateral joint binding’.

The case of Figure 6 is an example of attaching (b1) by welding or fastening with screws (bolts) in performing the side coupling. Accordingly, the front and back torsos are attached and arranged so that they cannot move.

In the case of FIG. 8, in performing the side joining portion binding, a binding belt 35f in the form of a belt provided with a metal member or a predetermined flexible synthetic resin member having the strength to bind the two is provided, and the binding belt 35f is provided. It is provided so that the first side engaging portion 35a and the second side engaging portion 35b are inserted into the binding belt 35f and tightened tightly. Accordingly, the binding belt 35f is shaped to have an inner periphery corresponding to an outer periphery arranged by contacting the first side engaging portion 35a and the second side engaging portion 35b together. In the example of FIG. 8, the binding belt 35f takes the form of a caterpillar and is shown on only one side of the left and right sides, but it is preferable to provide it on both the left and right sides of the side coupling portion. As shown in the example on the right side of FIG. 8, this type of side coupling allows the binding belt (35f) to slip to a certain extent, thereby providing a flow angle (a3) that can forcibly change the angle, and by adopting a tighter one, the slip is reduced. You can prevent it from happening.

When the binding belts 35f are made of a flexible synthetic resin member, it is easy to store a large number in a narrow space, and the operation of binding both the first side engaging portion 35a and the second side engaging portion 35b is performed. If a modified form occurs in a poem, it is easy to work quickly by adapting it accordingly.

At this time, the vertical support 10 is connected to the center of the first side coupling portion 35a, and the module support 20 is connected to the center of the second side coupling portion 35b.

In the upper drawing of FIG. 7, in the first side engaging portion 35a located in front of the side engaging portions 35 of the joint 30, a hole c1 on the left (or right) side of the joint 30 is provided with a hole c1 on the left (or right) side. The horizontal support 50a is inserted (fitted) and fixed. Conversely, in the second side engaging portion 35b located behind the side engaging portion 35 of the joint 30, a hole on the right (or left) thereof ( The right (or left) horizontal support 50b is inserted and coupled (fixed) to c1).

The configuration of the horizontal support 50 coupled to the side engaging portion 35 through the above-described method is provided so that the length can be adjusted as shown in the lower drawing of FIG. 7, from the left side of the first side engaging portion 35a in the drawing. The insertion-coupled left horizontal support (50a) is fixed by its outer circumferential surface contacting the inner circumferential surface of the inner hole (c1) of the first side coupling portion (35a), and moves by sliding a certain portion to adjust the length in the longitudinal direction (m1). ) is possible to combine.

Similarly, the right side horizontal support (50b), which is fitted and coupled from the right side of the second side coupling part (35b) in the opposite direction, is fitted and coupled to the second side coupling part (35b), and then is connected to the inner peripheral surface of the second side coupling part (35b). Independent (separate) length adjustment is possible by moving it in the longitudinal direction (m2). In the drawing, an example is shown where the horizontal support 50b on the right side is inserted from the right side of the second side coupling portion 35b and then its length is shortened to the point where it is exposed outside the inlet on the left side.

Using this method, the horizontal support 50a on the left and the horizontal support 50b on the right can be moved independently to freely adjust their lengths without interfering with each other, so that they can be adjusted to the maximum extent possible in the environment of the workplace where solar power facilities are installed. By adapting, you can maximize the length adjustment method. Meanwhile, after adjusting the required length, a threaded hole is formed in advance in the side coupling portion 35 for secure fixation, and a screw d1 is tightened there. In other words, it can be fixed by tightening the horizontal support with a screw, etc., see Figure 7.

Returning to Figure 3, the joint 30 including the side coupling portion is the joint 30 on the front side (1) that meets and couples to the inclined portion in front of the module support 20, and the module support 20. It includes a joint 30 on the rear side (2) that meets the vertical portion at the rear. In other words, it can be seen that it is provided separately into two parts.

When forming a joint (30) by combining the first side coupling portion (35a) and the second side coupling portion (35b) by coupling the side coupling portions, the rear side (2) of the module support (20) In order to correspond to the right-angled shape of the vertical part 22, or to correspond to the inclined inclined angle shape of the inclined part 21 on the front side 1 of the module support 20,

In the example of Figure 6, where the side coupling portion of the first side coupling portion 35a and the second side coupling portion 35b is configured (provided) to be fixed by welding/bolting,

As shown in the upper drawing of FIG. 6, the lower coupling portion 31 into which the vertical support 10 is inserted and connected and the upper coupling portion 32 into which the module support 20 is inserted and connected are attached to each other (b1) so that the mutual angle between them forms a right angle (a1). ) can be provided as a joint 30 on the rear side (2). As shown in the lower drawing of FIG. 6, when attached (b1) so that the angle between the lower coupling part 31 to which the vertical support 10 is connected and the upper coupling part 32 to which the module support 20 is connected is an acute angle (a2), the front It may be provided as a joint 30 on side 1.

The side coupling portion is connected by wrapping the first side coupling portion (35a) and the second side coupling portion (35b) with the binding belt (35f), so that a predetermined portion of the coupling belt slips and twists to provide a flow angle (a3). In the example of Figure 8 (provided),

It has the advantage of being able to install quickly by giving only an approximate setting angle and then forcibly change/adjust the predetermined setting angle depending on the site situation, rather than having to fix it by giving an exact setting angle from the beginning. At this time, since the installation structure 100 is provided in a triangular shape as a whole, the preset triangular shape is maintained after it is assembled, so there is no need for additional fixing.

As an example in FIG. 9, the module support 20 includes an inclined part 21 on which the solar power generation device 200 will be mounted and a vertical part 22 to be connected to the joint 30, and the inclined part ( A hinge coupling (20a) configured to be bendable by connecting the vertical part (21) and the vertical part (22) with a hinge/joint may be added. At this time, the upper end of the vertical part 22 is hinged (20a) with the rear end (back part) of the inclined part 21, and the lower end of the vertical part 22 is coupled to the upper part of the joint 30. It is inserted (fitted) into the part 32 and fastened, and after insertion, it is tightened with a screw (pn) to prevent it from moving (sliding).

In the module support 20, the inclination of the inclined part 21 on which the solar power generation device 200 is to be placed depends on the inclination angle of the joint 30 on the front side 1, which is the angle of the flow angle a3. This is achieved through the implementation of adjustment, and if necessary, the method of adjusting the flow angle a3 can be used even in the case of the rear side 2. Accordingly, a change occurs in the vertical height of the rear end of the module support 20 according to the inclination of the inclined part 21, and in response to the change, the lower end of the vertical part 22 is connected to the upper coupling part ( 32), insert it at the height (a4), match it, and bind it. At this time, the inclined part 21 and the vertical part 22 are accompanied by a slight angular change, and this is configured to correspond through the hinge coupling 20a provided to enable refraction.

According to the above installation structure and installation method, arbitrary adjustment of the inclination (tilt) of the inclined part 21 on which the solar power generation device 200 is to be placed, as needed depending on site conditions, seasons, and settings, etc. As this is possible, it is possible to prevent replacement, re-construction, or re-installation of the entire module support 20 due to the tilt being wrong or inappropriate to the site situation.

Hinge coupling (20a); vertical part (22); inclined part (21); solar power generation device (200); joint (30); vertical support (10); module support (20); First side coupling portion (35a); Second side coupling portion (35b); Horizontal support (50a) on the left; Transverse support (50b) on the right side; Installation structure (100);

Claims (1)

In order to install a solar power generation system in an idle space or on the roof of a building, the solar power installation structure includes a vertical support (10), a horizontal support (50), a module support (20), and a joint (30) connecting them,
In the joint 30, a first side engaging portion 35a and a second side engaging portion 35b, each having an internal hole c1, are arranged back and forth in parallel, and the first side engaging portion 35a and the second side engaging portion 35b are arranged in parallel. The coupling portion 35b is bound to form a side coupling,
The vertical support 10 is connected to the central lower coupling part 31 of the first side coupling part 35a, and the module support 20 is connected to the central upper coupling part 32 of the second side coupling part 35b. become,
The horizontal support 50 includes a left horizontal support 50a and a right horizontal support 50b, and the left horizontal support 50a is slidably inserted from the left side of the first side coupling portion 35a to allow length adjustment. The horizontal support (50b) on the right side is slidably inserted from the right side of the second side coupling portion (35b) to adjust its length and is provided to avoid interference with each other,
The side coupling portion includes a binding belt (35f),
The binding belt 35f has an inner periphery corresponding to an outer periphery arranged by contacting the first side engaging portion 35a and the second side engaging portion 35b together, and the first side engaging portion 35f is located inside the binding belt 35f. When the side coupling portion (35a) and the second side coupling portion (35b) are inserted, a certain amount of slip is allowed to allow a flow angle (a3) that can forcibly change the angle, so that the first side coupling portion (35a) and the second side coupling portion (35a) are inserted. If a deformed shape occurs during the work of binding the two coupling portions 35b, it is provided to facilitate quick work by adapting accordingly,
The module support 20 includes an inclined part 21 on which to place the solar power generation device, and a vertical part 22 to be connected to the joint 30, and the inclined part 21 and the vertical part 22 are It is configured to be bendable through a hinge coupling (20a). At this time, the upper end of the vertical part 22 is hinged with the rear end of the inclined part 21 (20a), and the lower end of the vertical part 22 is connected to the joint ( It is inserted into the upper coupling part 32 of 30),
Tilting of the inclined part 21 is achieved by simultaneously adjusting the flow angle of the front side (1) joint 30 and the flow angle adjustment of the rear side (2) hinge coupling 20a,
If a change occurs in the vertical height (a4) of the rear end of the module support (20) due to the tilt of the inclined part (21), the lower part of the vertical part (22) and the upper part of the joint (30) are connected in response to the change. In the insertion-coupled configuration of (32), the height (a4) corresponds, and at this time, the angular changes in the inclined part (21) and the perpendicular part (22) are corresponded through the bending hinge coupling (20a). ,
When fixing, the lower end of the vertical part 22 inserted into the upper coupling part 32 of the joint 30 is tightened with a screw (pn) and fixed so that it cannot move.
The inclination angle of the module support 20 is inclined at 30° with respect to the horizontal plane, and the galvanized C-beam steel fastening means 60 is screwed to the solar power installation structure and the solar power generation device is screwed thereon. doing,
Solar power generation system that is easy to install.