KR102353950B1 - Earthquake-resistant structures of photovoltaic power generation facilities - Google Patents

Abstract

The present invention relates to an antiseismic structure for photovoltaic power generation facilities. The antiseismic structure for photovoltaic power generation facilities according to the present invention is installed on a support pillar which supports a holder where a photovoltaic module of the photovoltaic power generation facilities is installed and comprises: a base having a shape of a flat plate, which is fixed on the ground by using an anchor bolt; an elastic member stacked on an upper part of the base and connected to the support pillar to absorb and relieve impact or vibration delivered through the support pillar; a binding means connecting the elastic member and the base and binding and fixing the elastic member to the support pillar; and a safety means preventing the elastic member from being damaged or broken by tensile force occurring in the elastic member to induce stable connection between the elastic member and the support pillar. Accordingly, the elastic member seated on the base fixed on the ground can be firmly bound to the base and the support pillar in a convenient way through the binding means, so that it can absorb and relieve vibration or impact occurring in the photovoltaic power generation facilities in a convenient way to allow the photovoltaic facilities to be used safely. In addition, easy manufacturing of the antiseismic structure ensures possibility of mass-production to allow versatility of the product. Moreover, the safety means can block the elastic member from being deformed beyond a threshold value by high tensile force, thereby preventing an accident likely to be caused by a damage or breakage to the antiseismic member in a conventional antiseismic structure in advance to enhance safety of the antiseismic structure in use.

Description

Earthquake-resistant structures of photovoltaic power generation facilities

The present invention relates to an earthquake-resistant structure of a photovoltaic power plant, and more particularly, to a photovoltaic power plant through a simple structure in which an elastic member mounted on a base fixed to the ground is firmly bound to a base and a support column through a binding means. It can easily absorb and eliminate vibrations or shocks, which can induce safe use of photovoltaic facilities, as well as secure mass productivity through the easy fabrication of earthquake-resistant structures, thereby securing the versatility of product use. It relates to the seismic structure of the solar power generation facility.

Recently, as factors exacerbating the energy crisis, such as a surge in international oil prices, climate change, and global warming, have emerged, the energy security crisis theory is emerging.

Solar power generation facilities, which can relieve some of the burden of the global warming problem and the expansion of power generation facilities generated by fossil fuels, convert sunlight into direct current electricity to produce electricity, and use a solar module with several solar cells attached. . Solar power generation facilities are spotlighted as a next-generation alternative energy source because they can be used semi-permanently as a distributed power generation system, are easy to maintain using solar cells, and are non-polluting and use unlimited solar energy sources.

The above solar power generation facilities are mostly installed on the roof or roof of houses, and large-scale solar power generation facilities have been installed in the mountains or land with abundant sunlight. It is installed on the roof of the building or on the roof.

In such a photovoltaic power generation facility, the photovoltaic module of the photovoltaic power generation facility made of a glass substrate or polysilicone may be easily damaged by the seismic force that vibrates on the concrete structure when an earthquake occurs.

Nevertheless, so far, the design for earthquake or vibration has not been applied to solar power generation facilities due to the increase in production cost and the weak earthquake intensity in Korea.

With the recent rapid changes in the global environment and the active activity of the seismic zone in Asia over the past few years, the government has not only built an advanced earthquake response system through the scientific development of earthquake response measurement equipment, etc. Following the announcement (2005) of the mandatory earthquake-resistant design for abnormal buildings, the earthquake-resistant design standards for firefighting facilities (draft) were prepared (2013), and a policy to strengthen the earthquake-resistant design of all facilities is being promoted.

Seismic design for facilities and power generation facilities is a comprehensive design technique for earthquakes, including seismic isolation design, which is a design technique to secure seismic safety by absorbing, reducing, and dissipating the seismic force transmitted to facilities and power generation facilities through buildings in the event of an earthquake. design technology.

To this end, a technology has been developed and proposed to safely protect solar power facilities from earthquakes by installing earthquake-resistant structures (devices) that can absorb and resolve vibrations or shocks (seismic forces) on the support pillars supporting the photovoltaic power generation facilities.

Conventionally, the seismic structure of the solar power generation facility has a complicated structure, which makes it difficult to implement realistically, and the earthquake-resistant member that absorbs the vibration or shock is damaged or damaged by the strong tensile force formed by the vibration or shock, so that the seismic performance is too easily reduced. There was a problem with the loss.

Furthermore, in the conventional solar power generation facility, the connection between the support column and the ground is released due to the damage or breakage of the seismic member, and the photovoltaic power generation facility itself falls or collapses. there was

The present invention has been proposed to solve the various problems as described above, and its purpose is to generate solar power through a simple structure in which an elastic member mounted on a base fixed to the ground is firmly bound to the base and the support column through a binding means. Vibration or shock generated in the facility can be easily absorbed and eliminated, so it is possible to induce the safe use of photovoltaic facilities. It is to provide an earthquake-resistant structure of a solar power generation facility that can do this.

In addition, by preventing the elastic member from being deformed beyond the critical value due to high tensile force through safety means, safety accidents that may occur due to damage or breakage of the earthquake-resistant member in conventional earthquake-resistant structures are prevented in advance to improve the safety of use of earthquake-resistant structures. It is to provide an earthquake-resistant structure of a solar power generation facility that can be strengthened.

The earthquake-resistant structure of the solar power generation facility according to the present invention for achieving the above object is a flat plate-shaped base fixed to the ground through an anchor bolt; An elastic member for absorbing and eliminating shock or vibration transmitted through the support pillar; and a binding means for coupling the elastic member and the base to each other, and coupling the elastic member and the support pillar to each other; and generated in the elastic member A safety means for inducing a stable connection between the elastic member and the support column by preventing damage or breakage of the elastic member due to the tensile force being applied;

The elastic member has a flat plate shape, has a metal lower panel laminated on the upper portion of the base, and has a predetermined elastic force, is laminated on the upper portion of the lower panel, and absorbs shock or vibration transmitted through the support column It consists of a flat plate-shaped elastic panel to solve, and a flat plate-shaped upper panel of a metal material laminated on the upper portion of the elastic panel,

The elastic panel is formed of a rubber plate body or a spring, and when the rubber plate body is formed, a fabric is embedded therein to strengthen the durability of the plate body,

The binding means is formed through the lower panel, one or more fastening holes having threads formed on the inner circumferential surface, and passing through the base to be fastened to the fastening holes, relying on the base to bind the lower panel to the base. A mood bolt for fixing, a plurality of binding holes formed in the lower part of the support column, the lower part is welded and fixed to the upper part of the upper panel, and the upper part is located through the binding hole, and a thread is formed on the outer circumferential surface. and a binding nut that is fastened to the binding bolt to bind and fix the support column to the upper panel,
The safety means includes a through hole formed through the center of the elastic member, a safety hole formed to communicate with the through hole at the center of the base, and a screw thread formed on the inner circumferential surface, and the support column and the elastic member. A safety stopper consisting of a plate-shaped safety plate supporting the upper portion of the elastic member, and a safety pillar extending downward from the center of the lower portion of the safety plate and penetrating the through hole, the outer circumferential surface of which is threaded and fastened to the safety hole; , characterized in that it comprises a rubber plate formed on the upper and lower surfaces of the safety plate of the safety stopper.

delete

As described above, according to the earthquake-resistant structure of the photovoltaic power plant according to the present invention, the elastic member mounted on the base fixed to the ground is firmly bound to the base and the support column through the binding means to the photovoltaic power plant through a simple structure. It can easily absorb and eliminate vibrations or shocks, which can induce safe use of photovoltaic facilities, as well as secure mass productivity through the easy fabrication of earthquake-resistant structures, thereby securing the versatility of product use. there is an effect

In addition, by preventing the elastic member from being deformed beyond the critical value due to high tensile force through safety means, safety accidents that may occur due to damage or breakage of the earthquake-resistant member in conventional earthquake-resistant structures are prevented in advance to improve the safety of use of earthquake-resistant structures. It has a strengthening effect.

1 is a perspective view of an earthquake-resistant structure of a solar power generation facility according to an embodiment of the present invention;
Figure 2 is an exploded perspective view of the earthquake-resistant structure of the solar power generation facility shown in Figure 1;
3 is an AA cross-sectional view of the earthquake-resistant structure of the solar power generation facility shown in FIG.
Figure 4 is a state diagram of the use of the earthquake-resistant structure of the solar power generation facility shown in Figure 1;

An earthquake-resistant structure of a solar power generation facility according to a preferred embodiment of the present invention will be described in detail based on the accompanying drawings. Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the gist of the present invention will be omitted.

1 to 4 show an earthquake-resistant structure of a solar power generation facility according to an embodiment of the present invention, FIG. 1 is a perspective view of the earthquake-resistant structure of a solar power generation facility according to an embodiment of the present invention, FIG. 1 is an exploded perspective view of the earthquake-resistant structure of the solar power generation facility shown in FIG. 1, FIG. 3 is an AA cross-sectional view of the earthquake-resistant structure of the solar power generation facility shown in FIG. 1, and FIG. Each of the structures used state diagrams are shown.

As shown in the figure, the earthquake-resistant structure 100 of the solar power generation facility according to an embodiment of the present invention includes a base 10, an elastic member 20, a binding means 30, and a safety means 40 ) is included.

As shown in Figures 1 to 3, the base 10 is to be firmly fixed to the ground through the anchor bolts (2), the elevating path having a flat plate shape.

Here, the base 10 is a medium for stably supporting the elastic member 20 and the support column 1 to be installed later by relying on the ground, and is preferably made of a metal material having excellent strength.

1 to 3, the elastic member 20 is stacked on the upper portion of the base 10, and a support pillar 1 for supporting a cradle on which a solar module is installed in a photovoltaic power generation facility, and It is connected to absorb and eliminate the shock or vibration transmitted through the support pillar (1),

It has a flat plate shape and has a lower panel 21 made of a metal material laminated on the upper portion of the base 10, and has a predetermined elastic force, and is laminated on the upper portion of the lower panel 21 to form the support column 1 It consists of a flat plate-shaped elastic panel 22 that absorbs and eliminates shock or vibration transmitted through, and a flat plate-shaped upper panel 23 of a metal material laminated on the upper portion of the elastic panel 22. .

Here, the lower and upper panels 21 and 23 of the elastic member 20 have a large contact area in order to easily transmit the shock or vibration transmitted from the ground and the support pillar 1 to the elastic panel 22 . It is implemented in a flat plate shape and is made of a metal material having excellent strength to protect the elastic panel 22 from the impact transmitted from the ground and the support pillar 1 .

Therefore, when an impact or vibration occurs to the ground and the support pillar 1 due to an earthquake or typhoon, etc., as shown in FIG. 4A, the base 10 and the support pillar 1 installed on the ground are connected to Through the lower and upper panels 21 and 23, the shock or vibration generated on the ground and the support column is effectively transmitted to the elastic panel 22 to be absorbed and resolved, so that the support column 1 due to an earthquake or typhoon, etc. It is possible to induce the safe use of the photovoltaic power generation facility by stably preventing the damage and damage of the photovoltaic power generation facility supported on the wall.

In the seismic structure 100 of the photovoltaic power generation facility of the present invention, the elastic member 20 is implemented in the shape of a square column composed of one body, but of course, it can be implemented in a shape such as a square or a cylinder with a plurality of pieces, and the above Although the elastic panel 22 is implemented as a rubber plate body having a fabric embedded therein, it is of course possible to implement it as a high elastic spring having excellent elasticity.

1 to 3 , the binding means 30 couples the elastic member 20 and the base 10 to each other, and the elastic member 20 and the support pillar 1 are mutually coupled and fixed. by doing,

At least one fastening hole 31 formed through the lower panel 21 and having a screw thread 31a formed on the inner circumferential surface thereof, and passing through the base 10 to be fastened to the fastening hole 31, A mood bolt 32 for binding and fixing the lower panel 21 to the base 10 depending on the base 10, and a plurality of binding holes 33 formed in the lower portion of the support column 1; The lower part is welded and fixed to the upper part of the upper panel 23, and the upper part is positioned through the binding hole 33, the binding bolt 34 having a screw thread 34a formed on the outer circumferential surface thereof, and the binding bolt 34 ) and is configured to include a binding nut 35 for binding and fixing the support pillar 1 to the upper panel 23 .

That is, the lower portion of the elastic member 20 is firmly coupled and fixed to the base 10 through the fastening hole 31 and the mood bolt 32 of the binding means 30 , and the upper portion of the elastic member 20 is fixed. is firmly coupled and fixed to the support column 1 through the binding hole 33, the binding bolt 34, and the binding nut 35 of the binding means 30, and the base 10 and the elastic member 20 and By securing a stable coupling structure between the support pillars 1, the structural safety of the earthquake-resistant structure 100 of the photovoltaic power generation facility of the present invention can be strengthened.

2 and 3, the safety means 40 prevents damage or breakage of the elastic member 20 due to the tensile force generated in the elastic member 20, thereby preventing the elastic member 20 from being damaged. By inducing a stable connection of the support column (1),

A through hole 41 penetrating through the center of the elastic member 20, and a safety hole formed to communicate with the through hole 41 at the center of the base 10, a screw thread 42a is formed on the inner circumferential surface. (42), a plate-shaped safety plate (43a) positioned between the support column (1) and the elastic member (20) to support the upper portion of the elastic member (20), and the lower center of the safety plate (43a) A safety stopper 43 extending downward and penetrating the through hole 41 but having a screw thread 43b ′ formed on an outer circumferential surface thereof and comprising a safety pillar 43b fastened to the safety hole 42 , and the safety stopper (43) is configured to include a rubber plate 44 formed on the upper and lower surfaces of the safety plate (43a).

In general, when the support pillar 1 is shaken by an earthquake or typhoon, a tensile force that pulls the elastic member 20 upward by the support pillar 1 is frequently generated. The elastic member 20 may be damaged or damaged, for example, the elastic panel 22 of the elastic member 20 may be separated from the upper and lower panels 21 and 23, and in this case, the base ( 10) and the support pillar (1) is disconnected, and a large-scale accident in which the solar power generation facility itself falls over may occur.

Therefore, as shown in FIG. 4B , when a high tensile force is generated in the elastic member 20 and stretched upward (when ascending and descending), the safety stopper 43 of the safety means 30 is fixed by relying on the base 10 . ), the upper portion of the elastic member 20 is naturally closely supported to prevent the elastic member 20 from being deformed (stretched) beyond a threshold value, thereby preventing the elastic member 20 from being deformed (stretched) by the tensile force formed in the elastic member 20 ) can be reliably prevented from large-scale safety accidents caused by deformation or damage, so that the safety of use of the device is strengthened.

Here, the elastic force (cushion force) of the rubber plate 44 formed on the upper and lower surfaces of the safety plate 43a of the safety stopper 43 is in close contact with the safety plate 43a of the safety stopper 43. Of course, the structural safety of the device is secured by minimizing the contact impact between the member 20 and the support pillar 1 .

In the earthquake-resistant structure 100 of the photovoltaic power generation facility of the present invention made of the above components, the elastic member 20 mounted on the base 10 fixed to the ground is the base through the binding means 30 . (10) and the support column (1) and the simple structure that is firmly bound to the vibration or shock generated in the photovoltaic power generation facility can be easily absorbed and eliminated, so that the safe use of the photovoltaic facility can be induced, and the earthquake-resistant structure It is possible to secure a large amount of productivity through the easy manufacturing of the product, which has the effect of securing the versatility of use of the product.

In addition, by preventing the elastic member 20 from being deformed beyond a critical value by high tensile force through the safety means 40, safety accidents that may occur due to damage or breakage of the earthquake-resistant member in the conventional earthquake-resistant structure are prevented in advance. This has the effect of strengthening the safety of use of earthquake-resistant structures.

The earthquake-resistant structure 100 of the photovoltaic power generation facility according to an embodiment of the present invention having the above configuration absorbs and eliminates vibration or shock as follows.

First, as shown in Fig. 4a, when vibration or impact is formed in the photovoltaic power generation facility in which the earthquake-resistant structure 100 of the photovoltaic power generation facility of the present invention is installed due to an earthquake or typhoon, etc., a support pillar for supporting the photovoltaic power generation facility Vibration or shock is transmitted to the elastic member 20 through (1) so that it is easily absorbed and resolved, so that it is possible to safely prevent damage or damage to the photovoltaic power generation facility due to an earthquake or typhoon.

At this time, as shown in FIG. 4B , when a high tensile force is generated by the elastic member 20 that absorbs and relieves shock, and the elastic member 20 is stretched upward above a threshold value, the safety stopper of the safety means 40 naturally Further deformation (sagging) is prevented while closely supported by (43) to prevent damage or breakage of the elastic member 20 due to high tensile force, so that sunlight through the seismic structure 100 of the photovoltaic power generation facility of the present invention Ensure the stable use of power generation facilities.

Although the present invention has been described with reference to the embodiments shown in the accompanying drawings, which are illustrative and not limited to the above-described embodiments, those of ordinary skill in the art will realize that various modifications and equivalent embodiments are possible therefrom. point can be understood. In addition, it goes without saying that modifications by those skilled in the art are possible within the scope that does not impair the spirit of the present invention. Accordingly, the scope of claiming the right in the present invention is not defined within the scope of the detailed description, but will be limited by the following claims and the technical spirit thereof.

1. Support post 2. Anchor bolt
10. Base 20. Elastic member
21. Lower panel 22. Elastic panel
23. Upper panel 30. Binding means
31. Fastener 32. Mood Bolt
33. Binding hole 34. Binding bolt
35. Binding nut 40. Safety means
41. Through hole 42. Safety hole
43. Safety Stopper 43a. safety valve
43b. Safety pillar 44. Rubber plate
100. Seismic structures of solar power generation facilities

Claims (2)

In the earthquake-resistant structure of the photovoltaic power generation facility installed on the support pillar (1) supporting the cradle on which the photovoltaic module is installed in the photovoltaic power generation facility,
A flat plate-shaped base 10 fixed to the ground through an anchor bolt (2);
an elastic member (20) stacked on top of the base (10) and connected to the support column (1) to absorb and eliminate shock or vibration transmitted through the support column (1);
Binding means 30 for coupling the elastic member 20 and the base 10 to each other and coupling the elastic member 20 and the support column 1 to each other; and
Safety means (40) for inducing a stable connection between the elastic member (20) and the support column (1) by preventing damage or breakage of the elastic member (20) due to the tensile force generated on the elastic member (20); Consists of including,
The elastic member 20 has a flat plate shape, has a metal lower panel 21 laminated on the upper portion of the base 10 , and has a predetermined elastic force, and is laminated on the lower panel 21 , A flat plate-shaped elastic panel 22 that absorbs and eliminates shock or vibration transmitted through the support column 1, and a flat plate-shaped upper panel of metal laminated on the elastic panel 22 ( 23), including
The elastic panel 22 is formed of a rubber plate body or a spring, and when the rubber plate body is formed, a fabric is embedded therein to strengthen the durability of the plate body,
The binding means 30 is formed through the lower panel 21, one or more fastening holes 31 in which a screw thread 31a is formed on the inner circumferential surface, and the fastening hole 31 passing through the base 10 ), a mood bolt 32 for binding and fixing the lower panel 21 to the base 10 depending on the base 10, and a plurality of The binding hole 33 and the lower part are welded and fixed to the upper part of the upper panel 23, and the upper part is positioned to pass through the binding hole 33, and the binding bolt 34 is formed with a thread 34a on the outer circumferential surface. and a binding nut 35 fastened to the binding bolt 34 to bind and fix the support column 1 to the upper panel 23,
The safety means 40 is formed to communicate with a through hole 41 penetrating through the center of the elastic member 20 and the through hole 41 in the center of the base 10, and the inner peripheral surface has a screw thread ( A safety hole 42 in which 42a) is formed, a plate-shaped safety plate 43a positioned between the support pillar 1 and the elastic member 20 to support the upper portion of the elastic member 20, and the safety plate A safety stopper (43a) extending downward from the center of the lower portion and passing through the through hole (41), but having a screw thread (43b') formed on the outer circumferential surface and comprising a safety pillar (43b) fastened to the safety hole (42) ( 43) and the earthquake-resistant structure of the solar power generation facility, characterized in that it comprises a rubber plate (44) formed on the upper and lower surfaces of the safety plate (43a) of the safety stopper (43). delete

Images