KR102267672B1 - Photovoltaic system - Google Patents

Abstract

The present invention relates to a photovoltaic device incorporating a structure for reinforcing a foundation rebar, a foundation pad and a vibration-proof function. The photovoltaic device incorporating a structure for reinforcing a foundation rebar, a foundation pad and a vibration-proof function forms a foundation rebar part (A) of a rebar concrete structure, constructs a vibration-proof unit (130) on the foundation rebar part (A), and forms a post (110) on the foundation rebar part (A). Therefore, the present invention can stably protect the photovoltaic device.

Description

A photovoltaic power generation device that combines a structure for reinforcing foundation reinforcement and a foundation pad with a vibration-proof function {Photovoltaic system}

The present invention relates to a photovoltaic power generation device combining a structure for reinforcing foundation reinforcement and a foundation pad and a vibration-proof function, and more particularly, it is provided with a vibration-proof unit to be installed between the post and the foundation pad to minimize the transmission of vibration. Through the vibration-proof unit, it provides a vibration-proof function in response to external force generated in the vertical or horizontal direction, and reduces vibration through the vibration-proof unit, and at the same time, since the posts are elastically and firmly coupled to each other on the installation surface or the base pad, mutual It relates to a photovoltaic power generation device incorporating a foundation reinforcing structure and a foundation pad and a vibration-proof function so that the installation is maintained stably without being separated.

In general, solar power generation is a power generation method that directly converts solar light energy into electrical energy.

Recently, due to the depletion or cost increase of petroleum energy and various energies, the importance of alternative energy has been greatly increased, and as an example, a solar power generation device using sunlight is required.

Such a photovoltaic device is usually a solar cell concentrating panel in which solar panels are connected in series/parallel in order to receive the required power, and the number of parallel lines of the photovoltaic module is a connection that is a device that collects them into one and delivers a direct current. It is composed of an inverter for converting to half and direct/AC.

Currently, photovoltaic power generation devices are being constructed in various ways. One is to install a foundation on the land and install structures and photovoltaic modules on the upper part, and the other is to install using the roof and walls of the building. separated in a way

However, in order to construct a photovoltaic device, the watertight performance of the roofing material, the installation and maintenance of the solar power device panel, and the simplicity of the array configuration must be satisfied at the same time, and the aesthetic and functional characteristics of the existing roofing material installation part must be greatly improved. Without change, the connection state of the connecting wire installed at both ends of the solar cell and the part connected to the base hardware should be stable.

A number of examples of how to construct such a solar power generation device are as follows.

As an example, there is a method of installing a structure by erecting an anchor after drilling a hole in the slab, which is accompanied by a problem that the waterproofing layer is destroyed in the process (when on the roof of a building). Currently, most construction uses the primary method of installing the pad after drilling and applying the same roof waterproofing agent as the waterproofing layer on the upper surface of the pad. There are many cases where rainwater is collected through the bolts and leaks occur in the slab.

As another example, before pouring concrete for slab construction, after fixing the foundation anchor (for example, L anchor or vertical anchor) of the photovoltaic device with a wire to the reinforcing bar for the slab structure, the concrete is poured, In this case, there is a problem that the position of the foundation anchor changes as the foundation anchor is pushed by the concrete being poured (as another way to fix the foundation anchor, the foundation anchor can be fixed by welding, but welding is generally recommended in the field) This is because there is a concern that rebar for slab structure may be cut during welding or damage to rebar tension)

If the position of the foundation anchor is changed by pouring concrete in this way, the foundation work must be done again. In this case, it is inefficient in terms of workability, such as drilling a hole in the poured concrete with a drill and injecting a chemical solution after inserting the vertical anchor. to be.

In addition, if the waterproof layer is damaged due to this, it is a big problem, and it may lead to a situation in which the root cause cannot be found because the damaged part cannot be found later.

Such a photovoltaic device can be easily damaged by affecting the solar cell module of the photovoltaic device, which is an area to be excited, as vibration is transmitted to the area with the concrete structure, which is the installation surface, when an earthquake occurs. Nevertheless, no seismic or seismic isolation design for earthquakes or vibrations has been applied to solar power generation systems until now 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 is not only building an advanced earthquake response system through the scientific development of earthquake response measurement equipment, etc. Following the announcement of mandatory seismic design for buildings with more than one storey (2005), the earthquake-resistant design standards for firefighting facilities (draft) were prepared (2013), and the policy of strengthening seismic design for 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.

For this purpose, coil-type seismic springs are applied to most seismic design patent technologies including 'Seismic device of solar power generation facility' of Korean Patent Laid-Open Publication No. 10-2012-0004314. These coil-type seismic springs always support facilities with heavy loads regardless of the occurrence of earthquakes.

Even a high-strength coil-type seismic spring is not an object with variable load, but if it is subjected to a heavy load for a long time in a stationary state, such as a large-scale photovoltaic device, eventually the high-strength coil-type seismic spring will contract and cause an earthquake. There is a problem in that it cannot exert its elasticity when it is done. In addition, it is necessary to develop a structure that dampens vibration in the vertical and horizontal directions at the same time.

Korean Patent Registration No. 10-1011792 Korean Patent Registration No. 10-1022696 Korean Patent Registration No. 10-1116438 Korean Patent Registration No. 10-1875795 Korean Patent Registration No. 10-1902126

The present invention has been devised to solve the above problems, and its object is to provide a vibration-proof unit to be installed between the post and the base pad to minimize the transmission of vibrations, and to vertically or horizontally through the vibration-proof unit. It provides a vibration-proof function in response to the generated external force, reduces vibration through the vibration-proof unit, and at the same time, because the posts are elastically and firmly coupled to each other on the installation surface or base pad, they do not separate from each other and stably installed. There is this.

Another object of the present invention is to absorb the vertical and horizontal vibrations in the vibration-proof unit while maintaining the mechanical connection structure through the post coupling structure via the vibration-proof unit to stably protect the photovoltaic device. .

Another object of the present invention is to not only look beautiful by adopting a method of fastening the bolt member from the top to the bottom of the post flange, but also to loosen the bolt member to separate the dustproof unit and replace it individually. is doing

Another object of the present invention is a new form of constructing a foundation reinforcing bar together at the time of construction, fixing a reinforcing structure and an exclusive frame to the foundation rebar constructed in this way, and then constructing a foundation pad using the reinforcing structure and an exclusive frame By applying the foundation construction method of In order to correct the position of the foundation, the case of damaging the waterproofing layer (temporary roof slab) can be completely excluded, so the fundamental problem of waterproofing can be fundamentally solved. As a result, it is possible to increase the efficiency of the foundation construction as well as to ensure the quality of the foundation construction.

According to one aspect of the present invention for achieving the above object, the foundation reinforcement part (A) of the reinforced concrete structure that is the basis of the solar power generation device is formed in a building or stratum (ground) slab, and the foundation reinforcement part ( A) on top of the construction of the anti-vibration unit 130, and through the anti-vibration unit 130, the post 110 is erected on the base reinforcing bar (A), a structure for reinforcing the foundation reinforcement and the foundation pad and the anti-vibration function are grafted As a photovoltaic device, the base reinforcing bar (A) is, after fixing at least one or more base reinforcing bars 11 to the slab reinforcing bars 10 that are reinforced for the construction of the slab, the foundation The slab concrete is poured and cured in a state where the upper end of the reinforcing bar 11 is exposed, and the slab 12 is constructed, and the base reinforcing bar 11 exposed at the bottom of the slab 12 is placed in the center and around it. Four anchor bolts 18 taking a vertical posture while forming a rectangular arrangement structure, and a binding reinforcing bar 19 that is welded while wrapping around the four anchor bolts 18 to tie each anchor bolt 18 together After disposing the reinforcing structure 13 made of a combination type, the reinforcing structure 13 is moved back and forth and left and right to match the basic construction specifications of the photovoltaic device after disposing the reinforcing structure 13 in place, A plurality of sub-reinforcing bars 14 are connected between the reinforcing structure 13 and the basic reinforcing bar 11 to fix the reinforcing structure 13, and the reinforcing structure 13 is placed in the center of the rectangular box-shaped After arranging the dedicated frame 15, the foundation pad 16 is constructed and formed by pouring and curing pad concrete in a state where the upper end of the reinforcing structure 13 is exposed; The anti-vibration unit 130 includes a first nut 131 screwed to the anchor bolt 18 , a second nut 132 spaced apart from the first nut 131 , and the first nut 131 . and a side spring member 133 integrally welded to both ends of the second nut 132 and the second nut 132 and the spiral through the bolt through hole 121 of the post flange 120 in the vertical direction. It includes a bolt member 134 for coupling, but the vibration-proof unit 130 is installed between the post 110 and the base pad 16 to minimize the transmission of vibrations, and through the vibration-proof unit 130 Provides a vibration-proof function in response to external force generated in the vertical or horizontal direction, reduces vibration through the vibration-proof unit 130, and at the same time, the post 110 on the installation surface or the base pad 16 is elastically and firmly coupled to each other. There can be provided a photovoltaic device incorporating a structure for reinforcing foundation reinforcement and a foundation pad and a vibration-proof function, characterized in that the installation is maintained stably without being separated from each other.

In this case, the anti-vibration unit 130 may further include a center spring member 140 which is manufactured to have a diameter of the post 110 and is installed in the lower center of the post flange 120 .

In addition, a ring-shaped center guide 122 axially coupled to the inner diameter of the center spring member 140 is formed on the bottom surface of the post flange 120 , and the upper portion of the center spring member 140 is placed on the center guide 122 . It is characterized in that the shaft is coupled.

In addition, the ends of the bolt member 134 and the anchor bolt 18 are characterized in that a sufficient separation distance is maintained so that the ends do not come into contact with each other even when the side spring member 133 is compressed and deformed.

The present invention as described above has an effect.

According to the photovoltaic device of the present invention, it is possible to minimize the transmission of vibration by providing a vibration-proof unit and to be installed between the post and the base pad, and has a vibration-proof function in response to external force generated in the vertical or horizontal direction through the vibration-proof unit and at the same time reduce vibration through the vibration-proof unit and at the same time, since the posts are elastically and firmly coupled to each other on the installation surface or the base pad, there is an effect that the installation is maintained stably without being separated from each other.

In addition, the post coupling structure through the dustproof unit according to the present invention has the effect of absorbing vertical and horizontal vibrations in the vibrationproof unit while maintaining the mechanical connection structure, thereby stably protecting the solar power generation device. .

In addition, since the present invention uses a method of fastening the bolt member from the upper side to the lower side of the post flange, it is not only beautiful in appearance, but also the effect of easy maintenance work such as removing the bolt member to separate the dustproof unit and replacing it individually has

In addition, the present invention is a new type of foundation in which the foundation rebar is constructed together during construction, the reinforcement structure and the exclusive frame are fixed to the foundation reinforcing bar constructed in this way, and then the foundation pad is constructed using the reinforcing structure and the exclusive frame By applying the construction method, the position of the foundation can be accurately set because the position of the reinforcing structure and the exclusive frame can be arbitrarily adjusted even if the position of the foundation reinforcing bar is changed when the concrete is poured for slab construction, and the position of the foundation can be accurately set as before. It is possible to completely eliminate the case of damaging the waterproofing layer (temporary roof slab) in order to correct the location, thereby solving the fundamental problem of waterproofing. As a result, it is possible to increase the efficiency of the foundation construction as well as to secure the quality of the foundation construction.

In addition, the present invention has an excellent effect in terms of workability as well as cost reduction, such as using a prefabricated exclusive frame made of a metal material when pouring concrete for the construction of the foundation pad, so that it can be used repeatedly in other sites ( In the current construction, plywood and one-time wood are used for the frame to pour the foundation pad, so it cannot be used consecutively at other sites. During installation, the wood is fixed with nails or staple guns, and even when dismantling, the wood must be forcibly disassembled. bad name).

In addition, the present invention implements a foundation pad comprising a reinforcing structure consisting of four anchor bolts constituting a rectangular arrangement structure and a binding reinforcing bar that wraps around each anchor bolt of each anchor bolt and binds them together. It has the effect of improving the efficiency of lot management such as production, transportation, storage, and handling, as well as securing the structural rigidity of the equipment, and facilitating installation and construction work.

1 is an exemplary view schematically illustrating a construction structure of a photovoltaic device to which a vibration-proof unit according to a first embodiment of the present invention is applied.
2 is an exploded view showing the structure of one embodiment of the anti-vibration unit according to the present invention.
Figure 3 is an assembly view showing the structure of one embodiment of the vibration-proof unit according to the present invention.
Figure 4 is an exemplary view schematically showing the construction structure of the photovoltaic device to which the vibration-proof unit according to the second embodiment of the present invention is applied.
Figure 5 is an exploded view showing the structure of the second embodiment of the vibration-proof unit according to the present invention.
Figure 6 is an assembly view showing the structure of the second embodiment of the vibration-proof unit according to the present invention.
7 to 11 are perspective views showing a method for constructing a foundation for a photovoltaic device according to an embodiment of the present invention.
12 and 13 are perspective views illustrating an example of a reinforcing structure and a dedicated frame used in a method for constructing a foundation for a photovoltaic device according to an embodiment of the present invention.
14 and 15 are a perspective view and a plan view showing another example of a reinforcing structure and a dedicated frame used in a method for constructing a foundation for a photovoltaic device according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exemplary view schematically illustrating a construction structure of a photovoltaic device to which a dustproof unit is applied according to a first embodiment of the present invention, and FIG. 4 is a photovoltaic device to which a dustproof unit according to a second embodiment of the present invention is applied. It is an exemplary diagram schematically showing the construction structure of the power generation device.

1 and 4, according to the photovoltaic device 100 of the present invention, the vibration is prevented by providing a vibration-proof unit 130 to be installed between the post 110 and the base reinforcing bar (A). It is possible to minimize the transmission, and provides a vibration-proof function in response to external force generated in the vertical or horizontal direction through the vibration-proof unit 130 , and reduces vibration through the vibration-proof unit 130 and at the same time, the installation surface or the base reinforcing bar Since the posts 110 on (A) are elastically and firmly coupled to each other, they are not separated from each other and are stably installed.

In the photovoltaic device 100 according to the present invention, a base reinforcing bar portion (A) is constructed at each location on the bottom surface of the slab 12, and the post of the photovoltaic device 100 is installed in the base reinforcing bar portion (A). (110) is a structure to be supported, the base reinforcing bar portion (A) is installed so that four anchor bolts 18 are exposed upwards at a point forming a square, and the post ( 110) A post flange 120 for fastening with the anchor bolt 18 is formed at the lower end.

The post flange 120 is a circular or square metal plate body, and a bolt through hole 121 is formed at a position corresponding to the anchor bolt 18 .

At this time, the anchor bolt 18 is not directly coupled to the bolt through hole 121 of the post flange 120 , but is coupled through the anti-vibration unit 130 in the middle.

Hereinafter, the structure of the anti-vibration unit 130 according to the first embodiment of the present invention will be described with reference to the accompanying drawings.

Figure 2 is an exploded view showing the structure of one embodiment of the anti-vibration unit according to the present invention, Figure 3 is an assembly view showing the structure of one embodiment of the anti-vibration unit according to the present invention.

As shown in the drawing, the anti-vibration unit 130 according to the first embodiment includes a first nut 131 screw-coupled to the anchor bolt 18, and a second nut 132 spaced apart from the first nut 131. ), the side spring member 133 for integrally welding the first nut 131 and the second nut 132 to both ends, and the bolt through hole 121 of the post flange 120 in the vertical direction. The second nut 132 is composed of a bolt member 134 that is spirally coupled.

The anti-vibration unit 130 having the above configuration is fixed by screwing the first nut 131 to the four anchor bolts 18 . At this time, the side spring member 133 and the second nut 132 are integrally coupled to the upper portion of the first nut 131 .

As described above, in a state in which the vibration-proof unit 130 is coupled to the four anchor bolts 18, respectively, the post and the post flange 120 are positioned on the upper part, and the bolt through hole 121 of the post flange 120 is inserted. As the bolt member 134 penetrates in the vertical direction and is spirally coupled to the second nut 132, the post construction of the photovoltaic device is completed.

At this time, in the coupled state, the ends of the bolt member 134 and the anchor bolt 18 are maintained at a sufficient separation distance so that the ends do not contact each other even when the side spring member 133 is compressed and deformed.

The coupling structure by the anti-vibration unit 130 as described above absorbs the vertical and horizontal vibrations from the side spring member 133 while maintaining the mechanical connection structure to stably protect the solar power generation device 100 . there will be

In addition, when the anchor bolt 18 protrudes above the post flange 120 as in the prior art, it is not aesthetically pleasing and the nut fastening portion is easily corroded, but in the present invention, the bolt member 134 is attached to the post flange ( Since the method of fastening from the upper part to the lower part of 120 is used, not only the appearance is beautiful, but also the maintenance work such as loosening the bolt member 134 and replacing the dustproof unit 130 individually becomes easy.

Hereinafter, the structure of the anti-vibration unit 130 according to the second embodiment of the present invention will be described with reference to the accompanying drawings.

Figure 5 is an exploded view showing the structure of two embodiments of the vibration-proof unit according to the present invention, Figure 6 is an assembly view showing the structure of the second embodiment of the vibration-proof unit according to the present invention.

As shown in the drawing, the anti-vibration unit 130 according to the second embodiment includes a first nut 131 screwed to the anchor bolt 18, and a second nut 132 spaced apart from the first nut 131. ), the side spring member 133 for integrally welding the first nut 131 and the second nut 132 to both ends, and the bolt through hole 121 of the post flange 120 in the vertical direction. The second nut 132 and the bolt member 134 spirally coupled, and a center spring member 140 made of about the diameter of the post 110 is installed in the lower center of the post flange (120).

The anti-vibration unit 130 having the above configuration is fixed by screwing the first nut 131 to the four anchor bolts 18 . At this time, the side spring member 133 and the second nut 132 are integrally coupled to the upper portion of the first nut 131 .

As described above, the center spring member 140 is positioned at the center of the four anchor bolts 18 in a state in which the anti-vibration unit 130 is coupled to each other.

The center spring member 140 is a large diameter spring member and may be manufactured to have a diameter similar to that of the post 110 .

In this case, the center spring member 140 may be coupled to the bottom surface of the post flange 120 or supported so that the position is fixed.

For example, a ring-shaped center guide 122 axially coupled to the inner diameter of the center spring member 140 is formed on the bottom surface of the post flange 120 , and an upper portion of the center spring member 140 is placed on the center guide 122 . It can be shaft-coupled to keep the position stable.

The post and post flange 120 are positioned on the upper portion where the vibration-proof unit 130 and the center spring member 140 are installed, and the bolt member 134 is perpendicular to the bolt through hole 121 of the post flange 120 . By penetrating in the direction and spirally coupled with the second nut 132, the post construction of the photovoltaic device is completed.

At this time, in the coupled state, the ends of the bolt member 134 and the anchor bolt 18 are maintained at a sufficient separation distance so that the ends do not contact each other even when the side spring member 133 is compressed and deformed.

The coupling structure by the anti-vibration unit 130 as described above absorbs the vertical and horizontal vibrations from the side spring member 133 while maintaining the mechanical connection structure to stably protect the solar power generation device 100 . there will be

In addition, when the anchor bolt 18 protrudes above the post flange 120 as in the prior art, it is not aesthetically pleasing and the nut fastening portion is easily corroded, but in the present invention, the bolt member 134 is attached to the post flange ( Since the method of fastening from the upper part to the lower part of 120 is used, not only the appearance is beautiful, but also the maintenance work such as loosening the bolt member 134 and replacing the dustproof unit 130 individually becomes easy.

In addition, according to the present invention, the upper and lower ends of the side spring member 133 of the anti-vibration unit installed between the post 110 and the base pad 16 are the first nut 131 on the side of the post 110 and the base pad 16, respectively. ) and the second nut 132 are coupled, a compressive load may act on each side spring member 133 depending on the load direction of the post 110 , or a tensile load may act on the contrary, depending on the load direction of the post 110 .

For example, when a load inclined to the right of the post 110 is applied, a compressive load is applied to the side spring member 133 disposed on the right side, and a tensile load is applied to the side spring member 133 disposed on the left side. By doing so, it is possible to provide a more stable support structure by balancing the forces between them.

The present invention, which provides a vibration-proof unit structure according to the first and second embodiments as described above, is when the basic concrete structure of the photovoltaic device installed in the building or the ground floor (ground) is constructed, when the slab is constructed. The foundation reinforcing bar that serves as the support of the foundation pad is installed together while holding the temporary position, and the reinforcing structure is installed based on the pre-constructed foundation rebar as a support base, and the foundation is used using an exclusive frame. By providing the base reinforcing bar (A) for constructing the pad, it is possible to support the accurate construction and solid support of the vibration-proof unit.

That is, through the construction of the foundation reinforcing bar (A) described below, it is possible to accurately set the position of the foundation of the photovoltaic device and fundamentally solve the problem of waterproofing, thus improving the efficiency of the basic construction of the solar power device. Not only can it be improved, but also the quality of the foundation construction for the solar power generation device can be secured.

Hereinafter, the construction of the foundation reinforcement portion (A) according to the present invention will be described.

First, as shown in FIGS. 7 and 8, reinforcing bars are placed in order to construct a foundation on the roof slab or the ground of a building, and the foundation reinforcing bars 11 are installed before pouring concrete, and then the concrete is poured into the slab. (12) is constructed.

This is to carry out the process of installing the foundation reinforcement 11, which becomes the support base of the photovoltaic device foundation, in the middle of the process while adopting the process of constructing the slab 12 as a basis.

That is, at least one or more basic reinforcing bars 11 can be bundled and fixed with fixing means such as wires 17 to the slab reinforcing bars 10, which are reinforced for the construction of the slab, at this time the base reinforcing bars ( 11), a pair of "U"-shaped reinforcing bars can be used.

In this way, a pair of basic reinforcing bars 11 made of "U"-shaped reinforcing bars are fixedly installed in several places of the slab reinforcing bars 10 .

For example, both upper ends of the foundation reinforcing bars 11 are placed in an inclined manner while facing upwards, and at the same time, the upper ends of each other are made to overlap each other one by one, and at this time, the overlapping parts are tied together with a wire 17 to make one The pair of foundation reinforcing bars 11 are integrally bound.

Subsequently, by binding and fixing the lower end of each foundation reinforcing bar 11 with a wire 17 to the slab reinforcing bar 10 , a pair of base reinforcing bars 11 can be fixedly installed on the slab reinforcing bar 10 side.

Here, the pair of base reinforcing bars 11 may be provided in several pairs and installed in several places at predetermined intervals, one pair for each position corresponding to each base seat of the photovoltaic device.

Then, after the slab concrete is poured by a known pouring method in a state where the foundation reinforcement 11 is installed on the side of the slab reinforcement 10, the slab 12 is constructed by curing for a certain period of time.

At this time, when pouring the slab concrete, the upper end of the foundation reinforcement 11, for example, the upper end including the part tied with the wire 17, is poured to a level that can be exposed above the slab floor after the slab construction.

Accordingly, after the construction of the slab 12, the upper end of the foundation reinforcement 11 can be exposed above the floor of the slab 12.

In this way, by using a "U"-shaped reinforcing bar as the basic reinforcing bar 11 serving as a support base for the foundation of the photovoltaic device, and applying a form in which two "U" shaped reinforcing bars are bound together in an inclined posture, It is possible to provide a solid support base on the foundation side of the photovoltaic device, and it is possible to minimize the position change such as pushing even when the slab concrete is poured.

Next, as shown in FIG. 9, the reinforcement structure 13 for the construction of the base pad 16, which is the substantial basis of the solar power generation device, is installed.

To this end, the reinforcement structure 13 is arranged around the base reinforcement 11 exposed from the bottom surface of the slab 12 in the center.

That is, the reinforcement structure 13 is placed on the bottom surface of the slab 12 around the seat where the base reinforcement 11 is located.

At this time, in the case of the foundation reinforcing bar 11, since the position can be changed while being pushed by the pouring pressure when the slab concrete is poured, the reinforcing structure 13 is moved little by little in the front and back and left and right directions according to the photovoltaic power generation device design specification sheet. By adjusting it according to the set base construction position, the reinforcing structure 13 is placed in the correct position.

For example, one by one the reinforcing structures 13 are assigned to the foundation reinforcing bars 11 at each location exposed to the slab 12, and then, the horizontal and vertical intervals between each reinforcing structure 13 are measured with a tape measure, etc. Check, and adjust the position of the reinforcement structure 13 according to the result, and position the reinforcement structure 13 in a position that meets the basic construction specifications of the photovoltaic device.

Subsequently, in a state in which the reinforcement structure 13 is positioned in place, a plurality of sub-reinforcing bars 14 are connected between the reinforcement structure 13 and the base reinforcement 11 to prevent the reinforcement structure 13 from moving. fixed installation

Here, the sub-reinforcing bar 14 can be connected by welding between the binding reinforcing bar 19 and the sub-reinforcing bar 14 of the reinforcing structure 13, and this sub-reinforcing bar 14 is exposed to the slab 12. It is preferable to connect from the side of the two base reinforcing bars 11 to the four places of the binding reinforcing bar 19 side.

At this time, in the case of the basic reinforcing bar 11, it can be connected by the binding rebar 19 side and the sub reinforcing bar 14 as it is tied by the wire 17, and the wire 17 is loosened and then spread to both sides It may be connected by the binding reinforcing bar 19 side and the sub reinforcing bar 14 in.

When the reinforcing structure 13 is connected to the base reinforcing bar 11 side using the sub reinforcing bar 14 in a state where the position of the reinforcing structure 13 is adjusted and positioned in this way, the reinforcing structure 13 is It may be fixedly installed in a fixed position on the basis of the base reinforcing bar 11 as a support base.

Meanwhile, the reinforcing structure 13 is embedded in the concrete structure constituting the foundation pad 16 , and serves as a structure for securing the structural rigidity of the foundation pad 16 .

As an example, the reinforcing structure 13 may be formed of an integral combination type of four anchor bolts 18 and a binding reinforcing bar 19 as shown in FIGS. 12 and 13 .

For example, the four anchor bolts 18 take a vertical posture in parallel with each other while forming a rectangular arrangement structure (one at each corner of the rectangle), and the binding reinforcing bars 19 are square It is welded to the anchor bolt side while surrounding the outer periphery of the anchor bolt 18 constituting the arrangement structure to tie the four anchor bolts 18 together.

At this time, the binding reinforcing bar 19 may be made of one reinforcing bar having a length that can be continuously wrapped around the outer periphery of the anchor bolt 18 constituting a square arrangement structure, or an anchor having a square arrangement structure. It may be made of four reinforcing bars having a length that can wrap four sides of the outer periphery of the bolt 18 one by one.

In the present invention, an example of applying the binding reinforcing bar 19 made of four reinforcing bars is shown.

Here, at least one row of binding reinforcing bars 19 surrounding the outer periphery of the anchor bolt 18 constituting a rectangular arrangement structure can be applied, and in the present invention, two rows of up and down maintaining a certain interval are formed. An example of applying the binding reinforcing bar 19 is shown.

In this way, by applying the reinforcing structure 13 that can be manufactured in a factory, etc., that is, the reinforcing structure 13 consisting of an integral combination type of four anchor bolts 18 and a binding reinforcing bar 19, Compared to a rebar structure manufactured by tying or assembling reinforcing bars directly in the company, it has advantages in on-site installation workability and ease of handling, as well as advantages in terms of quality assurance and constructability because standardization is possible.

As another example, the reinforcing structure 13, as shown in FIGS. 14 and 15, may be formed of an integral combination type of four anchor bolts 18 and a binding reinforcing bar 19.

For example, the four anchor bolts 18 take a vertical posture in parallel with each other while forming a rectangular arrangement structure (one at each corner of the rectangle), and the binding reinforcing bars 19 are square It is welded to the anchor bolt side while surrounding the outer periphery of the anchor bolt 18 constituting the arrangement structure to tie the four anchor bolts 18 together.

At this time, the binding reinforcing bar 19 may be made of one reinforcing bar having a length that can be continuously wrapped around the outer periphery of the anchor bolt 18 constituting a square arrangement structure, or an anchor having a square arrangement structure. It may be made of four reinforcing bars having a length that can wrap four sides of the outer periphery of the bolt 18 one by one.

In the present invention, an example of applying the binding reinforcing bar 19 made of four reinforcing bars is shown.

Here, at least one row of binding reinforcing bars 19 surrounding the outer periphery of the anchor bolt 18 constituting the rectangular arrangement structure can be applied, and in the present invention, two rows of up and down maintaining a certain interval are formed. An example of applying the binding reinforcing bar 19 is shown.

In this way, by applying the reinforcing structure 13 that can be manufactured in a factory, etc., that is, the reinforcing structure 13 consisting of an integral combination type of four anchor bolts 18 and a binding reinforcing bar 19, as in the past, the field Compared to a rebar structure manufactured by tying or assembling reinforcing bars directly in the company, it has advantages in on-site installation workability and ease of handling, as well as advantages in terms of quality assurance and constructability because standardization is possible.

In particular, in the case of the reinforcing structure 13 provided in another example above, when the exclusive frame 15 is disposed in the third step, the position of the dedicated frame 15 can be set more accurately and more easily. include structure.

To this end, at the end of the binding reinforcing bar 19 that is welded to the circumference of the anchor bolt 18 to form a rectangular trajectory, a spacing maintaining portion 20 extending outwardly (outside of the rectangular trajectory) for a certain length is integrally formed. do.

At this time, the spacing maintaining unit 20 may be formed on each binding reinforcing bar 19 disposed on at least two surfaces of each of the binding reinforcing bars 19 disposed on four sides, and on the four sides as in the embodiment of the present invention. It is preferable to form all of the binding reinforcing bars 19 to be arranged.

Here, the interval maintaining unit 20 may have a length corresponding to the interval between the binding reinforcing bar 19 and the exclusive frame 15, or may have a length slightly shorter than the interval.

Accordingly, when disposing the exclusive frame 15 on the periphery of the reinforcing structure 13, the end of the spacing maintaining portion 20 extending on four sides and the inner surface of the exclusive frame 15 are brought into contact with each other, By disposing the exclusive frame 15 while being close to it, the position of the exclusive frame 15 can be accurately set based on the reinforcement structure 13 positioned in the correct position, and eventually the base pad in the correct position and in an accurate form (16) can be constructed.

In addition, since it is possible to hold the dedicated frame 15 through the spacing maintaining part 20 of the binding reinforcing bar 19, the dedicated frame 15 is front and rear and left and right when pouring pad concrete in the reinforcement frame 13. flow can be effectively prevented.

That is, since the gap maintaining part 20 in the binding reinforcing bar 19 of the reinforcing structure 13 can hold the exclusive frame 15 while being in close contact with the inner surface of the exclusive frame 15, the exclusive frame 15 ) can be maintained, and thus the construction quality of the foundation pad 16 can be secured.

Next, as shown in FIGS. 10 and 11 , the foundation pad 16 is constructed by pouring pad concrete.

To this end, a rectangular box-shaped exclusive frame 15 is arranged around the reinforcing structure 13 fixed in place by the foundation reinforcing bar 11 .

That is, with the reinforcement structure 13 in the center, a rectangular box-shaped exclusive frame 15 is arranged around it.

At this time, the height of the exclusive frame 13 is a height corresponding to the lower portion of the anchor bolt 18 to which the binding reinforcing bar 14 belongs, for example, about 1/2 to 2/3 of the length of the anchor bolt 18 . may have a height corresponding to the length of

Subsequently, pad concrete is poured into the inside of the dedicated frame 15 in which the reinforcement structure 13 is accommodated.

At this time, the pad concrete poured into the dedicated frame 15 can be filled to a level corresponding to the height of the dedicated frame 15, and accordingly, the upper end of the reinforcement structure 13 above the pad concrete pouring surface, that is, The upper end of the anchor bolt 18 can protrude a certain length.

Subsequently, if the dedicated mold 15 is removed after the pad concrete poured into the dedicated mold 15 is cured for a certain period of time, the foundation pad 16 is constructed on the slab 12, and the foundation pad ( 16) As the four anchor bolts 18 are exposed on the upper surface, a photovoltaic device can be installed based on the exposed anchor bolts 18 and the foundation pad 16 at this time.

In particular, the exclusive frame 15 used in the third step is a rectangular frame made of a metal material used exclusively when constructing the foundation pad 16 , and may have a structure in which two bent plate bodies are combined.

To this end, the exclusive frame 15 includes a first exclusive frame 21 in the shape of an “a” and a second exclusive frame 23 in the “a” shape in which flanges 22 are formed at both ends. It can be done in combination.

And, by bonding the first exclusive frame 21 and the second exclusive frame 23 to each other in a rectangular frame shape, the exclusive frame 15 forming a rectangular frame shape can be completed.

That is, after the flanges 22 at both ends of the second exclusive frame 23 are closely attached to the inner surfaces of both ends of the first exclusive frame 21, each flange 22 of the second exclusive frame 23 is And by fastening both ends of the first exclusive frame 21 with bolts and nuts, a single combined type exclusive frame 15 forming a rectangular frame shape can be made.

In the case of such an exclusive frame 15, when the pad concrete is poured, it can be used in a combined state in the form of a square frame through the fastening of bolts and nuts, and after curing the pad concrete, that is, after the construction of the foundation pad 16, the bolts and nuts By releasing it, it can be removed in a state separated into the first exclusive frame 21 and the second exclusive frame 23 .

Accordingly, the first exclusive frame 21 and the second exclusive frame 23 that can be separated and combined during construction of the base pad 16 are formed in a combination form, and the exclusive frame 15 made of a metal material is used. By using it, it can be used repeatedly at various sites, and in the end, it is economically advantageous compared to squeezing and disposing of plywood at the site as before, and tearing off and disposing of the plywood after use. Because it is easy, there is an advantage in terms of workability.

As described above, the present invention is not limited to the specific preferred embodiments described above, and any person skilled in the art to which the invention pertains may make various modifications without departing from the gist of the present invention as claimed in the claims. It goes without saying that such modifications are possible within the scope of the claims.

10: slab reinforcement 11: foundation reinforcement
12: slab 13: reinforcement structure
14: sub reinforcing bar 15: exclusive frame
16: base pad 17: wire
18: anchor bolt 19: binding reinforcing bar
20: gap maintaining unit 21: first exclusive frame
22: flange 23: second exclusive frame
100: solar power generation device 110: post
120: post flange 121: bolt through hole
122: center guide 130: dustproof unit
131: first nut 132: second nut
133: side spring member 134: bolt member
140: center spring member A: basic reinforcing bar

Claims (7)

Form the foundation reinforcement part (A) of the reinforced concrete structure that is the basis of the solar power generation device on the slab of a building or ground floor (ground), and construct the vibration-proof unit 130 on the foundation reinforcement part (A), and the vibration-proof unit As a photovoltaic power generation device grafted with a vibration-proof function and a structure for reinforcing foundation reinforcement that allows the post 110 to be erected on the foundation reinforcement portion (A) via 130, the foundation reinforcement portion (A) is , after fixing at least one foundation reinforcing bar 11 to the slab reinforcing bar 10, which is reinforced for the construction of the slab, the slab concrete is poured in a state such that the upper end of the base reinforcing bar 11 is exposed. The slab 12 is constructed by pouring and curing, and four anchor bolts 18 that take a vertical posture while forming a rectangular arrangement structure around the base reinforcing bar 11 exposed at the bottom of the slab 12 in the center. ) and a reinforcing structure 13 made of an integral combination type of binding reinforcing bars 19 that are welded to wrap around the perimeter of the four anchor bolts 18 and tie each anchor bolt 18 into one, but for reinforcement After disposing the structure 13 for reinforcing in place in accordance with the basic construction specifications of the photovoltaic device while moving the structure 13 back and forth and left and right, a number of between the reinforcing structure 13 and the foundation reinforcing bar 11 After connecting the two sub-reinforcing bars 14 to fix the reinforcing structure 13, place the reinforcing structure 13 in the center and place a rectangular box-shaped exclusive frame 15 around it, the reinforcing structure ( 13) by pouring and curing pad concrete in a state where the upper end is exposed to construct and form the foundation pad 16; The anti-vibration unit 130 includes a first nut 131 screwed to the anchor bolt 18 , a second nut 132 spaced apart from the first nut 131 , and the first nut 131 . and a side spring member 133 integrally welded to both ends of the second nut 132 and the second nut 132 and the spiral through the bolt through hole 121 of the post flange 120 in the vertical direction. It includes a bolt member 134 for coupling, but the vibration-proof unit 130 is installed between the post 110 and the base pad 16 to minimize the transmission of vibrations, and through the vibration-proof unit 130 Provides a vibration-proof function in response to external force generated in the vertical or horizontal direction, reduces vibration through the vibration-proof unit 130, and at the same time, the post 110 on the installation surface or the base pad 16 is elastically and firmly coupled to each other. To ensure that the installation is maintained stably without being separated from each other, the anti-vibration unit 130 is manufactured about the diameter of the post 110 and further includes a center spring member 140 installed in the lower center of the post flange 120, A ring-shaped center guide 122 axially coupled to the inner diameter of the center spring member 140 is formed on the bottom surface of the post flange 120 , and the upper portion of the center spring member 140 is axially attached to the center guide 122 . Base reinforcement reinforcement, characterized in that the ends of the bolt member 134 and the anchor bolt 18 are maintained at a sufficient separation distance so that the ends do not come into contact with each other even when the side spring member 133 is compressed and deformed. A photovoltaic power generation device that combines a structure and a foundation pad with a dustproof function.
delete delete delete The method of claim 1,
The basic reinforcing bar 11 uses a "U"-shaped reinforcing bar, and using these two "U"-shaped reinforcing bars as a pair, the "U"-shaped reinforcing bars are arranged obliquely so that the upper ends thereof are crossed with each other, and then the wire 17 A structure for reinforcing foundation reinforcement, characterized in that it fixes the foundation reinforcing bars 11 in such a way that the portion where the foundation reinforcing bars 11 and the slab reinforcing bars 10 meet and the portion where the foundation reinforcing bars 11 meet while crossing each other using and a photovoltaic power generation device incorporating a base pad and a dustproof function.
The method of claim 1,
At the end of the binding reinforcing bar 19 welded to the periphery of the anchor bolt 18 , a gap maintaining part 20 extending a certain length to the outside is formed, and a dedicated frame 15 is arranged around the reinforcement structure 13 . When doing so, the four-sided spacing between the reinforcing structural frame 13 and the exclusive frame 15 is adjusted while making the inner surface of the exclusive frame 15 in contact with or close to the end of the spacing maintaining part 20 extending on four sides. A photovoltaic power generation device that combines a structure for reinforcing foundation reinforcement and a foundation pad and a vibration-proof function, characterized in that it allows
The method of claim 1,
As a metal bent plate body, the first exclusive frame 21 is assembled to the first exclusive frame 21 using the first exclusive frame 21 in the shape of a “L” and the flanges 22 formed on both ends of the first exclusive frame A structure for reinforcing foundation reinforcement and a foundation pad and a vibration-proof function, characterized in that it uses a dedicated frame 15 that can be used repeatedly several times and is composed of a combination type of the second exclusive frame 23 that forms a square frame structure together with (21). Incorporated solar power generation device.

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