KR102038314B1 - Fixing device of steel pipe pole for solar power generator - Google Patents

Abstract

The present invention relates to a vertical structure fixing device of a steel pipe pole for a photovoltaic power generation facility which forms a pole for installing an array for photovoltaic power generation by coupling an upper main pole to a lower base of a spiral shape, increases lateral tension of an assembled and coupled portion between the lower base of a spiral shape and the upper main pole, maximizes safety, and greatly reduces coupling and assembling time of the lower base and the upper main pole to further shorten overall construction time for constructing the array for photovoltaic power generation. According to the present invention, the vertical structure fixing device of a steel pipe pole for a photovoltaic power generation facility comprises: a lower spiral base having a first wedge insertion hole and a first screw hole; an upper main pole having a second wedge insertion hole and a second screw hole corresponding to the first wedge insertion hole and the first screw hole; a wedge member; and a coupling bolt. The coupling bolt is screwed into the second screw hole and the first screw hole while the first screw hole of the lower spiral base and the second screw hole of the upper main pole are vertically aligned in a line by the wedge member inserted into the second wedge insertion hole of the upper main pole and the first wedge insertion hole of the lower spiral base.

Description

Fixing device of steel pipe pole for solar power generator}

According to the present invention, the pole pole for installing the solar array is formed by the upper main pole coupled to the lower base of the spiral form, the horizontal tension of the assembly fastening portion between the spiral base and the upper main pole is increased, the safety As the assembly time of the lower foundation and the upper main pole is greatly reduced, the upper and lower structures of the photovoltaic steel pipe pillars can be shortened by one step. It is about.

As a key solution to environmental issues such as fossil energy depletion and global warming, developed countries are implementing bold support policies for solar power plants as part of their renewable energy supply policy.

Therefore, since 2002, Korea has been actively supporting the power generation gap support system, and as a result, solar power plants are rapidly expanding in recent years.

In order to construct such a photovoltaic power plant, civil engineering works are required after obtaining permission for development activities.

In other words, the construction of the conventional solar power plant was carried out in the following order.

Logging 2. Uprooting. 3. Transmutation. 4. Axle construction. 5. Compaction (rainy weather). 6. Excavation of foundation. 7. Foundation rubble. 8. Throw away. 9. Formwork installation. 10. Mortar casting. 11. Curing. 12. Formwork demolition. 13. Backfilling. 14. Commitment. 15. Drill holes for anchor bolts. 16. Anchor bolt and base mounting. 17. Building the main support (complete). 18. Installation of structure assembly module (solar cell). 19. DC Electric Works. 20. AC Electric Works. 21. Power system connection work. 22. Completion inspection. 23. Start of commercial development.

However, solar power plants are usually located or started in mountainous regions with low site prices and relatively easy to purchase, which creates environmental and economic difficulties.

In other words, when a solar power plant is located in a mountainous area, problems with topography change, good vegetation damage, soil leakage and contaminated water sources, damage to wild animals and plants, reduction of carbon sinks, landscape problems, and condensation efficiency due to weed predominance Problems such as reduction, the use of herbicides for weed management are caused. And this problem is difficult to avoid completely even when the solar power plant is located on a flat ground. In particular, the bottom of the photovoltaic power plant is almost made up of gravel or soil, and condensing is economically and economically due to environmental damage due to the above-mentioned runoff of soil, rapid rise in temperature, reduction of carbon absorption source, and generation of weeds. It is a cause that causes problems such as a decrease in efficiency.

For this reason, during the construction of photovoltaic power plants, pruning of tree roots and forestry changes in case of heavy rains in case of heavy rains result in drastic earthquake decay and drastically reduce the foundation construction process. As time goes by, power generation companies can increase profits and develop and provide various types of prefabricated poles for installation of screw-type photovoltaic arrays that can reduce the cost of construction and provide safe facilities. It is becoming.

1 is a perspective view illustrating an assembled screw pole of a conventional screw type for installation of a photovoltaic array.

As shown, the assembled screw pole of the conventional screw type and the lower base pole pole 10 of the screw form and the coupling portion 11 of the lower base pole pole 10 is formed with a coupling portion 11 of the expanded diameter at the top A coupling portion 21 having a corresponding extended diameter includes an upper main pole 20 formed at a lower end thereof, and a coupling portion 21 of the lower base pole 10 and a coupling portion 21 of the upper main pole 20. ) Are respectively penetrated in the vertical direction, four or more coupling holes 12 and 22 corresponding to each other are formed along the circumference. The coupling bolt 30 and the coupling nut 40 are coupled to each other through the coupling hole 22 of the upper main pole 20 and the coupling hole 12 of the lower base pole 10 so that the coupling of the upper main pole 20 is performed. The engaging portion 11 of the portion 21 and the lower base pole 10 is engaged. In other words, the coupling part 11 of the lower base pole 10 and the coupling part 21 of the upper main pole 20 are coupled through the coupling bolt 30 and the coupling nut 40 and thus the lower foundation pole 10. And the coupling between the upper main pole pole 20.

Here, the lower base pole 10 in the form of a screw is fixed by being embedded in the ground, the lower main pole pole 10 fixed to the ground so as to mount the upper main pole pole 20 by a crane and then the coupling bolt 30 and the coupling Since it is fixed through the nut 40, it was not easy to accurately fit the coupling hole 22 of the upper main pole 20 to the coupling hole 12 of the lower base pole 10 fixed to the ground. . In other words, it was not easy to accurately match the coupling holes of the unfixed upper main pole of the crane with the coupling holes of the fixed lower base pole. And this results in the delay of the coupling time between the lower base pole 10 and the upper main pole 20, as well as the installation work of the photovoltaic array is delayed.

Korean Laid-Open Patent Publication No. 10-2011-0049213 (published May 12, 2011), “Method for creating floor of solar power plant” Korean Patent No. 10-0948288 (announced March 17, 2010), “Solar tracker and solar tracking system for large-scale photovoltaic power plant including the same”

In an embodiment of the present invention, the pole pole for installing the photovoltaic array is formed by combining the upper main pole with the spiral-shaped lower base, and the lateral tension of the assembly fastening portion between the spiral base and the upper main pole is increased. Up and down the solar power plant steel pipe struts, which maximizes the safety and at the same time significantly reduces the combined assembly time of the lower foundation and the upper main poles. Provide structure fixing devices.

In addition, the embodiment of the present invention to improve the coupling structure between the spiral foundation and the main support in the construction process of the solar power plant, and to shorten the work time accordingly to shorten the overall process of the construction of the solar power plant It provides a vertical structure fixing device for photovoltaic power plant steel pipe support.

The upper and lower structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention, the upper coupling portion 110 is formed on the upper side of the expanded size relative to the horizontal direction, one or a tapered shape in the downward direction or Two or more first wedge insertion holes 111 and a plurality of first screw holes 112 for screwing the bolts penetrate the upper coupling portion 110 in the vertical direction along the circumference of the upper coupling portion 110. A lower spiral base 100 formed to have a spiral shape and fixed to the ground; The lower coupling part 210 having a size corresponding to the upper coupling part 110 of the lower spiral base 100 and extended in the horizontal direction is formed at the bottom, and has a tapered shape in the downward direction, but has a lower hole. The second wedge insertion hole 211 having the same size as the hole size of the upper end of the first wedge insertion hole 111 and the second screw hole 212 for screwing the bolt have a circumference of the lower coupling portion 210. Accordingly, the lower coupling portion 210 is formed to penetrate in the vertical direction, and the second wedge insertion hole 211 and the second screw hole 212 are respectively the first wedge insertion hole 111 and the first screw hole. An upper main pole 200 formed in the same number as 112 and positioned to correspond to each other in a vertical direction with the first wedge insertion hole 111 or the first screw hole 112; It is formed to have a tapered shape in the downward direction, and is sequentially inserted into the second wedge insertion hole 211 of the upper main pole pole 200 and the first wedge insertion hole 111 of the lower spiral base 100 and the first One or more wedge members 300 inserted and supported in a state spanning the first wedge insertion hole 111 and the second wedge insertion hole 211; And screwed along the second screw hole 212 of the upper main pole pole 200 and the first screw hole 112 of the lower spiral foundation 100, and the second screw hole 212 or the first screw. And a plurality of coupling bolts 400 installed in the same number as the holes 112, including the second wedge insertion hole 211 of the upper main pole 200 and the first wedge insertion of the lower spiral base 100. The first screw hole 112 of the lower spiral foundation 100 and the second screw hole 212 of the upper main pole 200 are vertically oriented through the wedge member 300 inserted into the hole 111. Accordingly, the screw coupling to the second screw hole 212 and the first screw hole 112 of the coupling bolt 400 may be made in a straight line.

According to an embodiment of the present invention, the pole pole for installing the photovoltaic array is formed by the upper main pole coupled to the lower base of the spiral form, the horizontal tension of the assembly fastening portion between the lower base and the upper main pole of the spiral form As this is increased and safety is maximized and the combined assembly time of the lower base and the upper main pole is greatly reduced, the entire air for constructing the photovoltaic array can be further shortened.

In addition, during the construction of the solar power plant, as the coupling structure between the spiral foundation and the main support is improved, the overall process of the construction of the solar power plant can be shortened by shortening the working time accordingly.

1 is a perspective view illustrating an assembled screw pole of a conventional screw type for installation of a photovoltaic array
Figure 2 is a perspective view illustrating the upper and lower structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention in an exploded state
Figure 3 is a side cross-sectional view of the combined state of the upper and lower structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention
Figure 4 is a diagram illustrating the construction process of the lower spiral base in the upper and lower structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention in a photorealistic image
5 is a diagram illustrating a construction state of a photovoltaic power generation facility to which the upper and lower structure fixing devices of the photovoltaic power plant steel pipe support according to an embodiment of the present invention are applied in a photorealistic image;
Figure 6 is a perspective view illustrating the upper and lower structure fixing device of the solar power plant steel pipe support according to another embodiment of the present invention in an exploded state
Figure 7 is a perspective view illustrating an exploded state of the upper main pole of the main portion of the upper and lower structure fixing device of the solar power plant steel pipe support according to another embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following detailed description of the present invention refers to embodiments in which the present invention may be practiced and to the accompanying drawings, which are shown by way of illustration of the embodiments. These embodiments are described in detail sufficient to enable those skilled in the art to practice the invention. It is to be understood that the various embodiments of the invention are different, but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention with respect to one embodiment. In addition, it is to be understood that the location or arrangement of individual components within each described embodiment may be changed without departing from the spirit and scope of the invention.

The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled. Like reference numerals in the drawings refer to the same or similar functions throughout the several aspects.

The terms used in the present invention have been selected as widely used general terms as possible in consideration of the functions in the present invention, but this may vary according to the intention or precedent of the person skilled in the art, the emergence of new technologies and the like. In addition, in certain cases, there is also a term arbitrarily selected by the applicant, in which case the meaning will be described in detail in the description of the invention. Therefore, the terms used in the present invention should be defined based on the meanings of the terms and the contents throughout the present invention, rather than the names of the simple terms.

In the present invention, when a part of the whole "includes" a certain component, this means that unless otherwise stated, it may further include other components, not to exclude other components. In addition, as described in the specification Wealth ”, The term “module” refers to a unit that processes at least one function or operation, which may be implemented in hardware or software, or a combination of hardware and software.

With reference to Figures 2 to 7 will be described for the up and down structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention.

First, with reference to Figures 2 and 5 will be described for the up and down structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention.

Figure 2 is a perspective view illustrating the upper and lower structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention in an exploded state, Figure 3 is a view of the solar power plant steel pipe support according to an embodiment of the present invention Figure 4 is a side cross-sectional view of the coupled state of the upper and lower structure fixing device, Figure 4 is a view illustrating the construction process of the lower spiral base in the upper and lower structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention in a realistic image. .

As shown, the upper and lower structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention, the lower spiral base 100, the upper main pole 200, the wedge member 300 and the coupling bolt 400 It is configured to include.

The lower spiral foundation 100 has an upper coupling portion 110 having a size extending in a horizontal direction at the top thereof, and the first wedge insertion hole 111 and the first screw hole (110) in the upper coupling portion 110. 112 is formed. That is, the upper coupling portion 110 is formed such that one or more first wedge insertion holes 111 and a plurality of first screw holes 112 penetrate along the vertical direction along the circumference thereof, and the first wedge insertion holes. Each of the 111 is tapered in a downward direction, and each of the first screw holes 112 is formed for screwing a bolt. The lower spiral foundation 100 is formed in a spiral shape and is fixed to the ground.

The upper main pole 200 is formed at the bottom of the lower coupling portion 210 of the size corresponding to the upper coupling portion 110 of the lower spiral base 100 and extended in the horizontal direction, the lower coupling portion ( A second wedge insertion hole 211 and a second screw hole 212 are formed in the 210. That is, the lower coupling portion 210 is formed such that one or more second wedge insertion holes 211 and a plurality of second screw holes 212 penetrate along the vertical direction along the circumference thereof, and the second wedge insertion holes. Reference numeral 211 is formed in a tapered shape in the downward direction, but the hole size at the bottom is formed to have the same size as the hole size at the top of the first wedge insertion hole 111 of the lower spiral foundation 100. In addition, the second screw hole 212 is formed for the purpose of screwing the bolt.

In detail, the second wedge insertion hole 211 and the second screw hole 212 of the upper main pole pole 200 may be respectively formed by the first wedge insertion hole 111 and the first screw hole of the lower spiral base 100. It is formed in the same number as 112 and is positioned to correspond to each other in the vertical direction with the first wedge insertion hole 111 or the first screw hole (112).

The wedge member 300 is formed to have a tapered shape in the downward direction, and the wedge member 300 is inserted into the first wedge of the second wedge insertion hole 211 and the lower spiral base 100 of the upper main pole 200. It is sequentially inserted into the hole 111 is inserted and supported in a state spanning the first wedge insertion hole 111 and the second wedge insertion hole 211. And the wedge member 300 is provided in a number corresponding to the first wedge insertion hole 111 of the second wedge insertion hole 211 to the lower spiral base 100 of the upper main pole pole 200.

The coupling bolt 400 is screwed along the second screw hole 212 of the upper main pole 200 and the first screw hole 112 of the lower spiral foundation 100, and the coupling bolt 400 is second The screw holes 212 or the first screw holes 112 are provided in the same number.

Then, the second spiral wedge insertion hole 211 of the upper main pole pole 200 and the wedge member 300 inserted into the first wedge insertion hole 111 of the lower spiral foundation 100 are formed of the lower spiral foundation 100. 1 The second screw hole 212 and the first screw hole of the coupling bolt 400 in a state in which the screw hole 112 and the second screw hole 212 of the upper main pole 200 are aligned in a straight line along the vertical direction. Screwing to 112 is made.

By the above-described configuration, the tapered wedge member 300, that is, the Lima-shaped bolt is formed when the lower spiral base 100, which is a screw-shaped pile, and the upper main pole 200, which is an upper main support, are engaged. By mounting first, the first screw holes 112 and the second screw holes 212 of the lower spiral base 100 and the upper main pole 200 can be exactly matched in the vertical direction, and thus the upper main Coupling the coupling bolt 400 to the second screw hole 212 of the pole 200 and the first screw hole 112 of the lower spiral base 100 can be made very easily. That is, as the coupling work between the lower spiral base 100 and the upper main pole 200 is relatively simplified, the corresponding work time can be shortened. This leads to shortening of the air of the photovoltaic power generation facilities, thereby reducing the cost of constructing the photovoltaic power plant and enabling the early execution of commercial power generation through the photovoltaic power plant.

In detail, the present applicant was able to shorten the air of the solar power plant by about 1 month or more by applying the upper and lower structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention described above. .

In addition, even after the coupling bolt 400 is slightly loosened due to vibration and the like after the upper and lower structure fixing devices of the solar power plant steel pipe support according to an embodiment of the present invention are tapered wedge member 300, that is, Lima shape Bolts are kept in place, and the inspection of the fixing bolts of the upper and lower structures of the steel pipe support and the mechanical stability of the photovoltaic power generation structure including the same by only tightening the coupling bolt (400) during the inspection (vertical load, wind pressure load) , Mechanical stability against ice load, etc.) can be maintained.

In addition, the construction of the solar power plant to which the upper and lower structure fixing devices of the solar power plant steel pipe support according to an embodiment of the present invention is performed in the following order, a significant shortening of the work process as compared to the conventional solar power plant construction process. It can be seen that this is done.

Logging 2. Uprooting. 3. Transmutation. 4. Axle construction. 5. Compaction (rainy weather). 6. Spiral foundation. 7. Combination of spiral foundation and main support (build up). 8. Install structure assembly module (solar cell). 9. DC electrical work. 10. AC Electric Works. 11. Power system connection work. 12. Completion inspection. 13. Start of commercial development.

Figure 5 illustrates the construction state of the photovoltaic power generation facility to which the upper and lower structure fixing device of the solar power plant steel pipe support according to an embodiment of the present invention in a photorealistic image.

Next, with reference to Figure 6 will be described for the up and down structure fixing device of the solar power plant steel pipe support according to another embodiment of the present invention.

Figure 6 is a perspective view illustrating the upper and lower structure fixing device of the solar power plant steel pipe support according to another embodiment of the present invention in an exploded state.

As shown, the upper and lower structure fixing device of the solar power plant steel pipe support according to the present embodiment is in the form of a long hole in which the second screw hole (212 ') of the upper main pole 200' is curved form 2 to 2 There is a difference from the upper and lower structure fixing device of the solar power plant steel pipe support according to the embodiment of Figure 5, and other configurations are the upper and lower structure fixing device of the solar power plant steel pipe support according to the embodiment of Figure 2 to In the present embodiment, the second screw hole 212 'of the upper main pole 200' will be described as the center, and other configurations and functions will be described. Since it will be referred to the description of the up and down structure fixing device of the support, the same reference numerals as in the embodiment of FIGS.

As described above, as the second screw hole 212 ′ of the upper main pole pole 200 ′ is formed in the form of a curved long hole, the coupling bolt 400 is connected to the first screw hole of the lower spiral base 100. Screwing to 112 can be made easier. In other words, as the second screw hole 212 ′ of the upper main pole pole 200 ′ has a predetermined clearance with respect to the coupling of the coupling bolt 400, the second screw hole ( 212 ′) and the first threaded hole 112 can be made easier, and at the same time the lateral tension of the prefabricated joining site between the upper main pole 200 'and the lower spiral base 100 can be increased. have.

Next, with reference to Figure 7 will be described for the up and down structure fixing device of the solar power plant steel pipe support according to another embodiment of the present invention.

Figure 7 is a perspective view illustrating an exploded state of the upper main pole of the main portion of the upper and lower structure fixing device of the solar power plant steel pipe support according to another embodiment of the present invention.

As shown, the upper and lower structure fixing device of the solar power plant steel pipe support according to the present embodiment, the upper main pole 1200 can be detachable to the pole main body 1210, the lower coupling portion 1211 of the pole main body 1210. The wedge pressing member 1220 and the wedge pressing member 1220 to allow the second wedge insertion hole 1212 to be completely formed in the lower coupling portion 1211 during the coupling. It is configured to include a fastening bolt 1230 to detachably couple to the coupling portion 1211 and at the same time adjust the degree of pressing against the wedge member (not shown) of the wedge pressing member 1220.

The semi-circular unit wedge insertion hole 1211a for forming the second wedge insertion hole 1212 at the time of mutual coupling is formed on one surface facing each other between the lower coupling portion 1211 and the wedge pressing member 1220 of the pole body 1210. 1221 are formed, respectively, in the pole body 1210, spiral grooves 1211b are formed on both sides of the unit wedge insertion hole 1211a for detachable coupling of the wedge pressing member 1220, and the wedge pressing member. In 1220, spiral holes 1222 corresponding to spiral grooves 1211b of the pole body 1210 are formed to penetrate in the horizontal direction.

Here, the unit wedge insertion hole 1211a of the lower coupling portion 1211 and the unit wedge insertion hole 1222 of the wedge pressing member 1220 have a second wedge insertion hole 1212 formed when the mutual coupling is downward. Of course, it is formed in a shape corresponding to it to achieve a tapered shape.

In addition, the tightening bolt 1230 is screwed into the spiral hole 1222 of the wedge pressing member 1220 and the spiral groove 1211b of the lower coupling portion 1211 while the wedge pressing member 1220 lower coupling portion 1211. In this case, the wedge member (2) is inserted into the second wedge insertion hole 1212 while the coupling strength of the wedge pressing member 1220 to the lower coupling portion 1211 is adjusted according to the tightening degree of the tightening bolt 1230. The degree of pressurization for 300 is adjusted.

By the above-described configuration, when the wedge member 300 needs to be separated again after being fitted into the second wedge insertion hole 1212 and the first wedge insertion hole 111 of the lower spiral base 100, if necessary, The wedge pressing member 1220 may be separated from the pole body 1210 to more easily separate the wedge member 300.

In addition, it is possible to adjust the inserted strength of the second wedge insertion hole 1212 of the wedge member by adjusting the tightening strength of the tightening bolt 1230, and when the tightening strength of the tightening bolt 1230 is increased, the second wedge of the wedge portion The function that is first attached to the insertion hole 1212 and the first wedge insertion hole 111 may be further improved.

In the present embodiment, the second screw hole 1213 formed in the lower coupling part 1211 is illustrated according to the embodiment of FIGS. 2 to 5, but the present invention is not limited thereto. It may be to follow the embodiment.

On the other hand, in the above embodiments, the upper and lower structure fixing device of the solar power plant steel pipe support of the present invention was applied to the spiral foundation method for the solar power plant, but the upper and lower structures of the solar power plant steel pipe support according to the present invention The device may be commonly applied to the construction of a prefabricated photoelectric pole which requires a top and bottom assembly process such as a prefabricated photoelectric pole for distribution and a prefabricated photoelectric pole for communication.

As described above, the present invention has been described in detail by specific embodiments such as specific components and the like, but the drawings are provided to help a more general understanding of the present invention, and the present invention is limited to the above embodiments. In other words, various modifications and variations are possible to those skilled in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and should not be defined, and not only the claims to be described later but all the equivalents or equivalent modifications to the claims shall fall within the scope of the present invention.

10: lower foundation pole base 11: engaging portion
12: coupling hole 20,1200: upper main pole
21: coupling portion 22: coupling hole
30: coupling bolt 40: coupling nut
100: lower spiral base 110: upper coupling portion
111: first wedge insertion hole 112: first screw hole
200,200 ': Upper main pole 210: Lower coupling
211: 2nd wedge insertion hole 212,212 ': 2nd screw hole
300: wedge member 400: coupling bolt
1210: pole body 1211: lower coupling portion
1211a: unit wedge insertion hole 1211b: spiral groove
1212: second wedge insertion hole 1213: second screw hole
1220: wedge pressing member 1221: unit wedge insertion hole
1222: Spiral hole 1230: Tightening bolt

Claims (1)

An upper coupling part 110 having a size extended in a horizontal direction is formed at an upper end thereof, and a plurality of agents for screwing one or more first wedge insertion holes 111 and bolts that have a tapered shape in a downward direction 1 screw hole 112 is formed so as to penetrate the upper coupling portion 110 in the vertical direction along the circumference of the upper coupling portion 110, is formed in a spiral shape to be embedded in the ground fixed spiral base 100 ;
Removably coupled to the pole body 1210 having a lower coupling portion 1211 corresponding to the upper coupling portion 110 of the lower spiral base 100 and the lower coupling portion 1211 of the pole body 1210. While the wedge pressing member 1220 and the wedge pressing member 1220 to completely form the second wedge insertion hole 1212 in the lower coupling portion 1211 when the coupling of the pole body 1210 Removably coupled to the lower coupling portion 1211 and at the same time includes a tightening bolt 1230 to adjust the degree of pressing against the wedge member (not shown) of the wedge pressing member 1220, of the pole body 1210 Semi-circular unit wedge insertion holes 1211a and 1221 are formed on one surface of the lower coupling portion 1211 and the wedge pressing member 1220 that face each other to form the second wedge insertion hole 1212 upon mutual coupling. , The unit wedge insertion hole 1211a of the lower coupling portion 1211 The unit wedge insertion hole 1222 of the wedge pressing member 1220 is formed such that the second wedge insertion hole 1212 formed at the time of mutual coupling may form a tapered shape in the downward direction, and the pole body 1210. Spiral grooves 1211b are formed on both sides of the unit wedge insertion hole 1211a for detachable coupling of the wedge pressing member 1220, and at the same time, the pole body 1210 is formed on the wedge pressing member 1220. The spiral holes 1222b corresponding to the spiral grooves 1211b of each of the plurality of spiral grooves 1211b are formed to penetrate in the horizontal direction, and the tightening bolt 1230 is the spiral hole 1222 of the wedge pressing member 1220. A second screw hole 1213 for screwing the bolts to couple the wedge pressing member 1220 to the lower coupling portion 1211 while being sequentially screwed into the spiral groove 1211b of the lower coupling portion 1211 Along the circumference of the lower coupling portion 1211 Is formed to penetrate the lower coupling portion 1211 in the vertical direction, the second wedge insertion hole 1212 and the second screw hole 1213 are the first wedge insertion hole 111 and the first screw hole ( 112 is formed in the same number as the first wedge insertion hole 111 or the first screw hole 112 and are located to correspond to each other in the vertical direction, the second screw hole 1213 is the coupling bolt 400 of the An upper main pole pole 1200 formed in the form of a bent hole curved to have a gap with respect to the coupling;
It is formed to have a tapered shape in the downward direction, and is sequentially inserted into the second wedge insertion hole 1212 of the upper main pole pole 1200 and the first wedge insertion hole 111 of the lower spiral base 100 to the One or more wedge members 300 fitted and supported in a state spanning the first wedge insertion hole 111 and the second wedge insertion hole 1212; And
The second screw hole 1213 of the upper main pole pole 1200 and the first screw hole 112 of the lower spiral foundation 100 is screwed into the first screw hole 112, the second screw And a plurality of coupling bolts 400 installed in the same number as the holes 1213 or the first screw holes 112.
The lower spiral foundation 100 through the wedge member 300 inserted into the second wedge insertion hole 1212 of the upper main pole pole 1200 and the first wedge insertion hole 111 of the lower spiral foundation 100. The first screw hole 112 of the coupling bolt 400 in a state that the first screw hole (112) and the second screw hole (1213) of the upper main pole pole (1200) is aligned in a straight line in the vertical direction. Screw connection)
As the second screw hole 1213 has the shape of a curved long hole, the lateral tension of the prefabricated coupling portion between the upper main pole pole 1200 and the lower spiral foundation 100 is increased,
The wedge member 300 fitted into the second wedge insertion hole 1212 while adjusting the coupling strength of the wedge pressing member 1220 to the lower coupling portion 1211 according to the tightening degree of the tightening bolt 1230. The wedge pressing member 1220 is separated from the pole body 1210 for the separation of the wedge member from the second wedge insertion hole 1212 and the first wedge insertion hole 111 at the same time the degree of pressurization of the pressure is controlled. The upper and lower structure fixing device of the solar power plant steel pipe support, characterized in that possible.

Images