KR102053047B1 - Chalice Structure - Google Patents

Abstract

Disclosed is a calix structure which has a plurality of stages connected to each other by three or more pillars to form a calix shape on the whole. Each stage comprises: a body unit which has an octagonal cross section and an empty space therein, and is formed in a circular shape on the whole; four structure reinforcing pipe units which are coupled to horizontal surfaces of upper and lower parts of the body unit, respectively, have a rectangular cross section and an empty space therein, and are formed in a circular shape on the whole; three or more upper horizontal reinforcing plate units which are coupled to a first structure reinforcing pipe unit and a second structure reinforcing pipe unit between the first structure reinforcing pipe unit coupled outwardly to the upper horizontal surface of the body unit and the second structure reinforcing pipe unit coupled inwardly to the upper horizontal surface of the body unit among the structure reinforcing pipe units; three or more lower horizontal reinforcing plate units which are coupled to a third structure reinforcing pipe unit and a fourth structure reinforcing pipe unit between the third structure reinforcing pipe unit coupled outwardly to the lower horizontal surface of the body unit and the fourth structure reinforcing pipe unit coupled inwardly to the lower horizontal surface of the body unit among the structure reinforcing pipe units; and three or more vertical reinforcing units which are coupled to the upper horizontal reinforcing plate unit and the lower horizontal reinforcing plate unit between the upper horizontal reinforcing plate unit and the lower horizontal reinforcing plate unit. The calix structure according to the present invention has excellent properties compared with existing calix structures formed by rebar concrete structures.

Description

Chalice Structure

The present invention relates to a construction structure, and more particularly, to a construction structure having excellent properties compared to the construction structure formed of a reinforced concrete structure.

The Holy Communion is one of the liturgical rites, a consecrated cup that is used to consecrate wine during the Eucharist during the Mass and to be received after being built with the Holy Blood. According to the legend, the cup used by Jesus at the Last Supper was one of the believers (presumed to be Joseph of Arimathea) receiving the blood of Jesus crucified. The goblet spread from Joseph to the hands of others, and rumors spread. The Catholic Church teaches that the wine used in the Eucharist actually becomes the blood of Jesus.

The sacred sculptures or structures have a sacred shape and are installed in the church or an affiliated building of the church to represent the sacred works. Typically, the rebuilt structure is formed of a reinforced concrete structure, as shown in FIG. Thus, conventional build structures have an excessive load. The total weight of the conventional structure chalice when estimating the weight of a reinforced concrete 1. 2.4 tonnes per m ³ This is a significant burden when considering the building structure to be installed is approximately 27.5 tonnes.

Conventional newly constructed structures may also generate cracks due to vibration and may also crack due to heat of hydration during concrete hardening. Such cracking causes a problem of deterioration of the finished structure. In other words, the aesthetics of the built structure is significantly lowered, which causes the value of the sculpture to be lost.

In addition, conventional construction structures do not have insulation and condensation may occur. Condensation causes mold to occur in the reproductive structure, as shown in FIG. 16.

Conventional newly constructed structures also have excessive construction periods, such as concrete curing and construction, and thus excessive construction costs. In addition, there is a problem that the risk of a safety accident is high because it must be manufactured sequentially in the site of the building to be installed.

The present invention has been made to solve the above problems of the prior art. Accordingly, it is an object of the present invention to provide a construction structure having excellent characteristics compared to the construction structure formed of a reinforced concrete structure.

Specifically, it is an object of the present invention to provide a new construction with improved structural stability by reducing the weight of approximately 1/10 compared to the construction of the reinforced concrete structure.

It is also an object of the present invention to provide a new construction which is made of steel so that cracks due to hydration heat do not occur.

It is also an object of the present invention to provide a built structure in which the insulation is contained inside the stage of the built structure so that no condensation occurs.

It is also an object of the present invention to provide a rebuilt structure that requires less construction period and cost.

It is also an object of the present invention that the risk of safety accidents occurring during the construction of the site by installing the main part of the cultivated structure is not the building where the cultivated structure is installed, that is, manufactured after moving to the building where the cultivated structure is installed and then installed. It is to provide a construction structure that can minimize the elements.

The construction structure of the present invention for achieving the above object is a plurality of stages are connected to each other by three or more pillars to form the overall composition.

In the construction structure of the present invention, each of the stages is an octagonal cross section of the inside of the hollow body and the circular shape as a whole; Inside the body portion, the structural reinforcing pipe portion is coupled to the upper horizontal plane and the lower horizontal plane, respectively, the cross section is rectangular, the interior is empty and generally circular; The first structural reinforcement between the first structural reinforcement pipe portion of the structural reinforcing pipe portion coupled to the upper horizontal plane of the body portion to the outside and the second structural reinforcement pipe portion to couple inward to the upper horizontal plane of the body portion Three or more upper horizontal reinforcing plate portions coupled with the pipe portion for reinforcing and the second structural reinforcing pipe portion; The third structural reinforcement between the third structural reinforcement pipe portion of the structural reinforcing pipe portion coupled to the lower horizontal surface of the body portion to the outside and the fourth structural reinforcement pipe portion to couple inward to the lower horizontal surface of the body portion Three or more lower horizontal reinforcing plate portions engaged with the pipe portion for construction and the fourth structural reinforcing pipe portion; And at least three vertical reinforcing parts coupled to the upper horizontal reinforcing plate part and the lower horizontal reinforcing plate part between the upper horizontal reinforcing plate part and the lower horizontal reinforcing plate part.

In the maturation structure of the present invention, the first structural reinforcement between the first structural reinforcement pipe part and the second structural reinforcement pipe part at each of its outer positions relative to one of the upper horizontal reinforcement plate parts is also provided. A pair of upper horizontal auxiliary reinforcing parts coupled to the pipe part for reinforcing and the second structural reinforcing part; The third structural reinforcing pipe portion and the fourth structural reinforcing pipe portion between the third structural reinforcing pipe portion and the fourth structural reinforcing pipe portion at each of its outer positions with respect to one of the lower horizontal reinforcing plate portions; A pair of lower horizontal auxiliary reinforcing parts for coupling; The first structural reinforcement pipe portion and the first structural reinforcement pipe portion and the third structural reinforcement pipe portion at their outer positions with respect to the one upper horizontal reinforcement plate portion and one lower horizontal reinforcement plate portion, respectively; A pair of outer vertical auxiliary reinforcing parts coupled with the third structural reinforcing pipe part; And the second structural reinforcement pipe portion between the second structural reinforcement pipe portion and the fourth structural reinforcement pipe portion at each of their outer positions with respect to the one upper horizontal reinforcement plate portion and one lower horizontal reinforcement plate portion. And a pair of inner vertical auxiliary reinforcing parts coupled to the fourth structural reinforcing pipe part.

Preferably, the vertical reinforcement part, the upper horizontal auxiliary reinforcement part, the lower horizontal auxiliary reinforcement part, the outer vertical auxiliary reinforcement part and the inner vertical auxiliary reinforcement part are each formed in a square pipe shape.

The thickness of the body portion is 2mm, the thickness of the upper horizontal reinforcing plate portion and the lower horizontal reinforcing plate portion is 12mm, the thickness of the vertical reinforcing portion is 6mm, the structural reinforcing pipe portion, the upper horizontal auxiliary reinforcing portion, the lower The horizontal auxiliary reinforcing part, the outer vertical auxiliary reinforcing part and the thickness of the inner vertical auxiliary reinforcing part may be 3mm respectively.

All or part of the upper horizontal reinforcement plate portion and the lower horizontal reinforcement plate portion are exposed without being covered by the body portion, and the pillar is between the lower horizontal reinforcement plate portion at some stage and the upper horizontal reinforcement plate portion at the lower stage. It is preferable to combine with the lower horizontal reinforcing plate portion and the upper horizontal reinforcing plate portion.

Three or more connection brackets formed in the shape of a vertical plate or a square pipe having a plurality of bolt holes are extended to the bottom of the ends of the construction structure, and the construction structure is installed in the building in which the construction structure is installed. It further comprises at least three anchor bolt structure is fixed by buried in the concrete pour, wherein the anchor bolt structure is anchored by buried in the concrete pour, anchor bolt portion is coupled to the anchor bolt portion and the concrete pour of A base plate portion exposed to the surface and a connection bracket portion extending vertically upwardly from the base plate portion and formed in a vertical plate or a square pipe shape having a plurality of bolt holes, wherein the connection formed at the bottom of the construction structure Bracket and Anchor Bolts It is preferable that the connecting bracket portion of the body is coupled by inserting and fastening bolts into their bolt holes.

The construction structure is divided into a movable structure and the anchor bolt structure, the movable structure is manufactured at the factory as a structure in which a plurality of the stages are coupled by the pillars and the connection bracket is formed at the bottom, and then the construction The construction structure is moved to a place of the building where the structure is installed, and after the concrete is poured into the building and the anchor bolt structure is fixed to the concrete casting, the construction structure by the coupling of the anchor bolt structure and the connecting bracket It is preferable to be installed in a building.

The movable structure is formed of two or more separate movable structures and is moved to a place where the building is located. At this time, the bottom of the upper movable structure among the movable structures has a vertical plate or square pipe shape having a plurality of bolt holes. Three or more connecting brackets are formed to extend downward, and three or more connecting brackets formed in the shape of a vertical plate or a square pipe having a plurality of bolt holes are formed at the top of the lower movable structure among the movable structures. The upper movable structure and the lower movable structure are coupled to each other by inserting and tightening bolts into bolt holes formed in the connecting brackets, and then, the building structure is the building. To be installed on Can.

Two or more heat insulating material injection holes are formed in the body portion of each stage, and the sprayed synthetic resin heat insulating material is injected through one of the heat insulating material injection holes, so that the foamed plastic heat insulating material is filled inside the body part. desirable.

The construction structure according to the present invention has superior properties compared to conventional construction structures formed of reinforced concrete structures. Specifically, the structural structure of the present invention is structurally improved by light weight, and is made of steel, so that no crack occurs due to hydration heat, and heat insulation is contained in the stage of the structural structure, so that no condensation occurs. After manufacturing the main parts, the installation site can be installed by simple construction, minimizing the risk of safety accidents.

1 is a view showing a schematic configuration of a restructuring structure according to an embodiment of the present invention.
2 is a cross-sectional view illustrating a cut structure according to an embodiment of the present invention.
Figure 3 is a plan view of any stage applied to the construction structure according to an embodiment of the present invention.
Figure 4 is a view showing a cut cross-sectional view cut at one point for each stage applied to the construction structure according to an embodiment of the present invention.
FIG. 5 is a cross-sectional view of a cut section at a different point for each stage applied to the rebuild structure according to an embodiment of the present invention.
6 is a view schematically showing the configuration of the body portion at any stage applied to the rebuilt structure according to an embodiment of the present invention.
7 is a view schematically illustrating the coupling between the schematic structure of the anchor bolt structure applied to the rebuilt structure according to an embodiment of the present invention and the connection bracket installed on the bottom of the movable structure.
Figure 8 is a picture of the actual structure excluding the body portion at any stage applied to the reconstruction structure according to an embodiment of the present invention.
FIG. 9 is a photograph of an actual structure in which an upper horizontal reinforcing plate part, a lower horizontal reinforcing plate part, and a vertical reinforcing part are combined at each stage applied to a reconstruction structure according to an embodiment of the present invention.
10 is a photograph of the actual appearance of any stage applied to the construction structure according to an embodiment of the present invention.
Figure 11 is a picture of the actual appearance of the column coupled to any stage applied to the construction structure according to an embodiment of the present invention.
12 and 13 are photographs taken of the construction process for installing a restructuring structure in a building according to an embodiment of the present invention.
FIG. 14 is a photograph of a state in which installation of the rebuilt structure of FIGS. 12 and 13 is completed.
FIG. 15 is a photograph showing a state in which a reinforced structure of reinforced concrete according to the related art is installed in a certain building.
FIG. 16 is a picture taken from the inside of the constructed structure of FIG. 15 to show a mold generated due to condensation caused by not being insulated.

Hereinafter, the present invention will be described in detail with reference to the drawings.

As shown in FIGS. 1, 2, and 14, the external shape of the rebuildable structure of the present invention is the same as that of the conventional rebuildable structure, which is conventionally manufactured from reinforced concrete structures. However, since the construction structure of the present invention has a shape and structure made of steel as described below, it can be reduced to about 1/10 as compared to reinforced concrete structures. Electro galvanized iron (EGI) may be used as a material used in the construction of the present invention, and a stainless steel sheet may be used if necessary.

1, 2, and 14, the construction structure 10 of the present invention, as a whole, the shape of the construction, a plurality of stages 12 are connected to each other by three or more pillars. It is common for 18 to 22 stages to be applied to the new structure. The construction structure 10 has the largest diameter of the upper end 12 and gradually decreases as it goes down, and then grows again. The pillar 600 is determined by the number required to maintain the load of the construction structure 10, four is usually employed, but if the construction structure 10 should be formed more robust up to six or eight Can be.

Each end 12 of the building structure 10 has a body portion 100, four structural reinforcement pipe portions 210, 220, 230 and 240, the upper horizontal reinforcement plate 310, the lower horizontal reinforcement plate 320 , A vertical reinforcement unit 400, a pair of upper horizontal auxiliary reinforcement 510, a pair of lower horizontal auxiliary reinforcement 520, a pair of outer vertical auxiliary reinforcement 530 and a pair of inner vertical auxiliary Reinforcement portion 540 is included.

As shown in detail in FIGS. 3 and 4, the body part 100 is octagonal in cross section, hollow inside, and generally circular. That is, the body portion 100 has an upper horizontal plane 110, a lower horizontal plane 120, an outer vertical plane 130, an inner vertical plane 140, an upper outer inclined plane 150, an upper inner inclined plane 160, and a lower outer inclined plane 170. ) And the lower inner inclined surface 180. Body portion 100 may be formed in a circular shape by joining the body portion having a suitable length and curvature by welding. The body piece may be formed by joining the upper plate 102 and the lower plate 104 by welding, as shown in FIG. 6. At this time, for example, the upper plate 102 has a shape consisting of the upper horizontal surface 110, the upper outer inclined surface 150 and the upper inner inclined surface 160, the lower plate 104 is the lower horizontal surface 120, the outer vertical surface ( 130, the inner vertical surface 140, the lower outer inclined surface 170, and the lower inner inclined surface 180 may have a shape. Alternatively, the upper plate has a shape consisting of an upper horizontal plane 110, an upper outer inclined plane 150, an upper inner inclined plane 160, a portion of the outer vertical plane 130, and a portion of the inner vertical plane 140, and the lower plate has a lower horizontal plane ( 120, a portion of the outer vertical surface 130, a portion of the inner vertical surface 140, a lower outer inclined surface 170, and a lower inner inclined surface 180 may be formed. The body portion 100 may have a plurality of ribs 102 extending vertically from the upper plate 102 and the lower plate 104 for strength reinforcement. The ribs 102 are formed at appropriate intervals and extend vertically to the extent that they do not interfere with the coupling of the upper and lower plates. As an example, the thickness of the body portion 100 is 2 mm. The height of the body portion 100 is 200 mm. That is, the distance between the outer surface of the upper horizontal surface 110 and the outer surface of the lower horizontal surface 120 is 200 mm. The width of the upper horizontal plane 110 and the lower horizontal plane 120 is approximately 233 mm, and the width of the outer vertical plane 130 and the inner vertical plane 140 is 100 mm. The width of the outer inclined surfaces 150 and 160 may be set larger than the width of the inner inclined surfaces 170 and 180.

As shown in Figures 4 and 5, the structural reinforcing pipes 210, 220, 230 and 240 are rectangular in cross section, hollow inside and generally circular, the body portion (in the interior of the body portion 100) The upper horizontal plane 110 and the lower horizontal plane 120 of 100 are respectively coupled by welding. The first structural reinforcing pipe portion 210 is coupled to the upper horizontal surface 110 of the body portion 100 to the outside. In particular, the first structural reinforcing pipe part 210 may be disposed in contact with or adjacent to a line where the upper horizontal plane 110 and the upper outer inclined plane 150 meet. The second structural reinforcing pipe part 220 is coupled inward to the upper horizontal surface 110 of the body part 100. In particular, the second structural reinforcing pipe part 220 is preferably disposed in contact with or adjacent to a line where the upper horizontal plane 110 and the upper inner inclined plane 160 meet. The third structural reinforcing pipe portion 230 is coupled to the lower horizontal surface 120 of the body portion 100 to the outside. In particular, the third structural reinforcing pipe portion 230 is preferably disposed in contact with or adjacent to a line where the lower horizontal surface 120 and the lower outer inclined surface 170 meet. The fourth structural reinforcing pipe part 240 is coupled inward to the lower horizontal surface 120 of the body part 100. In particular, the fourth structural reinforcing pipe part 240 may be disposed in contact with or adjacent to a line where the lower horizontal surface 120 and the lower inner inclined surface 180 meet. As an example, in the cross section of the structural reinforcing pipes 210, 220, 230 and 240, the horizontal and vertical length is 50mm, the thickness is 3.2mm.

As shown in FIG. 4, the upper horizontal reinforcing plate portion 310 is coupled to them by welding between the first structural reinforcing pipe portion 210 and the second structural reinforcing pipe portion 220. The upper horizontal reinforcing plate 310 is preferably formed by the number of pillars 600. The lower horizontal reinforcing plate portion 320 is coupled to them by welding between the third structural reinforcing pipe portion 230 and the fourth structural reinforcing pipe portion 240. The lower horizontal reinforcing plate 320 is preferably formed by the number of pillars 600. As one example, the thickness of the upper horizontal reinforcement plate 310 and the lower horizontal reinforcement plate 320 is 12 mm, and their horizontal and vertical widths are approximately 130 mm. However, it is natural that their width is formed with curvature to form a circle. Between the upper horizontal reinforcing plate portion 310 and the lower horizontal reinforcing plate portion 320, the vertical reinforcing portion 400 is joined to them by welding. The vertical reinforcement part 400 is preferably formed in a hollow rectangular pipe shape. As an example, in the cross section of the vertical reinforcement 400, the horizontal and vertical lengths are 100 mm and the thickness is 6 mm, respectively. A practical example of the shape of the upper horizontal reinforcement plate 310, the lower horizontal reinforcement plate 320 and the vertical reinforcement 400 is shown in FIG. 9. The upper horizontal reinforcement plate 310, the lower horizontal reinforcement plate 320 and the vertical reinforcement 400 may be formed by the number of pillars 600.

As shown in FIGS. 3 and 10, all or part of the upper horizontal reinforcement plate 310 and the lower horizontal reinforcement plate 320 may be exposed without being covered by the body. Thus, the column 600 is preferably coupled with them by welding between the lower horizontal reinforcing plate portion 320 of a certain stage and the upper horizontal reinforcing plate portion 310 of a lower stage, as shown in FIG. At this time, the column 600 has a horizontal and vertical length of 100mm in the cross-section, and a thickness of 6mm is used, it is preferable to be arranged to match the vertical reinforcement 400.

As shown in Figs. 5 and 8, the upper horizontal auxiliary reinforcing portion 510 is the first structural reinforcing pipe portion 210 and the second in each of its outer position relative to one upper horizontal reinforcing plate portion 310 Between the structural reinforcing pipe portion 220, the first structural reinforcing pipe portion 210 and the second structural reinforcing pipe portion 220 is coupled by welding.

The lower horizontal auxiliary reinforcing portion 520 is formed between the third structural reinforcing pipe portion 230 and the fourth structural reinforcing pipe portion 240 at each of its outer positions with respect to one lower horizontal reinforcing plate portion 320. The third structural reinforcing pipe part 230 and the fourth structural reinforcing pipe part 240 are coupled to each other by welding.

The outer vertical auxiliary reinforcement part 530 has a first structural reinforcement pipe part 210 and a third structure at each of their outer positions with respect to one upper horizontal reinforcement plate part 310 and one lower horizontal reinforcement plate part 320. Between the reinforcing pipe portion 230 is coupled to the first structural reinforcing pipe portion 210 and the third structural reinforcing pipe portion 230 by welding.

The inner vertical auxiliary reinforcement part 540 has a second structural reinforcement pipe part 220 and a fourth structure at each of their outer positions with respect to one upper horizontal reinforcement plate part 310 and one lower horizontal reinforcement plate part 320. The second structural reinforcing pipe part 220 and the fourth structural reinforcing pipe part 240 are coupled between the reinforcing pipe parts 240 by welding.

Coupling state of a pair of upper horizontal auxiliary reinforcing part 510, a pair of lower horizontal auxiliary reinforcing part 520, a pair of outer vertical auxiliary reinforcing part 530 and a pair of inner vertical auxiliary reinforcing part 540 Is clearly shown in FIG. 8. In FIG. 8, a pair of upper horizontal reinforcing parts 510, a pair of lower horizontal auxiliary reinforcing parts 520, one at an outer position around the upper horizontal reinforcing plate part 310 and the lower horizontal reinforcing plate part 320, and a It can be seen that the pair of outer vertical auxiliary reinforcing portion 530 and the pair of inner vertical auxiliary reinforcing portions 540 are disposed. The number of pairs of the upper horizontal auxiliary reinforcing part 510, the lower horizontal auxiliary reinforcing part 520, the outer vertical auxiliary reinforcing part 530 and the inner vertical auxiliary reinforcing part 540 is the number of the upper horizontal reinforcing plate part 310 Is formed identically. The upper horizontal auxiliary reinforcing part 510, the lower horizontal auxiliary reinforcing part 520, the outer vertical auxiliary reinforcing part 530, and the inner vertical auxiliary reinforcing part 540 are preferably formed in a hollow rectangular pipe shape. By way of example, in their cross section the transverse and longitudinal widths are 50 mm and the thickness is 3.2 mm.

As shown in FIG. 7, at the bottom of the stages of the construction structure 10 of the present invention described above, as many connection brackets 700 as the number of pillars 600 extend downward. The connection bracket 700 may be formed in a vertical plate or square pipe shape having a plurality of bolt holes 710.

The build structure 10 also includes as many anchor bolt structures 800 as the number of columns 600. The anchor bolt structure 800 is fixed by being buried in the concrete pours provided in the building or floor structure on which the construction structure 10 is installed, the anchor bolt portion 810, the base plate portion 820, and the connecting bracket portion 830. ) The anchor bolt portion 810 is buried in the concrete pour 20 provided in the building or the floor structure on which the construction structure 10 is installed is fixed. As shown in detail in FIG. 7, the anchor bolt portion 810 may be formed in a plate shape having a cross section having a '-' shape. For example, two anchor bolt portions 810 may be symmetrically disposed. The base plate portion 820 is coupled to the two anchor bolt portions 810 and is exposed to the surface of the concrete pouring 20. For even stronger coupling, four anchor bolt portions 810 may be coupled to the base plate portion 820. The connection bracket part 830 may extend in a vertical direction from the base plate part 820 and have a vertical plate or square pipe shape having a plurality of bolt holes 832. The coupling of the anchor bolt portion 810 and the base plate portion 820 and the coupling of the base plate portion 820 and the connection bracket portion 830 may be made by welding.

Thus, the connection bracket 700 formed at the bottom of the construction structure 10 and the connection bracket portion 830 of the anchor bolt structure 800 have a bolt 900 inserted into their bolt holes 710 and 832. It is coupled by being fastened. In addition, for stronger coupling, welding may be performed to a contact portion between the connection bracket 700 and the connection bracket portion 830 of the anchor bolt structure 800 after the bolt is fastened.

In the above configuration of the present invention, the construction structure 10 may be divided into a movable structure and an anchor bolt structure (800). The movable structure is a structure in which a plurality of stages are coupled by the pillars 600, and a connection bracket 700 is formed at the bottom thereof. This mobile structure is manufactured at the factory and then moved to the location of the building or floor structure in which the new construction 10 is installed, as shown in FIGS. 12 and 13. Pour concrete in the building. At this time, the anchor bolt structure 800 is buried in the concrete pour to be fixed to the concrete pour. Then, by combining the connection bracket portion 830 and the connection bracket 700 of the anchor bolt structure 800, as shown in Figure 14 can be installed in the building structure 10.

In the present invention, it is also possible to form one of the above-mentioned movable structures, but it is also possible to form two or more separated for mobility and ease of installation. In the case of forming two movable structures, connecting brackets of the number of columns 600 formed in a vertical plate or square pipe shape having a plurality of bolt holes at the bottom of the upper movable structure among them are extended to be installed below. Can be. In addition, three or more connection brackets formed in the shape of a vertical plate or a square pipe having a plurality of bolt holes may be installed at an uppermost end of the lower movable structure. The upper and lower movable structures thus formed are moved to the place where the building is located, and the upper and lower movable structures are joined by bolts inserted into the bolt holes formed in the connection brackets. At this time, in order to achieve a stronger coupling, welding may be performed on the contact portions between the connection brackets after the bolt is fastened. After combining the upper and lower movable structures, as described above, the movable structure 10 may be installed in the building by combining the movable structure with the anchor bolt structure 800. In this case, instead of combining the upper and lower mobility structures first, it is also possible to first combine the lower and lower mobility structures with the anchor bolt structure 800, and then combine the upper and lower mobility structures with the lower and movable structures.

On the other hand, two or more insulation injection holes (not shown) are formed in the body portion 100 of each stage in the construction structure 10 of the present invention. The heat insulating material injection hole can be formed anywhere in the body portion 100, but it is preferable to be provided on the upper inner inclined surface 160 or the lower inner inclined surface 180 aesthetically. By injecting the spray-type foamed resin insulation, in particular sprayed polyurethane insulation through one of the insulation material injection holes, the foamed resin insulation is filled inside the body portion 100. At this time, when only one heat insulating material injection hole is formed, the heat insulating material may not be filled in the body portion 100, and it is also difficult to check.

10: new construction 12: stage
100: body portion 210,220,230,240: structural reinforcement pipe
310, 320: horizontal reinforcement plate 400: vertical reinforcement
510,520: Horizontal auxiliary reinforcement unit 530,540: Vertical auxiliary reinforcement unit
600: pillar 700: connection bracket
800: anchor bolt structure 810: anchor bolt portion
820: base plate portion 830: connection bracket portion

Claims (9)

In the construction structure wherein a plurality of stages are connected to each other by three or more pillars to form the overall composition,
Each of the stages has an octagonal cross section and a hollow body, the body portion of which a circular shape as a whole;
Inside the body portion, the structural reinforcing pipe portion is coupled to the upper horizontal plane and the lower horizontal plane, respectively, the cross section is rectangular, the interior is empty and generally circular; The first structural reinforcement between the first structural reinforcement pipe portion of the structural reinforcing pipe portion coupled to the upper horizontal plane of the body portion to the outside and the second structural reinforcement pipe portion to couple inward to the upper horizontal plane of the body portion Three or more upper horizontal reinforcing plate portions coupled with the pipe portion for reinforcing and the second structural reinforcing pipe portion; The third structural reinforcement between the third structural reinforcement pipe portion of the structural reinforcing pipe portion coupled to the lower horizontal surface of the body portion to the outside and the fourth structural reinforcement pipe portion to couple inward to the lower horizontal surface of the body portion Three or more lower horizontal reinforcing plate portions engaged with the pipe portion for construction and the fourth structural reinforcing pipe portion; And at least three vertical reinforcing parts coupled to the upper horizontal reinforcing plate part and the lower horizontal reinforcing plate part between the upper horizontal reinforcing plate part and the lower horizontal reinforcing plate part. The method of claim 1,
Wherein each of the stages is between the first structural reinforcing pipe portion and the second structural reinforcing pipe portion at each of its outer positions relative to one of the upper horizontal reinforcing plate portions; A pair of upper horizontal auxiliary reinforcing parts coupled with the pipe part for; The third structural reinforcing pipe portion and the fourth structural reinforcing pipe portion between the third structural reinforcing pipe portion and the fourth structural reinforcing pipe portion at each of its outer positions with respect to one of the lower horizontal reinforcing plate portions; A pair of lower horizontal auxiliary reinforcing parts for coupling; The first structural reinforcement pipe portion and the first structural reinforcement pipe portion and the third structural reinforcement pipe portion at their outer positions with respect to the one upper horizontal reinforcement plate portion and one lower horizontal reinforcement plate portion, respectively; A pair of outer vertical auxiliary reinforcing parts coupled with the third structural reinforcing pipe part; And the second structural reinforcement pipe portion between the second structural reinforcement pipe portion and the fourth structural reinforcement pipe portion at each of their outer positions with respect to the one upper horizontal reinforcement plate portion and one lower horizontal reinforcement plate portion. And a pair of inner vertical auxiliary reinforcing parts coupled to the fourth structural reinforcing pipe part. The method of claim 2,
And the vertical reinforcement part, the upper horizontal auxiliary reinforcement part, the lower horizontal auxiliary reinforcement part, the outer vertical auxiliary reinforcement part and the inner vertical auxiliary reinforcement part are each formed in a rectangular pipe shape. The method of claim 3,
The thickness of the body portion is 2mm, the thickness of the upper horizontal reinforcing plate portion and the lower horizontal reinforcing plate portion is 12mm, the thickness of the vertical reinforcing portion is 6mm, the structural reinforcing pipe portion, the upper horizontal auxiliary reinforcing portion, the lower The horizontal auxiliary reinforcing portion, the outer vertical auxiliary reinforcing portion and the thickness of the inner vertical auxiliary reinforcing portion is a restructuring structure, characterized in that each 3mm. The method according to any one of claims 1 to 4,
All or part of the upper horizontal reinforcement plate portion and the lower horizontal reinforcement plate portion are exposed without being covered by the body portion, and the pillar is between the lower horizontal reinforcement plate portion at some stage and the upper horizontal reinforcement plate portion at the lower stage. And the lower horizontal reinforcing plate portion and the upper horizontal reinforcing plate portion are combined. The method according to any one of claims 1 to 4,
At the bottom of the ends of the construction structure, three or more connecting brackets formed in the shape of a vertical plate or a square pipe having a plurality of bolt holes extend downwards,
The cultivation structure further comprises at least three anchor bolt structure is buried in the concrete pour is provided in the building on which the construction structure is installed, wherein the anchor bolt structure is buried in the concrete pour anchor anchor portion And a base plate portion coupled to the anchor bolt portion and exposed to the surface of the concrete pour, and a connection bracket portion extending vertically upward from the base plate portion and formed in a vertical plate or square pipe shape having a plurality of bolt holes. ,
And the connection bracket portion of the anchor bolt structure and the connection bracket formed at the bottom of the construction structure are coupled by inserting and fastening bolts into their bolt holes. The method of claim 6,
The construction structure is divided into a movable structure and the anchor bolt structure, the movable structure is manufactured at the factory as a structure in which a plurality of the stages are coupled by the pillars and the connection bracket is formed at the bottom, and then the construction The construction structure is moved to a place of the building where the structure is installed, and after the concrete is poured into the building and the anchor bolt structure is fixed to the concrete casting, the construction structure by the coupling of the anchor bolt structure and the connecting bracket A surrogate structure, characterized in that installed in the building. The method of claim 7, wherein
The movable structure is formed of two or more separate movable structures and is moved to a place where the building is located. At this time, the bottom of the upper movable structure among the movable structures has a vertical plate or square pipe shape having a plurality of bolt holes. Three or more connecting brackets are formed to extend downward, and three or more connecting brackets formed in the shape of a vertical plate or a square pipe having a plurality of bolt holes are formed at the top of the lower movable structure among the movable structures. Extends to,
Wherein the building is located in the upper movable structure and the lower movable structure is coupled by inserting the bolt into the bolt holes formed in the connecting brackets, characterized in that after the construction structure is installed in the building Constructed structures. The method according to any one of claims 1 to 4,
Two or more heat insulating material injection holes are formed in the body part of each stage, and the sprayed synthetic resin heat insulating material is injected through one of the heat insulating material injection holes, and the foamed synthetic resin heat insulating material is filled in the body part. Characterized by the structure.

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