KR101739126B1 - Method for Forming Top-down-typed Underground Strucutre - Google Patents

Abstract

A method of forming an underground structure in a top-down manner, comprising the steps of: installing a first prismatic member on top of a top strut and securing it with a first member securing device; installing a beam securing device on top of the top strut; Installing a support beam on the upper portion, installing a second prismatic member on the upper portion of the support beam and fixing the second prismatic member with the second member coupling device, and the like.

Description

[0001] The present invention relates to a method of forming a top-down type underground structure,

The present invention relates to a method of forming a structure, and more particularly, to a method of forming an underground structure in a top-down manner.

Since the top-down construction method has been introduced in Korea, it has been variously modified and developed so that it is possible to select a method suitable for various situations. As one of such methods of construction, the present invention provides a formwork system that is constructed to be used as a support for a formwork forming an underground structure, a formwork system developed to be coupled to the formwork, . When the upper and lower processes such as rebuilding of reinforcement and concrete pouring / curing and construction of the stratified structure such as reinforced concrete structure and crawler under construction are completed in the formwork system formed at the upper part of the strut, the entire system is lowered to lower the formwork, So that it can be used again in the next layer form without repetition.

The top-down construction method is used to construct an underground structure in a place where construction is unfavorable, such as downtown construction, and refers to a method of forming an underground structure while descending from the ground to the underground.

In the step-by-step construction process of the underground structure, the mold for the upper slab / beam is installed, concrete is poured into the mold, and the concrete is cured. When the upper layer slab / beam is cured, the upper slab / beam is demolded from the upper slab / beam and lowered while maintaining its shape. The lowered formwork is again used to form the lower slab / beam. Thus, in the top-down construction method, the mold is reused as it descends.

Patent Publication No. 2011-0138309 discloses a method of connecting a column member and a beam in a top-down construction method. In this method, a beam connector is welded to a circular steel pipe having the same thickness and outer diameter as the column section. Thus, conventionally, when a beam is connected to a column member or two beams are connected, a beam is drilled or welded, and a screw jack is used when the beam interval is wide.

However, when the beam is permanently bonded, welding is useful. However, if the welding is performed until temporary bonding, the work must be separately performed when the beam is separated later. Thus, the working efficiency is lowered and the cost is increased. In addition, if the hole is pierced or welded, the beam may be deformed.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems,

First, when joining horizontal members in forming a form, it is easy to join and separate,

Second, a method of forming a tower-down type underground structure capable of enhancing a bonding force between horizontal members is provided.

In order to accomplish the above object, the present invention provides a method of forming a tower-down type underground structure, comprising: installing a column member on a ground; Coupling a bracket member to the pillar member; Installing a lower strut in a lateral direction on an upper portion of the bracket member; Installing an upper strut on the upper side of the lower strut, the upper strut being perpendicular to the lower strut; Providing a first prismatic member on the upper strut and fixing the first prismatic member to the upper strut; Installing a first formwork panel in an area where at least a beam is installed on the first prismatic member; Installing a beam connecting and securing device on the upper strut in an area where the first formwork panel is not installed; Installing a support beam on top of the beam connection fixture; Installing a second prismatic member on the support beam and fixing the second prismatic member to the support beam; Installing a steel frame panel on the side of the second rectangular member area; Installing a second formwork panel on top of the second prismatic member area; Placing the reinforcing bars on the first and second formwork panels and the steel frame panel, curing the concrete after pouring the concrete; The bracket member is disassembled from the column member and the bracket member, the lower strut, the upper strut, the first angular member, the first formwork panel, the beam connecting fixture, the support beam, the second angular member, the steel frame panel, And a demolding step of separating the concrete from the concrete and lowering it along the column member.

In the method of forming a tower-down type underground structure according to the present invention, a member-joining apparatus can be used when fixing the first and second rectangular members to the upper strand and the support beams, respectively. The member coupling device can be constituted by a ring portion, a bending extension portion, and a coupling portion.

One side of the collar may house the first or second prismatic member and the other side may extend to the lower horizontal plane of the upper strut or the support beam.

The bend extension may extend from the collar and may extend horizontally to surround the lower horizontal plane of the upper strut or support beam and extend to the outer vertical plane of the upper strut or support beam.

The coupling portion may extend upwardly from the bending extension portion and may be upwardly bent while enclosing an outer vertical surface of the upper strut or the support beam so as to be elastically coupled to an outer vertical surface of the upper strut or the support beam.

In the method of forming a tower-down type underground structure according to the present invention, the beam connecting and securing apparatus may be composed of a body portion, an upper coupling portion, and a lower coupling portion.

The upper side coupling portion may include an upper side accommodating portion extending upward from the body portion and opening upwardly to fix the lower end of the support beam internally.

The lower coupling portion may include a lower receiving portion extending downward from the body portion and opened downward to fix the upper end of the upper strut brace.

In the method of forming a tower-down type underground structure according to the present invention, the beam connecting and fixing apparatus may have a plurality of coupling holes in the upper and lower receiving portions. In this case, the beam connecting fixture may include a fixing portion. One side of the fixing part is coupled to the upper or lower receiving part, and the other side is coupled to the supporting beam or the upper supporting bracket so that the supporting bracket or the upper supporting bracket can be fixed to the upper or lower receiving part.

In the method of forming a top down type underground structure according to the present invention, the beam connecting and fixing apparatus may include a gap adjusting member inserted between the fixing portion and the supporting beam or between the fixing portion and the upper strut.

In the method of forming a tower-down type underground structure according to the present invention, the trunk portion of the beam connecting and fixing apparatus can be separated into a lower trunk portion and an upper trunk portion. The lower body portion may have a plurality of engaging holes. The upper body part can be inserted into the lower body part and can slide up and down, and can have a plurality of engaging holes. A fixing member, for example, a bolt and a nut may be coupled to the coupling hole of the lower body portion and the upper body portion, so that the lower and upper body portions can be fixed at a predetermined height.

According to the tower-down type underground structure forming method of the present invention having such a configuration, when joining the H-shaped steel member, the angled member, and the like by using the member joining apparatus, only the joining portion is hooked to the side of the H- Since the joining is performed, joining is easy, and when the joining is performed, the joining portion having elasticity can be easily separated by separating the joining portion from the H-shaped steel.

According to the tower-down type underground structure forming method of the present invention having such a configuration, when the horizontal H-shaped beams are vertically connected and fixed using the beam connecting and securing apparatus, the upper and lower H- And it is easy to connect / fasten. Further, since the beam connecting and fixing device has a plurality of through holes, it is possible to flexibly cope with the gap between the upper and lower H-shaped steel bars, and a gap adjusting member, for example, a wooden pipe or a steel pipe It is possible to compensate for the additional gap difference so that the use range can be greatly increased in the field.

FIG. 1 illustrates a step of installing a column member in a method of forming a tower-down type underground structure according to the present invention.
FIG. 2 illustrates a trenching step in the method of forming a top-down type underground structure of the present invention.
FIG. 3A illustrates a step of installing a bracket member in the method of forming a tower-down type underground structure according to the present invention.
FIG. 3B illustrates a bracket member used in the method of forming a tower-down type underground structure of the present invention.
FIG. 4 illustrates a bottom strut installation step in the method of forming a top down type underground structure according to the present invention.
FIG. 5 illustrates an upper strand installation step in the method of forming a top-down type underground structure according to the present invention.
FIG. 6A illustrates a step of installing a first prismatic member in the method of forming a top-down type underground structure according to the present invention.
6B shows a member coupling device for fixing the first prismatic member to the upper strut in the method of forming a tower-down type underground structure of the present invention.
FIG. 7 illustrates a first die panel installation step in the method of forming a top down type underground structure according to the present invention.
8A illustrates a step of installing a beam connection fixture in the method of forming a tower-down type underground structure of the present invention.
8B to 8D show a beam connecting and fixing apparatus used in a method of forming a top down type underground structure according to the present invention.
FIG. 9 illustrates a support beam installation step in the method of forming a tower-down type underground structure according to the present invention.
10A shows a step of installing a second prismatic member in the method of forming a top-down type underground structure of the present invention.
FIG. 10B shows a member coupling device for fixing the second prismatic member to the support beam in the top down type underground structure forming method of the present invention.
11 shows a channel installation step in the method of forming a top-down type underground structure of the present invention.
12 shows a step of installing a steel frame panel in the method of forming a tower-down type underground structure of the present invention.
FIG. 13 illustrates a second formwork panel installation step in a top down type underground structure forming method of the present invention.
14 shows a step of installing a thermal insulation material in the method of forming a top-down type underground structure of the present invention.
FIG. 15 illustrates concrete pouring and curing steps in the top down type underground structure forming method of the present invention.
FIG. 16 illustrates a mold demolding step in the top down type underground structure forming method of the present invention.
FIG. 17 illustrates a step of lowering a formwork system in the method of forming a top-down type underground structure of the present invention.

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

FIG. 1 illustrates a step of installing a column member in a method of forming a tower-down type underground structure according to the present invention.

As shown in FIG. 1, in order to form an underground structure, the pillar member 110, which is a pillar member, may be installed on the ground 100 first. The column member 110 supports the structure self weight, working load and the like, and a plurality of the column members 110 are inserted into the ground and can be sequentially exposed according to the excavation of the ground. The column member 110 may be an H-shaped steel or the like.

FIG. 2 illustrates a trenching step in the method of forming a top-down type underground structure of the present invention.

As shown in Fig. 2, after the pillar member 110 is installed or inserted, the pillar member 110 can be further exposed by further excavating the ground, if necessary. In general, the tappet can be carried out when the form is further lowered.

FIG. 3A illustrates a step of installing a bracket member in the method of forming a tower-down type underground structure according to the present invention.

The bracket member 120 can be coupled to the pillar member 110 as shown in Fig. The bracket member 120 can be symmetrically coupled to two side surfaces of the pillar member 110. The bracket member 120 can be disassembled from the side of the pillar member 110 as it is being built into the basement layer, and then can be reused while being coupled again.

FIG. 3B illustrates a bracket member used in the method of forming a tower-down type underground structure of the present invention.

3B, the bracket member 120 may include a support plate 121 supported on the side surface of the column member 2 and a support 122 for coupling the support plate 121 in the outward direction. The supporting plate 121 is symmetrically coupled with two pillars 110 sandwiching the pillars 110. The pair of supporting plates 121 facing each other can be tightly fixed to the pillars 110 by the connecting bars 123. [ The connecting bar 123 is formed in the form of a bolt having threads formed on its outer surface and can be screwed to the supporting plate 121 using a nut. The support plate 121 may have a through hole through which the connection bar 123 passes.

The bracket member 120 may include a reinforcing bar 124 to reinforce the support of the support 122. The reinforcing bar 124 can be slidably coupled between the support plate 121 and the support base 122.

The bracket member 120 may have a brace 125 supporting the lower portion to increase the supporting force against the upper load. The braces 125 engage the side surfaces of the pillar members 110 and can be welded together.

When the bracket member 120 is dismantled, the brace 125 welded to the column member 110 is cut off first. Then, the nut connected to the connecting bar 123 is separated from the supporting plate 121 by the connecting bar 123. When the bracket member 120 is reinstalled, the bracket member 120 can be lowered along the pillar member 110 and coupled to the pillar member 110 at a desired point.

The bracket member 120 may be welded to the pillar member 110, in which case the connecting bar 123 may not be provided.

FIG. 4 illustrates a bottom strut installation step in the top down type underground structure forming method of the present invention, and FIG. 5 illustrates a top strut installation step in the top down type underground structure forming method of the present invention.

As shown in FIGS. 4 and 5, the lower strut 130 and the upper strut 140, which are the transverse strut and the longitudinal strut, may be stacked on the upper portion of the bracket 120. The lower strut 130 may be placed on the upper part of the bracket member 120 and the upper strut 140 may be placed on the upper side of the lower strut 130 so that the lower strut 130 is vertically placed. The lower strut 130 and the upper strut 140 can be coupled with the flange of the lower strut 130 and the upper strut 140 by bolts or the like. The lower strut 130 and the upper strut 140 may be H-shaped steel or the like.

FIG. 6A illustrates a step of installing a first prismatic member in the method of forming a top-down type underground structure according to the present invention.

As shown in FIG. 6A, a plurality of first prismatic members 150 may be provided on the upper strut 140. The first prismatic member 150 is for forming a beam bottom, and may be installed in a transverse direction or a longitudinal direction. The first prismatic member 150 may be fixed to the upper strut 140 by the member coupling device 151. The first prismatic member 150 has a rectangular cross section and may be formed of metal, wood, zinc, or the like.

6B shows a member coupling device for fixing the first prismatic member to the upper strut in the method of forming a tower-down type underground structure of the present invention.

6B, the first prismatic member 150 can be fixed to the upper strut 140 by a member coupling device 151, which includes a ring portion, a bend extension portion, And the like. The annular member surrounds the first prismatic member 150 and extends to the lower horizontal surface of the upper strut 140. The bending extension portion is extended from the hook portion and is bent at the lower horizontal surface of the upper strut 140 and extends to the outer vertical surface of the upper strut 140 along the lower horizontal surface. The coupling portion extends upward along the outer vertical surface of the upper strut 140. With such a configuration, the member joining device 151 can elastically couple the first prismatic member 150 to the upper strut 140. The coupling part is coupled to the outer vertical surface of the upper strut bracket 140 so as to elastically press the upper strut 140 so that the upper strut 140 and the first angular member 150 are firmly coupled to each other, . In the case where the upper strut bracket 140 is formed of H-shaped steel, the depressed portion formed in a bent (inverted S) shape at the engaging portion incorporates the outer vertical surface of the upper strut 140 so that the upper strut 140 can be more firmly coupled can do. As described above, the member joining device 151 is of a fitting type, not a welding, so that joining and separation are easy.

FIG. 7 illustrates a first die panel installation step in the method of forming a top down type underground structure according to the present invention.

As shown in FIG. 7, the first formwork panel 160 can be installed on the first prismatic member 150. The first form panel 160 may be fixed to the first prismatic member 150 using a piece or the like.

8A illustrates a step of installing a beam connection fixture in the method of forming a tower-down type underground structure of the present invention.

As shown in FIG. 8A, a beam connecting and securing device 170 may be installed on the upper strut 140. The beam connecting and fixing device 170 is for forming a slab, and a plurality of beams can be installed.

8B to 8D show a beam connecting and fixing apparatus used in the method of forming a tower-down type underground structure of the present invention.

As shown in FIG. 8B, the beam connecting and fixing device 170 can be composed of a body 171, a lower coupling portion 172, an upper coupling portion 174, and the like.

The body portion 171 can support a lower coupling portion 172 protruding downward and an upper coupling portion 174 protruding upward from the center of the beam connecting and fixing device 170.

The lower coupling portion 172 may extend downward from the body portion 171. [ The lower coupling portion 172 may be a 'U' shaped receiving portion having an upper end of the upper strut 140, for example, the entire shape of which is opened downward.

The upper engagement portion 174 may extend upward from the body portion 171. [ The upper joining portion 174 may be a 'U' -shaped receiving portion having a shape in which the lower end of the support beam 180 is embedded, for example, the entire shape is opened upward.

8B, the 'C' -holding portion of the lower-side coupling portion 172 and the '-c' -receiving portion of the upper-side coupling portion 174 may have different sizes. In the construction site, standardized square pipe, H-shaped steel, etc. of various sizes are used. The 'U' -holding portion of the lower coupling portion 172 and the upper coupling portion 174 is formed in a different size Even when the size of the upper strut 140 and the size of the support beam 180 are different, it is possible to flexibly cope with the operation without additional work such as size adjustment.

8C, the beam connecting and securing apparatus 170 may further include a fixing unit 175 for fixing the upper strut 140 or the supporting beam 180. [

The fixing part 175 may be formed in an "a" shape so that the upper end brace 140 or the end of the supporting beam 180 can be tightly fixed to the inner side. The fixing portion 175 can be screwed to the lower engaging portion 172 or the upper engaging portion 174. A plurality of coupling holes H are formed in the fixing portion 175, the lower coupling portion 172 and the upper coupling portion 174 and the bolts B are inserted into the coupling holes H, The nut (N) can be coupled. Since the fastening portion 175 is screwed, the fastening portion 175 can be easily engaged and disengaged and a plurality of fastening holes are provided perpendicularly to the lower engaging portion 172 and the upper engaging portion 174, Or the thickness of the end portion of the support beam 180, that is, the thickness of the flange.

As shown in FIG. 8C, the beam connecting and fixing device 170 can be configured such that the height of the trunk portion 171 can also be adjusted. The body portion 171 may be separated into a lower body portion and an upper body portion, and upper and lower body portions may be inserted into each other to be slidable up and down. The lower body portion and the upper body portion are provided with a plurality of upper and lower through holes, and the lower body portion and the upper body portion can be fixed to a certain height by screwing a bolt and a nut into the coupling hole.

As shown in FIG. 8D, the beam connecting and fixing device 170 may further include a gap adjusting member 177. [

The gap adjusting member 177 can be used to correct the height difference between the upper strut 140 and the supporting beam 180. [ The gap adjusting member 177 may insert one or a plurality of the gap adjusting members 177. [ It may be preferable to use a rectangular pipe as the gap adjusting member 177.

FIG. 9 illustrates a support beam installation step in the method of forming a tower-down type underground structure according to the present invention.

As shown in Fig. 9, a support beam 180 can be provided on the beam connecting and securing apparatus 170. As shown in Fig. The support beam 180 can be firmly coupled to the beam connection and fixing device 170 by bolts or the like. The support beam 180 may be disposed to correspond to the width of the beam, and may be arranged in parallel with the lower strut 130. The support beam 180 may be an H-shaped steel or the like.

10A shows a step of installing a second prismatic member in the method of forming a top-down type underground structure of the present invention.

As shown in Fig. 10A, the second angular member 190 may be provided on the support beam 180. [ The second prismatic member 190 is for forming a slab having a thickness smaller than that of the beam, and may be installed perpendicularly to the support beam 180). The second prismatic member 190 can be fixed to the support beam 180 using a member coupling device or the like. The second prismatic member 190 has a rectangular cross section and may be made of metal, wood, synthetic resin, composite or the like.

FIG. 10B shows a member coupling device for fixing the second prismatic member to the support beam in the top down type underground structure forming method of the present invention.

The member coupling device 151 of FIG. 10B is the same as the member coupling device 151 of FIG. 6B, and the detailed description thereof is replaced with the description of FIG. 6B.

11 shows a channel installation step in the method of forming a top-down type underground structure of the present invention.

As shown in FIG. 11, the channel 200 can be installed on the first formwork panel 160 along the boundary of the area of the second prismatic member 190. The channel 200 can be deformed or removed by angles, angular members or the like depending on the form of the formwork panel, and can be selectively installed as needed.

12 shows a step of installing a steel frame panel in the method of forming a tower-down type underground structure of the present invention.

As shown in FIG. 12, the steel frame panel 210 is for forming side surfaces of the beam, and may be installed up and down along the boundary of the area of the second rectangular member 190.

FIG. 13 illustrates a second formwork panel installation step in a top down type underground structure forming method of the present invention.

As shown in Fig. 13, the second formwork panel 220 can be installed on the area where the second prismatic member 190 is installed. The second form panel 220 may form a slab area.

14 shows a step of installing a thermal insulation material in the method of forming a top-down type underground structure of the present invention.

The heat insulating material 230 may be provided on the first mold panel 160, the channel 200, the steel frame panel 210, and the second mold panel 220, as shown in FIG. The heat insulating material 230 can be selectively applied to a portion where the outdoor air and the heat insulation are required, such as a one-story ground floor.

FIG. 15 illustrates concrete pouring and curing steps in the top down type underground structure forming method of the present invention.

As shown in FIG. 15, a reinforcing bar is placed on the heat insulating material 230 and the concrete 240 is poured, and then the concrete is cured for a certain period of time. In the case where the heat insulating material 230 is not installed, reinforcing rods can be placed on the first and second form panels 160 and 220 and the steel frame panel 210 to pour concrete.

FIG. 16 illustrates a mold demolding step in the top down type underground structure forming method of the present invention.

As shown in FIG. 16, after the curing time has elapsed, structures other than the heat insulating material 230 and the concrete 240, that is, the molding system, are demolded from the concrete 240 and the heat insulating material 230. If the heat insulator 230 is not installed, the form system demolds from the concrete 240.

FIG. 17 illustrates a step of lowering a formwork system in the method of forming a top-down type underground structure of the present invention.

As shown in Fig. 17, the demoulded formwork system is moved downward along the pillar member 110 and is again secured to the pillar member 110 to form the next pile.

Although the present invention has been described based on examples, it is intended to exemplify the present invention. Those of ordinary skill in the art will appreciate that variations and modifications may be made thereto based on the above embodiments. However, since the scope of the present application is determined by the claims below, such variations and modifications can be construed as being included in the following claims.

100: ground 110: pillar member
120: Bracket member 121: Support plate
122: support 123: connection bar
124: reinforcing bar 125: brace
130: lower strut 140: upper strut
150: first prismatic member 151: member joining device
160: first form panel 170: beam connecting fixture
171: body portion 172:
174: upper coupling portion 175:
177: Spacing member 180: Support beam
190: second rectangular member 200: channel
210: steel frame panel 220: second formwork panel
230: Insulation material 240: Concrete
B: Bolt H: Coupling hole
N: Nut

Claims (6)

A method of forming an underground structure in a top down manner,
Installing a column member on the ground;
Coupling a bracket member to the column member;
Providing a lower strut in a lateral direction on an upper portion of the bracket member;
Installing an upper strut on the lower strut so as to be perpendicular to the lower strut;
Attaching a first prismatic member to an upper portion of the upper strut and fixing the first prismatic member to the upper strut;
Installing a first formwork panel in an area where at least a beam is installed on the first prismatic member;
Installing a beam connecting and securing device on an upper portion of the upper strut in an area where the first formwork panel is not installed;
Installing a support beam on the beam connecting fixture;
Providing a second prismatic member on the support beam and fixing the second prismatic member to the support beam;
Installing a steel frame panel on the side of the second prismatic member region;
Installing a second formwork panel on top of the second prismatic member area;
Placing reinforcing bars on the first and second formwork panels and the steel frame panel, curing the concrete after pouring the concrete; And
The bracket member is disassembled from the pillar member and the bracket member, the lower strut, the upper strut, the first angular member, the first formwork panel, the beam connecting and securing device, the support beam, the second angular member, And a demolding step of separating the panel from the concrete and descending along the column member,
The beam connecting and fixing device
Body portion;
An upper coupling portion extending upward from the body and having an upper receiving portion which is opened upward to internally fix the lower end of the supporting beam and has a plurality of coupling holes;
A lower coupling portion extending downward from the body and having a lower receiving portion that is opened in the lower direction to internally fix an upper end of the upper strut and has a plurality of coupling holes; And
And a fixing part for fixing the support beam or the upper strut bracket to the upper or lower receiving part, wherein one side is coupled to the upper or lower receiving part, and the other side is coupled to the supporting beam or the upper strut. A method of forming an underground structure in a top down manner. The method according to claim 1,
A member coupling device is used for fixing the first and second rectangular members to the upper strut and the support beam,
The member-
One side of which comprises the first or second prismatic member and the other side of which extends to the lower horizontal plane of the upper strand or supporting beam;
A bending extension portion extending from the annulus and extending horizontally to surround the lower horizontal surface of the upper strut or the support beam and extending to an outer vertical surface of the upper strut or the support beam; And
And an engaging portion extending from the bent extension portion and bending upward to surround the outer vertical surface of the upper strut or the support beam and elastically coupling with the outer vertical surface of the upper strut or the support beam. Method of Underground Structure Formation. delete delete The apparatus of claim 1, wherein the beam connecting and securing device
And a gap adjusting member inserted between the fixing portion and the support beam or the upper strand. [2] The apparatus according to claim 1,
A lower body portion having a plurality of engaging holes;
An upper body part inserted into the lower body part and sliding up and down, and having a plurality of engaging holes;
And a fixing member coupled to the coupling holes of the lower body and the upper body to fix the lower and upper bodies at a predetermined height.

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