KR102316321B1 - Connecting structure of unit plate for dispersing and supporting a vertical load and horizontal load and contruction method thereof - Google Patents

Abstract

The present invention relates to a structure for connecting a multi-layered plate that disperses and supports vertical and horizontal loads and a construction method using the same, and more particularly, to a temporary installation. By doing so, while coping with vertical loads and supporting vertical and horizontal loads while the multi-layered board is installed, the multi-layered board connection of the underground structure that supports the distribution of vertical and horizontal loads, which increases space utilization by forming a through hole using the split board in the multi-layered board It relates to a structure and a construction method using the same.

Description

Connecting structure of unit plate for dispersing and supporting a vertical load and horizontal load and contruction method thereof

The present invention relates to a structure for connecting an underground structure for distributing vertical and horizontal loads and a construction method using the same, and more particularly, to a temporary installation. By configuring to respond to horizontal loads, it supports horizontal loads while coping with vertical loads while the multi-layered board is installed. Underground structures that support the vertical and horizontal loads that increase space utilization by forming through holes in the multi-layered board using the split board are distributed. It relates to a multi-walled plate connection structure and a construction method using the same.

In general, when a road or land is dug up for subway construction or underground facility construction, the dug plate has been used to cover the excavated soil so that vehicles or pedestrians can smoothly run or walk on the road.

And when constructing an underground structure by the reverse punching method, after constructing the main column retaining wall such as H-beam, earth plate, CIP (Cast in-Place Pile), SCW (Soil Cement Wall), etc., excavate the inside of the retaining wall. When constructing slab construction to distribute and support vertical and horizontal loads such as earth pressure transmitted to the retaining wall sequentially toward the lower floor of the underground structure, struts such as beam-type structures should be applied to the retaining wall and the slab of the basement floor. The earth pressure was supported by installing in between.

The present invention is to apply a multilayer plate that enables safer and more convenient installation and disassembly of the strut of the part without a slab in the reverse punching method, and distributes and supports vertical and horizontal loads.

The deck plate temporarily installed in the underground structure used up to now has a flat rectangular parallelepiped shape. In order to withstand vertical load or external impact, the multi-layered plate installed on the H-beam was fixed by welding or various fixing devices.

For example, in Korean Utility Model Publication No. 20018-0000626, which is a 'fixing device for a multi-layered plate' for fixing a multi-layered plate to an H-beam, a fastening bracket formed by bending a plate and a part of the support is located between the fastening bracket and the bottom of the multi-layered plate Including a fastening member for fixing the fastening bracket to the multilayer plate so as to prevent friction or shock as well as friction between the multilayer plate and the support to prevent noise or wear, but the multilayer plate installed here is on the H-beam It is not a structure that responds to the vertical load coming down from the top while being firmly fixed and supports the horizontal load.

In addition, the 'concrete structure for covering construction', which is the Republic of Korea Patent Registration No. 0818733, has a fitting bar provided on the side of the concrete body forming the cover plate to reduce noise or increase durability when a vehicle passes by, and the fitting bar of the concrete body is formed Fitting grooves are provided on the opposite side and they are connected to each other, but this structure also corresponds to a vertical load and is not a structure for distributing support together with a horizontal load.

In addition, the Republic of Korea Patent Publication No. 1330177, 'a sheet using a steel tension sheet', is to reduce noise and vibration from a vehicle by connecting a tension member to the inside of a plurality of sheeting plates to remove a gap occurring between the sheeting plates. It is not a structure to support distributed horizontal load.

That is, in the related art, the cladding plate fixedly installed on the H-beam is installed to secure the passage of vehicles or pedestrians or a work space required for a certain amount of work. It was not structured to support distributed vertical and horizontal loads.

Republic of Korea Utility Model Publication No. 20018-0000626 (published on March 06, 2018) Republic of Korea Patent Publication Registration No. 0818733 (Registered on March 26, 2008) Republic of Korea Patent Publication Registration No. 1330177 (Registered on November 11, 2013)

This was made in consideration of the various problems of the prior art as described above, and its purpose is to provide an increase in the utilization of the multi-layered board by distributing the vertical and horizontal loads to the multi-layered board responsible for the vertical load.

In addition, another object of the present invention is to form a through hole in a multi-layered board that receives a horizontal load by using a divided multi-layered board, so that the multi-layered board disperses and supports vertical and horizontal loads while allowing vertical structures such as vertical steel pillars to pass through the through-hole to improve space utilization. It is to provide heightening.

In addition, another object of the present invention is to install a multilayer plate on a beam-shaped structure in a part where a permanent horizontal structure is not formed, such as a core or a lamp, and form a slab on the beam-shaped structure in the part where the permanent horizontal structure is formed to form an underground structure. The purpose of construction is to provide a stable construction by allowing the slab and the slab to support the horizontal load such as earth pressure transmitted from the retaining wall.

In addition, another object of the present invention is to support the horizontal load such as earth pressure transmitted from the retaining wall, so it is not necessary to construct a separate earth anchor or to significantly reduce the use of braces, so that the construction due to the simplification of materials is simplified. is to provide

According to the present invention, the multi-deck plate connection structure of an underground structure that distributes and supports vertical and horizontal loads is installed on the upper flange surface of a horizontal beam-shaped structure, the upper part is formed of a steel plate, and the lower outer periphery of the steel plate is a section steel forming an edge. In order to disperse and support the vertical load and the horizontal load applied from the outside of the multi-layered plate, at least one fixing hole is formed on one side of the multi-layered plate; a through hole formed in the lower section of the fixing hole; a nut hole formed on the other side of the hollow plate opposite to the through hole; It is characterized in that it is formed with a fixing bolt that is coupled to the nut hole through a fixing hole in a state in which the lining plate and the lining plate are in close contact with each other, thereby coupling the lining plate to each other.

In addition, the construction method using the multi-layered plate connection structure of the underground structure that distributes and supports vertical and horizontal loads in the underground reverse drilling method in which the multi-layered board is installed is,

(1) burying a plurality of vertical steel frame members in the excavated ground at a location spaced a certain distance from the retaining wall;

(2) installing a beam-shaped structure on the upper end or side of the vertical steel frame member;

(3) a step of continuously installing a duplex plate up and down or left and right on the upper flange surface of a horizontal beam-type structure installed in a part where a permanent horizontal structure is not formed;

(4) forming a slab by pouring concrete into a space between the cladding plate and the retaining wall and a portion where a permanent horizontal structure is formed;

(5) excavating the lower part of the slab and the slab;

(6) repeating steps (2) to (5) to the lower part of the foundation;

(7) forming a floor layer including a foundation and forming a basement outer wall and a permanent vertical material;

(8) It is characterized in that it comprises the steps of removing the beam-shaped structure supporting the multilayer plate sequentially in the direction from the lowest layer to the upper layer, and removing the vertical steel frame member in the part where the permanent horizontal structure is not formed.

The present invention has the effect of increasing the utilization of the multilayer board by distributing the vertical load and the horizontal load to the multilayer board responsible for the vertical load.

In addition, the present invention forms a through-hole in a multi-layered plate that receives a horizontal load by using a split-walled plate, so that a vertical structure such as a vertical steel column passes through the through-hole while the multi-layered plate supports vertical and horizontal loads in a distributed manner. have.

In addition, the present invention provides a beam-shaped structure in a part where a permanent horizontal structure is not formed by installing a multilayer plate supporting distributed vertical and horizontal loads, forming a slab in a part where a permanent horizontal structure is formed, and constructing an underground structure. Therefore, it is possible to stably support the horizontal load such as earth pressure transmitted from the retaining wall, thereby improving workability.

In addition, the present invention supports the horizontal load such as earth pressure transmitted from the retaining wall, and does not need to be constructed as an earth anchor or use of braces As it can greatly reduce the cost, there is a simple effect of construction due to the simplification of materials.

1 is an exploded perspective view of an embodiment of the present invention;
Figure 2 (a) is a front cross-sectional view of a double-deck plate in which a steel plate and a 'ㅁ'-shaped section are combined in an embodiment of the present invention, and Fig. 2 (b) is a steel plate and a 'C'-shaped section in addition to the steel plate in an embodiment of the present invention. Front sectional view of a veneer plate with a plate attached
3 to 5 are an exploded perspective view in which a multi-layered board and a divided multi-layered board are installed between beam-shaped structures in the present invention.
Figure 6 is an exploded perspective view in which a partition plate with a pad attached thereto is installed between beam-shaped structures in the present invention;
7 (a), (b) is an elevation view in which a support beam for a split deck plate is installed between beam-shaped structures in the present invention.
Figure 8 (a), (b) is a rear perspective view of the divided cladding plate in the present invention
9 to 14 are plan cross-sectional views showing a state in which the fixing bolt is fastened to the nut hole in order to connect the multi-layered plate and the multi-layered plate according to the present invention;
15 to 22 are state diagrams of the process of constructing an underground structure according to the present invention.
23 (a) is an exploded perspective view in which the slab reinforcing bar is coupled to the slab reinforcing plate to which the 'ㅁ' shaped section steel is coupled in the present invention, and FIG. This combined perspective view
24 is a cross-sectional view in which a clad plate and a clad plate attached to a steel plate and a 'C'-shaped section are combined in the present invention.
25 is a cross-sectional view of a state in which a cover having a protrusion formed in the upper center of the beam-shaped structure is installed in the present invention.
Figure 26 (a) is a cross-sectional view of a state in which the pedestal on which the second support beam is mounted is fixed to the first support beam in the present invention, and Figure 26 (b) is a perspective view of the pedestal on which the locking protrusion is formed in the present invention.

In detail, the duplex plate 110 is installed and fixed to the upper surface of the structure 300 in the form of a beam. The beam-shaped structure 300 is made of a steel frame like an H-beam, or is made of various materials having a beam function, such as a reinforced concrete beam made of reinforced concrete, or a composite beam in which a steel pipe is filled with concrete. As described in the prior art, the multi-walled plate 110 is mounted and fixed to the beam-shaped structure 300, and thus, detailed illustration thereof is omitted as various methods are typically installed. Hereinafter, an embodiment of the present invention will be described in detail based on the accompanying drawings.

1 is an exploded perspective view of a multi-layered plate of an embodiment of the present invention, and FIG. 2 (a) is a front cross-sectional view of a multi-layered plate in which a steel plate and a 'ㅁ'-shaped section are combined in an embodiment of the present invention, and FIG. 2 (b) is the present invention In one embodiment, it is a front cross-sectional view of a steel plate and a cladding plate attached to a 'C'-shaped section steel.

The multilayered plate connection structure 100, which is a preferred embodiment of the present invention, includes a steel plate 112 that forms an upper portion of the continuously installed multilayered plate 110, a section steel 111 that forms a rim that is the lower outer periphery of the steel plate, and a multilayered plate 110 of The fixing hole 120 formed on one side, the fixing hole 120, the through-hole 142 formed in the lower section steel 111, the nut hole 130 formed in the other side multi-layered plate 110 opposite to the through-hole 142, It is coupled to the nut hole 130 through the fixing hole 120 and is composed of a fixing bolt 140 for coupling the multilayer plate 110 and the multilayer plate 110 to each other. Since the fixing hole 120 is formed to be opened upward, it is easy to insert the fixing bolt 140 to facilitate the operation. In addition, if necessary, it is possible to reinforce the strength of the laminated plate 110 by pouring concrete on the top of the steel plate 112 forming the upper part of the laminated plate 110 .

The inlet of the nut hole 130 forms a taper 134 to be wider than the diameter of the fixing bolt 140 toward the outside so that coupling with the fixing bolt 140 is easy, as described in FIG. 10 below. When screwing into the nut hole 130 with 140, even when the central axis of the fixing bolt 140 and the central axis of the nut hole 130 do not exactly match, the fixing bolt 140 is taper 134 by the The nut hole 130 is naturally approached and screwed together, so that the work is quick, and even if the double hole plate 110 and the double hole plate 110 are not exactly aligned with each other when combined, the fixing bolt 140 is the nut hole 130 . By being guided to the center of the nut hole 130 precisely by the taper 134 , there is an effect that the duplexed plate 110 and the duplexed plate 110 are accurately coupled.

The section steel 111 coupled with the steel plate 112 constituting the double-walled plate 110 uses a 'ㅁ' shape as shown in FIG. 2(a) or a 'c' shape as shown in FIG. 2(b), In the case of using the 'c'-shaped section steel 111 as shown in b), the open portion as shown in FIGS. 23(b) and 24 in the 'c'-shaped section steel 111 is directed toward the inside of the center of the double-walled plate 110. The fixing bolt 140 passes while forming a through hole 142 among the 'C'-shaped open parts to form a through hole 142 through which the steel plate 112 and the welding are integrated and the fixing bolt 140 passes. A small back plate 117 with a hole formed therein is fixed to the 'c'-shaped open part by welding, and partly in the portion where the nut hole 130 and the through-hole 142 are located among the 'c'-shaped section steel 111 . Creates a 'ㅁ' shape.

Since the duplex plate 110 is continuously arranged up and down or left and right and coupled through the fixing bolts 140, the structure is simplified and the workability is excellent. In addition, the divided multilayer plate 160 to be described below has the same structure only different in size compared to the multilayer plate 110 in order to form a through hole. ,

The multi-layered plate 110 is continuously arranged up and down or left and right and coupled through the fixing bolts 140, so that the structure is simplified and the workability is excellent. It is structured to bear the load.

3 to 5 are separated perspective views in which the multi-layered board 110 and the divided multi-layered board 160 are installed between the beam-shaped structures 300 in the present invention. In the installed configuration, a through-hole 180 as a through-space is required for the passage of a vertical steel column installed vertically on the installed multi-layered plate 110, and the area of the through-hole 180 is smaller than the area of the multi-layered plate. In a small case, the through-hole 180 is formed in a portion different from the multi-layered plate 110 and the divided multi-layered plate 160 by installing the divided multi-layered plate 160 having a smaller area than the multi-layered board 110 .

In general, the size of the multi-layered plate 110 is varied and used depending on the site where the multi-layered plate 110 is installed. Most of the multi-layered board 110 has a rectangular shape with a vertical side longer than a square shape than a square shape.

Pad 230 having a size equal to or higher than the height of the end 171 of the first support 172 when the divided deck 160 is installed on the first support beam 170 mounted on the beam-shaped structure 300 . However, the width of the end 171 of the first support 172 mounted on the structure 300 is excluded, so that the width of the end 171 of the first support 172 mounted on the structure 300 is excluded. A stepped groove 161, which is a space for accommodating the , is formed, and accordingly, the divided decking plate 160 can be easily installed on the first support beam 170 mounted on the beam-shaped structure.

That is, in order to form a through-hole 180 for installing a vertical structure such as a vertical steel column that vertically penetrates the multi-layered plate 110 continuously installed on the beam-shaped structure 300, the multi-layered plate 110 and the multi-layered plate 110 ) in order to install the split decking plate 160 between the beam-shaped structures 300 in the right angle direction to install the first support beam 170, the first support beam 170 is a lightweight truss structure or light section steel. It includes a first support 172 made of a structure. In the divided decking plate 160, a stepped groove 161 is formed by a pad attached to the lower portion of the divided decking plate 160, and for the coupling of the divided decking plate 160 and the multilayered plate 1100, the divided decking plate 160 is the multilayered plate. The fixing hole 120 , the through hole 142 , the nut hole 130 , and the fixing bolt 140 having the same configuration as the 110 are provided, and the coupling method is also described above and is the same as the coupling method of the double hole plate 110 .

Figure 3 is for removing one divided deck 160 if necessary after two divided unit bottoms 160 are installed in advance between the multi-layered plate 110 and the multi-layered plate 110, and FIGS. 4 and 5 are in various sizes. It is for installing the divided multilayer plate 160 while forming the through hole 180, first, leaving a distance equal to the width in which the divided multilayer board 160 is installed in the direction of the beam-shaped structure 300, and then the multilayer board 110 to the left and right. After placing the end 171 of the first support 172 in the place where the stepped grooves 161 formed on the lower surfaces of both ends of the divided cladding plate 160 installed in the direction of the beam-shaped structure 300 are positioned after placing the The divided multilayer plate 160 is installed on the upper part, and then the multilayer board 110 and the divided multilayer board 160 are coupled with a fixing bolt 140 .

That is, a pad 230 is attached to the lower portion of the divided-walled plate 160 installed on the upper surface of the beam-shaped structure 300 , and thereby the first supporters are attached to both ends of the pad 230 attached to the divided-clothed plate 160 . (172) Since the stepped groove 161 capable of accommodating the end 171 is formed, the divided duplex plate 160 can be seated while maintaining the horizontal level on the first support beam 170 .

As described above, by attaching the pads 230 to the lower surfaces of both ends of the multi-layered board 110 and the divided multi-layered board 160, the heights of the multi-layered board 110 and the divided multi-layered board 160 can be uniformly matched, thereby further improving the workability. .

4 is an exploded perspective view in which a plurality of divided cladding plates having different sizes are installed on the first and second supporting beams mounted to form a through hole between the beam-shaped structures in the present invention. The through-hole 180 is formed in the multi-layered plate 110 installed on the upper surface of the beam-shaped structure 300, and a plurality of divided multi-layered plates 160 and 160 ′ of different sizes are installed accordingly, and the multi-layered plate 110 is dismantled and removed. A first support beam 170 and a second support beam 242 are installed in order to install a plurality of divided deck plates 160 and 160 ′ in the space of .

To this end, a pad 230 corresponding to the height of the first support beam 172 is attached to the lower surface of one end of the divided panel 160 , and the length of the pad 230 attached to the divided panel 160 is determined by the length of the divided panel. It is formed by subtracting the width of the first support 172 from the entire length of the end of 160 and is positioned between the first support 172 and the first support 172, and the other side adjacent to the divided decking plate 160 A plurality of pads 230 having the same length as that of the multi-layered plate 110, or a plurality of pads 230 formed in a circular or square shape although not specifically shown in the drawing, are attached to the lower surface of the multi-layered plate 110 as well. In addition, in installing two or more of the plurality of divided multilayer boards 160 ′ having different sizes of the divided multilayer board 160 , the divided multilayer board 160 ′ is smaller in size than the divided multilayer board 160 . Install the 2 support beams 242. Since the height of the upper end of the second support beam 242 and the upper end of the first support beam 170 are the same, the pad 230 is not attached to the divided decking plate 160 ′ installed on the second support beam 242 . In addition, as shown in FIG. 5 below, a second support beam 242 for supporting one end of the divided decking plate 160 is installed in order to reinforce the supporting force for the divided decking plate 160 .

5 shows a through-hole 180 formed between the divided-clad plate 160 and the divided-clad plate 160. The through-hole 180 is in the center and the divided-clad plate 160 is mounted on the first support 172, respectively. and the second support beam 242 is mounted on the first support beam 170 in the parallel direction of the beam-shaped structure 300 in the front and rear directions of the through hole 180 to support one end of each divided deck 160 . As one thing, the second support beam 242 has a function of reinforcing the support force for the divided public plate 160 .

6 is a cross-sectional view of a state in which the pad is attached to the lower surface of the divided multilayer plate.

In order to install the split decking plate 160 on the upper surface of the beam-shaped structure 300, the end 171 of the first support 170 is mounted on the horizontal beam-shaped structure 300 and the first support ( On the upper portions of both ends 171 of 170), the divided decking plate 160 is installed using the stepped grooves 161 of the divided decking plate 160. That is, to the lower surfaces of both ends of the multi-layered plate 110 and the divided multi-layered plate 160, the pads 230 corresponding to the height of the end 171 of the first support 172 constituting the first support beam 170 are attached, respectively, The length of the pad 230 attached to the divided clad plate 160 seated on the upper end 171 is formed by subtracting both ends 171 from the total length of the divided clad plate 160, and the divided clad plate 160 A pad 230 having the same length as that of the multi-layered plate 110 is attached to the lower surface of the hollow plate 110 on the other side, or a plurality of pads 230 ′ formed in a circular or square shape as shown in FIG. 8(b) are attached.

7 (a), (b) is an elevation view in which a first support beam for supporting a divided deck plate is installed between beam-shaped structures in the present invention, and FIG. The first support beam 170 is a structure made of a light truss-shaped steel, and FIG. 7(b) is a structure in which the first support beam 170 is made of a light-weight steel beam. It is formed in a 'T' shape for In addition, although not specifically shown in the drawing with respect to the second support beam 242, the second support beam 242 is also made of a lightweight truss structure or a lightweight section steel structure as described above, thereby appropriately responding to the external force applied from the periphery. By reducing the weight, it is possible to safely and quickly construct the product while increasing the economic feasibility.

8 (a), (b) is a rear perspective view of the divided multilayer plate in the present invention, as shown in FIG. 8 (b), a pad 230 having a constant length as shown in FIG. ) instead, a circular pad 230' is attached as shown in FIG. 8(b). This also attaches a circular pad 230 'inward from the edge of the divided deck plate 160 to a stepped groove 161, which is a space that can accommodate the end 171 of the first support 172, inwardly. , the shape of the pad may have various shapes such as a square in addition to the circular pad 230 ′. In addition, pads 230 may be installed at both ends of the multi-layered board 110 to have the same height as the divided multi-layered board 160 .

9 to 14 are plan cross-sectional views showing a state in which the fixing bolt is fastened to the nut hole in order to connect the multi-layered plate and the multi-layered plate in the present invention. The first fastening nut 131 or the second fastening nut 132 formed in the ut bottom plate 110 formed with a section steel 111 made of a rectangular steel pipe and a nut hole 130 of the double hole plate 110 facing it. ) is a planar cross-sectional view of a state in which the fixing bolt 140 is fastened and fixed.

9 to 11 show a through-hole 142 in a section steel 111 made of a rectangular steel pipe forming an edge on the outer peripheral surface of the multi-layered plate 110 in order to couple the multi-layered plate 110 and the multi-layered plate 110 to each other, and the through-hole 142 is formed. At the inlet of the ball 142, a through hole 141 having a diameter larger than the screw thread of the through bolt 140 and smaller than the screw thread of the through bolt 140 is installed so that the screw thread of the fixing bolt 140 passes in a spiral. Although not shown in detail in the drawings, when using the 'C'-shaped section steel 111 described above instead of the quadrangular 'ㅁ'-shaped section steel 111 constituting the double-walled plate 110, the fixing bolt 140 passes through In order to form the through hole 142, as shown in FIG. 24, a small back plate 117 having a hole through which the fixing bolt 140 passes while forming the through hole 142 among the open portions of the 'c' shape is formed in a 'c' shape. It is fixed by welding to the open part of the 'C'-shaped section steel 111 to partially make a 'ㅁ' shape, which is the same shape as the 'ㅁ'-shaped section steel 111 .

A nut hole 130 is formed at a position corresponding to the through hole 142 on the other side of the multi-layered plate 110 facing the multi-layered plate 110 in which the fixing hole 120 and the through-hole 142 are formed, and the nut hole ( A first fastening nut 131 is installed on the inner side of 130). The coupling of the multi-layered plate 110 and the multi-layered plate 110 is a nut hole 130 of the multi-layered plate 110 on the other side through the through hole 142 of the one side of the multi-layered plate 110 in which the fixing bolt 140 is formed with a fixing hole 120 . ) is screwed with the first fastening nut 1310.

Here, the fixing bolt 140 is formed with a screw thread at the end, and the middle part has a smaller diameter than the screw thread while removing the screw thread, and a square bolt head is formed at the start part.

As shown in FIG. 10, even if the center line of the through hole 142 and the center line of the nut hole 130 do not coincide with the center line of the through hole 142 and the center line of the nut hole 130, the double hole plate 110 and the multi hole plate 110 are placed so that they do not coincide with each other. ) by the taper 134 formed at the inlet, the double-walled plate 110 and the multi-walled plate 110 are naturally coupled to each other during the fastening process of the fixing bolt 140 and the nut hole 130 . That is, the end of the fixing bolt 140 is formed in a thread shape with a length (ℓ) shorter than the length (L) of the through hole 142, and the middle portion of the fixing bolt 140 is formed straight with a diameter smaller than the screw thread. The head of the fixing bolt 140 is formed in a square shape. The through-hole 141 forming the entrance of the through-hole 142 of the multilayer plate 110 is formed so that the screw thread of the fixing bolt 140 passes through the spiral, and the inner diameter of the through hole 142 is the thread of the fixing bolt 140 . It is formed larger than the diameter and when the screw thread of the fixing bolt 140 passes through the through hole 141, the middle part of the fixing bolt 140 has room in the vertical direction, left and right, and is formed at the entrance of the fastening nut 131 of the other side plate 110. It is naturally fastened by the taper 134 . In addition, since the fixing bolt 140 does not easily deviate from the through hole 142 of the fixing hole side multi-layered plate 110 by the through hole 141, the fixing bolt 140 is temporarily assembled through the through hole 141 in advance during transportation. When assembling the cover plate 110 and the cover plate 110, which is the main construction, after the fixing bolt 140 is already in a temporary assembly state, there is an advantage that can be performed more quickly.

More specifically, the inlet portion of the nut hole 130 that is abutted against the other side plate 110 forms a taper 134 that is larger than the diameter of the fixing bolt toward the outside to form a taper 134 , which is abutted with the nut hole 130 . Even when the central axis of the through hole 142 and the central axis of the nut hole 130 do not exactly match, the fixing bolt 140 is naturally coupled to the nut hole 130 by the taper 134, thereby making the double hole plate 110. And even when the multi-layered plate 110 is not correctly placed, not only can the multi-layered plate 110 and the multi-layered plate 110 be accurately combined by the taper 134 formed in the nut hole 130, but also the construction can be performed more quickly and accurately. The thread of the fixing bolt 140 passes through the through hole 141 in a state in which the through hole 141 and the first fastening nut 131 are respectively formed in close contact with each other. Since the middle portion of the fixing bolt 140 is formed with a smaller diameter than the through hole 141, the fixing bolt 140 can freely move up and down, left and right. In this state, the fixing bolt 140 is easily fastened to the first fastening nut 131 of the nut hole 130 formed in the nut hole 130 on the other side by using the taper 134 of the nut hole 130 . In this process, since the multilayer plate 110 and the multilayer plate 110 are fixed, the assembling property is improved and the construction time can be shortened. It does not come off during transportation, so it is possible to prevent the risk of loss.

12 to 14 show that the fixing bolt 140 is fastened to the nut hole 130 having the second fastening nut 132 and the guide tube 133 in the present invention, and the through hole of the double hole plate 110 ( The fixing bolt 140 passing through 141 passes through the guide tube 133 of the nut hole 130 formed on the other side vented plate 110 and is fastened with the second fastening nut 132 integrally formed with the guide tube 133. It is to be coupled to each other the duplex plate (110). The screw thread of the nut hole 130 fastened with the fixing bolt 140 is formed in the second fastening nut 132 coupled to the outer side of the guide tube 133 without being formed inside the nut hole 130 , and the threaded nut is formed. The second fastening nut 132 of the ball 130 is fixed by welding to the outer surface of the 'ㅁ'-shaped section steel 111 that forms the edge of the double-walled plate 110 , and the fixing bolt 140 and the nut hole 130 . ) of the second fastening nut 132 is not only the same as the method described above, but also the same as described above with the 'C'-shaped section steel 111 .

The following describes in more detail a construction method of an underground structure using a multi-layered plate connection structure that disperses and supports the vertical and horizontal loads configured as described above.

15 to 22 are state diagrams of the process of constructing an underground structure according to the present invention. First, as shown in FIG. 15, a retaining wall 10 is formed on the floor surface on which an underground structure is constructed, and the retaining wall 10 is an H beam, an earth plate, CIP (Cast in-Place Pile), SCW ( Soil Cement Wall), etc.

When the construction of the retaining wall 10 is completed, the vertical steel frame members 20 are buried at regular intervals on the floor surface at a location spaced a certain distance from the retaining wall 10, and at the upper end of the vertical steel frame members 20 After fixing the bracket, the beam-shaped structure 300 is mounted on the upper end of the vertical steel frame member 20 and fixed by bolts/nuts and welding. A beam-shaped structure having the same height as the height of the beam-shaped structure 300 installed at the upper end of the vertical steel frame member 20 may be formed not only on the upper end but also on the inner side of the underground outer wall line where the underground outer wall is formed. .

In addition, as shown in Fig. 16, the upper part of the beam-shaped structure 300, a core or a lamp, etc., is installed continuously up and down or left and right in a continuous hollow plate 110 is not formed.

At this time, in a portion where the multi-layered plate 110 and the multi-layered plate 110 are in close contact with each other, a fixing bolt 140 is inserted into the fixing hole 120 formed in the multi-layered plate 110 to pass through the through hole 142 formed in the section steel 111 . After the through-hole 142 is fastened with a nut hole 130 formed on the other side of the multi-layered plate 110 opposite to the through-hole 142, the multi-layered plate 110 and the multi-layered plate 110 are coupled to each other. In addition, since the combination of the multilayer plate 110 and the structure 300 in the form of a beam that is a steel frame part is combined in various general methods widely used in the prior art, the illustration thereof will be omitted.

When the multilayer plate 110 is installed in the beam-shaped structure 300, in the space formed between the multilayer board 110 and the retaining wall 10, as shown in the enlarged detailed view of FIG. 16, the lower part is toward the retaining wall 10. After installing the torn 'ㄴ'-shaped plate 11 and installing the 'Z'-shaped iron plate 12 that receives the 'ㄴ'-shaped iron plate 11 toward the double-walled plate 110, pouring mortar or concrete therein, or By installing a separate reinforcing bar, the horizontal load of the retaining wall 10 is transmitted to the duplex board 110 .

In addition, as shown in FIGS. 17 to 18 , a reinforcing bar 41 is reinforced in the portion where the upper permanent horizontal structure of the beam-shaped structure 300 is formed, and the end of the reinforcing bar 41 is connected to the corrugated plate 110 . 23, a receiving groove 115 is formed in the section steel 111 of the double-walled plate 110 in order to receive it in an outer inner part of The end portion is accommodated, but the receiving groove 115 uses a mesh 116 or the like to prevent the concrete being poured when the slab 40 is poured.

Next, a part of the basement is excavated, a bracket is fixed to the vertical steel frame member 20, and then the structure 300 in the form of a basement beam is seated and fixed with bolts/nuts and welding.

When the structure 300 in the form of an underground beam is installed as described above, the duplex board 110 is installed continuously up and down or left and right on the upper part of the structure 300 in the form of a basement beam.

At this time, at the portion where the multi-layered plate 110 and the multi-layered plate 110 are in close contact with each other, the multi-layered plate 110 and the multi-layered plate 110 are coupled to each other using a fixing bolt 140 in the same manner as constructed above, and the When the retaining plate 110 is installed, the horizontal load of the retaining wall 10 is reduced by pouring concrete or installing a reinforcing bar in the space formed between the retaining plate 110 and the retaining wall 10 in the same manner as above. ) will be transmitted.

The reinforcing bar 41 is reinforced at the end of the portion where the slab is formed, but the end of the reinforcing bar 41 is accommodated in the receiving grooves 115 formed at regular intervals formed on the outside of the clad plate 110 in the same manner as above. After that, concrete is poured to form the basement slab 40 .

In addition, when curing is completed after forming the basement slab 40 as described above, as shown in FIG. 20 , in the portion where the permanent horizontal structure is not formed, a duplex plate 110 is installed on the beam-shaped structure, and After that, proceed with excavation and repeat this until the foundation.

As shown in FIG. 21, when the foundation is poured, concrete is poured inside the retaining wall 10 to form the underground outer wall 50 and the permanent vertical material 70, and the multilayer plate 110 and the beam-shaped structure 300 are formed. When it is removed, the installation of the underground structure is completed as shown in FIG. 22 .

In addition, in the construction method of an underground structure using the multi-layered plate connection structure 100 of the underground structure for distributing and supporting vertical and horizontal loads, it is divided into the multi-layered plate 110 to form a through-hole 180 through which the vertical steel column passes. Although the installation of the multi-layered board 160 is not specifically illustrated, the installation structure and method of the multi-layered board 110 and the divided multi-layered board 160 installed on the upper flange surface of the horizontal beam-shaped structure 300 is shown in FIG. 3 . to 5, a description thereof will be omitted.

When the construction method using the multi-layered plate connection structure 100 for distributing and supporting vertical and horizontal loads in the underground reverse drilling method in which the multi-layered plate 110 is installed is implied and explained step by step,

(1) burying a plurality of vertical steel frame members 20 in the excavated ground at a location spaced apart from the retaining wall 10 by a predetermined distance; (2) installing a beam-shaped structure 300 on the upper end or side of the vertical steel frame member 20; (3) The horizontal H (30) beam installed in the part where the permanent horizontal structure is not formed and the upper flange surface of the beam-shaped structure 300 to install the duplex plate 110 continuously up and down or left and right step; (4) forming a slab 40 by pouring concrete into the space between the duplex board 110 and the retaining wall 10 and a portion where a permanent horizontal structure is formed; (5) excavating the lower part of the hollow plate 110 and the slab 40; (6) repeating steps (2) to (5) to the bottom of the foundation; (7) forming the bottom layer 60 including the foundation and forming the underground outer wall 50 and the permanent vertical material 70; (8) removing the beam-shaped structure 300 supporting the duplexed plate 110 sequentially in the direction from the lowest layer to the upper layer, and removing the vertical steel frame member 20 in the portion where the permanent horizontal structure is not formed. characterized by In addition, depending on the site conditions, the construction step leading from step (3) to step (4) may be changed to the construction step leading from step (4) to step (3), and the construction according to this change is the same as described above.

In the present invention, a beam-shaped structure 300 installed in a part where a permanent horizontal structure is not formed, such as a core or a lamp, is installed with a duplex plate 110 that distributes and supports vertical and horizontal loads, and is installed in a part where a permanent horizontal structure is formed. By forming the slab 40 in the beam-shaped structure 300, the workability is improved by stably supporting the horizontal load such as earth pressure transmitted from the retaining wall 10, and the present invention has a permanent horizontal structure. The ceiling plate 110 that distributes and supports the vertical and horizontal loads installed in the non-formed part supports the horizontal load such as earth pressure transmitted from the retaining wall 10, greatly reducing the use of braces or constructing a separate earth anchor. Construction is easy due to the simplification of materials. In addition, the present invention forms a through-hole 180 through which a vertical steel column passes by using a divided cladding plate 160 in a corrugated plate 110 for distributing and supporting a vertical load and a horizontal load. It has the effect of increasing space utilization by allowing vertical structures such as vertical steel columns to pass through the through-holes while distributing and supporting the load.

25 is a cross-sectional view of a state in which a cover having a protrusion formed in the upper center of the beam-shaped structure is installed. When installing on the upper surface of the structure 300 in the form of a beam, the duplex plate 110 must be installed accurately with the central portion of the upper surface of the structure 300 in the form of a beam left and right. To this end, the cover 250 is installed on the upper surface of the structure 300 in the form of a beam, and both sides of the cover 250 are bent downward to cover both ends of the upper surface of the structure 300 in the form of a beam. The cover 250 was seated without sliding from the structure 300 in the form of a beam, and a central fixing protrusion 251 was formed in the upper center of the cover 250 on both sides of the central fixing protrusion 251 . It was made to accurately and conveniently position the duplex plate (110).

That is, when the cover 250 is installed on the structure 300 in the form of a beam and the duplexed plate 110 is mounted on both sides of the central fixing protrusion 251, respectively, the duplexed plate 110 can be easily installed in the structure 300 of the beam form. It can be installed accurately and safely in the upper center.

In addition, between the central fixing protrusion 251 in the upper center of the cover 250 and the side end of the cover 250, an auxiliary protrusion 252 capable of accommodating the section steel 111 formed by the rim in the double hole plate 110 is formed. It was made to prevent the horizontal movement of the hollow plate (110). And in order to absorb a tolerance between the upper width of the beam-shaped structure 300 and the width of the section steel 111, the inner width of the cover 250 surrounding the upper part of the beam-shaped structure 300 is the upper width of the beam-shaped structure 300. The width of the central fixing protrusion 251 and the auxiliary protrusion 252 is also larger than the width of the section steel 111 . In this way, the central fixing protrusion 251 and the auxiliary protrusion 250 are formed on the upper part of the cover 250 to prevent the movement of the section steel 111 while accommodating the section 250, so that the construction can be done quickly and accurately, and the sliding of the hollow plate 110 during construction. By preventing this, there is an effect of increasing the stability of construction.

Figure 26 (a) is a cross-sectional view of a state in which the pedestal on which the second support beam is mounted in the present invention is fixed to the first support beam, and Figure 26 (b) is a perspective view of the pedestal on which the locking protrusion is formed in the present invention, in the form of a beam. In order to install the second support beam 242 between the first support beam 170 and the first support beam 170 mounted on the upper surface of the structure 300 in the vertical direction to the side surface of the first support beam 170 . The first support beam 170 on which the pedestal 240 is installed not only to fix the 'L'-shaped pedestal 240, but also to more firmly fix the pedestal 240 to the first support beam 170. It can be reinforced by adding a backing plate 260 to the opposite side. In mounting the second support beam 242 on the pedestal 240, the second support beam 242 is formed to protrude from both sides of the upper side of the pedestal 240 so that the second support beam 242 does not slide from the pedestal 240. The second support beam 242 can be quickly and safely seated on the first support beam 170 .

Therefore, in a state in which the second support beam 242 is seated on the support 240 by using the locking jaw 241 of the upper portion of the support 240 , a divided deck plate having different lengths is placed on the upper portion of the second support beam 242 . (160') can be installed, and the cross section of the second support beam 242 is formed in a 'T' shape to reinforce rigidity so that the second support beam 242 is in close contact with the lower part of the divided deck plate 160'. The vertical load can be stably supported.

As described above, although the present invention has been described with reference to limited embodiments and drawings, the terms or words used in the present specification and claims should not be construed as being limited to conventional or dictionary meanings, and the technical spirit of the present invention It must be interpreted with a corresponding meaning and concept.

Accordingly, the configuration shown in the embodiments and drawings described in the present specification is only one embodiment of the present invention, and does not represent all the technical spirit of the present invention, so within the limit not departing from the claims of the present invention, various It should be understood that there may be equivalents and variations.

10: retaining wall 20: vertical steel frame member
40: slab
41: reinforcing bar 50: basement outer wall
60: bottom layer 70: permanent vertical material
100: multi-layered plate connection structure 110: multi-layered plate
120: fixing hole 130: nut ball
131: first fastening nut 132: second fastening nut
133, 143: guide tube 134: taper
140: fixing bolt 141: through hole
142: through hole 160: split plate
161: stepped groove
170: first support beam 171: end
172: first support 180: through hole
230, 230': pad
240: pedestal 241: jamming jaw
242: second support beam 250: cover
251: protrusion 252: auxiliary projection
300: beam-shaped structure

Claims (12)

It is installed on the upper flange surface of the structure in the form of a horizontal beam, and the upper part is formed of a steel plate, and the lower outer periphery of the steel plate is installed with a section steel forming an edge.
at least one fixing hole formed on one side of the veneer plate; a through hole formed in the lower section of the fixing hole; a nut hole formed on the other side of the hollow plate opposite to the through hole; It is formed with a fixing bolt that is coupled to the nut hole through a fixing hole in a state in which the lining plate and the lining plate are in close contact with each other, thereby coupling the lining plate to each other,
In order to form a divided deck plate divided into two or more in order to form a through hole in a part of the deck plate installed on the upper flange surface of the horizontal beam-shaped structure, the divided deck plate distributes and supports vertical and horizontal loads,
at least one fixing hole formed on one side of the divided multilayer plate; a nut hole formed on the other side of the divided multilayer plate facing the fixing hole; The multi-layered plate and the divided multi-layered plate are in close contact with each other, and the divided multi-layered plate and the divided multi-layered plate are coupled with a nut hole through a fixing hole in a state in which they are in close contact with each other.
The cover plate is in close contact with the slab to be poured and cured, and concrete is poured and cured between the retaining wall and the retaining plate to distribute and support the vertical and horizontal loads transmitted from the retaining wall to the slab,
A multilayered plate connection structure of an underground structure supporting distributed vertical and horizontal loads, characterized in that an accommodating groove for accommodating the end of the reinforcing bar protruding from the end surface of the slab is provided at the end of the multilayered plate in close contact with the slab.
delete The method according to claim 1,
The inlet of the nut hole forms a taper that is larger than the diameter of the fixing bolt as it goes outward, so that even when the central axis of the through hole and the central axis of the nut hole do not match exactly when connecting the clad plate and the clad plate, the fixing bolt is tapered by the taper. A multilayer plate connection structure of an underground structure that distributes and supports vertical and horizontal loads, characterized in that it is naturally coupled to the nut hole.
The method according to claim 1,
The end of the fixing bolt has a thread shape and is formed with a length (ℓ) shorter than the length (L) of the through hole, the middle part of the fixing bolt is formed straight with a diameter smaller than the screw thread, and the head of the fixing bolt is formed in a square shape, At the entrance of the through hole, a through hole is formed so that the screw thread of the fixing bolt passes in a spiral, and the inner diameter of the through hole is formed larger than the thread diameter of the fixing bolt. An underground structure that supports distributed vertical and horizontal loads, characterized in that it can be easily fastened to the nut hole that has a taper on the other side plate while having room to the left and right, and the fixing bolt is not easily deviated from the through hole by the through hole. Duplex plate connection structure.
The method according to claim 1,
When the veneer plate is continuously mounted on the beam-shaped structure, a 'U'-shaped cover of a certain width is installed to cover the upper part of the beam-shaped structure in order to prevent the clad plate from slipping off the beam-shaped structure, and the cover In the center, a central fixing projection is formed, and an auxiliary projection is formed between the central fixing projection and the side surface of the cover while accommodating the beam and preventing the horizontal movement of the beam. For this purpose, the inner width of the cover surrounding the upper part of the beam-shaped structure is larger than the upper width of the beam-shaped structure, and the width of the central fixing protrusion and the auxiliary protrusion is also larger than the width of the section steel. Duplex plate connection structure of underground structure.
The method according to claim 1,
In order to form a through-hole for installing a vertical structure penetrating vertically to a duplex plate continuously installed on a beam-shaped structure, the first support beam is mounted on both sides of the through-hole in a direction perpendicular to the beam-shaped structure, front and rear of the through-hole Distributed support for vertical and horizontal loads, characterized in that the second support beam is mounted on the first support beam in the parallel direction of the beam-shaped structure in the direction, and the multi-layered plate and the divided multi-layered plate are positioned in the portion where the through-hole is not formed. Duplex plate connection structure of underground structure.
7. The method of claim 6,
In order to make the upper heights of the first support beam and the second support beam the same, the 'L'-shaped pedestal in the vertical direction to the side of the first support beam and the back plate are fixed together on the opposite side, respectively, and the second support beam When the beam is seated on the top of the pedestal, the second support beam is formed on the upper part of the pedestal to prevent the second support beam from being separated from the pedestal.
delete delete The construction method using the multi-layered plate connection structure of the underground structure that distributes and supports vertical and horizontal loads in the underground reverse drilling method in which the multi-layered board is installed is,
(1) burying a plurality of vertical steel frame members in the excavated ground at a location spaced a certain distance from the retaining wall;
(2) installing a beam-shaped structure on the upper end or side of the vertical steel frame member;
(3) continuously installing a duplex plate up/down or left/right on the upper flange surface of a horizontal beam-type structure installed in a part where a permanent horizontal structure is not formed;
(4) forming a slab by pouring concrete into the space between the cladding plate and the retaining wall and a portion where a permanent horizontal structure is formed;
(5) excavating the lower part of the slab and the slab;
(6) repeating steps (2) to (5) to the lower part of the foundation;
(7) forming a floor layer including a foundation and forming a basement outer wall and a permanent vertical material;
(8) vertical load and horizontal load, characterized in that it comprises the steps of removing the beam-shaped structure supporting the multilayer plate sequentially from the lowest layer to the upper layer direction and removing the vertical steel frame member in the part where the permanent horizontal structure is not formed A construction method using a multi-deck connection structure of an underground structure that is distributed and supported.
11. The method of claim 10,
The step of installing the multilayer plate includes inserting a fixing bolt into at least one fixing hole formed in at least one of the multilayer plates in the portion where the multilayer plate and the multilayer plate are in close contact with each other, and then fastening the fixing bolts with a nut hole formed in the other multilayer plate. A construction method using a multi-layered plate connection structure of an underground structure that disperses and supports vertical and horizontal loads, characterized in that the multi-layered plates are combined.
12. The method of claim 11,
Vertical load and horizontal load, characterized in that a first fastening nut formed with a screw thread to be fastened to the fixing bolt is formed on the inner side of the nut hole, or a second fastening nut formed with a screw thread to be fastened with the fixing bolt is formed on the outer side of the nut ball to be fastened with the fixing bolt. A construction method using a multi-walled connection structure of an underground structure that disperses and supports the

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