KR100585850B1 - Complex system with cantilever wall-type structure for omitting transfer girder and transfer plate - Google Patents

Abstract

The present invention relates to a composite structure including a cantilever wall structure, which can omit the transition layer, and more particularly, by joining an inner wall body to a column in a cantilevered form in a composite structure in which a wall structure is combined on a columnar ramen structure. The vertical load acting on the cantilever wall is not transferred directly to the lower wall, but the moment due to the horizontal force transmitted to the flat slab of each layer and the shear force of the cantilever wall to the column to make the columnar ramen structure at the bottom. The present invention relates to a composite structure including a cantilever wall structure in which a transition layer for a layer can be omitted.

The composite structure including the cantilever wall structure that can omit the transition layer of the present invention is a composite structure in which the wall structure is combined on the columnar ramen structure, extending from the ramen structure and arranged and designed as an outer frame of the wall structure. Multiple pillars; A plurality of flat slabs installed while forming a layer in the wall structure space surrounded by the plurality of pillars; And a cantilever bearing inner wall which is positioned between the flat slab and the flat slab, but joined to and installed on the pillar to face the inside of the wall structure.

Composite structure, wall structure, cantilever, transition layer, flat slab

Description

Complex system with cantilever wall-type structure for omitting transfer girder and transfer plate}             

1 is a schematic diagram of the present invention showing a stress transmission mechanism when the cantilever bearing inner wall supports a gravity load.

2 and 3 is a view showing an embodiment in which the present invention is applied to the plane of the existing box-type high-rise apartment and plate-shaped apartment.

4 and 5 illustrate embodiments of a method for forming a discontinuous joint.

6 and 7 are detailed cross-sectional view and reinforcement detail cross-sectional view of the discontinuous joint.

8 is a view showing the installation and dismantling plan for the construction when applying the present invention.

<Description of Major Symbols in Drawing>

100: pillar 150: border beam

200: flat slab 250: heating floor layer

300: cantilever bearing inner wall 350: discontinuous material

The present invention relates to a composite structure including a cantilever wall structure, which can omit the transition layer, and more particularly, by joining an inner wall body to a column in a cantilevered form in a composite structure in which a wall structure is combined on a columnar ramen structure. The vertical load acting on the cantilever wall is not transferred directly to the lower wall, but the moment due to the horizontal force transmitted to the flat slab of each layer and the shear force of the cantilever wall to the column to make the columnar ramen structure at the bottom. The present invention relates to a composite structure including a cantilever wall structure that solves the limitation of installing a transition layer and thus reduces the height of a building.

Depending on the purpose of the building or the purpose of changing the elevation, the arrangement of the upper and lower columns may be different. In this case, the transition layer system is adopted to safely transmit the axial force and horizontal load of the upper layer to the lower part for structural stability. That is, in the apartment complex or the underground parking lot, the lower floor of the lower part is formed of a columnar ramen shopping center and a resident convenience facility or a parking lot, and the upper part of the upper part is formed of a wall-shaped apartment. Most of the columns of the lower part and the lower part of the column do not fit so that the transition layer is formed at the upper floor of the lower part where the apartment starts to stably transfer the upper load to the lower part.

Conventionally, a transfer girder or a transition slab (flat slab) is mainly applied for such a transition layer system, and the thickness of the transition layer is considerable and occupies a lot of layer height. Specifically, for example, when adopting a transition beam, when the grid line of the main line is designed to be arranged around 8.0m × 8.0m, the structure is more than 2.5 ~ 3.0m to support the apartments of the upper 25-30 floors. Transition beams with and without the need for larger scales are required to design transition layers with heavier thicknesses.

However, the increase in dance of the members constituting the transitional floor as described above restricts the construction plan and directly affects the height of the building, impairs economics, and leads to the application of mass concrete, which leads to separate casting under the influence of heat of hydration. Caused the problem of lengthening.

The present invention has been made to improve the conventional problems, in the composite structure combined with the wall structure on the columnar ramen structure to join the inner wall to the pillar in the cantilever form to transfer the vertical load acting on the cantilever wall directly to the lower wall Cantilever wall type that solved the limitation of installing the transition layer for the upper wall to make the columnar ramen structure at the bottom by transmitting to the column by the moment of the horizontal force and the shear force of the cantilever wall. Its purpose is to provide a composite structure including a structure.

It is an object of the present invention to provide a composite structure including a cantilever wall structure which can omit the transition layer usable as an apartment structure which can increase the number of floors by the same height by eliminating the need for a transition layer occupying a considerable thickness.

Another object of the present invention is to provide a wall structure including a cantilever wall structure which can omit the transition layer which enables easy construction and reduction of construction period by eliminating the transition layer composed of heavy members.

The composite structure including the cantilever wall structure, which can omit the transition layer of the present invention, is arranged in the outer frame of the wall structure extending from the ramen structure in the composite structure in which the wall structure is combined on the columnar ramen structure. Multiple pillars; A plurality of flat slabs installed while forming a layer in the wall structure space surrounded by the plurality of pillars; And a cantilever bearing inner wall which is positioned between the flat slab and the flat slab, but joined to and installed on the pillar to face the inside of the wall structure.

The cantilever bearing inner wall and the flat slab may be joined while forming a discontinuous joint under the cantilever bearing inner wall. At this time, the cantilever bearing inner wall is installed while forming a discontinuous joint with the flat slab once in several layers, can be installed over all layers of the wall structure, or the cantilever bearing inner wall is omitted in some layers to form an open joint. It is also possible to form discontinuous joints.

In particular, the junction of the flat slab and the cantilever bearing inner wall in which the discontinuous joint is formed may be flexibly reinforced by reinforcing the horizontal wall reinforcement at the upper end and the lower end of the cantilever bearing inner wall.

In addition, the discontinuous joint may be formed by further installing a discontinuity material having a predetermined thickness between the flat slab and the cantilever bearing inner wall, wherein the discontinuous material may use styrofoam or caulking material, and the discontinuous material on the flat slab The heating floor layer can be formed more than the thickness of re-installation.

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

1 is a schematic diagram of the present invention showing the stress transmission mechanism when the cantilever bearing inner wall supports the gravity load, Figures 2 and 3 is a transition layer of the present invention in the plane of the existing BOX-type high-rise apartment and plate-like apartment As an embodiment in which a composite structure including a cantilever wall structure can be omitted, the present invention provides a column 100, a flat slab 200 and a cantilever strength in a composite structure in which a wall structure is coupled to a columnar ramen structure. It is comprised including the wall 300.

The pillar 100 extends from the ramen structure and is arranged and designed as an outer frame of the wall structure, and supports the cantilever bearing inner wall body 300 to be described later to replace the eccentric moment with the axial force of the flat slab 200. .

The flat slab 200 is installed while forming a layer in the wall structure space surrounded by the plurality of pillars 100, and serves to support the eccentric moment coming from the pillars 100 with a compressive force in the horizontal direction of the concrete.

The cantilever bearing inner wall body 300 is located between the flat slab 200 and the flat slab 200, but is joined to the pillar 100 so as to face the inside of the wall structure, and supports a gravity load to support the pillar ( 100).

As shown in FIG. 1, the moment generated by the cantilever bearing inner wall body 300 is not horizontally transmitted to the axial force and the moment but is horizontally transferred to be supported by the diaphragm of each layer of the flat slab 200. The flat slab 200 and the cantilever bearing inner wall 300 are structurally burdened with mutual stress. That is, when the wall is joined to the pillar 100 in the form of a cantilever, the bending moment generated in the pillar 100 due to the eccentricity is transferred to the axial force acting on the flat slab horizontally.

As a result, the vertical load acting on the cantilever bearing inner wall 300 is not transmitted directly to the lower wall but is transmitted to the column by the moment due to the horizontal force transmitted to the flat slab of each layer and the shear force of the cantilever bearing inner wall 300. Bar, the inner wall 300 of the wall structure is to act as a bearing wall for supporting the gravity load. This eliminates walls in low-level structures such as underground parking lots, lobbies, and malls without the transition floor, and makes it possible to implement columnar ramen structures, making it easier to plan not only vertical construction but also parking.

The present invention can be applied to the plane of the box-type apartment and the plate-like apartment as shown in FIG. The building having the apartment structure of the upper floor structurally supports the core wall of the seismic load, the lateral load such as wind load, etc., and the cantilever bearing inner wall 300 acts in such a manner as to support the gravity load.

In addition, as shown in FIG. 2, a perimeter girder 150 may be installed in the apartment balcony to prevent excessive deflection and vibration of the flat slab 200. Particularly, in the box-type apartment of FIG. 2, since the inner wall 300 is installed in the form of a cantilever to be joined to a column, an open space is naturally formed between the cantilever bearing inner wall 300 and the core wall. Using this as a passage will lead to efficient space design.

In addition, the present invention allows the flat slab 200 and the cantilever bearing inner wall body 300 to be joined while forming a discontinuous joint. FIGS. 4 and 5 illustrate embodiments of the method of forming the discontinuous joint. The discontinuous joint is for preventing the vertically accumulated force from being transferred to the lower layer.

FIG. 4 illustrates a case in which the cantilever bearing inner wall 300 is installed while forming a discontinuous joint with the flat slab 200 in several layers, and is installed in all layers of the wall structure, and FIG. 5 shows the cantilever bearing inner wall. 300 is installed while forming a discontinuous joint with the flat slab 200 once in several layers, but the discontinuous joint is formed by forming an open joint in which the cantilever bearing inner wall 300 is omitted in some layers.

In FIG. 4 and FIG. 5, several layers (two to four layers, preferably divided into sections of construction units) are configured as one module to form a discontinuous joint for each unit module. In particular, when the discontinuous joint is placed in one layer as shown in Figure 5 there is an advantage that the plan can be freely because there is no inner wall in the opened layer.

In order to form the discontinuous joint more effectively, the cross-sectional configuration as shown in FIGS. 6 and 7 may be used. 6 and 7 are detailed cross-sectional views and detailed reinforcement cross-sectional views of the discontinuous joint, wherein the discontinuous joint is further formed by discontinuous material 350 having a predetermined thickness between the flat slab 200 and the cantilever bearing inner wall 300. I am trying to. That is, the upper portion of the junction of the cantilever bearing inner wall body 300 and the flat slab 200 in which the discontinuous joint is formed is a flat slab 200 and a discontinuous material 350 installed on the flat slab 200 at a predetermined thickness. And a cantilever bearing inner wall 300 installed on the discontinuous material 350.

The discontinuous material 350 is provided at a position where the cantilever bearing inner wall 300 is installed in order to discontinuously discontinue the upper and lower parts, and excessive shear generated in the cantilever bearing inner wall 300 supporting several layers as a unit molar ratio. It is adopted in order to prevent stress and not to transfer the stress vertically. As the discontinuous material 350, a styrofoam or caulking material can be easily employed.

The heating slab layer 250 may be further formed on the flat slab 200 by a panel heating method or the like above the thickness of the discontinuous material 350. It will be able to function as a residential building.

In addition, if necessary, it is possible to reinforce the bending moment in the upper and lower portions of the cantilever bearing inner wall body 300 forming the discontinuous joint, and FIG. 7 shows an embodiment thereof. In the above embodiment, the junction between the flat slab 200 and the cantilever bearing inner wall 300 in which the discontinuous joint is formed is configured to reinforce and reinforce the horizontal wall reinforcement 360 at the upper end and the lower end of the cantilever bearing inner wall 300, in particular, the upper part. The cantilever bearing inner wall body 300 and the flat slab 200 are integrated.

8 is a view showing the installation and dismantling plan for the copper bar 500 when applying the composite structure including the cantilever wall structure that can omit the transition layer of the present invention. Dongbari installation and dismantling plan can be changed according to the site situation, but the present invention is installed in consideration of the fact that the present invention is completed in a structure that burdens the load by installing the inner wall 300 as a bearing wall, thereby eliminating the transition layer. 200) and the cantilever bearing inner wall 300 when construction will be necessary to pay attention to the structural stability.

Specifically, when the cantilever bearing inner wall body 300 is installed and constructed by forming three-layer unit modules as shown in FIG. 8, when placing the slab 200 for the second bottom layer of the discontinuous joint as a whole. It is preferable to maintain not only the casting layer but also its bottom layer 100% so that the load can not be transmitted to the cantilever bearing inner wall 300 before the cantilever bearing inner wall 300 maintains the design strength of two or more layers.

Referring to Figure 8 will be described in detail for the installation and disassembly of the group.

(1) Until the concrete of the three-floor flat slab 200 secures more than the reference strength, the ①, ②, ③ groups are maintained.

(2) When placing flat slab on the 4th floor, No. ② group shall be dismantled and No. ③ group shall maintain 50% of the initial number. However, No. ① group shall be maintained at 100% until the 4th floor flat slab concrete achieves more than the standard strength.

(3) When placing the fifth floor, the ① and ③ clubs are dismantled and the ④ clubs are kept to 50% of the initial number.

(4) When casting the sixth floor, the copper bar ④ is dismantled, and the copper bar ⑤ is maintained at 100% until the concrete of the six-floor flat slab has secured above the standard strength.

(5) When placing the floor on the 7th floor, disassemble the ⑤ group and keep the ⑥ group 50%.

(6) The above method is also applied to the 8th, 9th, and 10th floor pours.

According to the present invention, in the composite structure in which the wall structure is combined on the columnar ramen structure, the inner wall is joined to the pillar in the form of a cantilever to transfer the vertical load acting on the cantilever wall to the flat slab of each layer without transferring to the lower wall. By transferring the moment due to the horizontal force and the shear force of the cantilever wall to the column, the transition layer for the upper wall can be omitted to make the columnar ramen structure at the bottom. As a result, by eliminating the need for a transitional floor covering a considerable thickness, it becomes possible to use it as an apartment structure that can increase the number of floors at the same height and to expect easy construction and reduction of construction period.

Claims (8)

In the composite structure where the wall structure is combined on the columnar ramen structure, A plurality of pillars extending from the ramen structure and arranged and designed as an outer frame of the wall structure; A plurality of flat slabs installed while forming a layer in the wall structure space surrounded by the plurality of pillars; And, A cantilever bearing inner wall body disposed between the flat slab and the flat slab and joined to and installed on the pillar to face the inside of the wall structure; Composite structure comprising a cantilever wall structure that can omit the transition layer characterized in that it comprises a. In claim 1, The cantilever bearing inner wall body is a composite structure including a cantilever wall structure that can omit the transition layer, characterized in that the joining and installation while forming a discontinuous joint in the lower portion of the flat slab and the cantilever bearing inner wall. In claim 2, The cantilever bearing inner wall is formed as a unit module while forming a flat slab and a discontinuous joint once in several layers, and includes a cantilever wall structure capable of omitting the transition layer, which is installed on all layers of the wall structure. Complex structure. In claim 2, The cantilever bearing inner wall is formed as a unit module while forming a flat slab and a discontinuous joint once in several layers, wherein the discontinuous joint is formed by forming an open joint in which the cantilever bearing inner wall is omitted in some layers. Composite structure including a cantilever wall structure can be omitted. The method according to any one of claims 2 to 4, The joint portion of the flat slab and the cantilever bearing inner wall forming the discontinuous joint is a composite having a cantilever wall structure capable of omitting the transition layer, wherein a horizontal wall reinforcement is reinforced at the upper end and the lower end of the cantilever bearing inner wall. rescue. The method according to any one of claims 2 to 4, The discontinuous joint is a composite structure including a cantilever wall structure that can omit the transition layer, characterized in that the discontinuous material is further installed between the flat slab and the cantilever bearing inner wall with a predetermined thickness. In claim 6, The discontinuous material is a composite structure having a cantilever wall structure that can omit the transition layer, characterized in that the styrofoam or caulking material. In claim 6, The composite structure having a cantilever wall structure that can omit the transition layer, characterized in that the heating bottom layer is further formed on the flat slab more than the thickness of the discontinuous material installation.

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