KR100766798B1 - Double transfer slab system for improving serviceability of understructure - Google Patents

Abstract

A double transfer slab system for utilizing an underground space is provided to make the best use of underground space by mounting a machine room between double transfer slabs, and to reinforce the structure by distributing load from a wall through the double transfer slabs and decreasing shear force. A double transfer slab system includes a first transfer slab(2) installed in a lower part of a wall(100) to distribute load transmitted through the wall, and a second transfer slab(4) installed in the bottom of the wall, spaced from the first transfer slab and supported by an underground beam to distribute load of the wall transmitted from the first transfer slab. The first and second transfer slabs are formed of a box, and a reinforcing wall(8) is extended from the wall placed between the first and second transfer slabs to transmit load from the first transfer slab to the second transfer slab.

Description

Double transfer slab system for improving serviceability of understructure

1A and 1B are front and plan cross-sectional schematic diagrams showing a general wall structure reaching a basement floor.

Figures 2a and 2b is a front and plan cross-sectional schematic diagram showing a first example of the structure to increase the utilization of the underground space using the transition beam system according to the prior art.

3a and 3b are schematic cross-sectional and front cross-sectional views showing a second example of a structure that increases the utilization of the underground space using the transition slab system according to the prior art.

4 is a third exemplary view showing a state in which shear reinforcement is applied to an existing transition slab.

5A and 5B are shear and planar cross-sectional schematic diagrams showing the construction of a double transition slab system according to the present invention;

6 is a front sectional view (first example) showing a state in which a load of a wall is transferred to a double transition slab according to the present invention.

Figure 7 is a front sectional view (second example) showing a state in which the load of the wall is transferred to the double transition slab according to the present invention.

* Explanation of symbols for main parts of the drawings

2: first transition slab 4: second transition slab

6: machine room 8: reinforcement wall

9: reinforcement truss 100: wall

102: column beam

The present invention relates to a double transition slab system for supporting a wall to increase the utilization of the underground space in the construction of a wall structure, more specifically a building consisting of a double structure of the upper wall structure type and lower column-beam structure type The double transition slab is installed at the position where the structural form changes in to increase the usability of the lower space, while effectively transferring the load from the wall to the column regardless of the position of the upper wall and the lower column-beam position. To provide a structurally safe transition slab system.

In general, multi-unit buildings such as newly constructed apartments and multi-purpose buildings use underground spaces as spaces for constructing machinery facilities, shopping malls, and convenience facilities for residents as well as parking spaces. It was difficult to strengthen the ratio. The existing underground parking lot is about 40%, and the government is preparing a standard to strengthen the underground parking area from 40% to 80% in an effort to eliminate parking on the ground.

In the wall structure, the wall is built up to the underground space to support the load of the upper structure. Since the wall built in the underground space occupies a large area of the underground space, the utilization of the underground space is reduced and the parking lot is reduced. Or other uses are significantly lower.

1A and 1B show a cross-sectional view of a general wall structure, showing a structure in which the wall 100 reaches the basement and the column beams 102 are arranged around the wall 100. The wall structure can be seen that the parking space is narrowed by the wall 100 causes a decrease in the utilization of the underground space.

Recently, there has been an increase in the case of applying a double structure in which a wall structure is applied to the upper side and a beam-column structure is applied to the underground space as a solution to solve the parking lot problem by efficiently expanding the underground space of the existing wall structure system. . In this dual structure, a transfer beam system or a transition slab system is adopted to transfer the load transferred from the upper wall structure to the lower pillar to the lower column.

2A and 2B show a conventional transition beam system for increasing underground space utilization. Figures 2a and 2b shows a structure that increased the utilization of the underground space by establishing a transfer girder 104 in the lower portion of the wall 100 in order to safely transfer the load from the upper wall to the lower column will be. However, in the case of a transition beam system, the wall 100 may be transferred to the column through the transition beam only when the position of the wall 100 coincides with the position of the basement column-beam 102. If the upper wall position and the lower column position do not match, very large shear forces are generated in the slab located at the transition part, which is structurally very disadvantageous. However, in recent years, as the upper layer planar shape becomes free, there are many cases where the wall position of the upper layer portion and the beam-pillar position of the lower portion do not coincide, and in this case, it is impossible to apply the transition beam system.

In the case where the position of the upper wall and the position of the lower beam-pillar do not coincide with each other, the transition slab system for transferring the upper load to the column by matting the entire slab instead of the transition beam in the part where the structural system changes is often introduced. It happens a lot.

3A and 3B show an existing transition slab structural system that transfers the load of the upper wall to the lower column by constructing a transition slab (flat slab) 106 at the bottom of the wall 100. However, in this case, as the upper load is transferred to one transition slab, a very large shear load may be transmitted to the transition slab, and such load may cause brittle fracture such as shear failure in the transition slab. Also, great care must be taken when breaking transition slabs can lead to destruction of the entire structure. In order to prevent such shear failure, excessive transition slab thickness is required, and economical and constructability often decreases.

In order to overcome the problems of the conventional transition slab 106 structure system described above, the transition slab 106 is supported to support the load transmitted from the wall 100 to the underground column-beam 102 as shown in FIG. A structure in which the shear reinforcement 108 is installed at is shown. Shear reinforcement may be used to increase the shear slab's ability to resist shear forces. However, the thickness of the transition slab is very thick. In addition, a lot of shear stiffeners are required for structural safety, and since the transition slab is very thick, it is very difficult to construct the reinforcement for the entire transition slab. Therefore, the existing transition slab system can be said to have a structurally dangerous problem, and when the structural reinforcement of the transition slab is carried out, the economical efficiency and workability are very low, and the structural efficiency is also low.

Accordingly, the present invention has been proposed to solve the above problems, in the lower wall structure by installing a double transition slab at the position where the structural form is changed in a double structure of the upper wall structure type and the lower column-beam structure type It aims to provide a structurally safe transition slab system, while effectively transferring the load from the wall to the column, regardless of whether the position of the upper wall and the lower column-beam position coincide.

In addition, the present invention improves the economics and workability of the transition slab system by reducing the shear force by the load transmitted from the wall to the two transition slabs to eliminate the need for shear reinforcement, and the space between the double transition slab to the machine / facility room Another purpose is to provide a transition slab system that can maximize the utilization of space and provide space for free structural reinforcement.

In order to achieve the above object, the present invention, the first transition slab is installed at the lower predetermined position of the wall for distributing and supporting the load transmitted through the wall primarily; And a second transition slab installed below the bottom of the wall at a predetermined distance from the first transition slab, supported by an underground column beam, for distributing and supporting the load of the wall transferred from the first transition slab. And a double transition slab system installed between the first and second slabs to increase the usability of the underground space including a reinforcement wall and a truss for reinforcing the structure.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 5 and 6.

In the embodiment of the present invention, as shown in Figure 5a and 5b is installed across the wall 100 in the horizontal direction at the lower predetermined position of the wall 100, the load transmitted through the wall 100 is 1 A first transition slab 2 for dispersing and supporting with a difference; And a load of the wall which is installed at the bottom of the wall 100 at a predetermined distance from the first transition slab 2 and is supported by the underground column-beam 102, and is transmitted from the first transition slab 2. And a second transition slab 4 for dispersing and supporting it.

Here, the space between the first transition slab 2 and the second transition slab 4 is used as the machine / equipment chamber 6. In the exemplary embodiment of the present invention, an example in which the first and second transition slabs 2 and 4 are separately installed on a wall is not limited thereto, and the first and second transition slabs 2 and 4 are not limited thereto. The transition slabs 2 and 4 can also be formed in the form of boxes.

In addition, in the embodiment of the present invention is located between the second transition slab 4 through the first transition slab 2, is installed to extend by a predetermined length from the wall 100 is transmitted from the wall 100 It further includes a reinforcing wall 8 serving as a load passing bridge so that the load to be transferred is directly transferred to the second transition slab 4 and the lower pillar side by riding the first transition slab 2.

Figure 6 shows that the load of the wall through the double transition slab according to the present invention is indicated by the arrow.

As shown in the figure, the load transmitted through the wall 100 is distributed to both sides of the first transition slab 2 (in the direction of the arrow in the drawing), and the wall passing through the first transition slab 2 ( The load of 100 is distributed to both sides of the second transition slab 4 and transmitted to the column-beam 102 to safely support the load of the wall. In addition, since the load is distributed through the first and second transition slabs 2 and 4, the shear force applied to the transition slab is reduced by the load descending through the wall, so that no additional shear reinforcement is required.

The reinforcement wall 8 provided between the first and second transition slabs 2 and 4 has a load on the wall 100 that is not distributed in the first transition slab 2, and rides through the reinforcement wall 8. It is transferred directly to the transition slab 4 and the lower column side to drastically reduce the shear load of the transition slab, thereby eliminating the construction of the shear stiffener of the transition slab, thereby securing economical and constructability.

According to the configuration of the present invention described above, only the column beams 102 are constructed in the basement space, and the machine / equipment chamber 6 is also located between the first and second transition slabs 2 and 4, so that the underground It is to maximize the utilization of space. In addition, since the machine room exists between the double slabs, structural reinforcement using walls or trusses is free between the double slabs.

FIG. 7 shows that a reinforcing truss 9 can be used in place of the reinforcing wall in the first example of FIG. 6 as a second example according to the present invention. The effect of this reinforcement truss 9 can be said to be the same as the case of using a reinforcement wall.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be obvious to those with

As described above, according to the present invention, in the structure consisting of a double structure of the upper wall structure type and the lower column-beam structure type, while installing a double transition slab at the position where the structural form changes, while also increasing the utilization of the lower space The machine room can be installed between double transition slabs to maximize underground utilization.

In addition, in the present invention, since the load of the wall is distributed through the double transition slab, the shear force applied to the transition slab is reduced by the load coming down through the wall so that no additional shear reinforcement is required, and the internal space of the double transition slab is reinforced. Wall / reinforcement truss can be installed, so structural reinforcement is free. As a result, due to the reduction of shear force and free structural reinforcement applied to the transition slab, it is effective to greatly improve the safety of the double-walled structure consisting of the upper wall type and the lower column-beam structure. .

Claims (5)

A first transition slab installed at a lower predetermined position of the wall to primarily support and distribute the load transmitted through the wall; And A second transition slab installed at a lower portion of the bottom of the wall at a predetermined distance from the first transition slab and supported by an underground column beam, for distributing and supporting the load of the wall transferred from the first transition slab; Dual transition slab system for increasing the usability of the underground space comprising a. The method of claim 1, Double transition slab system for increasing the usability of the underground space, characterized in that the first and second transition slab is made of a box shape. The method according to claim 1 or 2, It is further provided with a reinforcement wall installed to extend to the wall located between the first and second transition slab to act as a load passing bridge so that the load transferred from the wall is transferred directly from the first transition slab to the second transition slab side. Dual transition slab system to increase the usability of underground space. The method according to claim 1 or 2, A reinforcement truss that extends to the wall positioned between the first and second transition slabs and acts as a load passing bridge so that the load transmitted from the wall is transferred directly from the first transition slab to the second transition slab and the lower column side. Dual transition slab system for increasing the usability of the underground space further comprising. The method according to claim 1 or 2, And a machine room formed in the space between the first and second slabs.

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