KR101129017B1 - Steel strip-strut structurte with its strip having wider width for underground retaining wall - Google Patents

Abstract

PURPOSE: A wide strip-strut structure for underground earth retaining work is provided to reduce the number of struts by minimizing the bending of strips to increase the interval between the struts. CONSTITUTION: A wide strip-strut structure for underground earth retaining work is configured as follows. An arch(11) is formed between two points of a strip(10) where struts(12) are connected so that a load applied to the strip is delivered to the points along the arch. Connecting blocks are formed in the two points to facilitate connection with the struts and disperse loads concentrated on the two points. Shear stiffeners(14,15,16) are formed in specific portions near the upper peak point of the arch and in the two points of the strip.

Description

STRIP-STRUT STRUCTURTE WITH ITS STRIP HAVING WIDER WIDTH FOR UNDERGROUND RETAINING WALL

The present invention relates to a strip-bearing structure used as a temporary material for supporting a load of soil walls in an underground mudstone construction, and more specifically, to a wide strip-bearing structure that can increase the installation spacing of the beam by effectively distributing the load of the soil walls. will be.

Recently, as the need for expansion of social indirect facilities increases, many underground excavation works are proceeding in the city center. The characteristics of the underground excavation work are the maximum space excavation and the deep depth excavation to make the best use of the close construction and the limited underground space which are close to the subway, the overpass, the underground structure, the ground structure for the office space and the residential space. have.

In particular, in the underground excavation work for constructing large-scale underground structures in the limited space of the downtown area, the stability of the surrounding ground should be the first priority. Therefore, the earthquake construction necessary for maintaining the stability of the surrounding ground must be reviewed. It is an important part. The earthquake construction method can be divided into two methods: the use of the temporary earthquake structure and the construction of the underground structure in response to the earth pressure and water pressure. Hypothetical crest structure has the risk of collapse of crest structure due to possibility of civil complaints and stability of surrounding ground, and there are many cases of actual collapse. In addition, there are many cases in which civil complaints are generated due to displacement of surrounding grounds, resulting in suspension or compensation.

The temporary facility used for the earthquake for current earthwork is steel pile and earth plate, CIP (Cast in Place Wall), SCW (Soil Cement Wall), etc. And Earth Anchor, Soil Nailing, Rock Bolt, and Top-Down.

In the case of using the temporary struts, it is highly likely to cause the increase of air and the change of the surrounding ground during the dismantling process, but the work environment for the underground construction is better than the top-down method. There is an advantage that can reduce the cross section of the slab is currently widely used.

On the other hand, in the case of using the above hypothetical struts, in order to support the lateral pressure of the soil wall, H-Pile piles are vertically installed on the soil walls facing each other, and then a plurality of transverse strips are arranged in a direction orthogonal to the H-Pile piles. Done. In addition, a brace is installed between the strip and the strip. After all, the transverse pressure of the earth wall is transmitted in the order of H-Pile pile-> belt-> brace.

Meanwhile, the brace between the girdle and the girdle serves as a point of the girdle, and eventually the girdle bends against the load transmitted from the pile between the brace and the brace.

By the way, although the bending deformation of the member is different depending on the support conditions of the point, in general, the bending deformation increases in proportion to the span of the band, and the case of a simple beam in which an equally distributed load is applied, for example, span Increases in proportion to the square of 4 Therefore, in order to prevent the bending deformation of the bands, the gap between the braces serving as a point must be reduced, thereby causing problems of increased cost due to the increase in the number of braces and a decrease in construction efficiency, which makes the construction work space narrow. Done.

Republic of Korea Patent Publication No. 10-0543059

One object of the present invention is to reduce the number of braces and increase the construction space between the braces by increasing the installation interval of the brace to minimize the bending deformation of the band as described above.

In addition, the shear reinforcement is installed in the center of the span where the brace is installed and the width of the strip is the smallest, it is possible to prevent the shear failure at the same time.

In the wide belt-brace structure for the underground earthquake construction according to the present invention, an arch is formed between both points and points to which the belt support of the belt is connected so that a load loaded on the belt can be transferred to the point along the arch. ; Both points are provided with connecting blocks of a predetermined length for facilitating connection with the brace and for distributing the load concentrated at both points; Shear reinforcement is provided in a predetermined region near the upper apex of the arch and in a predetermined region of the point of the strip.

In the wide belt-brace structure for the underground earthquake construction according to the present invention, a reinforcing member may be provided between the wide belt and the wide belt to prevent local destruction of the strip-belt connection.

In the wide belt-supported structure for the underground mudstone construction according to the present invention, recesses are formed at both points of the strip, and the connection block may be embedded in the recess.

According to the present invention, since the wide band acts as an arch, the load can be effectively supported even in the case where the brace is wide, so that the brace can be increased and the number of braces can be reduced.

1 is a view for explaining an embodiment of the present invention.
2 is a view for explaining another embodiment of the present invention.
3 is a view for explaining another embodiment of the present invention.
4 shows the stress state of the arch.

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

In addition, like reference numerals designate like elements.

Arches are usually composed of flexural materials, which are often used in structures that require large spans, such as gymnasiums and theaters, because their axial effects are greater than those of bending moments. More specifically, the arch has a property to open to both sides when a load is applied from the upper side, in which the fixed point to control the spreading properties by fixing the two points to the relatively small cross-section It can also support effectively enough.

Fig. 4 (a) schematically shows an arch loaded with a point load, and the diagrams of (b) to (d) show axial force stress, shear force stress, and bending moment stress diagram in the case of Fig. 4A in order. It is shown.

Referring to FIG. 1, which shows a first embodiment of the present invention, in the strip 10, an arch 11 is formed on the opposite side of the earth wall, and preferably, both ends 19 and 20 of the arch 11. It becomes the load point of the strip | belt-length 10 in which this brace 12 is installed. In addition, it is preferable that both ends 19 and 20 of the arch 11 to which the brace 12 is connected have a rectangular shape to prevent local damage due to load concentration and to smoothly transfer the load to the brace 12. .

As such, when the arches 11 are formed on the strip 10, the loads transmitted from the earth walls through the H-pile piles to the strip 10, typically the equally distributed loads, are formed at both ends thereof from the upper peak of the arch 11. 19, 20, and both ends 19, 20 are held by the brace 12, even if the cross section of the arch 11 is not large, the bending performance of the strip 10 can be greatly improved. Therefore, the installation interval of the brace 10, which is determined in consideration of the bending deformation of the belt length 10 can be increased.

By the way, in the case of the band 10, the arch 11 is formed as described above, since the arch points 19 and 20 become the points of the band 10 that behaves as beams, a relatively large shear stress is generated. Referring to c), when the arch 11 itself is viewed as the upper center apex, the band 10 shows a large shear stress near the span center. Therefore, in the case of the band with the arch 11 formed, it is preferable to perform shear reinforcement near the upper center vertex of the arch 11 and at both end points 19 and 20 thereof. In the shear reinforcement method, stiffeners 14, 15, and 16 are generally used.

On the other hand, between the one span of the strip 10 and the one span of the adjacent strip 10 is connected by welding or bolt 17 fastening method, a separate reinforcement plate in the junction between the strip 10 and the strip 10 It is preferable to reinforce the joint by padding (22). The reinforcement plate 22 may help to prevent local fracture between the strip 10 and the strip 10.

In addition, according to an embodiment of the present invention, it is preferable that a connection block 13 for connecting the belt 10 and the brace 12 is provided. The connecting block 13 is connected to the bolt 18 or welded at the ends (19, 20) of the strip 10. Typically, buttresses 12 and strip 10 is connected to the connecting jack in the middle, but does not use a separate connection block (13). However, when the arch 11 effect is used to increase the installation span of the brace 12 as in the present invention, the amount of connection points 19 and 20 of the brace 12 and the strip 10, i.e., the amount of the arch 11, is increased. Since load concentration may occur at the point, it is important to distribute the load through the connection block 13 of a predetermined length in order to distribute such concentrated load to prevent local damage. As described above, the connecting block 13 generally uses H-pile.

In addition, the buttress can also use H-Pile, but a circular steel pipe having a symmetrical cross section or a square cross section square tube is widely used. In the case of using a circular steel pipe as a brace, it is common to use a separate connecting portion 21 to connect the circular steel pipe and the connecting block 13 above. Such a connection portion 21 is composed of a circular connector, the base plate is connected to the circular connector, the reinforcing plate connected to the base plate, etc., the steel tube-shaped support 12 is inserted, the connection jack may be connected to. Connection block 13 is connected to the connection jack, or if there is no connection jack is directly connected to the reinforcement plate.

2 is a view for explaining another embodiment of the present invention. In another embodiment of the present invention, instead of the curved arch 11 as shown in FIG. 1, the square tube 110 is padded on the strip 10.

In the embodiment of FIG. 1, the arches 11 may be connected by welding or bolting to form the wider bands 10, or the bands 10 having the arches 11 may be integrally formed. However, rather than forming a curved arch (11), as shown in Figure 2, connecting the square tube 110 to both points (190, 200) of the strip is easier to manufacture.

In the vicinity of the square tube 110, it is preferable to install a separate shear stiffener 140 because the shear force may be relatively large compared to the cross-sectional area of the strip.

3 is a view for explaining another embodiment of the present invention. In the embodiment of FIG. 3, the same connection block 1300 as in the embodiment of FIG. 1 is employed, but the connection block 1300 is a strip 10. Are embedded in the ends 1900 and 2000. In addition, concave portions 2100 are formed at end portions 1900 and 2000 of the strip 10 so that the connection block 1300 may be embedded. Although the connecting block 1300 is embedded in the ends 1900 and 2000 where the brace 12 is formed as shown in FIG. none. In addition, by embedding the connection block 1300, it becomes easier to adjust the deviation in the longitudinal construction of the support 12 is installed between the strip 10 and the strip 10. Actually, when constructing underground mudstones, it is common for the props 10 to reach several tens of meters, but depending on the ground conditions, the installation angle of the strip 10 for the props 10 may be different for each of the props 12, and thus the connection jack Etc., the deviation should be adjusted. In this case, embedding of the connection block 1300 may facilitate the deviation adjustment.

Although the present invention has been shown and described with reference to certain preferred embodiments, the present invention is not limited to the above-described embodiments and the general knowledge in the technical field to which the present invention pertains is not limited to the technical spirit of the present invention. Of course, various changes and modifications are possible. In addition, in order to explain the technical idea of the present invention, the accompanying drawings are partially enlarged and reduced, not drawn to scale.

In particular, each of the embodiments of Figs. 1 to 3 of the present invention, as well as any combination thereof, is also included in the protection scope of the present invention.

10: Sash
11: arch
12: brace
13: connecting block
14, 15, 16: shear stiffener (spinner)
19, 20: both ends
22: gusset
110: square tube
2100: recess

Claims (3)

As a wide belt-brace structure for underground cladding construction,
The belt is formed with an arch between both the point and the point where the brace is connected so that the load loaded on the band can be transferred to the point along the arch,
Both points are provided with a connection block of a predetermined length for facilitating connection with the brace and distributing the concentrated load at both points.
Shear reinforcement material is provided in a predetermined region near the upper apex of the arch and a predetermined region of the point of the strip,
Recesses are formed at both points of the strip,
The connecting block is buried in the concave portion, characterized in that the wide strip-buttress structure. The method of claim 1,
A wide stripe-brace structure, characterized in that between the wide stripe and the wide stripe is provided with a reinforcing member for preventing local destruction of the stripe connection. delete

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