KR100812338B1 - Temporary prestress system for transmit prestress to land side protection wall - Google Patents

Abstract

A preloading system of a retaining wall is provided to form a working space in a construction site by transferring the optimum preload to a retaining wall easily, and regulating the preloading area and the arrangement of struts. A preloading system of a retaining wall comprises struts(1) installed in an inside space of a pit excavation site at regular intervals and attached with a hydraulic jack(2) to generate pressure force, an axial force transfer body(3) connected to an output end of the hydraulic jack and composed of a straight pile(4a) and inclined piles(4b) contacted with a loading plate by a rubber plate(5) to transfer the pressure force of the hydraulic jack widely to a loading plate as preload, a loading plate(6) formed by arranging a plurality of wales(7) to be piled up mutually, reinforced with a stiffening plate(8) to have high shear stress and attached to a wall pile buried under the ground at right angles to apply preload on the wall pile, and a steel plate(10) equipped with a stopper(9) or a stopper attached to the contact surface of the loading plate and the axial force transfer body to retain the straight pile and the inclined piles within the limited location without sliding to transfer preload from the axial force transfer body to the loading plate without loss.

Description

Temporary prestress system for transmit prestress to land side protection wall}

BRIEF DESCRIPTION OF THE DRAWINGS The top view which showed the principal part structure of the loading system of the preceding load of the retaining wall which concerns on this invention in separated state.

Figure 2 is a plan view showing a preload state of the preload system of the retaining wall according to the present invention.

3 is a front view taken along line III-III of FIG. 2;

Figure 4a is a side view showing an example of the use of the loading board with a two-ply band in the preload system of the retaining wall according to the present invention.

Figure 4b is a side view showing an example of the use of the loading board with a three-ply band in the preload system of the retaining wall according to the present invention.

Figure 4c is a side view showing a two-ply arrangement structure of the brace in the preload system of the retaining wall according to the present invention.

5A is a view for explaining a form of insertion of a strip of loading board in a preload system of a retaining wall according to the present invention;

Figure 5b is a view for explaining the form of protruding strip of the loading board in the preload system of the retaining wall according to the present invention.

Fig. 6 is a plan view showing an application example of a prior load system of a retaining wall according to the present invention.

7 is a side cross-sectional view taken along the line VII-VII of FIG. 6.

8 is a plan view illustrating an example to which a conventional brace method is applied.

9 is a side cross-sectional view taken along the line VII-VII of FIG. 8.

<Description of the symbols for the main parts of the drawings>

1: prop 2: hydraulic jack

3: axial force carrier 4a: straight pile

4b: warp pile 5: rubber sheet

6: loading board 7: belt

8: reinforcement 9: stopper

10: iron plate 11: wall pile

12: pedestal 13: other straps

Korean Unexamined Patent Publication Nos. 1998-43585, 2003-19937, 2004-31451, 2006-26569,

The present invention relates to a wall construction method that is installed to prevent the collapse of the ground during the ground excavation carried out prior to the construction of the underground structure, and in particular, while significantly reducing the number of arrangement of the braces to completely suppress the displacement of the ground back ground The present invention relates to a preloading system of a retaining wall which can reduce the airflow and can improve the safety of the building structure due to no breakage of the building wall.

If there are structures that need to secure stability, such as joint holes, buried pipelines, tunnels, obsolete buildings, and sensitive buildings on uneven settlements, step-by-step construction should be carried out first to stabilize the ground and then start the construction work. There is a case.

As a construction method for suppressing the displacement of the retaining wall, the anchoring method for stabilizing the ground by inserting the anchor body on the back of the retaining wall and loading the preceding load thereto is the simplest method. However, the anchoring method cannot be carried out at the site where there is underground structure such as tunnel, buried conduit, joint hole, etc., or anchor may be buried in the land of another owner.

On the other hand, the earthquake continuous wall method in which the earthquake wall suppresses the displacement of the ground, or the method of reducing the displacement of the back ground by grouting on the back surface of the earthquake solves the problem of the anchor method, but the construction cost is expensive because it can not pitch This applies only in circumstances.

The brace construction method that installs the retaining wall as a brace in accordance with the excavation process at the construction site is commonly used because of its easy construction and low cost.

8 is a plan view illustrating an example related to a conventional prop method.

Install a retaining wall (A) along the boundary of the excavation site to prevent ground displacement caused by the excavation of the ground, and a brace (C) provided with a hydraulic jack (B) in the interior space between the retaining wall (A) Repeating the process of supporting the earth wall (A) in accordance with the excavation process by arranging a plurality of predetermined intervals, the support (C) is installed in two rows with an intermediate pile inserted in the center to have a sufficient shear stress.

And between the intermediate pile (D) by placing a plurality of pedestals (E) at regular intervals to prevent the buckling of the brace (C). In addition, the corner portion of the site is generally arranged in the form of a truss brace (C), which is to ensure that the space for the work is provided inside the site in addition to the intention to stably support the retaining wall (A). .

In practice, however, the above-described brace method becomes quite difficult to work utilizing the internal space of the site.

That is, because the brace (C) is arranged in layers up and down in accordance with the excavation process of the site and the middle pile (D) is vertically connected between them, as shown in Figure 9 the interior space of the site is filled with obstacles This is because there are many difficulties in the construction.

The problem of the brace construction method can be solved by omitting the intermediate pile (D) arranged in the internal space of the site or reducing the number of arrangement.

The preloading method is an explosive method that replaces the brace method because it has the advantage of supporting the retaining wall (A) firmly without loading the brace (C) by loading the preceding load on the retaining wall (A). It is expected.

In the loading method, the preceding load is usually generated by a hydraulic jack.

As an example, Korean Laid-Open Patent Publication No. 1998-43585 connects a stripe in an orthogonal direction to a buried pile and supports the edges with a brace, while attaching a stripe to the surface of the stripe and simultaneously attaching the stripe to the layered stripe. An earthquake method is disclosed that resists earth pressure by tensioning a cable to cause a prestress moment to act.

In addition, Korean Patent Laid-Open Publication Nos. 2003-19937 and 2004-31451 provide a plurality of pedestals in a perpendicular direction to a vertical pile, and fix one end and the other end while continuing the ends of each pedestal with a steel wire. A prestressing method is disclosed in which the vertical pile is prevented from buckling by tensioning with a fixing device so that the preceding load is loaded.

In addition, Korean Laid-Open Patent Publication No. 2006-26569 discloses a method of obtaining a preloading effect by connecting a tip of a support beam disposed in an excavated underground space with support lines such as wire ropes, cables, and chains, and tensioning it with a hydraulic jack. have.

In this way, the known load loading method is mostly set the length of the pedestal short, connecting the end of the steel wire, cable, chain, etc. and tensioning one side so that the preceding load acts as the end of the pedestal wall of the wall Since it is the structure which raises a bearing capacity, the obstacle arrange | positioned to the internal space of a site | part can be reduced significantly.

However, structurally, the preceding load is a structure that acts as the end of a short support stand by a steel wire, a cable, a chain, etc., so that the magnitude of the preceding load cannot be increased more than a certain amount.

The requirement of the preloading method is to ensure that the optimal preload is transmitted to the earthquake structure without difficulty, thereby ensuring the safety of the trenching work and also allowing the expansion of the brace arrangement. It is to make room for work.

The present invention is to solve the problems seen in the conventional prior loading method described above, to provide a preloading system of the wall of the earthquake wall consisting of a structure that can adjust the size of the preceding load according to the type of back soil, earth wall construction method Therefore, it is intended to allow the optimal preload to be transmitted to the wall of the mud wall without difficulty, and to adjust the space between the props by adjusting the preload area so that the working space can be created inside the site. .

In the earth anchoring method, the preceding load loading system of the present invention, which realizes the above object, causes the preceding load from the brace to the hydraulic jack, and the preceding load is transferred to the wall pile via the load plate which is adjusted in width. As can be expected to prevent the occurrence of obstacles in the internal space of the site, and thus can be applied to the actual construction of the part that has been theoretically possible until now to satisfy the economics, stability and constructability at the same time.

In order to achieve the above-described object, the present load loading system of the retaining wall of the present invention is disposed at predetermined intervals in the excavation construction site and has a brace for generating a pressing force by a hydraulic jack, a straight pile and an inclination disposed at both sides thereof. The output ends of the linear pile and the slant pile are formed in the same plane, and the linear pile is coaxially connected to the brace to support the axial force carrier and the ground for propagating the pressing force of the hydraulic jack to a wider extended range. It is formed by superimposing a plurality of strips in the orthogonal direction to the normal wall pile, and the load plate to prevent the ground-side displacement of the back wall of the retaining wall by loading the preceding load via the axial force carrier to the wall pile Can be.

In the present invention, a rubber plate may be interposed between the axial force carrier and the load carrier plate so that the preceding load transmitted through the axial force carrier is unilaterally transmitted or no slip occurs during transmission.

In addition, it is possible to further extend the support range of the wall pile by connecting the other belt length to both sides of the load plate.

On one side of the load carrier plate in contact with the axial force carrier, a stopper disposed outward of the inclined pile may be prevented from sliding of the axial force carrier.

The load plate may be composed of a band of two or three layers arranged up and down in order to expand the area associated with the wall pile.

Similarly, the brace can also be arranged in two or three layers up and down to have a reinforced shear stress.

The contact area expansion of the loading board and the wall pile can be made by connecting different strips on both sides of the strip.

In addition, the contact area between the load-bearing plate and the wall pile can be enlarged by a structure in which both ends of the strip are protruded outward, and the other strips are coaxially moved together with a padding plate and fastened with bolt-nuts. Can be.

The prior art loading system of the retaining wall according to the present invention will be described in detail as a preferred embodiment according to the accompanying drawings.

1 is a separation diagram showing the main configuration of the preload load system of the retaining wall according to the present invention, the normal brace 1 used in the excavation work is a hydraulic jack (2) is attached to the end of the pressing force through this It is possible to produce, and the output terminal of the hydraulic jack (2) has a configuration in which the axial force carrier (3) is connected.

The axial force transmission body 3 is comprised of the linear pile 4a arrange | positioned coaxially with the said hydraulic jack 2, and the inclined pile 4b obliquely attached to both sides of this linear pile 4a, and the said linear pile 4a ) And the output end of the inclined pile 4b are formed in the same plane. The ends of the straight pile (4a) and the inclined pile (4b) is in contact with the loading plate 6 through the rubber plate (5), the pressing force generated in the hydraulic jack (2) is the load plate (6) Through the preceding load.

The load-bearing plate 6 is a structure in which a plurality of ordinary strips 7 are superimposed and used, which is reinforced to have high shear stress through attachment of the reinforcing plate 8. The iron plate 10 with the stopper 9 located on the outer side of the inclined pile 4b is attached to the surface in contact with the axial force carrier 3 in this load-bearing plate 6.

In addition, as shown in FIG. 2, the stopper 9 may be implemented by directly attaching the steel plate 10 to the corresponding portion of the load bearing plate 6.

2 is a view showing the state of the preceding load by the loading system of the earth retaining wall of the present invention, the rubber plate (5) attached to one side of the linear pile (4a) and the inclined pile (4b) of the axial force carrier (3) In contact with the iron plate 10 of the lower plate 4 in a state of being kept intact by the stopper 9, the load plate 6 is to be orthogonal to the wall pile 11 embedded in the ground horizontally By being attached, the pressing force generated by the hydraulic jack 2 is loaded on the wall pile 11 as a preceding load.

In the present invention, the preceding load caused by the hydraulic jack (2) is transmitted to the load plate 6 via the axial force carrier (3), in this process the elasticity of the rubber plate (5) to act as a whole of the preceding load The stopper 9 partitions the end portions of the straight pile 4a and the inclined pile 4b in contact with the load-bearing plate 6 via the rubber plate 5. As it is maintained without departing from the range, the preceding load generated by the hydraulic jack 2 is evenly distributed to the load bearing plate 6 so that it is not applied as a bias load.

That is, as shown in FIG. 3, the stopper 9 is partitioned and installed at a predetermined range in a portion where the linear pile 4a and the inclined pile 4b of the axial force transmitting body 3 are in contact with each other in the loading plate 6. This stopper 9 is actually provided by welding a material such as L-shaped steel to a steel plate 10 of a suitable form or the like, or directly on one side of the strip 7 that constitutes the load plate 6. Can be attached by installation.

Thus, the straight pile 4a and the inclined pile 4b are held by the stopper 9 which partitions a certain range without slipping to a limited position so that the preceding load through the axial force carrier 3 loses the load. Act to be delivered to (6).

Fig. 4A shows a two-ply arrangement example of the bands 7 constituting the loading plate 6 in the present invention, and Fig. 4B is a side cross-sectional view showing a three-ply arrangement example of the bands 7, in terms of construction site conditions. In the case where the vertical arrangement interval of the wall pile 11 is to be set wide, it is necessary to increase the shear stress of the band sheet 7, and in this case, as shown in FIG. Can be solved by adding.

In practice, the loading board 6 with the two-ply belt 7 or the three-ply belt 7 is placed on and supported on the pedestal 12 integrally attached to the wall pile 11.

As described above, in the preceding load loading system of the retaining wall of the present invention, the pressure applied by the hydraulic jack 2 at the end of the prop 1 is transferred to the axial force carrier 3 to act as a preload on the wall pile 11. Since the axial force carrier 3 is spread out in a straight line 4a and an inclined file 4b and is formed in the same plane, the preceding load applied to the wall pile 11 acts with the same force over a considerable range. Therefore, even if the number of arrangement of the braces 1 is reduced in the space of the trench site, the loading of the desired load of the wall pile 11 can be exhibited.

In addition, when a large preceding load is required and the shear stress of the brace 1 must also be reinforced, the brace 1 may be disposed in two or more layers as illustrated in FIG. 4C to cope with it.

The load-bearing system of the prior art wall of the present invention can also be installed by extending the length of the load plate 6 composed of the band 7.

FIG. 5A shows an example in which the other strips 13 are further connected to both sides of the loading plate 6, and the illustrated example shows the strips in which the other strips 13 to be connected constitute the loading plate 6. 7 shows an example of the connection of the band insertion type inserted into the inner side, and FIG. 5B shows a part of the band length 7 constituting the load carrier plate 6 protrudes to the outside, where the other band length 13 is coaxial. An example of the connection of the strip-protrusion type which is connected to the phase and is fastened with the bolt-nut depending on the padding plate 14 is shown.

According to the present invention, the preload load system of the retaining wall according to the present invention arbitrarily changes the length and width of the prop 1, the axial force carrier 3, and the load plate 6 according to the construction site conditions. Can be installed.

FIG. 6 is a schematic plan view of a site to which the preloading system of the retaining wall according to the present invention is applied, and both end portions of the braces 1 arranged at equal intervals are loaded onto the loading plate 6 through the axial force carrier 3. As a result, the wall pile 11 is supported over a wide range.

For this reason, the number of arrangement | positioning of the said prop 1 becomes remarkably smaller than the conventional method, and the arrangement | interval spacing increases significantly. Since the arrangement interval of the brace 1 can be widened in this way, as shown in FIG. 7, the arrangement interval of the intermediate pile D and the pedestal E, and the arrangement interval of the brace 1 in the vertical direction can also be widened. In particular, the wall pile 11 can be stably supported even if the vertical arrangement interval of the brace 1 is set wide to match the spacing of the building slab, so that the building wall can be cut off and constructed.

As described above, the preloading system of the retaining wall according to the present invention is such that the preloading force of the hydraulic jack interposed in the brace is transmitted to the loading board in a wide range via the straight pile and the slope pile of the axial force carrier. In addition, since the elastic force of the rubber plate interposed between the axial force carrier and the load carrier plate acts so that the preceding load does not act as the unbalanced load, the vertical and horizontal arrangement intervals should be adjusted when arranging the brace according to the excavation of the site. Even if it is set wide, there is an advantage that the support of the wall pile by the load plate is stable.

Accordingly, the spacing of the necessary members such as intermediate piles, pedestals, etc., which are arranged together with the braces in the excavation site can be set wide, thereby creating a wide space, and improving the workability of the excavating equipment. Construction cost is reduced and economical.

In addition, even if the vertical arrangement interval of the brace in the preload load system of the retaining wall according to the present invention is set to a wide range in the range of 3.5m to 4.5m of the interlayer spacing of a general building slab, the support stability of the wall pile is ensured, In addition, the reduction of the amount of used is greatly reduced, and the construction can be simplified without the break of the building wall, thereby simplifying the construction, and the shortening of the air can be obtained. Also, the stability of the building structure resulting from the construction will be excellent. do.

Claims (8)

delete Bracing is disposed in the internal space of the trench construction site at a predetermined interval and receiving a pressing force by the hydraulic jack; It consists of a straight pile and inclined piles arranged obliquely to both sides, and the output ends of the straight pile and the inclined pile are formed in the same plane, the linear pile is connected to the brace in the coaxial direction to broaden the pressing force of the hydraulic jack Axial force carriers to propagate in the range; It is formed by superimposing a plurality of strips in the orthogonal direction on a normal wall pile supporting the ground, and loads the loading plate to prevent ground displacement of the back wall of the retaining wall by loading the preceding load via the axial force carrier as the wall pile. ; A preload load system of a retaining wall in which a rubber plate is interposed between the axial force carrier and the load carrier plate so that the preceding load transmitted via the axial force carrier is not eccentrically transmitted or slipping occurs during transmission. Bracing is disposed in the internal space of the trench construction site at a predetermined interval and receiving a pressing force by the hydraulic jack; It consists of a straight pile and inclined piles arranged obliquely to both sides, and the output ends of the straight pile and the inclined pile are formed in the same plane, the linear pile is connected to the brace in the coaxial direction to broaden the pressing force of the hydraulic jack Axial force carriers to propagate in the range; It is formed by superimposing a plurality of strips in the orthogonal direction on a normal wall pile supporting the ground, and loads the loading plate to prevent ground displacement of the back wall of the retaining wall by loading the preceding load via the axial force carrier as the wall pile. ; And a preloading system of the retaining wall, which is configured with different bands that are further connected to both sides of the loading plate so as to expand the support range of the wall pile. The method according to claim 2, One side of the load carrier plate in contact with the axial force carrier is provided with a stopper located on the outside of the inclined pile to prevent slipping of the axial force carrier, the preload load system of the retaining wall. The method according to claim 3, The loading board is a preloading system of a retaining wall having a configuration in which two or three layers of bands are arranged up and down in order to expand the contact linkage area with the wall pile. delete The method according to claim 3, A preloading system for an earthquake wall consisting of a structure capable of further expanding an area in contact with a wall pile by inserting another stripe on both sides of the strip forming the loading plate. delete

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