KR20030085264A - soil sheathing method of rahmaen frame using prestress support and bracket and bracket thereof - Google Patents

Abstract

PURPOSE: A sheeting method of a Rahmen structure using a prestress wale bearing beam and panel point metallic materials is provided to bear earth pressure added on a retaining wall effectively, to secure a working space economically and effectively by excluding the installation of a strut, to shorten a period of construction and to apply for medium and small sites. CONSTITUTION: The sheeting method of a Rahmen structure using a prestress wale bearing beam and panel point metallic materials comprises the steps of interposing excavation piles vertically, installing wales horizontally on the front of the pile, attaching prestress wale bearing beams(3,3') on the surface of the wales by bolting, locating folded panel point metallic materials(4) on an intersection of the prestress wale bearing beam(3) and the prestress wale bearing beam(3'), then coupling the wales, the prestress wale bearing beam(3,3') and the panel point metallic materials(4) to be unified, so that each one of wales, prestress wale bearing beams(3,3') and panel point metallic materials(4) is formed to have a Rahmen structure which occurs evenly-distributed moments to support retaining walls and to occur resistance against earth pressure.

Description

Soil sheathing method of rahmaen frame using prestress support and bracket and bracket approximately}

The present invention relates to an earthquake method that supports the earth wall excavated at a civil engineering site to prevent the earth wall from collapsing. Particularly, the present invention relates to a pre-stress band support beam and a prestress band support interpolation in a state where a plurality of prestress band support beams are fixed to the band member. By combining a separate hardware at the gap, it becomes a raamen structure in which all of the banding material, prestressed band support, and the point hardware are integrated into one body, making the structure very simple and achieving a significant effect on the working space. It is a short-stacked raamen structure.

Existing earthquake construction is divided into a concrete permanent earthquake that is integrally formed on the earth wall or rock wall, and a temporary earthquake project that is installed to prevent the earth wall or rock wall from collapsing only during excavation work and then dismantled after completion of construction.

In general, during temporary construction, the H-beam struts are erected at random intervals, and earth plate or rock walls are supported by stacking earth plate between them to secure the H-beam struts to the wall. Multiple struts or earth anchors were installed in the ground and the brackets were firmly fixed to the H-beams by brackets to withstand the earth pressure.

That is, as shown in FIG. 5, a plurality of props 101, 101 ′ are formed in a lattice and oblique directions in an excavation space where the ends of the plurality of strips 100 are interviewed with each other, thereby supporting the props 101, 101 ′. By fixing the banding material 100 by) there is a support method that withstands the earth pressure generated from the earth wall,

As shown in FIG. 6, the earth anchors 102 embedded in the ground by inserting and fixing a plurality of earth anchors 102 and 102 ′ with a predetermined length so that the ends of the strip member 100 face the earth wall from the excavation spaces interviewed with each other. There is an earth anchor method to withstand the earth pressure generated from the fixing of the strip member 100 and the earth wall by the fixing force of (102 ').

However, the reinforcement method described above is not only uneconomical because of heavy steel usage, but also has a very narrow work space by a plurality of reinforcement beams. Slow air is a very long problem.

In addition, the above-mentioned earth anchor method has a merit that the work space in the excavation space is largely secured by inserting and fixing a plurality of earth anchors in the ground, but the earth anchor insertion space around the excavation space is necessary so that the adjacent ground There is a hassle to obtain the use agreement of the, and the back space and the work is difficult by the earth anchor in the length, in particular, when the anchoring ground is weak, there is an unsuitable problem of the fixing force of the earth anchor falls.

Therefore, as in Patent Registration No. 188465 issued and registered by the applicant of the present invention to eliminate the problems as described above, instead of the conventional struts or earth anchors, by installing a lap band with a cable mounted on the girdle, a predetermined length is provided at both ends. The prestressing (prestressing) by using the prestressing moment generated in the banding material by using a prestressing band support method to resist the earth pressure has been provided.

However, there is a problem in that the earth retaining method also has to use a brace on the gap point where the ends of the prestressed gird support and the prestressed gird support are perpendicular to each other.

Since one prestress band support beam exerts a prestress moment only on the soil wall on one side, there is a relatively weak problem with the earth pressure acting on both ends of the strip support beam.

The present invention has been made to eliminate the problems described above, by placing a separate hardware bracket on the gap point opposite the ends of the plurality of pre-stress strip support beams, thereby integrating each pre-stress strip support and strip material. By combining them into the laminar structure,

The Raamen structure effectively withstands the earth pressure acting on the front of each earthen wall, and requires no installation of the brace, so it is very economical and can secure a breakthrough work space. It is an object of the present invention to provide a raamen structure mud-proof method using prestressed band-supports and gap point hardware, which is particularly suitable for medium and small-sized sites, which can shorten air because there is no interference.

Figure 1 is an exploded perspective view showing a coupling state of the prestressed strip girders and the hot spot hardware according to the present invention

Figure 2 is a front view showing a coupling state of the pre-stressed gimbal support beam and the point hardware according to the present invention

Figure 3 is a moment diagram acting on the soil wall by the soil barrier method according to the present invention aamen structure

Figure 4 is a construction state of the excavation earth wall to which the present invention earthquake method is applied

Figure 5 is a state diagram of the construction of the conventional earthquake construction method using a brace

Figure 6 is a state diagram of the construction of the conventional earthquake method using an earth anchor

Explanation of symbols on the main parts of the drawings

1,1 ': File 2,2': Belt strip

3,3 ': Prestressed girders 4,4': Separation point hardware

5,5 ': Mating hole 6,6': Finishing plate

7: reinforcement stand 8,8 ': fixing hole

9,9 ': gusset

Hereinafter, preferred embodiments of the present invention will be described.

1 is a combined perspective view showing the pre-stress stripe support beam and the point hardware separated according to the present invention, and FIG. 2 is an enlarged view of the main portion of the prestressed strip support beam and the point hardware.

Insert the excavation pile (1) 1 'in the longitudinal direction, and install the stripping material (2) (2') in the transverse direction on the front surface of the pile (1), the stripping material (2) (2 ') In the well-known earth film construction method which attaches prestressed stripe support beam 3 (3 ') by bolt joining to the surface of

The bending point hardware 4 and 4 'is positioned at the intersecting point at which the ends of the prestressed stripe support 3 and the prestressed stripe support 3' described above are opposed to each other. (2 ') and prestressed band-supports (3) (3') and hot spot hardware (4) (4 ') are combined and fixed to be integrated,

Each of the integrated strip material (2) (2 '), prestress strip material support (3) (3'), and the point hardware (4) (4 ') becomes a ramen structure in which a uniformly distributed moment is generated. Simultaneous support of the soil walls on all sides is to create a resistance to earth pressure.

The hot spot hardware (4) (4 ') used in this method forms a closing plate (6) (6') formed in a plurality of coupling holes (5) (5 ') at both ends of the right-angle H-shaped steel, A reinforcing rod 7 is formed on one side of the right-angled point hardware 4 and 4 ', and a plurality of fixing holes 8 and 8' are continuously formed on the other main surface of the point hardware 4 and 4 '. By connecting the two ends of the prestressing strip support beam (3) (3 ') spaced by the coupling holes (5) (5') of the closing plate (6) (6 '), and a plurality of fixing holes (8) (8 ') is configured to be combined with the banding member (2) (2').

Further, on both sides of the H-shaped steel points 4 and 4 ', a right-angle bent reinforcement plate 9 and 9' is further formed, and according to the construction scale of the points 4 and 4 '. It can also increase strength.

Referring to the operation of the present invention by the above configuration in more detail by the accompanying drawings as follows.

First, as in the conventional strut method and earth anchor method, the excavation H-pile or sheet pile (Sheet Pile) is inserted and excavated, and the banding material (1) (1 ') in the horizontal direction in front of the pile ( 2) Install (2 ').

Attach the prestressed stripe support (3) (3 ') to the surface of the stripe material (2) (2') thus installed, but the stripe support (2) (2 ') and the prestressed stripe support (3) (3). ') Is bolted to each other through a plurality of bolt holes formed in each flange portion.

In this way, the prestressed stripe support beams 3 and 3 'installed at the middle of the stripping material 2 and 2' of each excavation surface have another prestressed stripe support beams 3 and 3 'at right angles to each other. Spaced apart from each other,

At this time, the end plate 6 of both ends of the point hardware (4) (4 ') in a state where the right-angled point hardware (4) (4') is located at both ends of the prestressed strip support beam (3) (3 '). The prestressed stripe support (3) (3 ') spaced apart from the prestressed stripe support (3) (3'), which is formed using the coupling holes (5) (5 ') formed in the (6'). Will be connected to each other.

In addition, by using a plurality of fixing holes (8) (8 ') continuously formed on one side of the hot spot hardware (4) (4') and bolted to the band member (2) (2 ') described above. (2 '), prestressed strip girders (3) (3'), and hot spot hardware (4) (4 ') are all integrated.

This integrated configuration has a ramen structure as shown in FIG. 3 so that the corner points of each corner become fixed support points.

Therefore, in the state where the moment due to the earth pressure is concentrated to the center part, the center moment is distributed to both sides by the prestressed band support beams (3) (3 ') to block the concentration of bending and earth pressure. It spreads and spreads evenly to the front surface, thereby minimizing the concentrated load of the prestressed stripe support (2) (2 '), and attaining the material reduction effect by the distribution of the overall earth pressure.

Therefore, as shown in FIG. 4, the earthen construction method of the Raamen structure connected to each other in a rectangular frame with respect to the excavation surface is relatively easy to install and dismantle, but does not require any braces, and the work space is greatly increased as well as air. It will contribute greatly to the reduction of.

In addition, the reinforcing rod 7 formed on one side of the aforementioned point hardware 4 and 4 'and the reinforcing plates 9 and 9' welded to both sides are for increasing the strength of the point hardware. Therefore, it can be used by welding the reinforcing rod and reinforcement plate of various sizes and thicknesses

Prestressed stripe support (2) (2 ') Also, because the tension cable is a single wire, or using a variety of support, such as double or double wire, it can be applied to a wider scale of site.

As described above, the present invention includes the pre-stressed gimbal support and the earthen construction method of the ramen structure using the point hardware, and the point hardware can effectively withstand the earth pressure acting on the entire earth wall by the ramen structure. Since it is not necessary at all, it is very economical and it is possible to secure a groundbreaking work space. The construction speed is very fast and there is no interference with adjacent lands, so the air can be shortened, which is particularly suitable for small and medium sites.

Claims (3)

Insert the excavation pile (1) 1 'in the longitudinal direction, and install the stripping material (2) (2') in the transverse direction on the front surface of the pile (1), the stripping material (2) (2 ') In the well-known earth film construction method which attaches prestressed stripe support beam 3 (3 ') by bolt joining to the surface of The bending point hardware 4 and 4 'is positioned at the intersecting point at which the ends of the prestressed stripe support 3 and the prestressed stripe support 3' described above are opposed to each other. (2 '), prestressed band-supports (3) (3'), and hot spot hardware (4) (4 ') to be integrated and fixed, Each of the integrated strip material (2) (2 '), prestress strip material support (3) (3'), and the point hardware (4) (4 ') becomes a ramen structure in which a uniformly distributed moment is generated. A soil-abrasion method using a prestressed band-supported beam and gap point hardware, which simultaneously supports soil walls from all sides and generates resistance to earth pressure. Both ends of the right-sided spaced precast strip support (3) (3 ') are joined at right angles by H-shaped steel points 4 and 4', The hot spot hardware 4 and 4 'form finish plates 6 and 6' formed at a plurality of coupling holes 5 and 5 'at right angles of both ends of the H-shaped steel. 4) A reinforcing plate 7 is formed on one side of the 4 ', and a plurality of fixing holes 8 and 8' are continuously formed on the other main surface of the intervening point 4 and 4 ', thereby finishing the plate. (6) (6 ') connects both ends of prestressed strip support beams (3) (3') spaced by coupling holes (5) (5 '), and to a plurality of fixing holes (8) (8'). Hot-spotted steel for the lamination process using a pre-stressed belt-supported beam and gap-point hardware, characterized in that it is coupled with the strip-holder (2) (2 '). [3] The method according to claim 2, wherein both sides of the H-shaped steel points 4 and 4 'are further attached and secured at right angles to the reinforcement plates 9 and 9'. The pointed steel for the lattice construction using the prestressed girders and the pointed hardware characterized by increasing the strength of