KR101298020B1 - Special prestressed method - Google Patents

Abstract

The present invention relates to a temporary earth wall support method for supporting earth pressure generated during open cut ground excavation for underground construction of civil engineering structures or building structures.
Earth wall support method of the present invention, in the earth wall support method, the step of constructing a side pile; Excavation step; Installing a strip and a brace on the earth wall formed by excavation; Installing PS cable fixing devices on both sides of the stripe; Installing a plurality of intermediate load transmission materials at predetermined intervals of the strip length; Fixing both ends to the cable fixing device via the PS cable intermediate load transmitting member; Installing a meter (load meter) on the intermediate load transmission material and the PS cable fixing device; Tensioning the PS cable using the PS cable tensioning means installed in the intermediate load transmission material; Re-straining the PS cable according to the design load by checking the values of each instrument; The process was repeated to design the excavation depth to support the earth walls.

Description

Temporary earth wall support method {SPECIAL PRESTRESSED METHOD}

The present invention relates to a temporary earth wall support method for supporting earth pressure generated during open cut ground excavation for underground construction of civil engineering structures or building structures. It is related to the hypothetical earth-wall support method, which is arranged similarly to the external force and the design control value to the intermediate load transmission material, and to offset and recover the displacement and load by adjusting the tension and stroke.

In general, as a temporary earth wall support method, a preload method using a hydraulic jack for a brace, ground anchor, ground nail, and brace is used.

The strut method is to support the earth pressure on both sides by installing the brace in the excavation interior horizontally and vertically, or to install the plural intermediate piles to prevent the buckling of the brace and after constructing the structure by this intermediate pile Inevitably there is a disadvantage in that a hole is generated in the slab to cause a waterproofing problem.

In addition, the intermediate piles and the braces installed in the horizontal / vertical directions impede the import of materials for the construction of the structure or impede the overall work such as the rebar and the formwork, making the work difficult and the air longer. This also leads to problems in structure quality control due to the narrow working space.

The ground anchor method is a method for supporting the earth pressure by applying an anchor to the earth wall provided by the excavation to apply a tensile force to the anchor.

This can improve the problem of the reinforcement method to some extent, but there is a problem of civil complaints due to the vibration and ground subsidence generated during the drilling process for anchor installation may cause damage to the adjacent structure, underground buried material. In addition, in the soft ground, the friction between the anchor body and the ground is small, there is a disadvantage that the length of the anchor must be increased in order to obtain the desired ground support force, which leads to an increase in construction cost.

The ground nail method is to install a steel bar or reinforcement to the earth wall ground side provided by excavation so as to support the earth pressure.

This applies when the required anchor length cannot be secured due to the intersection of adjacent underground structures or underground burials. This method has problems such as structural stability and excessive ground displacement due to unsuccessful stepping. Therefore, ground conditions are relatively good and are generally limited in the surrounding conditions where ground displacements can be tolerated. In addition, the construction cost increases as more drilling work is involved than the anchoring method, and there is a problem of civil complaints due to the vibration and ground subsidence, such as the anchoring method, which may cause damage to adjacent structures and underground works.

In addition, the preload method using the hydraulic jack on the brace is a method that can maintain the structural stability and minimize the ground displacement by applying the preceding load to the excavation back ground by installing the above-mentioned support method hydraulic jack. However, as the brace method, braces in the middle pile and horizontal / vertical direction are obstacles to earthworks and construction of the structure. In the case of the scene, excessive steel requirements and problems are still followed.

In addition, Korean Patent Laid-Open Publication Nos. 2003-19937 and 2004-31451 present prestressed temporary installations and their construction methods, which have greatly reduced the number of intermediary piles, which caused many obstacles in the construction of facilities by using a number of triangular pedestals, fixing devices, and steel wires. have. This method is to reduce the number of braces and intermediate piles by tensioning the steel wires in the corner fixing device and applying prestress to a separate band installed on the pedestal.

However, in order to apply prestress to the entire band of bands through the pedestals in the narrow space of the corner where the fixing device is installed, very large tensile force (over 100ton) is required. Inconvenient work, there is a safety problem during construction. In addition, as the strength of the prestress applied according to the position of the tensile point is different, there is a risk of poor construction unlike the intention of the designer. Even if the prestress is applied uniformly regardless of the position of the tensile point, it is applied uniformly regardless of the soil condition of the earth wall, so excessive prestress is applied in the good ground, and in the case of soft ground, prestress is insufficient. There is a problem. In addition, there is a disadvantage in that the working time is lengthened because the work must be continued while cutting the elongated wire due to the elastic elongation of the wire.

As described above, in order to solve the problems of the conventional earth wall support method, the present invention arranges the load transmission brace and the reaction force band in a similar manner as the moment shape with the PS cable to reload the load and design management by the external force as the intermediate load transmission material. Tension and stroke adjustment provides offset and resilience against displacements and loads, greatly reducing the number of braces and intermediate piles, and adjusting prestressing forces at each intermediate load carrier location to ensure uniform support. At the same time, the purpose is to be able to freely carry out load adjustment work as needed.

Earth wall support method according to the present invention for achieving the above object,

In the earth wall support method,

Constructing a side pile;

Excavation step;

Installing a strip and a brace on the earth wall formed by excavation;

Installing PS cable fixing devices on both sides of the stripe;

Installing a plurality of intermediate load transmission materials at predetermined intervals of the strip length;

Fixing both ends to the cable fixing device via the PS cable intermediate load transmitting member;

Installing a meter (load meter) on the intermediate load transmission material and the PS cable fixing device;

Tensioning the PS cable using the PS cable tensioning means installed in the intermediate load transmission material;

Re-straining the PS cable according to the design load by checking the values of each instrument;

The process is repeated to design the excavation depth, characterized in that to support the earth wall.

In addition, the shape of the cable that is the load transfer brace and the reaction force is characterized in that the arrangement similar to the moment formation.

In addition, the apparatus for supporting the earth wall,

A PS cable fixing device configured on both sides of the stripe;

A plurality of intermediate load transfer members disposed between both PS cable fixing devices and having an actuator function for adding or reducing the tension of the PS cable;

A PS cable fixed at both ends to the PS cable fixing device via the intermediate load transfer member;

Characterized in that it consists of; a measuring instrument (loader) is installed at the PS cable support point.

In addition, the intermediate load transmission member forms a longitudinal long hole through which the PS cable passes, and a holder having a PS cable hole in communication with the long hole therein, and connected to the holder to an end portion of the intermediate load transmission member. The screw shaft is exposed, and the tension nut is fastened to the screw shaft from the outside of the end portion of the intermediate load transmission material.

The earth wall construction method according to the present invention having the structure as described above is the most information construction and construction that is offset by the adjustment of the stroke of the active intermediate load transmission material to be adjusted while feeding back with the field measurement value and the design management value for the load and displacement by the external force Sanctification can be achieved.

In addition, according to the most information-based construction, it has the effect of avoiding the structural stability to the best by quickly responding to the situation in the field and maintaining the elastic stress so that it is always elastic.

In addition, there is an advantage that can be extended to a wide range of applications depending on site conditions to increase the applicability of the site.

In addition, the above-mentioned advantages can reduce the amount of steel and the joint portion compared to the conventional methods, there is an advantage that can reduce the air shortening and construction costs accordingly.

1 is a schematic process diagram of the earth wall support method according to the present invention.
Figure 2 is a front view showing the structure of the earth wall support method according to the present invention.
3 is a cross-sectional view taken along the line AA.
Figure 4 is an enlarged cross-sectional view of the main portion of the PS fixing device of the present invention.
Figure 5 is an enlarged plan sectional view of the main portion of the PS fixing device of the present invention.
6 is a sectional view taken along line BB of Fig.
7 is a cross-sectional view taken along line CC of FIG. 4.
8 is a perspective view showing the structure of the intermediate load transmission material according to the present invention.
9 is a planar cross-sectional view showing the main portion of the structure of the intermediate load transmission material according to the present invention.
Fig. 10 is a side sectional view of a main portion showing the structure of an intermediate load transmission material according to the present invention.
11 is another embodiment of the present invention intermediate load transmission.

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

According to Figure 1, the earth wall support method according to the invention, the step of constructing a side pile (10); Excavation step; Installing a strip 14 and a brace 12 on the earth wall formed by excavation; Installing PS cable fixing devices (20) on both sides of the strip (14); Installing a plurality of intermediate load transfer members (30) at predetermined intervals of the belt (14); Fixing both ends to the cable fixing device via the PS cable 50 and the intermediate load transfer member 30; Installing a measuring instrument (load meter) on the intermediate load transmission material 30 and the PS cable fixing device 20; Tensioning the PS cable 50 using the PS cable 50 tensioning means installed in the intermediate load transmission material 30; Re-straining the PS cable 50 according to the design load by checking the value of each instrument; The process is repeated to design the excavation depth to support the earth walls.

The shape of the PS cable 50 that is the reaction force band with the intermediate load transmission material 30 is disposed similar to the moment formation.

In particular, the apparatus to be applied to the STM system method of the present invention is installed on the belt 14 to install the side pile 10, and to support the earth wall after excavation. According to the length of the both ends or the length of the belt 14, the brace 12 is installed in the middle portion, the temporary earth wall support device of the present invention is installed between the brace 12.

The temporary earth wall support device includes a PS cable fixing device 20 configured at both sides of the strip 14; A plurality of intermediate load transfer members 30 disposed between both PS cable fixing devices 20 and having an actuator function for adding and subtracting a tension force of the PS cable 50; A PS cable 50 having both ends fixed to the PS cable fixing device 20 via the intermediate load transfer member 30; It consists of a measuring instrument (loader) installed in the PS cable 50 support point.

In particular, the intermediate load transmission material 30 determines the length and number according to the calculation of the interval of the support. This intermediate load transmission material 30 has a longitudinal long hole 31 through which the PS cable 50 penetrates on both sides in a circular or polygonal pipe structure having a hollow inside. This long hole 31 is for tensioning the PS cable 50 in the longitudinal direction. The holder 32 for mounting the PS cable is embedded in the intermediate load transfer member 30, and the screw shaft 33 exposed to the end of the intermediate load transfer member 30 is connected to the holder 32. The tension nut 34 is fastened to the screw shaft 33 exposed to the outside of the end portion of the intermediate load transmission material 30.

Holder 32 is a tubular body that is installed through the long hole 31, is installed through the connecting plate 35, the stepped at the inlet to the connecting plate 35 corresponding to the screw shaft 33 end ( The holder 32 and the screw shaft 33 are connected to each other by forming an opening hole 351 having a 352 so that the connection nut 353 is seated therein so that the screw shaft 33 is fastened through the inlet.

In addition, the screw shaft 33 and the holder 32 is provided with a guide 40 spaced apart from the inner diameter of the intermediate load transmission member 30 at a predetermined interval so as to move in a stable track. The guide 40 has a hole in the connection plate 35 is formed in the center portion is connected to the connection plate 35 is inserted.

In addition, ribs 36 formed on both sides of the intermediate load transmission member 30 in parallel with the same or larger intervals than the long holes 31 are formed on both sides of the long holes 31. A plurality of bolt holes 37 are formed at regular intervals at 36. This is to be fixed by holding the holder 32 by inserting a fixing bolt 38 in the bolt hole 37 when applying the appropriate tension force of the PS cable 50 to fix the position.

Of such a structure; The intermediate load transmission material 30 is bolted to the belt 14 by forming a flange at one end. Of course, welded joints can be allowed depending on site conditions.

In addition, the shape of the intermediate load transmission material 30 and the PS cable 50, which is a reaction band, is arranged similarly to the moment formation acting on the strip 14 according to the earth pressure and the water pressure of the earth wall. That is, since the moment shape has a parabolic structure in which both ends of the strip 14 are convex to the center, the intermediate load transfer member in a direction close to the direction of the force at the point where the PS cable 50 is supported by the intermediate load transfer member 30. It forms the direction of (30). In this way, the intermediate load transmission material 30 located in the center of the belt 14 is connected to a right angle and is inclined toward both ends. And the length of the intermediate load transmission material 30 becomes short from the center part of the strip 14 to both ends.

In addition, the PS cable fixing device 20 is provided with a support 20 is fixed to both sides of the strip 14, the central portion of the support 20 is a plurality of PS cable 50 is individually installed through PS cable hole 24 is formed, the cable hole is provided with a cable pressing hole (26). The cable pressing hole 26 is formed in the center of the cable insertion hole and tapered in the form of a wedge narrowing in the direction of the tip and at the same time cut grooves 27 are formed on both sides to insert the cable into the cable insertion hole and the tip above the If the PS cable 50 is pulled in the tensioned direction while being inserted into the PS cable hole 24, the cable pressing hole 26 is also inserted into the PS cable hole 24 of the support 20 together with the cable. At this time, while the end of the cable pressing hole 26 is lodged in the PS cable hole 24, the notch groove 27 is narrowed to press the PS cable 50 so that the PS cable 50 is no longer the PS cable hole 24 ) Can't escape and is firmly fixed.

When the temporary earth wall support device of the present invention is installed as described above, the both ends of the PS cable 50 are firmly fixed to the PS fixing device, and then the hydraulic jack 60 (actuator) installed on the intermediate load transmission material 30 is used. By retracting the screw shaft 33 by operating the fastening nut, the PS cable 50 is tensioned by pulling the holder 32 connected therein. At this time, the hydraulic jack 60 is installed to the pressure gauge 62 as shown in Figure 11 so that the contractor can visually check the pressure.

When the PS cable 50 is tensioned, the measurement load value is increased in the measuring instruments installed in each intermediate load transmission material 30, and thus, until the design load value is reached.

When the design load value is reached, the operation of the hydraulic jack 60 is stopped, and the measuring instrument installed in each intermediate load transmission material 30 is checked. Since the hydraulic jack 60 operates in one place to tension the PS cable 50, the measuring device may be caused by factors such as the frictional force between the PS cable 50 and the holder 32, the characteristics of the PS cable 50, and the characteristics of the ground. The measured values of appear differently.

At this time, the tightening nut is rotated in accordance with the measured value or the hydraulic jack 60 is used to increase or decrease the tension of the PS cable 50 so as to be close to the design load value.

When the first stage SPM system is completed, the same procedure as in the beginning is repeated to firmly support the earth wall of the depth according to the design.

10-Side Pile 12-Brace 14-Belt
20-PS cable retainer 22-Support 24-PS cable hole
26-Cable inlet 27-Cutout 28-Cable insertion hole
30-Medium load carrier 31-Long hole 32-Holder
33-Screw shaft 34-Tension nut 35-Connecting plate
351-Opening hole 352-Stepped 353-Connecting nut
36-Rib 37-Bolted hole 38-Positioning bolt
40-Guide 42-Connecting plate hole 50-PS cable

Claims (6)

In the earth wall support method,
Vertically installing the side piles 10 at regular intervals;
Rowing the strip 14 at the tip of the side pile 10;
Installing the PS cable fixing device 20 at both ends of the strip 14;
Installing a plurality of intermediate load transmitting members 30 at the front end of the strip 14;
Fixing both ends of the PS cable 50 to the PS cable fixing device 20 to be mounted on the intermediate load transfer member 30;
Installing an instrument (load meter) on the intermediate load transmission material 30 and the PS cable fixing device 20;
Tensioning the PS cable 50 by manipulating the intermediate load transmission material 30;
The intermediate load transmission member 30 forms a long hole 31 penetrated to both sides of the body in the longitudinal direction, and is provided with a holder 32 for mounting the PS cable 50 to slide in the long hole 31. The cable 50 penetrates the intermediate load transmission member 30, and the screw shaft 33 is helically coupled to the body, but the end of the cable 50 is installed to be idling with the holder 32, and the holder 32 when the screw shaft 33 is rotated. Temporary earth wall support method, characterized in that the tension nut (34) is fastened to the screw shaft (33) to be transported along the long hole (31) to prevent the rotation of the screw shaft (33). delete delete delete delete delete

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