KR100440726B1 - Apparatus for confirming well barrel's foundation on rock floor in the bridge base - Google Patents

Abstract

The present invention relates to a well that serves as a foundation for bridges and bridges during bridge construction, and more particularly, whether the bottom of the well is mounted on a rock having a certain strength in the construction of the well. The present invention relates to a rock-mounting verification device for bridge foundation wells that can be accurately confirmed and safely performed.

Rock-mounting confirmation device of the well of the present invention is a plurality of pipes 20 installed in the longitudinal direction in the well 10, the cable 30 is installed in the plurality of pipes 20 to propagate ultrasonic waves And an ultrasonic sensor 40 installed at the tip of the cable 30 to emit ultrasonic waves to the rock and receiving the ultrasonic waves reflected from the rock, and generating ultrasonic waves as being connected to the end of the cable 30. And an ultrasonic analyzer 50 for propagating to the ultrasonic sensor 40 and analyzing the components of the rock by analyzing the ultrasonic waves received from the ultrasonic sensor 40 and the cable 30.

Description

Rock mounting confirmation device for bridge foundation wells {APPARATUS FOR CONFIRMING WELL BARREL'S FOUNDATION ON ROCK FLOOR IN THE BRIDGE BASE}

The present invention relates to a well that serves as a foundation for bridges and bridges during bridge construction, and more particularly, whether the bottom of the well is mounted on a rock having a certain strength in the construction of the well. The present invention relates to a rock-mounting verification device for bridge foundation wells that can be accurately confirmed and safely performed.

In general, when constructing a bridge, a well hole method is used to sink a well bucket into the ground as a foundation of a bridge. The wells are installed by the following procedure.

First, as shown in FIG. 1a, the earth and sand and the gravel are stacked on the river bed on which the pier is to be erected, and the ground rises above the water, and then the concrete cylinder 1a of the predetermined height is opened on the ground. The lower end of the concrete cylinder (1a) is formed in a wedge shape as shown to effectively dig the ground. In this state, when excavating soil and ground soil in the concrete cylinder (1a), the concrete cylinder (1a) is settled into the ground by its own weight.

Next, as shown in FIG. 1B, formwork is installed on the upper portion of the concrete cylinder 1a, and the concrete is poured to connect the concrete cylinder 1b of a predetermined height. When the ground in the concrete cylinders 1a and 1b is excavated again, the concrete cylinders 1a and 1b are settled back into the ground by their own weight. Again install the formwork on the upper portion of the concrete cylinder (1b) and extend the new concrete cylinder (1c) by pouring concrete.

This process is repeated so that the bottom concrete cylinder (1a) is mounted on the rock with a certain strength.

2 shows a state in which a well 1 formed of a plurality of concrete cylinders by the above process is mounted on a rock bed. When the well (1) is mounted on the rock, concrete is poured into the well (1). First, the concrete (2a) that is well cured in water is poured, and the filling concrete (2b) is poured on it. Next, the cover concrete 2c is poured to complete the foundation of the piers.

The well 1 as described above can be mounted on a solid rock to support the load of the bridge, so when the well 1 is installed, it must be checked whether the well 1 is mounted on a solid rock.

Conventionally, there is a method for confirming rock mounting of the well 1 by a direct inspection confirmation method and an indirect inspection confirmation method.

The direct inspection method is to excavate the well (1) to the rock surface of the design depth and settle down, perform the pumping work in the well (1), and then use the lifting mechanism to inspect the bottom of the well in the well (1) It is a method to directly check whether the excavation bottom of the well 1 is mounted on the rock.

This direct inspection check method has the advantage that it is easy to ensure the quality control by direct visual confirmation and easily determine whether the lower part of the well 1 is eccentric with respect to the upper part during installation.

However, since the water in the well (1) has to be pumped out, air and construction costs increase, and when the lower end of the well (1) is not securely mounted on the rock, water is gradually introduced between the bottom of the well and the ground. There is a safety problem because there is a risk of incoming boiling and a hebbing phenomenon where water enters all at once, and it is a check method that depends on the naked eye, so depending on the experience of the inspector, There is a tendency that the bottom of the well is considered to be mounted on the rock by checking only the rock at the center of the excavation base without checking the bottom.

Indirect inspection check method is to check whether the diver is submerged to the excavation bottom of the well and visually take a picture while reading the photo to confirm the rock installation, and to collect rock specimens from the excavation bottom There is a method of requesting a test institution to determine whether the rock is installed by checking whether it is a rock having a certain strength or more.

Such an indirect method has the advantage that it can inspect rock at the bottom of the excavation even if the depth of water is deep and it is relatively easy.However, in the case of visual confirmation by divers, there are many subjective factors, which leads to reliability problems. In case of confirmation, there is a problem that image quality is blurred, so accurate inspection is impossible.In the case of confirmation by rock specimen, the collected rock specimen is not at the bottom of the well but is often at the center of the excavation bottom. The disadvantage is that you cannot accurately grasp the state.

The present invention is to solve the problems of the prior art, an object of the present invention can accurately check the rock state of the bottom of the well, which is the edge of the excavation bottom, to ensure the stability of the check operation, the settlement of the well It is easy to check regardless of depth, and provides reliable objective inspection results, and provides a rock-mounting confirmation device for bridge foundation wells that shortens the air required for inspection and reduces costs.

Rock-mounting confirmation device of the well of the present invention for achieving the above object is a plurality of pipes installed in the lengthwise direction inside the well, the cable is installed in the plurality of pipes, the ultrasonic wave is installed at the tip of the cable Ultrasonic sensor for launching and receiving the ultrasonic waves reflected from the rock, and the ultrasonic wave connected to the end of the cable to generate an ultrasonic wave propagated to the cable and the ultrasonic sensor and analyze the ultrasonic wave received from the ultrasonic sensor and the cable to analyze the components of the rock It consists of an ultrasonic analyzer.

Figure 1a is a cross-sectional view of the lower concrete cylinder of the well showing the general installation process of the well basin bridge;

Figure 1b is a cross-sectional view of the lower concrete cylinder and the middle concrete cylinder of the well showing the general installation process of the well basin bridge;

Figure 2 is a longitudinal cross-sectional view of the installation state of a common well basin bridge;

Figure 3 is a longitudinal cross-sectional view of the installation state of the well bucket of the present invention,

Figure 4 is a cross-sectional view of the well bucket of the present invention cut along the line A-A in Figure 3,

Figure 5 is a block diagram showing an ultrasonic analyzer, cable and ultrasonic sensor of the rock device check device of the well bucket of the present invention.

<Code Description of Main Parts of Drawing>

1: well cylinder 1a, 1b, 1c: concrete cylinder

2a: underwater concrete 2b: filled concrete

2c: cover concrete 10: well

10a, 10b, 10c: concrete cylinder 11a: underwater concrete

11b: filling concrete 11c: cover concrete

20: pipe 20a, 20b, 20c: unit pipe

21: joint member 30: cable

40: ultrasonic sensor 50: ultrasonic analyzer

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

Figure 3 is a longitudinal cross-sectional view of the installation state of the well bucket of the present invention, Figure 4 is a cross-sectional view of the well bucket of the present invention cut by the line AA in Figure 3, Figure 5 is an ultrasonic wave of the rock device check device of the well bucket of the present invention It is a block diagram which shows an analyzer, a cable, and an ultrasonic sensor.

As shown, the rock mounting confirmation device of the well according to the present invention includes a plurality of pipes 20 installed in the lengthwise direction in the well 10, a cable 30 installed in the plurality of pipes 20, An ultrasonic sensor 40 installed at the tip of the cable 30 to emit ultrasonic waves to the rock and receiving ultrasonic waves reflected from the rock, and ultrasonic waves generated as being connected to an end of the cable 30 to generate the ultrasonic waves. And an ultrasonic analyzer 50 for propagating to the ultrasonic sensor 40 and analyzing the components of the rock by analyzing the ultrasonic waves received from the ultrasonic sensor 40 and the cable 30.

The plurality of pipes 20 are installed in a well angled position in the well 10 as shown in Figure 4, the four pipes 20 are respectively installed at a position forming an angle of 90 degrees.

Installation of the pipes 20 is installed by the following process.

First, when manufacturing the lowermost concrete cylinder 10a forming the well 10, the unit pipe 20a of a predetermined length is impregnated. The lowermost concrete cylinder 10a is placed on the ground to be installed according to the conventional method, and the inside thereof is excavated to sink the concrete cylinder 10a to a predetermined depth.

Next, a unit pipe 20b having a predetermined length is connected to the unit pipe 20a to form a mold, and then concrete is formed to form a concrete cylinder 10b, between the unit pipe 20a and the unit pipe 20b. Since the remnants of concrete should not be allowed to soak in, install an appropriate joint member (21).

After excavating the inside again, the concrete cylinders 10a and 10b are settled to a predetermined depth, and then the unit pipe 20b is connected to the unit pipe 20b in the same manner as the above method, and the concrete is formed by placing the concrete with the formwork installed. The cylinder 10c is formed.

This process is repeated until the bottom of the well 10 is mounted in the design depth or rock to install the pipe 20 in the well 10,

Pipe 20 located at the bottom of the well (10) may be damaged by ground excavation or blasting, so the pipe 20 around the bottom of the well (10) should be reinforced.

The method for confirming whether the well 10 is mounted on a rock with a certain strength by using the rock mounting confirmation device of the well according to the present invention as described above is as follows.

First, the cable 30 with the ultrasonic sensor 40 installed at the tip is inserted into the inner space of the pipe 20 so that the ultrasonic sensor 40 is lowered to the bottom of the well 10 and the end of the cable 30 is removed by the ultrasonic analyzer ( 50).

Next, the ultrasonic analyzer 50 is operated to generate ultrasonic waves to propagate to the cable 30 and the ultrasonic sensors 40 and to emit ultrasonic waves from the ultrasonic sensors 40.

When ultrasonic waves having a predetermined wavelength and amplitude are emitted from the ultrasonic sensor 40, ultrasonic waves are reflected by the rock, and the reflected ultrasonic waves are received by the ultrasonic sensor 40 and input to the ultrasonic analyzer 50 via the cable 30. . The ultrasonic analyzer 40 analyzes the wavelength and amplitude of the input ultrasonic waves to analyze whether the bottom of the well 10 is mounted on a solid rock bed.

The reflected ultrasonic waves are different depending on the type of soil and rock where the bottom of the well 10 is located, so that the well 10 may be mounted on a desired rock bed.

The rock mounting confirmation by the ultrasonic analysis as described above may be carried out by putting the ultrasonic sensor 40 and the cable 30 at the same time in the four pipes 20, or may be carried out in the pipe 20 sequentially. .

If any part of the well 10 is not mounted on a solid rock, the above process is repeated to continue to sink the well 10.

In the case where the well 10 is placed on a rock having the required strength, concrete is poured into the inside of the well 10 as in the prior art. First, an underwater concrete 11a that is well cured in water is poured and The filling concrete 11b is poured, and finally, the cover concrete 11c is poured to complete the foundation of the piers.

The rock mounting confirmation device of the well of the present invention can reduce the construction cost because it is not necessary to pump the work inside the well 10 to confirm the rock installation of the well 10, the inspector or the diver inside the well There is no need to enter to prevent accidents.

In addition, since the present invention is a scientific method compared to the conventional method, it is possible to objectively check whether the rock is mounted accurately, and in particular, it is possible to accurately check whether the bottom of the well 10 is mounted, that is, whether the rock at the edge of the bottom of the excavation is accurate. Can be.

In addition, the present invention does not require pumping work, and it is possible to promptly check whether the rock is installed immediately at the construction site without requiring a procedure such as requesting a test institution or analyzing a photograph taken after the collection of rock specimens. Propulsion can be done to shorten the air.

As described above, the rock mounting confirmation device of the well of the present invention can accurately check the rock state of the bottom of the well, which is the edge of the excavation bottom, there is no problem of stability during the check operation, the settlement of the well It can be easily checked regardless of the depth, reliable and objective test results can be obtained, and the effect of reducing the air required for the inspection and reducing the cost is achieved.

Although the invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that modifications and variations can be made within the spirit and scope of the invention, and such modifications and variations will fall within the scope of the appended claims.

Claims (3)

A plurality of pipes 20 installed in the longitudinal direction in the well 10, Cable 30 is installed inside the plurality of pipes 20 to propagate ultrasonic waves, An ultrasonic sensor 40 installed at the tip of the cable 30 to emit ultrasonic waves to the rock and receive ultrasonic waves reflected from the rock; The ultrasonic wave is generated as being connected to the end of the cable 30, propagates to the cable 30 and the ultrasonic sensor 40, and analyzes the ultrasonic waves received from the ultrasonic sensor 40 and the cable 30 to analyze the components of the rock. Rock mounting confirmation device of the bridge foundation well, characterized in that consisting of an ultrasonic analyzer (50). The apparatus of claim 1, wherein the pipe (20) is composed of a plurality of unit pipes, and the plurality of unit pipes are connected to each other by a joint member (21). 2. The rock mounting confirmation apparatus of claim 1, wherein the plurality of pipes (20) are four pipes each installed at a position forming a 90 degree angle of the well (10).