KR101552191B1 - a tests system for tunnel behavior by displacement sensor - Google Patents

Abstract

The present invention relates to a displacement meter module for attaching one or more measurement sensors to an upper surface and a lower surface of a body having a predetermined thickness and forming upper and lower surfaces parallel to each other, And a controller for measuring the magnitude and direction of the force in each region where the behavior is generated after connecting the displacement meter module to the main cable and connecting the main cable to a data logger To a tunnel motion measurement system using a displacement meter.

Description

[0001] The present invention relates to a tunnel system,

The present invention relates to a displacement meter module for attaching one or more measurement sensors to an upper surface and a lower surface of a body having a predetermined thickness and forming upper and lower surfaces parallel to each other, And a controller for measuring the magnitude and direction of the force in each region where the behavior is generated after connecting the displacement meter module to the main cable and connecting the main cable to a data logger To a tunnel motion measurement system using a displacement meter.

Generally, various prior art methods are applied to form a tunnel.

In addition, the above-mentioned preceding work forms the ground condition of the place where the tunnel is to be formed and the perforation for inserting the blasting material for blasting.

Continuously, by drilling at a certain depth in the free shear section to form the tunnel, samples can be collected to confirm the development state and weathering state of the joints present in the rock, distribution characteristics of fracture zones, will be.

In addition, the behavior due to the settlement of the tunnel, etc. is measured while progressing the blasting for forming the tunnel in sequence.

Then, the displacement of the tunnel due to the vibration or the like is measured through a displacement meter or the like which is buried even after completion of the tunnel.

In connection with such a technique, the conventional patent No. 567810 discloses a technique for measuring the amount of preceding settlement when a tunnel is formed.

However, in the case of the preceding settlement amount measuring method, there is a problem that the measuring device for measuring the preceding settlement of the tunnel surface increases in size, making it difficult to mount the measuring device.

Also, in order to solve the above-mentioned problem, a sensor combination body such as a 784985 which can measure inclination can be applied to a tunnel. However, as shown in FIG. 1, A sensor 100 attached to the connection structure 230 of the structure 200 and serving as an inclinometer to sense the inclination angle of the attachment site; The upper structure 210 fixed to the upper structure of the monitored structure, the lower structure 220 fixed to the lower structure, and the lower structure 220 fixed to the upper structure and the lower structure, And an attachment structure 200 connected to the connection structure 230, the connection structure 230 being connected to the cylinder and the rod to be able to expand and contract in length.

The sensor 100 further includes a signal amplifier 110 and a data collector 300 for accumulating the sensed signal to the outside.

However, in the sensor combination as described above, since the data collector 300, the sensor 100, and the signal amplifier 110 are integrally provided and their volume is increased, .

Further, it is impossible to precisely know the magnitude and direction of the compressive force acting in the horizontal and vertical directions, and it is impossible to grasp the action point of the shear force.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the prior art, and it is an object of the present invention to enable estimation of magnitude and direction of a force and a shear point in a tunnel and to obtain data on safety management and efficient construction method during tunnel construction, And to provide a tunneling behavior measuring system using a displacement meter that can be easily installed with a simple configuration and capable of accurate measurement of displacement, so as to minimize the volume and to prevent the breakage due to blasting etc. .

In order to achieve the above object, the present invention provides a displacement meter module having a structure in which a measurement sensor is attached to an upper surface and a lower surface of a body having a predetermined thickness and at least an upper surface and a lower surface, And the displacement meter module is connected to the main cable, and the main cable is connected to the tuner module through a tunnel, And a data logger located at a lower portion of the tunnel.

The displacement meter module of the present invention includes a measurement sensor formed as a strain gauge on the inside of the housing and a controller for giving an ID to measurement values of the respective measurement sensors and connecting the measurement sensors to the main cable, And a data logger having a filter, an A / D converter, a signal amplifier, a data processing unit, an output unit, and a power supply unit integrally connected to the data logger.

In addition, the displacement meter module of the present invention provides a tunneling behavior measuring system using a displacement meter in which a body is formed of a hexahedron and a measurement sensor is mounted on at least two of the six sides.

In addition, the displacement meter module of the present invention includes a vertical stress supporting plate, which is separated from a vertical stress supporting plate, and a load transmitting unit installed to move the vertical stress supporting plate, And a tunnel motion measurement system using the displacement meter.

In addition, the displacement meter module of the present invention includes a vertical stress supporting plate, which is separated from a vertical stress supporting plate, and at least one measuring sensor is mounted on the upper surface of the vertical stress supporting plate, And a horizontal stress supporting plate symmetrically positioned in a direction different from the vertical stress supporting plate and having one or more measuring sensors, respectively.

In addition, the displacement meter module of the present invention provides a tunneling behavior measuring system using a displacement meter in which a horizontal stress supporting plate is connected to an inner side of a pipe mounted on a load transmitting means through a support.

In the displacement meter module according to the present invention, the horizontal stress supporting plate is provided with a slot while being held by a latching protrusion formed on a connecting bar of the load transmitting means, and a load supporting piece for easily transferring stress is connected to both ends of the horizontal stress supporting plate And the load supporting pieces are provided so as to protrude from both sides of the vertical stress supporting plate.

The load transferring means of the present invention provides a tunneling behavior measuring system using a displacement meter selected from a plurality of connecting bars or a filled and hardened connecting block for simultaneously moving the vertical stress supporting plate.

Also, the displacement meter module of the present invention provides a tunneling behavior measuring system using a displacement meter in which a vertical stress supporting plate to which a measurement sensor is fixed is installed separately on the upper side of the load transmitting means.

In addition, the displacement meter module of the present invention is a tunnel motion measurement system using a displacement meter in which a load transmission plate is connected to an upper side of a horizontal stress support plate via at least one attenuation unit, and at least one vertical stress support plate is connected to the upper side of the load transmission plate to provide.

As described above, according to the present invention, it is possible to predict the magnitude and direction of a force and a shear point in a tunnel and to obtain data on safety management and efficient construction method during construction of a tunnel to reduce the construction cost, This is simple and prevents breakage due to blasting and the like, and is easy to install with a simple structure and enables accurate measurement of displacement.

1 is a perspective view of a conventional sensor combination for inclination measurement.
2 is a perspective view showing an installed state of a tunnel behavior measuring system using a displacement meter according to the present invention.
3 is a connection state diagram of a displacement meter module according to the present invention.
4 and 5 are a perspective view and an operational state view showing the displacement meter module according to the present invention, respectively.
6 and 7 are a perspective view and an operational state view showing a displacement meter module according to another embodiment of the present invention, respectively.
8 is an operational state diagram showing a displacement meter module according to the present invention.
9 and 10 are a perspective view and an operational state view showing a displacement meter module according to another embodiment of the present invention, respectively.
11 is an operational state diagram illustrating a displacement meter module according to another embodiment of the present invention.
12 to 14 are side views showing a displacement meter module according to another embodiment of the present invention, respectively.

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

FIG. 2 is a perspective view showing the installation state of the tunneling behavior measuring system using the displacement meter according to the present invention, FIG. 3 is a connection state diagram of the displacement meter module according to the present invention, 6 and 7 are a perspective view and an operational state view showing a displacement meter module according to another embodiment of the present invention, respectively, FIG. 8 is an operational state view showing a displacement meter module according to the present invention, and FIG. And FIGS. 9 and 10 are a perspective view and an operational state view showing a displacement meter module according to another embodiment of the present invention, FIG. 11 is an operational state view showing a displacement meter module according to another embodiment of the present invention, 14 is a side view showing a displacement meter module according to another embodiment of the present invention.

A plurality of displacement meter modules 500 are arranged at regular intervals along an excavation surface 100 of a tunnel (T) excavation section, and the displacement meter module 500 is embedded in a tunnel surface through a shotcrete layer.

At this time, the displacement gauge module 500 uses a stray gauge type sensor for measuring deformation at a certain area.

After connecting the displacement meter module 500 to the main cable 300, the main cable 300 is connected to the data logger 400 located below or outside the tunnel T.

The displacement gauge module 500 is provided only on the body 530 with the controller 520 for giving a measurement ID to the measurement values of the measurement sensor 510 and the measurement sensor 510.

In addition, the data logger 400 includes a data processing unit 410 for storing or processing measurement data, a signal amplifying unit 430 for amplifying the measurement signal, an output unit 450 for sending measurement data to the outside, A digital-to-analog (A / D) converter 470 for converting an analog value of measurement data into a digital signal, and a power supply unit 490 for supplying power to a measurement sensor.

The displacement gauge module 500 includes a body 530 having a predetermined thickness and two parallel surfaces, that is, an upper surface and a lower surface. The upper surface 530a and the lower surface 530b of the body 530 may have one or more And the measurement sensor 510 are respectively attached to the sensor.

In addition, the displacement meter module 500 includes a body 530 having a hexahedron, and a displacement meter is mounted on at least two sides of the hexahedron.

That is, the body 530 has a free surface or at least two surfaces parallel to each other, and when the measurement sensors are installed on the two parallel surfaces, the two surfaces are simultaneously moved by the external force You can install it.

The displacement meter module 500 includes a plurality of vertical stress supporting plates 531 separated from the vertical stress supporting plates 531 and fixed to the upper surface of the body 530, And a load transmitting means 535 installed so that the vertical stress supporting plate 531 moves at the same time in the vertical direction at the same time.

The displacement meter module 500 includes a vertical stress support plate 533 separated from a vertical stress support plate 531 by which at least one measurement sensor is fixed to one surface of the body 530, And a horizontal stress supporting plate 537 having one or more measuring sensors arranged to intersect with the vertical stress supporting plate 533 in a direction different from that of the vertical stress supporting plate 533. [ .

At this time, a plurality of the horizontal stress supporting plates 537 may also be provided in parallel.

In addition, the displacement meter module 500 is installed so that the horizontal stress support plate 537 is variable without interfering with the operation of the vertical stress supporting plate through the free moving unit 540 connected to the load transmitting means 535.

At this time, the free moving unit 540 is composed of a combination of a holding pipe provided in a support or a slot formed in the horizontal stress supporting plate, or a pipe having a clearance gap through which the horizontal stress supporting plate is moved on the inner diameter side .

The load transmitting means 535 is selected from among a plurality of supports for interconnecting the vertical stress supporting plates so as to maintain a predetermined interval or filling members formed by integrally connecting the vertical stress supporting plates.

That is, the displacement meter module is selected from among a plurality of connection bars installed to move the vertical stress supporting plates at the same time as the load transmitting means, or connection blocks in which the corresponding plurality of vertical stress supporting plates are simultaneously cured.

A load supporting piece 537a having a large area is connected to both ends of the horizontal stress supporting plate 537 so as to easily transmit stress, and the load supporting piece 537a is installed to protrude from both sides of the vertical stress supporting plate .

Subsequently, the displacement meter module 500 is installed such that the vertical stress supporting plate 533 to which the measurement sensor is fixed is separated from the upper side or the lower side of the body 530, and the respective vertical stress supporting plates operate separately.

At this time, the displacement meter module 500 includes a load transmission plate 580 connected to the upper side of the horizontal stress support plate 537 via an attenuation unit 560, and at least one The vertical stress supporting plate 537 is connected.

Meanwhile, a plurality of the horizontal stress supporting plates 537 may be separately provided on the side of the body 530.

The operation of the present invention constructed as described above will be described.

As shown in Figs. 2 to 14, the present invention is measured by using a displacement gauge, which is an electric resistance meter, which is a strain-gauge type, attached to an object when the object is deformed by an external force.

At this time, the strain gauge changes the electrical resistance of the strain gauge attached when the vertical or horizontal stress supporting plate, which is a structure, is deformed, so that strain can be measured from the strain gauge and the vertical or horizontal displacement can be known.

The cable 515 of the displacement meter module 500 is connected to the main cable 300 and the main cable 300 is connected to the data logger 400 located under the tunnel T, And outputs the measured amount of strain measured by each displacement meter module 500 to the outside through the data logger 400.

The displacement meter module 500 is provided with a controller 520 for sending data by giving a unique ID to one side of the measurement sensor 510 so that individual data measured by each measurement sensor 510 is transmitted to one main cable The data measured by each of the measurement sensors 510 can be accurately determined even if the measurement data is transmitted through the measurement sensor 300.

In addition, the data logger 400 includes a data processor 410, a signal amplifier 430, and an output unit 450. The data logger 400 collects data measured by each measurement sensor 510 in one data logger 400) and then output.

That is, the signal sent from each measurement sensor 510 is converted into an analog signal through the A / D converter 470, amplified through the signal amplification unit 430, and then filtered by the filter 450 The data is processed by the data processing unit 410, and then the data is stored. The data is output to the outside through the output unit 450.

The displacement meter module 500 includes one or more measurement sensors 510 on a top surface 530a and a bottom surface 530b of a body 530 formed to have a predetermined thickness and having at least an upper surface and a lower surface When the body 530 is embedded in a shotcrete or the like formed in the tunnel, the body 530 is deformed according to the behavior of the tunnel and the displacement of the measurement region can be known.

At this time, in the displacement meter module 500 of the present invention, when the measurement sensor attached to the upper surface and the lower surface performs a displacement operation from the upper part to the lower part, a displacement with respect to the tension acts on the lower surface of the shrinkage, You will know.

In addition, the displacement meter module 500 includes a body 530 formed of a hexahedron having a solid state, and the measurement sensor 510 is mounted on at least two of the six sides, It is possible to measure the stress acting on the substrate.

The displacement gauge module 500 may be formed of a body 530, which is not a solid hexahedron but has two or more overall contours.

That is, the body 530 of the present invention is separated and installed so as to have a predetermined thickness, and a plurality of vertical stress supporting plates 531, each of which is fixed to one surface thereof, and a vertical stress supporting plate 533, And a load transferring means 535 installed so as to move at the same time in the case of the solid state body.

The displacement meter module 500 further includes a horizontal stress support plate 537 having at least one measurement sensor positioned in a direction different from the vertical stress support plate 533 as well as the vertical stress support plate 533 The displacement magnitude in the vertical direction and the displacement of the compressive force acting in the horizontal direction are simultaneously measured.

At this time, the displacement meter module 500 is installed so that the horizontal stress supporting plate 537 is variable without external interference through the free moving unit 540 connected to the load transmitting means 535, so that the vertical stress supporting plate and the horizontal stress supporting plate It is possible to measure the behavior in the vertical and horizontal directions simultaneously without causing mutual interference.

The free moving unit 540 may be selected from a combination of a holding pipe provided in a support pipe which is a pipe having a clearance gap or a load transmitting means and a slot formed in the horizontal stress supporting plate and a vertical stress supporting plate, It is also possible to connect the horizontal stress support plate while connecting.

The load transferring means 535 may be formed of a plurality of supports for interconnecting the vertical stress supporting plates so as to maintain a predetermined interval or a filling material formed by integrally connecting the vertical stress supporting plates. The vertical stress support plate acts like a single body at the same time.

In addition, both ends of the horizontal stress supporting plate 537 are connected to a load supporting piece 537a for easily transferring stress, and are installed so as to protrude from both sides of the vertical stress supporting plate so as to be operated only in the horizontal direction.

Subsequently, the displacement meter module 500 includes a vertical stress supporting plate 533, to which the measurement sensor is fixed, separated from the upper side or the lower side of the body 530, so that a displacement acting in different directions in a region where shearing force acts .

At this time, the displacement gauge module 500 has at least one vertical stress (load) on the upper side of the load transmission plate 580 when the load transmission plate 580 is connected via the attenuation unit 560 to the upper side of the horizontal stress support plate 537, In the structure in which the support plate 537 is connected, the stress transmitted to the horizontal stress supporting plate during the displacement measurement by the vertical stress supporting plate is attenuated to prevent the interference due to the measurement of the horizontal stress supporting plate.

Meanwhile, when a plurality of horizontal stress supporting plates 537 are provided on the side of the body 530, the horizontal stress supporting plate 537 can measure the shearing force even when the shearing force acts in the compression direction.

500 ... displacement meter module 510 ... measuring sensor
520 ... controller 530 ... body
531 ... vertical stress supporting plate 537 ... horizontal stress supporting plate
580 ... load transfer plate

Claims (11)

And a plurality of displacement gauge modules each of which attaches a measurement sensor to two surfaces of a body formed to have two parallel surfaces while facing each other while having a thickness,
The displacement meter module is fixedly installed at predetermined intervals along the desired tunnel surface, and then the displacement meter module is simultaneously deformed according to the behavior of the tunnel to measure the magnitude and direction of the displacement at each position of the tunnel where the behavior occurs and,
Connecting each of the displacement meter modules to a main cable, connecting the main cable to a data logger located at a lower portion of the tunnel, measuring the displacement magnitude and direction at each position,
The displacement gauge module comprises a vertical stress supporting plate having at least one or more measuring sensors separated from each other so as to be spaced apart from each other so as to have a predetermined thickness, and a vertical stress supporting plate And one or more horizontal stress supporting plates provided at intersecting positions with respect to the vertical stress supporting plate in a direction opposite to the vertical stress supporting plate and including at least one measuring sensor. [2] The apparatus of claim 1, wherein the displacement meter module comprises: a measurement sensor provided as a strain gauge inside the housing; and a controller for assigning an ID to a measurement value of each measurement sensor, Wherein the main cable is connected to a data logger having a filter, an A / D converter, a signal amplifier, a data processing unit, an output unit, and a power supply unit integrally. delete delete delete The displacement gauge module according to claim 1, wherein the displacement transmitter module comprises: a plurality of connection bars installed so that the vertical stress support plate moves simultaneously,
And a plurality of vertical stress supporting plates which are filled and corresponding to one another are cured at the same time. The displacement measuring device according to claim 1, wherein the displacement meter module is connected to a horizontal stress supporting plate through a free moving unit mounted on the load transmitting means,
The free moving unit may be a pipe having an interval corresponding to the movement of the horizontal stress supporting plate,
And a horizontal stress supporting plate is installed to move around the support by a combination of a latching jaw provided in the support and a slot formed in the horizontal stress supporting plate. . The load cell according to claim 1, wherein the displacement gauge module comprises load supporting members connected to both ends thereof to facilitate transmission of compressive force to the horizontal stress supporting plate,
Wherein the load supporting pieces are installed to protrude from both ends of the vertical stress supporting plate. delete The displacement meter according to claim 1, wherein the displacement meter module is connected to a load transmission plate via an attenuation unit on an upper side of a horizontal stress support plate, and a vertical stress support plate is connected to upper and lower sides of the load transmission plate, respectively. Tunneling behavior measurement system. The displacement transmitter according to claim 1, wherein the displacement meter module is connected to a load transmission plate via an attenuation unit on the upper side of a horizontal stress support plate, and a vertical stress support plate is separately installed on the upper and lower sides of the load transmission plate. Tunnel Behavior Measurement System Using.

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