RU2330238C2 - Device and method for monitoring technical condition of tunnels - Google Patents

Abstract

FIELD: measuring instruments.

SUBSTANCE: device comprising three flexible bars provided with strain gauges. The flexible bars are affixed at one of their ends to a plate disposed on the inner side at the end face of the tunnel block. The other ends of the flexible bars are connected together onto a stop bar. The stop bar is affixed to a plate similar to the first plate disposed on the inner side at the end face of the adjacent tunnel block. Not less than three devices are placed into each movement joint along the inspected segment of the tunnel and position vectors of each of the tunnel blocks are logged into a computer of an input data recorder of the strain gauges. Basing on all the points, a tridimensional framework is created and taken as a reference of measurement. Then measurements are periodically taken and current position changes of the blocks are compared with said reference of measurement. A matrix of deviation from the framework points is formed thereby. The changes are logged in and it is determined whether they are within acceptable limits.

EFFECT: increasing the accuracy of measurement.

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Description

The invention relates to measuring technique and can be used to control the spatial movements of tunnel blocks.

In the study of the reliability of building structures, especially tunnel structures, there is a great need to take into account seismic effects. For example, the North Mui railway tunnel with a length of 15.33 km is located in extremely unfavorable geological, hydrological, seismic and mining conditions.

Reliable and safe operation of the North Mui Tunnel (SMT) to a large extent depends on the effectiveness of measures aimed at monitoring and evaluating its technical condition. Therefore, an extremely important problem for the safe operation of the tunnel is monitoring the condition and location of the tunnel blocks.

Known multi-element transistor [1], consisting of two, three or four unidirectional strain gauges. Each of the strain gauges has a sensitive wire grating, a dielectric base and terminal wiring of the dielectric substrate of the electrical connector and receiver, a multi-core connecting cable.

Each unidirectional strain gage consists of two sections and the gap between them. The sections have a wire sensitive grating, the gratings are connected in series with an insulated conductor with a low resistivity.

The output wires of each sensitive array are connected to an electrical connector. A multi-element strain gauge using a multi-core cable is connected to multi-channel measuring equipment and works as follows.

Before loading the structure using multichannel measuring equipment measure the nominal value of the electrical resistance of each unidirectional strain gauge in the device.

When a structure is loaded according to a given program, its surface is deformed, while the nominal resistance of each unidirectional strain gauge changes, the value of which is measured and processed using measuring equipment and computers using a known method.

The disadvantages of this device include the fact that it does not provide monitoring of the entire tunnel, but only at a local point.

A device is also known for recording linear strains [2]. To increase the efficiency of use, the device contains a movable and fixed support mounted on the measured object, a flexible rod located between the supports, a sensor with a sensitive element in the form of optical fibers directed towards each other, and a transmitting element installed between the sensor and the flexible rod.

The device is equipped with a cantilever fixed leaf spring with a regulator of its position, made in the form of an adjusting screw, a squeeze plate, which is rigidly connected to the free end of the leaf spring and mounted perpendicular to it. The sensitive element is made in the form of two fiber optic cables.

The proposed device operates as follows:

Based on the terms of reference, the maximum permissible recorded offset of the support relative to the support on the building and the distance between them is determined. Then, by calculation, the rod and squeeze plate are placed on the leaf spring, after which the device is mounted on the building with the subsequent adjustment of the sensor. The essence of the setting is that with the help of a fork and an adjustable screw, the squeeze plate is installed in a position in which the light power losses in the sensor element of the sensor exceed the minimum by an average of 3 dB.

The loss values thus established are assumed to correspond to the zero position of the movable support.

A shift of the support by a certain amount down will cause the rod to rotate by a certain angle, while the fork, mounted on the rod through the rod, acts on the cantilever part of the leaf spring, bending it up. A squeeze plate rigidly mounted on a leaf spring interacts with a fiber optic cable. This reduces the loss of light power, which is recorded by the equipment.

Disadvantages: this device is also designed to register voltages at a local point in the tunnel and does not purport to monitor the entire tunnel.

Known software package B-34 [3] for determining the coordinates of network points and metrological accuracy assessment.

The essence of the method lies in the fact that when calculating the coordinates of the determined points that are remote from the starting points, the predefined points are taken as the source, serving for the subsequent determination of the coordinates of the deleted points.

The software package includes the following menu:

- equalization of geodetic networks of leveling, trilateration, triangulation, polygonometry of spatial linear networks;

- calculation of coordinates of points, including polar notch, direct angular notch in directional directions, in corners, on a plane, calculation of polygonometry, spatial linear notch;

- coordinate transformation includes geodesics in flat rectangles, flat rectangles in geodesics, flat rectangles from zone to zone, geodetic coordinates in spatial rectangular, spatial rectangular in geodesic, spatial rectangular from ellipsoid to ellipsoid;

- metrological calculations include the conversion of differential corrections from the system to the system, the assessment of the accuracy of the determined points, the calculation of the probability of the determined points on the plane and in space.

The B-34 software package has been implemented in units of the Federal State Unitary Enterprise “Aerogeodesy” and in other organizations of Russia and Belarus.

The proposed software package B-34 is applicable when performing large-scale topographic surveys, engineering survey and other works.

Using this method to monitor the technical condition of the tunnel will be very expensive, and impossible, since the tunnel is underground.

However, the mathematical apparatus for determining the coordinates of the tunnel blocks can be used.

The closest analogue is a device for measuring deformations and forces [4], containing a sensing element in the form of an elastic ring with strain gages, support rods and a register of output signals. The pre-tensioning of the sensitive element is adjusted using a frame with two holes - with micrometric thread and smooth, each located in opposite jumpers of the frame. Through these holes, the frame interacts with two removable support rods with ball tips rigidly connected to the elastic ring in opposite places, while the connecting elements are made on one rod in the form of a micrometer screw, and on the other - the screw head.

The device operates as follows:

Strain gages are connected to the recording device and note their readings in the unloaded condition of the ring. By rotating the frame clockwise, the ring is pre-tensioned, the value of which is controlled by the indicators of the recording device. The tension is due to the fact that the frame, when turning, moves freely in the angular direction relative to the cylindrical head of the connecting element associated with the support rod.

After creating the necessary pre-tensioning device is installed on the test object.

When a compression load acts on the measured object, the strain gauges receive linear deformation, and the output signal changes. From this change in signal, you can determine the change in base. Disadvantages: the proposed device also captures only voltages in a local place and cannot provide monitoring of the entire tunnel, moreover, it is quite expensive.

The technical effect of the claimed device is to ensure accuracy with a high degree of reliability in determining the spatial position of tunnel blocks in various operating conditions at a given distance.

This effect is achieved by the fact that the device for monitoring the technical condition of the tunnels contains strain gauges, an output signal recorder, three elastic rods, each of which is equipped with a strain gauge and is mounted on a plate located on the inner side at the end of the tunnel block, the other ends of the elastic rods are connected together on the thrust a rod, which is mounted on a second plate, similar to the first, located nearby on the inner side at the end of the adjacent tunnel block.

This device is used in the implementation of the method for determining the technical condition of the tunnel, in which at least three devices for monitoring the technical condition of the tunnel are located in each expansion joint of each pair of blocks in the studied section of the tunnel, with which the displacement vectors of the points of the block are fixed, the picture of the spatial displacements of each block is determined relative to the coordinate system associated with the initial block, a spatial frame of points is constructed in this coordinate system, corresponding to boiling the number of devices that accept it as a base frame, at predetermined time intervals is carried out similar measurements, form a matrix of spatial deviations skeleton points changing fixed and determine whether the changes are within the permissible.

Figure 1 presents a General view of a device for monitoring the technical condition of the tunnel.

Figure 2 shows the arrangement of devices for monitoring the technical condition of the tunnel.

The entire tunnel consists of blocks, in Fig. 1 only two blocks of the tunnel 1 and 2 are shown, a deformation seam 3. A plate 4 is installed from the end of the block 1, and a plate 5 is installed from the end of the block 2. The elastic rods 6 are fixed at one end to the plate 4, the other end connected together in the node 8 of the thrust rod 9, the thrust rod with the other end abuts against the plate 5. Each elastic rod 6 is equipped with a strain gauge 7. The strain gauges 7 are connected via wires to the output signal recorder 10.

These devices are located evenly at the end of the tunnel blocks, figure 2 shows the placement of the plates 5 and along the entire length of the investigated part of the tunnel.

The device operates as follows. Under the influence of rocks, the blocks 1 and 2 of the tunnel change their position in space, while the elastic rods 6 are subjected to deformation, tension or compression.

The deformation of each elastic rod 6 is fixed by a strain gauge 7, which feeds an electrical signal to the output signal recorder 10, from the latter the signal is transmitted to the measuring system.

Since each strain gauge 7 is fixed at a known point of the elastic rod 6, its length is known, then you can determine the coordinate of the lobe where the device is located.

If we have information about the location of devices at three points of the tunnel block, then we will get the coordinates of the location of the tunnel block.

In the proposed method for determining the technical condition of the tunnel, it is proposed to place less than three devices for monitoring the technical condition of the tunnel on each expansion joint of each pair of blocks in the studied section of the tunnel. Using these devices, the vector of displacement of the points of the block is fixed, a picture of the spatial displacements of each block relative to the coordinate system associated with the initial block is determined. Then, in this coordinate system, a spatial frame of points is constructed, corresponding to the number of devices, and it is taken as a reference base.

At given intervals, similar measurements are carried out, a matrix of deviations of the points of the spatial frame is formed. Commit changes and determine if the changes are within acceptable limits.

Tests were carried out on the models of the tunnel, they showed that the accuracy of the measurements is within ± 0.01 mm.

Literature

1. USSR author's certificate No. 1786932, IPC G01B 7/16, publication date 10/12/1995

2. RF patent No.2019790, IPC G01D 11/16, publication date 09/15/1994

3. VN Balandin et al. “Satellite and traditional geodetic measurements”, St. Petersburg, Federal State Unitary Enterprise “Airborne Geodesy”, 2003, pp. 95-97.

4. RF patent №2010155, IPC G01B 7/18, publication date 03/30/1994

Claims (2)

1. A device for monitoring the technical condition of the tunnel, containing strain gauges, an output signal recorder, elastic rods, characterized in that there are three elastic rods, each of which is equipped with a strain gauge and mounted on a plate located on the inner side of the end of the tunnel block, the other ends of the elastic the rods are connected together on a thrust rod, which is mounted on a second plate similar to the first, located nearby on the inner side at the end of the adjacent tunnel block, the strain gauges are connected to output recorder. 2. A method for determining the technical condition of the tunnel, characterized in that at least three devices for monitoring the technical condition of the tunnel are located in each expansion joint of each pair of blocks on the studied section of the tunnel, using which the displacement vectors of the block points are fixed, the picture of the spatial displacements of each block relative to coordinate systems associated with the initial block, build in this coordinate system a spatial frame of points corresponding to the number of devices, take it as a As a reference base, at given intervals of time, similar measurements are carried out, a matrix of deviations of the points of the spatial frame is formed, the changes are recorded and it is determined whether the changes are within acceptable limits.

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