JPH044969Y2 - - Google Patents

Description

[Detailed Description of the Invention] (3-1) Industrial Application Field The present invention relates to an apparatus for measuring displacement inside a tunnel using a laser beam.

(3-2) Conventional technology In general, when constructing tunnels using NATM, it is essential for construction management to understand the behavior of the surrounding ground and the behavior of the tunnel as a structure, but it is necessary to understand the behavior of the surrounding ground and the behavior of the tunnel as a structure. The most important factor is the displacement situation inside the tunnel.

Conventionally, to measure the displacement status of the tunnel interior, a so-called convergence measurer was used to measure the distance between base point anchors that were previously attached to the tunnel interior wall surface. , measurement accuracy is poor, individual differences are likely to occur, scaffolding is required for measurement in the case of large tunnels, and there are many problems such as being unable to perform other tasks while measuring, and it requires a lot of manpower. death,
Moreover, there were drawbacks such as the inability to perform continuous measurements.

Recently, measurement methods using laser beams have also come into use. One method is to detect the position of the machine by shining a laser beam onto the light receiving plate of a machine installed in the tunnel, and convert the displacement of the tunnel interior from the position of the machine with respect to the tunnel interior. However, this method has the disadvantage that the displacement inside the tunnel cannot be directly determined.

Another method is to measure the displacement of the tunnel interior by installing a laser light source in the cross section of the tunnel and deflecting it horizontally or vertically to measure the displacement at each point within the tunnel. There is a way to calculate it. However, in this case, as shown in FIG. 7, the means for deflecting the laser beam is to place a mirror or prism 2 in front of the laser light source 1 and mechanically rotate it, thereby deflecting the laser beam 3. is irradiated to each point 4, but
The accuracy of the mechanical parts had a major effect on the measurement accuracy, and the disadvantage was that there was no mechanical rotation mechanism that could provide sufficient measurement accuracy.

The applicant of the present application has also proposed the following method which eliminates the drawbacks of the above-mentioned method for measuring displacement inside a tunnel (filed on December 21, 1982, patent application No. 1982-
No. 241683). That is, as shown in FIG. 1, a laser beam 3 is emitted from a laser light source 1 installed at a reference point in a tunnel 5 in the direction of tunnel travel, and the brightness of a measurement surface of a light receiving device 11 installed at a measurement position is measured. The center of the laser beam is determined by measuring the distribution, the pulse motor is used to align the center of the light receiving device with the center of the beam, and the amount of correction is determined to measure the displacement within the tunnel.

As shown in the figure, the laser beam has an extremely small angle θ
It moves straight through the tunnel while spreading out, but
Since the angle θ is extremely small, the diameter of the laser beam (referred to as the spot diameter) is small even if the light source and the measured position are far apart, and its brightness does not decrease much. Therefore, if a through hole slightly smaller than the spot diameter of the laser beam is provided in the center of the light receiving device, multi-point measurement is possible.

FIG. 8 schematically shows a light receiving device used in this method. That is, a through hole 12 and two pairs of photoelectric conversion elements 13 are provided in the center of the light receiving device 11, and the photoelectric conversion elements 13 are connected to a displacement detection device 14 by wiring. The displacement detection device 14 detects the deviation between the center of the laser beam 3 and the center of the light receiving device 11, and issues correction commands to the pulse motor 15 in the left-right and front-back directions, and the pulse motor 15 receives this command and moves the screw shaft 16 is rotated as required, screwed into the screw shaft 16, and the light receiving device 11
The position of the light receiving device 11 is corrected by the action of the female screw 17 fixed to the. The amount of correction is measured and recorded by a displacement meter 18 fixed at a predetermined point within the tunnel.

This method allows multi-point measurement, continuous measurement and
This method has the advantage of being able to record continuously and simultaneously measure the swelling, deformation, etc. of the tunnel wall and the subsidence of the tunnel, and is also an extremely excellent method, as it does not require manpower and thus saves costs.

However, this method requires complicated equipment;
However, the disadvantage of increased equipment costs could not be avoided.

(3-3) Purpose of the invention The present invention eliminates the drawbacks of the conventional method of measuring the internal displacement of a tunnel as described above, has low equipment cost,
Moreover, it is an object of the present invention to provide a measuring device for measuring the displacement inside a tunnel, which can accurately measure the displacement inside the tunnel.

(3-4) Structure and operation of the invention The invention fixes a substrate at a predetermined point at the position to be measured,
A light receiving plate is attached to the substrate via a spring and a micrometer so that it can slide in one direction or in two directions orthogonal to each other, and a through hole is provided in the center of the light receiving plate, which is slightly smaller than the spot diameter of the laser beam. A photoelectric conversion element is attached outside the through hole in the above-mentioned one direction or in two directions orthogonal to each other, and a laser beam emitted in the tunnel traveling direction is applied to the light receiving plate, and the photoelectric conversion element and the voltmeter connected to it are connected. The above purpose is achieved by determining the deviation between the center of the laser beam and the center of the light receiving plate by the action of are doing.

Embodiments of the present invention will be described below based on the drawings. FIG. 1 shows the relationship between the light source 1 and the light receiving plate 11. This is similar to the prior art example described above in that the diffusion angle θ of the laser beam is extremely small and therefore multi-point measurement is possible.

FIG. 2 [A is a plan view, B is a front view] is a diagram showing the structure of the light receiving plate 11, etc. of the measuring device according to the present invention. In the figure, a through hole 12 with a rectangular cross section is provided in the center of the light receiving plate 11, and a pair of photoelectric conversion elements 13 are arranged adjacent to the through hole 12 in one direction (left and right direction in the drawing). installed.
The left and right widths of the through hole 12 are slightly smaller than the spot diameter 6 of the laser beam at that position.

Further, the substrate 21 is fixed at a predetermined point within the tunnel by a bracket 22 or the like. A pair of plates 23 are attached to one surface of the substrate 21, and a pair of slide rods 24 parallel to each other are attached to the plates 23.
is fixed. Holes 19 parallel to each other are bored in the light receiving plate 11, and a slide rod is inserted into the holes 19, so that the light receiving plate 11 is slidably attached to the substrate 21.

A spring 25 is installed between one side of the plate 23 and the side of the light receiving plate 11, and a spring 25 is installed between one side of the plate 23 and the side of the light receiving plate 11.
A micrometer 26 is attached to 3. The micrometer 26 includes a measuring end 26A and a threaded portion 26B for slightly moving the measuring end. The pair of photoelectric conversion elements are wired and connected to a voltmeter 27 so that the difference in voltage generated therebetween can be measured (see FIG. 5).

Figures 3 to 5 are diagrams showing the measurement principle and measurement method of the measuring device according to the present invention. Figure 3 shows the situation before correction with a micrometer, and Figure 4 shows the situation after correction. It shows
In each case, A shows the brightness distribution of the laser beam, B shows a front view showing the position of the photoelectric conversion element, and C shows a plan view thereof. Moreover, FIG. 5 is a wiring diagram of a photoelectric conversion element and a voltmeter.

If the left side photoelectric conversion element in FIGS. 3 and 4 is 13-1 and the right side is 13-2, and the voltages generated by the laser beam are e ₁ and e ₂ respectively, then in the case of FIG. e ₁ > e ₂ and the voltage e given by e = e ₁ − e ₂
is measured by the voltmeter 27.

In the case of FIG. 4, e ₁ =e ₂ and the voltmeter 27 does not measure the voltage.

The measurement of the displacement inside the tunnel using this measuring device is carried out as follows.

A light receiving plate is installed at a predetermined point in the tunnel to be measured, irradiates it with light from a laser light source, and adjusts the micrometer so that the voltmeter reads 0. The micrometer reading at that time
Let D be ₁ .

If a displacement occurs in the tunnel, the voltmeter will read e.

Turn the micrometer and adjust until the voltmeter reads 0. Let the micrometer reading at that time be D ₂ .

The displacement D of the tunnel interior is expressed by the following formula.

D=D ₁ −D ₂ (3-5) Examples other than the above In the examples described above, the photoelectric conversion elements of the light receiving plate are mainly arranged in the left-right direction, and therefore the displacement inside the tunnel is measured only in the horizontal direction. However, it is of course possible to measure displacement in the vertical direction by arranging it vertically, and in some cases, it is possible to measure displacement in the horizontal and vertical directions (generally two directions perpendicular to each other) at a single measured position. It is desirable to have two devices for measuring . FIG. 6 shows another embodiment, in which A is a plan view and B is a front view. In this example, one device can measure in two directions perpendicular to each other (for example, both horizontal and vertical directions). That is, in the same figure, in this example, the board 21 is fixed at a predetermined point in the tunnel by a bracket 22, etc., and a slide rod 24 fixed to a plate 23 and a hole 39 (not shown) are connected to the board 21, which is fixed at a predetermined point in the tunnel by a bracket 22 or the like. An intermediate plate 31 is slidably attached therebetween. Further, the light receiving plate 11 is slidably attached to the intermediate plate 31 via a slide rod 34 fixed to the plate 33 and a hole 19. A spring 25 is installed between the side surface of one plate 23 and the side surface of the intermediate plate 31, and between the side surface of one plate 33 and the light receiving plate 11. 26 is attached. Two pairs of photoelectric conversion elements 13 are attached to the center of the light receiving plate 11 adjacent to the through hole 12 in the vertical and horizontal directions. Each pair of photoelectric conversion elements 13 is connected to a voltmeter 27, respectively. In this example, internal displacement in both the vertical and horizontal directions can be measured with one device.

In the above embodiments, the device according to the present invention is used to measure the displacement inside a tunnel, but as is clear from the structure and operation of the device,
It can also be used extremely conveniently to measure subsidence in places other than tunnels. For example, it can be extremely conveniently used to measure ground subsidence before and after a water filling test of a large oil tank.

(3-6) Effects of the invention This invention has a through hole and a photoelectric conversion element in the center of a light receiving plate that is slidably attached to a substrate fixed at a predetermined point in the tunnel via a spring and a micrometer. and irradiate the light receiving plate with light from a laser light source installed at a reference point in the tunnel,
A voltmeter detects the electric potential difference generated by one or two pairs of photoelectric conversion elements arranged in one direction or two directions orthogonal to each other, and the difference is adjusted with a micrometer so that it becomes 0. The present invention provides a device for measuring displacement inside a tunnel by measuring and recording, and has the following excellent effects.

If surveying laser beams are used inside the tunnel, they can be used as is.

Multi-point measurement is possible.

It is possible to simultaneously measure the swelling, deformation, etc. of the tunnel wall and the subsidence of the tunnel.

Since no complicated device is required to adjust the position of the light receiving plate, equipment costs are low.

In summary, the present invention plays a major role in increasing the efficiency of tunnel construction work, ensuring work safety, and reducing construction costs.

It can also be conveniently used to measure ground subsidence in places other than tunnels.

[Brief explanation of the drawing]

Fig. 1 is a diagram showing the relationship between the laser light source and the light receiving plate, and Fig. 2 is a diagram showing the structure of the light receiving plate, etc. of the measuring device according to the present invention, where A is a plan view, B is a front view,
Figures 3 to 5 show the measurement principle and measurement method of the measuring device according to the present invention. Figure 3 shows the situation before correction with a micrometer, and Figure 4 shows the situation after correction. In each case, A shows the brightness distribution of the laser beam, B shows the front view showing the position of the photoelectric conversion element, C shows the top view, Figure 5 shows the wiring diagram of the photoelectric conversion element and the voltmeter, and Figure 6 shows the main picture. FIG. 8 is a diagram showing another embodiment of the measuring device according to the invention, in which A is a plan view, B is a front view, FIG. 7 is a diagram showing a conventional method of calculating the displacement inside a tunnel, and FIG. 1 is a diagram schematically showing a light receiving device in a conventionally proposed method for measuring displacement inside a tunnel. 1...Laser light source, 2...Mirror or prism, 3...Laser light, 4...Each point, 5...Tunnel, 6...Spot diameter, 11...Light receiving plate, light receiving device, 12...Through hole , 13... photoelectric conversion element, 1
9...hole, 21...board, 22...bracket,
23...Plate, 24...Slide rod, 25...Spring, 26...Micrometer, 26A...Measuring end, 26B...Threaded portion, 27...Voltmeter, 31...
...Intermediate plate, 33...Plate, 34...Slide rod, 3
9...hole.

Claims (1)

[Scope of utility model registration request] A laser light source is installed at a reference point in the tunnel and emits a laser beam in the direction of travel of the tunnel, a substrate is fixed at predetermined points at a plurality of measurement positions in the tunnel, and a spring and a micrometer are connected to the substrate. a light receiving plate that is slidably attached in one direction perpendicular to the laser beam or in two directions perpendicular to the laser beam and mutually orthogonal, and has a through hole in the center having a width slightly smaller than the spot diameter of the laser beam; one or two pairs of photoelectric conversion elements attached to the surface of the light receiving plate on the laser light source side in contact with the outer edge of the through hole and facing each other in the one direction or the two directions; A device for measuring displacement inside a tunnel, which consists of a voltmeter connected to measure the difference in voltage generated by a photoelectric conversion element.