JP2676039B2 - Wedge type pressure gauge and its installation method - Google Patents

Description

TECHNICAL FIELD The present invention relates to a wedge-type earth pressure gauge which has high measurement sensitivity and can be stably and reliably fixed in a borehole.

[Conventional technology]

The ground pressure gauge for measuring the change in ground pressure is roughly classified into a rigid ground pressure gauge of a method of prestressing and fixing in the borehole by a wedge mechanism and a flexible ground pressure meter of a method of fixing using a flat jack.

Among them, the Hast measuring instrument shown in Fig. 9 is known as a rigid geostatic pressure gauge. This is an iron pillar 1 as a sensor,
It is composed of a wedge 2, a support base 3, and a pressure plate 4, and a reaction force in the A direction is generated to prevent the pressure plate 4 from moving,
The wedge 2 is pulled in the B direction by the hydraulic ram 5, and the iron column 1 as a sensor is pressed in the C direction and fixed in the bore hole. An electromagnetic coil is attached to the iron pole 1, and a load is generated on the iron pole 1 due to a change in ground pressure, so that the amount is detected as a change in magnetostriction.

Figure 10 shows the Hawkes and Bailey measuring instrument,
The cylinder 7 incorporating the vibrating string 6 in the radial direction is used as a sensor,
It is fixed in the borehole by the action of the wedge 9, and the deformation of the cylinder 7 due to the change of the ground pressure is detected as the change of the frequency of the vibrating string 6.

[Problems to be solved by the invention]

However, in the Hast measuring instrument of the above rigid earth pressure gauges, since the sensor is fixed by one wedge, the fixation is likely to be unstable, and installation may fail. There is a problem that the measurement sensitivity is low for detection, drift occurs for a long time, and only one measuring instrument can be installed in one borehole.

Also, in the above Hawkes and Bailey measuring device,
Since there is only one wedge and it is eccentric from the center axis of the borehole, the sensor may be imperfectly fixed. Also, since a thin iron wire is used as the vibrating string, it is affected by temperature changes. It has a problem that it is easy to lack long-term durability.

The present invention solves the above problems, and an object of the present invention is to provide a wedge-type earth pressure gauge that has high measurement sensitivity and can be stably and reliably fixed in a borehole.

[Means for solving the problem]

Therefore, the wedge-type earth pressure gauge of the present invention comprises a ring-shaped sensor, pressure plates arranged on both sides of the ring-shaped sensor,
Two or more wedges are movably arranged between the ring-shaped sensor and the pressure plate, and the ring-shaped sensor and the pressure plate can be fixed to the borehole by the wedges. The installation method includes a hydraulic drive device for moving the wedge, and a reaction force device for preventing the ring-shaped sensor and the pressure plate from moving. While fixing the device with a rivet that can be cut at a constant pressure, after fixing the reaction force device and the hydraulic drive device, insert these at arbitrary positions in the borehole,
By pulling the wedge by the hydraulic drive device, the ring-shaped sensor and the pressure plate are pressed against the borehole, the rivet is cut, and the hydraulic drive device and the reaction force device are recovered.

[Operation] In the present invention, as shown in, for example, FIG. 1, a wedge-type earth pressure gauge 10 has a ring-shaped sensor 12 fixed in a borehole 14 by a pressure plate 13 and a wedge 15 at a constant pressure so that It senses changes in the ground pressure component.

The installation method is, for example, as shown in FIG.
13 and the wedge 15 are fixed by the sheer rivet 30, and the wedge type earth pressure gauge 10 is inserted into the reaction force device 25, and then the hydraulic drive mounting 20
Is fixed in the reaction force ground 25, and the wedge 15 and the piston 22 are fixed by the shear rivet 30. This assembly is inserted into the borehole 14 at an arbitrary position, and the piston 15 pulls the wedge 15. When the wedge 15 moves, the ring-shaped sensor 12 and the pressure plate 13
However, since the movement is blocked by the reaction force plate 27,
The pressure plate 13 is pressed against the hole wall of the borehole 14 by the action of the wedge 15, and when the installation pressure is reached, the wedge type earth pressure gauge 10 and the hydraulic drive device are provided.
The shear rivet 30 connecting with 20 is disconnected. Finally, the hydraulic drive device 20 and the reaction force device 25 are collected, and the installation work is completed.

〔Example〕

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a side view of the wedge type earth pressure gauge of the present invention, and FIG. 2 is a sectional view taken along the line II-II in FIG.

In the figure, the wedge type earth pressure gauge 10 of the present invention is a strain gauge on both sides of a thick cylinder made of nickel chrome molybdenum steel.
Ring sensor 12 with 11 attached, and this ring sensor
It is composed of two wedges 15 slidably provided between the pressure plate 12 and the pressure plate 13. One end of each of the two wedges 15 has a connecting member 16 and a bolt 17
Is fixed. The connecting member 16 is provided with a connecting hole 16a for connecting to a piston of a hydraulic drive system described later. In addition, the pressure plate 13 and the wedge 15 have temporary fixing holes.
13a and 15a are provided, and by fixing them with a sheer ribet described later, a wedge type pressure gauge can be inserted into the borehole 14. Reference numeral 19 is a lead wire for extracting a signal from the strain gauge 11.

The wedge-type ground pressure wedge 10 is configured such that the ring-shaped sensor 12 is pressed by the pressure plate 13 and the wedge 15 into the bore hole 14 at a constant pressure (installation pressure of about 10
It is fixed at 0 kg / cm ² ) and is sensitive to changes in the ground pressure component in a fixed direction. That is, the change in the ground pressure in the direction in which the pressure plate 13 is pressure-bonded is changed by the ring-shaped sensor via the pressure plate 13 and the wedge 15.
Detected as 12 distortion amounts. The borehole 14 has a hole diameter of 75 mm as a standard, but if the finish is not good, stable installation cannot be performed, and if the hole is not sufficiently self-supporting, it may not be able to be installed, so it is mainly used for measurement in hard rock. use.

In the above example, the strain gauges 11 are attached to both outer side surfaces of the ring-shaped sensor 12 at two locations, but they may be attached to the inner peripheral surface or the inside of the ring-shaped sensor 12, and the number of attachments may be changed appropriately. Good.

Next, the installation device of the wedge type ground pressure gauge 10 will be described with reference to FIGS.

FIG. 3 shows a side view of a hydraulic drive device 20 for pulling the wedge 15, which comprises a hydraulic cylinder 21, a piston 22 and a connecting member 23 fixed to the tip of the piston 22. The connecting member 23 has a connecting hole 23a. Are formed.

4 and 5 show a reaction device, FIGS. 4 and 5 show a reaction device, FIG. 4 is a side view, and FIG. 5 is a line V-V in FIG. FIG. The reaction force device 25 includes a reaction force frame 26 and a reaction force plate 27 welded and fixed to the tip thereof, and the reaction force plate 27 includes a ring-shaped sensor.
A supporting member 29 for supporting 12 and the heating plate 13 is welded and fixed. The shapes of the reaction force plate 27 and the support member 29 are
As shown in FIG. 5, the reaction force plates 27 of the two wedges 15 are passed through, but the ring-shaped sensor 12 and the pressure plate 13 are shaped so as to be stopped by the reaction force plates 27. Therefore, when installing the earth pressure gauge, when pulling the wedge 15,
It is possible to apply pressure to the pressure plate 12 and the pressure plate 13 to prevent their movement.

Next, a method of installing the wedge type earth pressure gauge of the present invention will be described with reference to FIG.

First, the pressure plate 13 and the fifteenth temporary fixing hole in FIG.
13a and 15a are put together and fixed by a sheer rivet 30 [see FIG. 6 (a)], and the wedge type pressure gauge 10 is attached to the reaction force device.
Insert within 25. Next, after the hydraulic drive device 20 is inserted and fixed in the reaction force device 25, the connection hole 16a (FIG. 1) on the wedge 15 side and the connection hole 23a on the piston 22 side are fixed by the shear rivet 30.

As shown in FIG. 6 (a), the above-mentioned assembly is provided with a borehole.
It is inserted at an arbitrary position of 14, and the wedge 15 is pulled by the piston 22. When the wedge 15 moves, the ring-shaped sensor 12 and the pressure plate 13
However, since the movement is blocked by the reaction force plate 27,
The pressure plate 13 is pressed against the hole wall of the borehole 14 by the action of the wedge 15, and when the installation pressure is reached, the wedge type earth pressure gauge 10 and the hydraulic drive device are provided.
The shear rivet 30 connecting with 20 is disconnected [6th
Figure (b). Finally, the hydraulic drive device 20 and the reaction force device 25 are recovered, and the installation work is completed [Fig. 6 (c)]. The measurement is
You can start right after this.

In order to investigate the response characteristics of the wedge type ground pressure gauge of the present invention, a load test of a mortar block was carried out with a biaxial test device. An actual wedge-type earth pressure gauge is installed in the borehole at the center of the block, several initial values of the external pressure P ₁ in the next pressure sensing direction and the external pressure P ₂ orthogonal to this are set, and the external pressure P ₁ and the strain ε output are set. The ratio (ε / P ₁ = sensitivity) was calculated. As shown in FIG. 7, the sensitivity showed a substantially constant value under all the installation conditions. Since the wedge type manometer has high rigidity in the direction of sensing the change of earth pressure, the influence of rock rigidity on the sensitivity is small. Therefore, it can be considered that the sensitivity of the bedrock to which the wedge type pressure gauge is applied can be regarded as almost constant.

In order to confirm the stability during long-term measurement, the main unit was placed in an unrestrained mortar block indoors and the change over time was read. As shown in FIG. 8, a slight decrease in the installation pressure immediately after the installation and a change due to the temperature change are observed, but both are sufficiently small. Regarding the durability in the field, it is considered that the measurement may become impossible in a bad environment such as extremely high temperature and high humidity due to the deterioration of the material of the strain gauge or the ring-shaped sensor or the weathering of the hole wall. It is considered to have sufficient durability for the measurement inside the rock.

Note that the present invention is not limited to the above embodiment, and various modifications are possible.

For example, in the above embodiment, the change in the ground pressure is detected by the strain gauge, but the present invention is not limited to this.
The magnetostriction detection and the frequency detection described in the conventional example may be adopted. However, the adoption of the strain gauge in the wedge-type earth pressure gauge is a new technique and has a unique effect described below.

Further, in the above embodiment, two wedges are used,
You may provide two or more.

〔The invention's effect〕

As described above, according to the present invention, since the earth pressure gauge is fixed by two or more wedges, the ring-shaped sensor can be installed in the center of the borehole in a stable state and at any position in the borehole.

Further, since the ring-shaped sensor has a cylindrical shape, it is possible to obtain sufficient sensitivity to changes in the ground pressure and specify the direction in which the ground pressure is sensed.

Further, since a change in ground pressure is electrically detected by the strain gauge as strain of the ring-shaped sensor 12, only a cable is connected to the main body. Therefore, the burial depth can be increased, and up to three holes can be installed in one borehole.
Furthermore, since a strain gauge is used, temperature compensation is possible, and if a strain gauge for high temperature or low temperature is used, measurement can be performed in a temperature environment other than normal temperature.

Further, unlike the hydraulic capsule, it is not necessary to stabilize the mortar and the hydraulic pressure so that the measurement can be started immediately after the installation.

[Brief description of the drawings]

FIG. 1 is a side view showing an embodiment of a wedge type pressure gauge of the present invention,
FIG. 2 is a sectional view taken along the line II-II in FIG. 1, FIGS. 3 to 5 are views showing a wedge type earth pressure gauge installation apparatus according to the present invention, and FIG. 3 is a hydraulic drive apparatus. A side view, FIG. 4 is a side view of the reaction force device, FIG. 5 is a sectional view taken along the line VV in FIG. 4, and FIG. 6 is a view for explaining a method of installing the wedge type earth pressure gauge of the present invention. FIG. 7 is a diagram showing the sensitivity characteristic of the wedge type ground pressure gauge of the present invention, FIG. 8 is a diagram showing the time change characteristic of the wedge type ground pressure gauge of the present invention, and FIG. 9 is of the conventional wedge type ground pressure gauge. An example is shown, (a) is a cross-sectional view, (b) is a side view, and FIG. 10 is a cross-sectional view showing another example of a conventional wedge-type earth pressure gauge. 10 …… wedge type pressure gauge, 12 …… ring sensor, 13 …… pressure plate, 14 …… borehole, 15 …… wedge, 20 …… hydraulic drive device, 22 …… piston, 25 …… reaction force device, 27 …… Reaction force plate, 30 …… Shear rivet.

Claims (3)

(57) [Claims] 1. A ring-shaped sensor capable of detecting ground pressure, pressure plates arranged on both sides of the ring-shaped sensor, and two or more movably arranged between the ring-shaped sensor and the pressure plate. A wedge-type earth pressure gauge, characterized in that the ring-shaped sensor and the pressure plate can be fixed to the borehole by the wedge. 2. The wedge type earth pressure gauge according to claim 1, wherein a strain gauge is attached to the ring-shaped sensor. 3. A wedge having a ring-shaped sensor, pressure plates arranged on both sides of the ring-shaped sensor, and two or more wedges movably arranged between the ring-shaped sensor and the pressure plate. A method for installing a pressure-type earth pressure gauge, comprising: a hydraulic drive device for moving the wedge; and a reaction force device for preventing the ring-shaped sensor and the pressure plate from moving, the pressure plate, the wedge, and the wedge. While fixing the hydraulic drive device with a rivet that can be cut at a constant pressure, after fixing the reaction force device and the hydraulic drive device, insert these at arbitrary positions in the borehole,
A method for installing a wedge-type earth pressure gauge characterized in that the hydraulic drive device and the reaction force device are collected by pulling the wedge by the hydraulic drive device to press the ring-shaped sensor and the pressure plate into the borehole and cutting the rivet. .