KR19980067359A - Displacement measuring device - Google Patents

Abstract

The present invention relates to a measuring mechanism for measuring displacements occurring in the ground supporting structures and structures in civil engineering and building construction, including tunnels, and more specifically, to simply measure the displacements generated by converting them into electrical signals. An apparatus comprising: a displacement rod for generating displacement by an external pressure, a body portion for holding and supporting the displacement rod, a displacement conversion portion for converting a displacement generated by the displacement rod into an electrical signal, and Characterized in that it consists of an inverse conversion unit for reducing the electrical signal generated in the displacement conversion unit to the length of the displacement actually generated.

Description

Displacement measuring device

The present invention relates to a displacement measuring device used as a ground displacement measuring instrument, a rock bolt accelerometer, and a ground sediment meter for measuring displacements generated in the ground, rock, and structure during civil engineering and construction work including tunnels. The present invention relates to a device for simply measuring the displacement generated by the electrical signal.

When constructing tunnels and other structures, the project is designed based on the results of limited ground surveys and soil tests, and the construction is progressed accordingly. However, the ground condition tends to be different from that of the design. Displacement is also measured differently from design. Therefore, accurate measurement of displacement of structures, etc., is essential for accurate and safe construction.

In addition, by actually measuring the foundation-based state, the displacement of the soil and the displacement of the structure, it is possible to accurately evaluate the new construction method and to establish and compare with the existing construction method.

In addition, it is possible to prevent unexpected risks in the design by analyzing the measurement results, and to identify the cause and prevent the risks during maintenance after the completion of construction.

As such, the displacement measurement of the ground and the structure can be said to be essential.

1 is a cross-sectional view illustrating an embodiment of a displacement measuring apparatus used in the related art, and FIG. 2 is an installed state cross-sectional view illustrating a state in which the displacement measuring apparatus shown in FIG. 1 is installed.

As shown in the related art, the conventional displacement measuring device has a cylindrical shape capable of accommodating a plurality of displacement rods 4a to 4d which are displaced together according to the displacement of the structure or the ground. The outer periphery includes a body 1 having a spiral protrusion 7 and a fixed plate 3a to 3d having a plurality of through holes which prevent the displacement rods 4a to 4d from flowing inside the body 1. It is installed inside.

A screw groove is formed in the inner circumferential surface of the end portion 7 of the body 1, the coupling portion 5 is screwed into the screw groove, and fixing plates 3a to 3d in the cylindrical space inside the coupling portion 5. The fixing plate 5 'of the same shape as that is fixedly installed.

In addition, the front end portion of the coupling portion 5 is formed with a protrusion 5a formed with a screw groove coupled to the screw groove formed at the end of the body 1, is screwed with the body 1, and also the coupling portion 5 A screw groove 5b is formed on the inner circumferential surface of the terminal of the end portion, and is coupled to the screw groove in the packing 6.

As shown in FIG. 2, the displacement measuring instrument is easily inserted into the tunnel by inserting the coupling portion 5 into the radiation wrench and rotating the spiral portion along the outer circumference of the body 1 to rotate in the ground. Is inserted. The installation is then completed by indenting the concrete around the body 1 and curing the concrete 8 and the body 1 integrally, thereby integrating the displacement meter into the structure generating the displacement.

When pressure is received from the structure or the ground in the installed displacement measuring instrument as described above, displacement occurs in a specific part.

3 is a cross-sectional view illustrating a state in which a deflection occurs due to the pressure generated by the structure of the conventional ground displacement measuring apparatus.

As shown in FIG. 2, as described above, the displacement measuring device is fixedly installed at an appropriate portion, and then the packing 6 installed at the coupling portion 5 is opened, and the coupling portion (using a length measuring mechanism such as a vernier caliper) is used. 5) The lengths of the first to fourth displacement rods 4a to 4b exposed to the outside of the fixed plate 5 'formed and fixed therein are measured, and the measured lengths are set to initial values.

Subsequently, when a predetermined time elapses, the vertical displacement is applied to the displacement measuring device according to the earth pressure and the lipid by the soil, rock, etc. surrounding the tunnel, and the body 1 of the displacement measuring device is The first to fourth displacement rods 4a to 4d which are bent in a vertical direction under pressure and fixed to the inside of the body 1 by the first to fourth fixing plates 3a to 3d are also bent at the same time. The degree of warpage varies depending on the earth pressure and displacement difference received by each part.

Therefore, when the body 1 of the displacement measuring device is bent, the length of the first to fourth displacement rods 4a to 4d exposed through the fixing plate 5 'inside the coupling portion 5 is changed. The length of the changed first to fourth displacement rods 4a to 4d is measured using a vernier caliper or the like, and then the initial measurement time and the changed measurement length of the first to fourth displacement rods 4a to 4d are reference values. By comparing and analyzing the lengths of the wires to determine how much pressure is applied to which part, the tunnel construction progress step is decided later or tunnel management is completed.

The conventional displacement device as described above is a vertical displacement applied to the displacement rod by the length change generated in the displacement rod using a length measuring mechanism such as a vernier caliper fixedly installed by the fixed plate inside the body Although the measurement results are different depending on the proficiency of the measurement person, the accuracy of the measurement is not enough to detect the accurate ground displacement, and due to this error, the degree of displacement delivered to each part cannot be accurately read. It will have a huge impact on tunnel construction and aftercare.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and is intended to provide a displacement measuring apparatus capable of constantly measuring the displacement generated by the displacement rod by extracting and reading the displacement generated in the displacement rod as an electrical signal.

1 is a cross-sectional view showing an embodiment of a displacement measuring apparatus used in the prior art.

FIG. 2 is an installation state sectional view for illustrating a state in which the displacement measuring device illustrated in FIG. 1 is installed.

3 is a cross-sectional view illustrating a state in which a deflection occurs due to the pressure generated by the structure of the conventional ground displacement measuring apparatus.

4 is a cross-sectional view illustrating one embodiment of the present invention.

5 is an assembled cross-sectional view for illustrating a configuration of a displacement converting unit centered on a variable resistor.

Figure 6 is a cross-sectional view of the installation of another embodiment to which the present invention is applied.

In order to achieve the above object, the displacement measuring apparatus of the present invention is a displacement rod is generated by the external pressure, the body portion for holding the displacement rod and the displacement generated by the displacement rod electrical signal Displacement conversion unit for converting to, and the reverse conversion unit for reducing the electrical signal generated by the displacement conversion unit to the length of the displacement actually generated.

Hereinafter, the features will be described in detail with reference to the accompanying drawings.

4 is a cross-sectional view illustrating one embodiment of the present invention.

The trunk portion 10 has a front end portion of a conical shape, a body 11 having a cylindrical length portion, an intermediate connector 12 coupled to a screw groove at an outer edge of the end portion of the body 11, and an intermediate connector ( 12 is formed of an assembly 13 coupled to the screw groove formed on the inner peripheral surface of the end portion, and a packing 14 coupled to the screw groove formed on the inner peripheral surface of the terminal portion of the assembly.

In addition, a plurality of fixing plates 20 having a plurality of through holes 21 are fixedly installed in the body 11, and displacement rods 30: 30a to 30d are fixed to the through holes 21. In addition, the end portions 30 'of the displacement rods 30' (30a 'to 30d') are connected to the mobile terminals of the variable resistors 40: 40a to 40d so that the length of the displacement rods 30 can be expanded and contracted. To change the resistance of.

5 is an assembled cross-sectional view for illustrating a configuration of a displacement converting unit centered on a variable resistor.

The displacement converter may be manufactured using various electric elements, piezoelectric elements, or variable resistors, but will be described by using a variable resistor as shown in the drawing as an example.

The variable resistor 40 may coat the carbon film 42, which is a resistive material, on the metal plates 42 and 42 'formed in the substrate 41 so that the resistance is proportional to the length of the metal plate, and the carbon film 42 is formed by the two metal plates. It can be encapsulated in all or coated in either of them. In addition, the case 46 of the variable resistor 40, as the displacement rods 30 are stretched, as the end portion 30 'is moved, the case to facilitate the movement of the movable rod 43 is the same displacement occurs The grooves 47 formed along the longitudinal direction in the 46 are tongued. In addition, a shorting terminal 44 for shorting the two metal plates 42 and 42 'is provided at the lower portion of the movable rod 43, and the shorting terminal 44 is supported by the shorting terminal support 45. The moving rod 43 is protruded on the upper part of this support body. External lead terminals a, b, and c are provided at each end of each of the metal plates 42 and 42 'to facilitate resistance measurement from the outside.

In addition, the outer circumferential surface of the body 11 is formed with a spiral projection is easy to dig into the soil or concrete, it is easy to dig into the inside of the structure or soil by rotation. In addition, a screw groove is formed on the outer circumferential surface of the end portion 11 'of the body 11, and the intermediate connector 12 is installed in the screw groove to facilitate the installation of the variable resistor 40. That is, the intermediate connector 12 is separated from the body 11 to connect the end portions of the movable rod 43 and the displacement rod 30 of the variable resistor 40, and after the connection is completed, the intermediate connector 12 and the body are connected. Combine.

In addition, a screw groove is formed in the inner circumferential surface of the terminal portion of the intermediate assembly 12 so that the coupling body 13 is coupled, and an inner circumferential surface of the terminal portion of the coupling body 13 is also provided with a packing 14, and the packing 14 penetrates. The ball is formed so that the lead-out cable 15 is fixed through. In addition, the fine wires in the lead-out cable 15 are connected to predetermined lead terminals a, b, and c of each variable resistor 40, and at the end of the lead-out cable, a current flowing by applying a voltage to the variable resistor 40 is applied. By measuring and calculating the resistance value based on this current value, an inverse converter (not shown) for calculating the changed displacement is provided.

In addition, the present invention is the length change step of causing the length change by the pressure of the surrounding structure or soil, the resistance change step of changing the resistance value from the length change step, the initial resistance value and the measured resistance value of the resistance change step It characterized in that it comprises an inverse transformation step of measuring the change in length from.

When a plurality of displacement rods 30 are provided with pressure from a structure or earth and sand, predetermined portions of the displacement rods 30 are warped, and thus a change in length occurs. In response to this change in length, the movable rod 43 moves accordingly, thereby changing the resistance value of the variable resistor. In addition, the current resistance value is calculated by applying a voltage to the resistor and measuring the current flowing. Compare this to the resistance value calculated in the same way at the time of installation. This change in resistance

R = ρ l / S

Since the change in length means the change in length.

Figure 6 is a cross-sectional view of the installation of another embodiment to which the present invention is applied.

The embodiment shown in FIG. 6 is for measuring the ground subsidence and the surface subsidence of the present invention.

Displacement measuring device 100 is a displacement rod 120 having a different length coupled to the cement 130 to be integrally displaced with the base 110, and the electrical change in the length generated by the displacement rod A signal converter for converting the signal, for example, the variable resistor 140, and the inverse converter 150 for measuring the changed length using the resistance change generated from the variable resistor 140. Since the basic principle of measuring the displacement is the same as described in the previous embodiment, it will be omitted. Reference numeral 160 is a protective cap for protecting the variable resistor and the displacement rods.

The embodiments described above are not limited to the contents of the present invention, the present invention can be applied as it is to a rock bolt accumulator, and can be applied to other devices to measure the displacement.

The present invention according to the above configuration can be measured by converting the change in the length of the displacement rod generated by the electrical signal, thereby eliminating inaccuracies due to the measurement of the eye, it is easy to measure the number of measurements can be increased freely It works.

Claims (6)

Displacement rod is generated displacement by the external pressure; Body portion for fixing the displacement rod; A displacement converting unit converting the displacement generated by the displacement rod into an electrical signal; Displacement measuring device for measuring the displacement generated in the ground, characterized in that it comprises an inverse transform unit for reducing the electrical signal generated by the displacement conversion unit to the length of the displacement actually generated. According to claim 1, wherein the body portion is a body having a cylindrical length; And a coupling coupled to the screw groove of the end of the body, and a packing coupled to the screw groove formed on the termination of the assembly. 3. The displacement generated in the ground of claim 2, wherein the body portion includes an intermediate connector screwed between the body and the assembly between the body and the assembly to facilitate installation of the displacement converter. Displacement measuring device for measuring the The ground according to any one of claims 1 to 3, wherein a plurality of fixing plates having a plurality of through holes are fixedly installed on an inner circumferential surface of the body, and a displacement rod is inserted into and fixed to the through holes. Displacement measuring device for measuring the generated displacement. The displacement measuring unit according to any one of claims 1 to 3, wherein the displacement converting unit is a variable resistor and converts the length change of the displacement rod into a change in resistance value. Measuring device. Measuring the length change from the length change step of changing the linear distance of the displacement rod by the pressure of the ground, the resistance change step of changing the resistance value from the length change step, and the initial resistance value and the measured resistance value of the resistance change step. Displacement measuring device for measuring the displacement generated in the ground, characterized in that it comprises a reverse conversion step.