KR101385889B1 - Apparatus for fixing measurement cable of tdr measurement system - Google Patents

Abstract

The present invention relates to an apparatus for fixing a measurement cable of TDR measurement equipment. The present invention includes a boring hole formed in measurement ground; a fixing pipe inserted into the boring hole and having a plurality of through-holes on the outer surface; a fixing unit provided at a lower end of the fixing pipe for fixing a lower end of a measurement cable inserted into the fixing pipe; and a fixing member provided at an upper portion of the fixing pipe for fixing the measurement cable. According to the present invention, when the measurement cable is buried in the boring hole formed in the ground of a measuring target area, the measurement is exactly performed since the measurement cable is buried in a straight line state. In addition, the cable transport and installing work are simplified.

Description

Measuring line fixing device of TDR measuring equipment {APPARATUS FOR FIXING MEASUREMENT CABLE OF TDR MEASUREMENT SYSTEM}

The present invention relates to a measuring line fixing device of the TDR measuring equipment.

TDR (Time Domain Reflectometry) is a device that detects the discontinuous position of a cable and is generally used in the communication field. On the other hand, TDR technology has been developed as a device for measuring the water content of the soil, equipment for measuring the displacement of the rock, equipment for measuring the displacement of the inclined ground due to the expansion of the application field.

As one of the application fields of TDR technology, TDR measuring equipment that measures the water content of soil is a TDR measuring instrument which is embedded in the ground and connected to the measuring line to generate electric pulses on the measuring line and detects the reflected wave reflected through the measuring line. (Also known as a TDR sensor), and a notebook computer connected to the TDR meter for processing and displaying data sensed by the TDR meter.

The operation of the TDR measuring equipment is as follows.

When an electric pulse is generated by the TDR instrument, the electric pulse is transmitted downward along the ground along the measurement line. Since the dielectric constants of water and soil in the ground are different, the local capacitance changes in the groundwater location, and the reflection waveform of the electric pulse appearing on the TDR meter is changed. Therefore, it is possible to measure the groundwater distribution (level) of the ground by using a notebook computer for the reflected waveform of the electric pulse generated at this time.

US Patent Publication No. 2009/0273352 (published Nov. 5, 2009), Republic of Korea Patent No. 10-1269325 (Registration date May 23, 2013), Republic of Korea Patent No. 10-1312072 (Registration date September 09, 2013) Measurement equipment is disclosed.

Each of the prior arts has a structure in which a measuring line is installed in the ground of a region to be inspected to measure the state of the ground.

The boring hole bored in the vertical direction of the ground with a boring machine in the ground of the inspection area, the measurement line inserted in the vertical direction to the boring hole along the boring hole, and the standard yarn filled in the boring hole in which the measurement line is inserted. The measurement line is composed of a coated wire made of plastic material and a thin conductor wire inserted inside the coated wire so as to have excellent portability.

However, the structure as described above is fixed to the measurement line by injecting a standard yarn in the state in which the measurement line is inserted into the boring hole along the boring hole, so that the measurement line is not positioned in a straight line along the boring hole. For this reason, the groundwater level where the groundwater is actually located does not match the length of the measurement line, and an error occurs in the measurement.

An object of the present invention is to provide a measuring line fixing device of the TDR measuring equipment to keep the measuring line in a straight state in the boring hole when the boring hole formed in the ground of the inspection target area.

In addition, another object of the present invention is to provide a measuring line fixing device of the TDR measuring equipment is easy to carry and simple installation work.

In order to achieve the object of the present invention, boring holes formed in the ground to be inspected; A fixing tube inserted into the boring hole and having a plurality of through holes in an outer circumferential surface thereof; A fixing unit provided at a lower end of the fixing tube and fixing a lower end of the measurement line inserted into the fixing tube; The measuring line fixing device of the TDR measuring equipment is provided on the fixing tube provided with a fixing member for fixing the measuring line.

The fixing tube preferably includes a plurality of unit fixing tubes and connecting means for connecting adjacent unit fixing tubes to each other.

The connecting means preferably includes a male screw thread formed on the outer peripheral surface of the end of one unit fixing tube, and a female screw thread formed on the inner inner surface of the end of the other unit fixing tube and fastened to the male screw.

The fixing unit includes a support member coupled to the fixed tube and fixedly supported by the measurement line, and coupling means for coupling the support member to the fixed tube, wherein the support member includes a fixed plate part to which the measurement line is fixedly supported, It is preferable that the support plate is formed extending to the side of the fixing plate coupled to the fixing tube.

An elastic member may be further provided between the support member and the measurement line.

In addition, to achieve the object of the present invention, boring holes formed in the ground to be inspected; The measurement line fixing device of the TDR measuring device is inserted into the boring hole, and provided with a measurement line insertion hole into which the measurement line is inserted, and includes a fixing bar made of a porous material.

The fixing bar preferably includes a plurality of unit fixing bars and connecting means for connecting adjacent unit fixing bars to each other.

In the present invention, when the measurement line is installed in the boring hole formed in the ground to be inspected, the measurement line is installed in a straight state along the boring hole in the boring hole. As a result, the reflection position of the electric pulse measured by the measurement line and the water level (distribution) of the groundwater in the dike become proportional, so that the water level of the groundwater in the dike can be accurately measured.

In one embodiment of the present invention, the measurement line is inserted into the boring hole by inserting the measurement line into the inside of the fixed tube and fixing one side of the measurement line to the fixing unit and fixing the other side to the fixing member. Installation of measuring lines in boring holes is simplified. In addition, in another embodiment, the measurement line is inserted into the boring hole by inserting the measurement line into the measurement line insertion hole of the fixing bar and inserting the fixing bar into which the measurement line is inserted into the boring hole. The job is simple.

1 is a cross-sectional view showing a state in which the TDR measuring equipment with a first embodiment of the measuring line fixing device of the TDR measuring equipment according to the present invention is installed;
2 is a cross-sectional view showing a first embodiment of a measuring line fixing device of the TDR measuring apparatus according to the present invention,
Figure 3 is a cross-sectional view showing another embodiment of the fixing tube constituting the first embodiment of the measuring line fixing device of the TDR measuring equipment according to the present invention,
4 is a plan view showing a fixing unit constituting a first embodiment of a measuring line fixing device of the TDR measuring equipment according to the present invention;
5 is a front sectional view showing a fixing unit constituting a first embodiment of a measuring line fixing device of a TDR measuring apparatus according to the present invention;
6 is a plan view showing a fixing member constituting a first embodiment of a measuring line fixing device of the TDR measuring equipment according to the present invention;
7 is a front sectional view showing a fixing member constituting a first embodiment of a measuring line fixing apparatus of the TDR measuring apparatus according to the present invention;
8 is a cross-sectional view showing a second embodiment of a measuring line fixing device of the TDR measuring apparatus according to the present invention;
9 is a cross-sectional view showing a fixing bar constituting a second embodiment of a measuring line fixing device of the TDR measuring apparatus according to the present invention.

Hereinafter, with reference to the accompanying drawings an embodiment of a measuring line fixing device of the TDR measuring apparatus according to the present invention.

1 is a cross-sectional view showing a state in which the TDR measuring equipment with a first embodiment of the measuring line fixing device of the TDR measuring equipment according to the present invention is installed. 2 is a cross-sectional view showing a first embodiment of a measuring line fixing device of the TDR measuring apparatus according to the present invention.

1 and 2, a first embodiment of a measuring line fixing device of a TDR measuring apparatus according to the present invention will be described. First, the TDR measuring apparatus includes a measuring line 100, a TDR measuring instrument 200, and a terminal 300. The terminal 300 and the TDR meter 200 are connected by a cable, and the measurement line 100 is connected to the TDR meter 200.

The TDR meter 200 is connected to the measurement line 100 to generate an electric pulse on the measurement line 100 and detects the reflected wave reflected through the measurement line 100. The measurement line 100 may be directly connected to a terminal of the TDR meter 200, and the measurement line 100 may be connected to the TDR meter 200 by a coaxial cable C. The TDR measuring instrument 200 may be a product such as HL8200NET produced by Hyperlab, Inc. and CRT-1000 manufactured by Cambell.

The terminal 300 is connected to the TDR meter 200 to process and display data sensed by the TDR meter 200. The terminal 300 is preferably a notebook computer.

The measurement line 100 includes a plurality of conductor lines 110 arranged in parallel with each other, and an insulation coating line 120 which surrounds the conductor lines 110 and fixes the conductor lines 110 to be parallel to each other. The conductor lines 110 are preferably two.

The measurement line 100 has a set length. The measurement line 100 is set according to the depth of facilities to be installed such as dams, banks, and the ground.

It is preferable that the cross-sectional shape of the said conductor line 110 is a rectangle. The cross-sectional shape of the conductor line 110 is implemented in various ways. The conductor wire 110 may be made of stainless steel, copper, steel, or the like.

It is preferable that the cross-sectional shape of the insulation coating line 120 is a rectangle. The insulation coating line 120 is formed so that the vertical length is sufficiently short compared to the horizontal length of the square cross section of the insulation coating line 120 to facilitate winding and easy handling. The conductor lines 110 are located in parallel with the insulation coating line 120. The insulation coating line 120 is preferably made of a material having a smaller dielectric constant than soil. The insulation coating line 120 is preferably made of plastic, and more preferably made of polyvinyl chloride (PVC).

The first embodiment of the measuring line fixing device according to the present invention includes a boring hole (H), a fixing pipe 410, a fixing unit 420, and a fixing member 430 formed in the ground to be inspected.

The measuring line 100 is installed on the ground to measure the water content of the soil, is installed on the rock to measure the displacement of the rock, or is installed on the inclined ground to measure the displacement of the inclined ground. Hereinafter, the case where the measurement line 100 is installed in the bank to measure the water content of the soil will be described.

When the measurement line 100 is installed on the embankment, the boring hole H is formed by a boring machine on the inspection target ground of the embankment. Boring hole (H) is formed in the vertical direction of the ground to be inspected.

Fixing tube 410 is inserted into the boring hole (H). Fixing tube 410 has a length corresponding to the length of the boring hole (H), a plurality of through holes 411 are provided on the outer peripheral surface. The fixed tube 410 is preferably a plastic material. The measurement line 100 is inserted into the fixed tube 410. The outer diameter of the fixing tube 410 is preferably formed to correspond to the inner diameter of the boring hole (H), but may be formed smaller than the inner diameter of the boring hole (H).

In another embodiment of the fixing tube 410, as shown in Figure 3, the fixing tube 410 is a plurality of unit fixing tube 410A and the connecting unit 440 connecting the adjacent unit fixing tube 410A to each other It may include. When the length of the fixing tube 410 is long, it is preferable that the fixing tube 410 is composed of a plurality of unit fixing tube (410A). The connecting means 440 is formed on the male threaded portion 441 formed on the outer circumferential surface of one end of the unit fixing tube 410A and the female threaded portion on which the male threaded portion 441 is fastened by being formed on the inner circumferential surface of the end of the other unit fixed tube 410A. 442.

As shown in FIG. 4, the fixing unit 420 is provided at the lower end of the fixing tube 410 to fix and support the lower end of the measurement line 100 inserted into the fixing tube 410. The fixed unit 420 is coupled to the fixed tube 410 and includes a support member 421 to which the measurement line 100 is fixedly supported, and a coupling means 422 to couple the support member 421 to the fixed tube 410. . The support member 421 preferably includes a fixed plate portion 421a to which the measurement line 100 is fixedly supported, and support feet 421b extending to the side of the fixed plate portion 421a to be coupled to the fixed tube 410. Do. The fixed plate portion 421a is preferably formed in a disk shape having a uniform thickness, and a coupling hole 421c for fixing the measurement line 100 is formed therein. Preferably, the support feet 421b are three. Coupling means 422 is preferably an adhesive. The coupling means may also be a screw.

Meanwhile, an elastic member 423 may be further provided between the support member 421 and the measurement line 100. Preferably, the elastic member 423 is a coil spring, one side of the elastic member 423 is fixed to the fixing plate portion 421a of the support member 421 and the other is connected to the end of the measurement line 100.

The fixing member 430 is provided at an upper portion of the fixing tube 410 to fix the upper portion of the measurement line 100. The fixing member 430 preferably includes a fixed plate portion 431 to which the measurement line 100 is fixedly supported, and support feet 432 extending from the side of the fixed plate portion 431 to be coupled to the fixed tube 410. Do. The fixed plate portion 431 is preferably formed in a disk shape having a uniform thickness, it is preferable that the fixing groove 433 is fixed to the measurement line 100 is formed therein. Preferably, the support feet 432 are three. Support feet of the fixing member 430 is fixedly coupled to the fixing tube 410 by a coupling means.

The process of fixing the measurement line 100 with the measurement line fixing device of the first embodiment, first, the measurement line 100 is inserted into the inside of the fixed tube 410, and then the fixing unit provided at the lower end of the fixed tube 410 ( One end of the measurement line 100 is fixed to 420. The fixing pipe 410 into which the measurement line 100 is inserted is inserted into the boring hole H. After pulling the measurement line 100 tautly, the upper portion of the measurement line 100 is fixed to the fixing member 430. Then, a standard yarn is injected into the fixed tube 410. The measuring line 100 is connected to the TDR measuring instrument 200. When the elastic member 423 is provided between the fixed unit 420 and the measurement line 100, the tension state of the measurement line 100 is maintained by the elastic force of the elastic member 423, thus making the measurement line 100 more straight. Will be kept in a state.

When the fixing tube 410 is composed of a plurality of unit fixing tube (410A) it is used to connect the unit fixing tube 410A to each other in accordance with the length of the measurement line 100.

8 is a cross-sectional view showing a second embodiment of a measuring line fixing device according to the present invention.

As shown in FIG. 8, the second embodiment of the measuring line fixing device according to the present invention includes a boring hole H formed in the ground to be inspected and a boring hole H, and the measuring line 100 is disposed therein. And a fixing bar 450 provided with a measurement line insertion hole 451 to be inserted.

Fixing bar 450 is made of a porous material. It is a porous material that can absorb water such as sponge and flower foam. The outer diameter of the fixing bar 450 preferably corresponds to or slightly smaller than the inner diameter of the boring hole (H). The cross-sectional shape of the measurement line insertion hole 451 of the fixing bar 450 is formed to correspond to the cross-sectional shape of the measurement line 100, and the cross-sectional size of the measurement line insertion hole 451 is the cross-sectional size of the measurement line 100. Corresponding to or slightly larger.

In another embodiment of the fixing bar 450, as shown in FIG. 9, the fixing bar 450 is a connection connecting a plurality of unit fixing bars 450A and unit fixing bars 450A adjacent to each other. Means; When the length of the fixing bar 450 is long, it is preferable that the fixing bar 450 is composed of a plurality of unit fixing bars 450A. The connecting means includes a cylindrical groove 452 formed at one end of one unit fixing bar 450A and an annular rod-shaped insertion protrusion formed at one end of the other unit fixing bar 450A and inserted into the cylindrical groove 452. It consists of 453. On the other hand, the connecting means may be excluded.

In the process of fixing the measurement line 100 with the measurement line fixing device of the second embodiment, first, the measurement line 100 is inserted into the measurement line insertion hole 451 of the fixing bar 450, and then the measurement line 100 The inserted fixed bar 450 is inserted into the boring hole (H). The measuring line 100 is connected to the TDR measuring instrument 200. When the fixing bar 450 is composed of a plurality of unit fixing bars 450A, the unit fixing bars 450A are connected to each other to fit the length of the measurement line 100.

Hereinafter, the operation and effects of the measurement line fixing device of the TDR measuring apparatus according to the present invention.

The measuring line fixing device of the TDR measuring apparatus according to the present invention can be applied to various fields, hereinafter, it will be described to measure the water content of the dike according to the height of the dike by installing on the dike.

First, the boring hole (H) is drilled in the vertical direction from the upper surface of the embankment, and then the measurement line 100 is fixed to the measurement line fixing device and then inserted into the boring hole (H). In the first embodiment of the measurement line fixing device, the measurement line 100 is inserted into the boring hole H, and then a standard yarn is injected into the fixing pipe 410 for fixing the measurement line 100.

In the state where the measurement line 100 is connected to the TDR meter 200, when the TDR meter 200 generates electric pulses, the electric pulses along the conductor lines 110 of the measurement line 100 may be embanked (D). Is transmitted in the vertical direction, and an electric field is formed in the measurement line 100 as electric pulses flow through the conductor lines 110. Since the dielectric constants of the water and the soil are different, the electric pulses are changed in the part where the groundwater of the embankment D is located, and the electric pulses reflected in the changed state are detected by the TDR meter 200. Data sensed by the TDR meter 200 measures the distribution (location) of groundwater functioned on the bank by the terminal in which the driving software is stored.

In the present invention, when the measurement line 100 is installed in the boring hole H formed on the ground to be inspected, the measurement line 100 is installed in a straight state along the boring hole H in the boring hole H. As a result, the reflection position of the electric pulse measured by the measurement line 100 and the water level (distribution) of the groundwater in the dike are proportional, so that the water level of the groundwater in the dike can be accurately measured. That is, when the electric pulse flowing along the measuring line 100 is reflected, the groundwater level is measured as the time when the electric pulse is reflected, so that the measuring line 100 is installed in the boring hole H in a straight state. Although the level of the groundwater can be measured accurately, when the measurement line 100 is installed in the boring hole (H) in a curved state, the level of the groundwater cannot be accurately measured.

In the case of the first embodiment of the present invention, the measuring line 100 is inserted into the fixing tube 410, and one side of the measuring line 100 is fixed to the fixing unit 420, and the other side is fixed to the fixing member 430. Since the measuring pipe 100 is installed in the boring hole H by inserting the fixing pipe 410 into the boring hole H, the operation of installing the measuring line 100 in the boring hole H is simplified. In addition, in the second embodiment, the measurement line 100 is inserted into the measurement line insertion hole 451 of the fixing bar 450 and the fixing bar 450 into which the measurement line 100 is inserted is inserted into the boring hole H. Since the measurement line 100 is installed in the boring hole H by insertion, the operation of installing the measurement line 100 in the boring hole H is simplified.

In addition, in the first embodiment of the present invention, when the fixed tube 410 is composed of a plurality of unit fixing tube (410A) when the transport fixing tube 410 is separated into unit fixing tube (410A) and unit fixing tube (410A) when installed ) Will be assembled to facilitate transportation. In addition, in the second embodiment, when the fixed bar 450 is composed of a plurality of unit fixing bars 450A, the fixing bar 450 is separated into unit fixing bars 450A when carrying and unit fixing bars when installed ( Since 450A) are assembled, transportation is convenient.

100; Measurement line 110; Conductor
410; Fixed tube 420; Fixed unit
430; Fixing member 450; Fixed bar
H; Boring hall

Claims (7)

Boring holes formed in the ground to be inspected;
A fixing tube inserted into the boring hole and having a plurality of through holes in an outer circumferential surface thereof;
A fixing unit provided at a lower end of the fixing tube and fixing a lower end of the measurement line inserted into the fixing tube;
And a fixing member provided at an upper portion of the fixing tube to fix the measuring line. The apparatus of claim 1, wherein the fixing tube comprises a plurality of unit fixing tubes and connecting means for connecting adjacent unit fixing tubes to each other. According to claim 2, The connecting means is a measurement of the TDR measuring equipment including a male threaded portion formed on the outer peripheral surface of the end of one unit fixing tube, and a female threaded portion formed on the inner peripheral surface of the end of the other unit fixing tube is fastened to the male threaded portion; Line fixing device. According to claim 1, wherein the fixing unit is coupled to the fixed tube and the support member is fixed to the measuring line, and the coupling means for coupling the support member to the fixed tube,
The support member is a measurement line fixing device of the TDR measuring equipment including a fixed plate portion is fixed to the measurement line and the support feet extending to the side of the fixed plate portion coupled to the fixed tube. The measuring line fixing device of claim 4, wherein an elastic member is further provided between the supporting member and the measuring line. Boring holes formed in the ground to be examined;
And a measurement line insertion hole inserted into the boring hole and having a measurement line inserted therein, and a fixing bar made of a porous material. The apparatus of claim 6, wherein the fixing bar comprises a plurality of unit fixing bars and connecting means for connecting adjacent unit fixing bars to each other.

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