KR20100062529A - Leak sensing apparatus - Google Patents

Abstract

PURPOSE: A leak sensing apparatus is provided to confirm accurate leak occurrence position sensed by a reverse direction and a right direction and minimize a sensing line. CONSTITUTION: A conductive line(410) has a conductivity to a lengthy direction. A first resistance line(420) is formed parallel with the conductive line to the lengthy direction. A second resistance line(430) is formed parallel with the first resistance line to the lengthy direction. The second resistance line is electrically connected with the first resistance line on a position. A controller alternatively supplies a power source to the first resistance line and the second resistance line. The controller produces a distance with gaining a resistance value from the conductive line in a leak generation.

Description

Leak Sensing Apparatus

The present invention relates to a leak detection apparatus, which is directly attached to a place where a leak (LEAKGE) is generated by a tape method (wall, pipe, equipment, etc.) in a device for detecting a leak, the structure is simple and the leak generating position The present invention relates to a leak detection device that can accurately determine the resolution.

The present applicant has proposed a tape type physical property leak sensor device in Patent Registration No. 10-0827385 registered on April 28, 2008.

The leak sensor device has a tape shape, and a plurality of conductor lines are formed side by side in the longitudinal direction to detect a leak at the upper end, and a resistor having a constant resistance value is formed at a predetermined interval in the conductor line, so that the conductor lines are formed in the conductor line. In the event of a leak, the conductor lines formed side by side are turned on by the leak and an alarm is issued to the remote controller.

At the same time, the total resistance of each resistor to the position where the leak is generated is determined by the controller so that the distance can be confirmed.

However, in the conventional tape-type physical property detection leak sensor device is formed a resistor at a predetermined interval, it is difficult to determine the exact position when the distance is large, and also a plurality of conductor lines should be formed for the installation of the resistor.

In addition, since the power is applied only in one direction of the conductor line, the flow of current in one direction occurs. At this time, since the moisture constituting the leak is ionized to increase the resistance value, an error in distance measurement occurs.

Therefore, it is difficult to accurately determine the position of occurrence of the leak, which causes a problem that the reliability of the device is lowered.

An object of the present invention has been proposed to improve the problems in the prior art as described above, while minimizing the detection line formed in the tape-type leak detection device and alternately applying power to the detection line in the forward and reverse directions The present invention provides a leak detection device that prevents moisture from ionizing and confirms an accurate leak occurrence position with each resistance value detected by forward and reverse directions.

According to a preferred embodiment of the present invention for achieving the above object,

In the form of a tape, the base film layer, the conductive line layer, the protective film layer is sequentially laminated upwards in the leak detection device for detecting physical properties by the leak,

The conductive line layer,

A conductor line formed with conductivity in the longitudinal direction,

A first resistance line spaced apart from the conductor line and formed in parallel in the longitudinal direction;

It is formed side by side in the longitudinal direction while being spaced apart from the first resistance line, and consists of a second resistance line electrically connected to the first resistance line at any position,

And a controller configured to alternately supply power to the first resistor line and the second resistor line, and to calculate a distance by obtaining each resistance value from the conductor line when a leak occurs.

As described above, according to the leak detection apparatus according to the present invention, it is possible to confirm whether leakage occurs by two or three conductive lines, and moisture is ionized by alternately supplying power in the forward and reverse directions on the conductive line. The resistance value can be prevented from changing to ensure the accuracy of the distance measurement.

In addition, by calculating the leakage position in the forward and reverse directions from the resistance value obtained from the alternately supplied power, this also has the effect of accuracy of the distance measurement.

Hereinafter, a leak detection apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of the physical property detection tape 100 of the present invention, the adhesive layer 200, the base film layer 300, the conductive line layer 400, the protective film layer 500 is upward from the bottom surface Are sequentially stacked.

The adhesive layer 200 is attached to a place where leakage occurs and is configured in the form of an adhesive tape.

The base film layer 300 is a layer for forming the conductive line layer 400 thereon, and PET, PE, PTFE, PVC or other Teflon-based to form the insulation and the pattern of the conductive line layer 400 in a printing method. It is formed of a material.

The conductive line layer 400 is a layer in which a plurality of conductor lines and resistance lines are formed in a pattern form, and is spaced apart from each other in the longitudinal direction of the property sensing tape 100 in parallel to the upper surface of the base film layer 300 in a strip form. Is placed on.

The protective film layer 39 is stacked on top of the conductive line layer 400 and is formed of PET, PE, PVC, or Teflon-based material as a layer for protecting the pattern of the conductive line layer 400 from external stimuli.

FIG. 2 is a view illustrating a pattern forming state of the conductive line layer 400. The conductor line 410 printed with silver compound and the first resistance line 420 spaced apart from the conductor line 410 are formed. ), And a second resistance line 430 formed side by side while being spaced apart from the first resistance line 420 is configured, and any one portion of the first resistance line 420 and the second resistance line 430 (preferably Ends) are connected to each other to allow electrical conduction.

In addition, terminals 411, 421, and 431 for receiving power from the controller 900 are formed at the ends of the conductor line 410 and the resistance line 420, respectively.

The conductor line 410 is made of pure conductor such as silver and has a resistance of 0 to 20Ω, and the resistance lines 420 and 430 are formed to have a resistance of about 50 to 500Ω.

The conductor lines 410 and the resistance lines 420 and 430 constitute a leak detection circuit as shown in FIG. 3, and power in the forward and reverse directions is alternately supplied from the controller 900 to each of the resistance line terminals 421 and 431. In addition, the controller 900 receives power from the conductor line terminal 411 to calculate a resistance value in each direction.

4 is a diagram showing the shape of the protective film layer 500, when the protective film layer 500 is stacked on top of the conductive line layer 400 is completely isolated from the outside, the conductive line layer 400 when the leakage occurs Since it is impossible to detect the leak in, the hole 510 is formed at every predetermined interval.

The hole 510 is formed to have a long groove, a circular groove, or other shape in the width direction of the property sensing tape 100 so that the conductor line 410 and the first resistance line 420 may be exposed. The spacing between) is preferably formed to have a spacing of 0.5-1.5 cm.

5 is a view illustrating a state in which a plurality of physical property detection tapes 100 are extended and connected to a controller 900. When the length of the leakage detection property is long, the physical property detection tape 100 is connected through a connector 700. Can be connected to extend each other.

In addition, the conductive line layer 400 and the signal line 800 are connected through the connector 600 to be connected to the controller 900.

In this case, the connector 600 is connected to the conductor line terminal 411 and the resistance line terminals 421 and 431.

Describe the process of detecting leaks.

First, the physical property detection tape 100 is attached to a desired position of the property detection.

Since the adhesive layer 200 is formed on the bottom of the physical property detection tape 100, the physical property tape 100 may be easily attached.

A voltage of about V flows through the resistance lines 420 and 430. The processor 910 inside the controller 900 illustrated in FIG. 6 controls the power supply unit 920 to control the first resistance line 420 and the second resistance line. Alternating with 430 causes a voltage to flow every predetermined period.

That is, since the first resistance line 420 and the second resistance line 430 are electrically connected to each other, the forward voltage v1 and the reverse voltage v2 periodically flow alternately as shown in the circuit configuration of FIG. 3. will be.

When leakage occurs and water, chemical solution, and other physical properties (conductors) drop at a predetermined position on the upper portion of the property detection tape 100, the leakage between the conductor line 410 and the first resistance line 420 as shown in FIG. A closed circuit by 440 is configured.

The resistance value and the voltage vary according to the position of the leak 400. In this case, when the positive voltage v1 is applied, a closed circuit of 'v3' is configured so that the resistance value is controlled through the conductor line terminal 411. When the voltage v2 in the reverse direction is applied, a closed circuit of 'v4' is configured so that a resistance value is supplied to the processor 910 through the conductor line terminal 411. Will be.

When the forward and reverse voltages v1 and v2 are alternately supplied, ionization of moisture contained in the leak is prevented, so that the resistance value at the position where the leak is generated does not change and a constant resistance value is obtained.

In addition, since the processor 910 obtains two resistance values and voltage values through different paths through the closed circuit of 'v3' and the closed circuit of 'v4', the leak generation position is verified.

That is, since the processor 910 knows the lengths of the resistance lines 420 and 430, the processor 910 compares the voltage value and the resistance value input through the path of 'v3' and the resistance value and the voltage value input through the path of the 'v4'. To determine a more accurate position.

Therefore, the resistance value and the voltage value are input from the processor 910 to calculate the distance according to the resistance value and the voltage value, and the processor 910 compares the calculated value with a preset value through the display unit 930. The detection distance is displayed and an alarm sound is generated through the alarm sound generator 940.

FIG. 7 is a view illustrating another pattern formation state of the conductive line layer 400, in which the conductor line 410 is excluded and only two resistance lines 420 and 430 are formed, and the processor 910 is described above. When power is alternately supplied in the forward and reverse directions, and a leak 440 is generated across the first resistance line 420 and the second resistance line 430, the processor 910 receives a voltage from the resistance line terminals 421 and 431. The distance is calculated by obtaining values and resistance values.

1 is a cross-sectional view of the present invention.

2 shows a pattern of a conductive line layer.

3 is a circuit diagram of a pattern for leak detection.

4 shows the form of a protective film layer.

5 is a view showing a connection state between the controller and another tape;

6 is an internal circuit block diagram of the controller.

7 shows another example of a conductive line layer.

<Description of the symbols for the main parts of the drawings>

200: adhesive layer 300: base film layer

400: conductive line layer 410: conductor line

420,430 Resistance Line 440 Leak

500: protective film layer 600, 700: connector

800 signal line 900 controller

Claims (2)

In the form of a tape, the base film layer, the conductive line layer, the protective film layer is sequentially laminated upwards in the leak detection device for detecting physical properties by the leak, The conductive line layer, A conductor line formed with conductivity in the longitudinal direction, A first resistance line spaced apart from the conductor line and formed in parallel in the longitudinal direction; It is formed side by side in the longitudinal direction while being spaced apart from the first resistance line, and consists of a second resistance line electrically connected to the first resistance line at any position, And a controller configured to alternately supply power to the first resistor line and the second resistor line, and to calculate distance by obtaining each resistance value from the conductor line when a leak occurs. In the form of a tape, the base film layer, the conductive line layer, the protective film layer is sequentially laminated upwards in the leak detection device for detecting physical properties by the leak, The conductive line layer is formed with a first resistance line and a second resistance line formed side by side in the longitudinal direction, And a controller configured to alternately supply power to the first resistance line and the second resistance line, and calculate a distance by obtaining each resistance value through the alternately supplied power when the leakage occurs. Device.

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