KR101200918B1 - Leak sensing apparatus having heating function - Google Patents

Abstract

The present invention provides a leak detection device having a heating function for simultaneously performing a leak detection and a heating function by supplying a signal for leak detection and power for generating heat to a resistive conductor line configured in a tape type leak detection device. To provide.

The present invention for achieving the above object, the base film layer formed in the form of a tape; Conductive lines formed side by side with a plurality of conductive lines having resistance on an upper surface of the base film layer; And a controller for alternately applying a power supply for heating and a detection signal for detecting a leak to a conductive line constituting the conductive line.

Description

Leak sensing apparatus having heating function

The present invention relates to a leak detection device, which directly attaches to a place where a leak (LEAKGE) is generated by a tape method (wall, pipe, equipment, etc.) in a device for detecting a leak, by adding a heating function to flow inside. The present invention relates to a leak detection device having a heating function for preventing fluid from being generated and freezing.

Applicant has already proposed a tape type leak detection device several times.

The leak detection device has a tape shape, and a plurality of conductor lines having resistance in parallel to the longitudinal direction are formed by a printing method at the top to detect a leak, and when the leakage occurs in the conductor line, the conductor lines formed side by side are The conduction by the leak changes the resistance value, and the leak is detected by reading the converted resistance value from a remote controller to generate an alarm.

At the same time, the conductor line resistance up to the location where the leak occurred can be read and the controller can check the distance of the leak location.

Such a tape type leak detection device can be easily diverted from the leak detection function to enable various types of applications, and such various applications are required.

SUMMARY OF THE INVENTION An object of the present invention is to heat a leak detection and heating function simultaneously by supplying power for generating a signal and heat for leak detection to a conductor line having resistance configured in the tape type leak detection device as described above. It is to provide a leak detection device having a function.

The present invention for achieving the above object,

A base film layer formed in a tape shape;

Conductive lines formed side by side with a plurality of conductive lines having resistance on an upper surface of the base film layer;

And a controller for alternately applying a power supply for heating and a detection signal for detecting a leak to a conductive line constituting the conductive line.

As described above, the leak detection device having a heating function according to the present invention, by adding a heating function to the leak detection device in the form of a tape, as well as whether or not a leak occurs when the leak occurs when installed outside the pipe through which the fluid flows. It can be used for heating or to prevent the effect is excellent in the applicability of various fields.

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

1 is a configuration diagram according to a first embodiment of the present invention, in which an adhesion layer 100, a base film layer 200, a conductive line 300, and an upper protective film layer 400 are sequentially stacked upward from a bottom surface thereof. It is done.

The adhesive layer 100 is attached to a place where leakage occurs and is configured in the form of an adhesive tape.

The base film layer 200 is a layer for forming the conductive line 300 thereon, and is formed of PET, PE, PTFE, PVC or other Teflon-based to form the insulation and the pattern of the conductive line layer 300 in a printing method. It is made of material.

The conductive line 300 is a layer in which conductive lines 310, 320, 330, and 340 having a plurality of resistive resistances are formed.

The conductive lines 310, 320, 330 and 340 are formed by a silver compound by a printing method, wherein any one portion (preferably the end) of the first conductive line 310 and the second conductive line 320 are mutually The second conductive line 330 and the fourth conductive line 340 are similarly configured to be electrically connected to each other.

The base film layer 200 and the upper protective film layer 400 are bonded by ultrasonic or heat fusion, and then attached by attaching an adhesive layer 100 in the form of a double-sided tape to the bottom of the base film layer 200.

The tips of the conductive lines 310, 320, 330, and 340 are connected to the controller 600 to receive a sensing signal for detecting a leak and power for heating.

The upper protective film layer 400 is a layer for protecting the conductive line 300 formed on the base film layer 200 from external magnetic poles, and is formed of a PET, PE, PVC, or Teflon-based material, and has a second conductivity. Holes 410 are formed at predetermined intervals corresponding to the positions at which the line 320 and the third conductive line 330 are formed, so that when the leak occurs, the leak is introduced through the hole 410 and the second conductive line 320 and the second conductive line 320 are formed. The third conductive line 330 is conductive.

In this case, the hole 410 may have a long groove, a circular groove, or other shapes so that the second conductive line 320 and the third conductive line 330 are exposed.

The conductive line 300 constitutes a circuit as shown in FIG. 3. When the sensing signal and the power are applied to the conductive lines 310, 320, 330, and 340, the first conductive line 310 or the second conductive line is described. The detection signal for leak detection from the controller 600 is applied to the 320 in a pulse form at regular intervals as shown in FIG. 6 (a), and whether the leak occurs in the controller 600 through the third conductive line 330 Will be detected.

That is, when the leak flows through the hole 410 of the upper protective film layer 400, the first conductive may be conducted between the second conductive line 320 and the third conductive line 330 by the leak 500. The detection signal applied through the line 310 or the second conductive line 320 is changed into a resistance value through the third conductive line 330 and flows into the controller 600 to check whether leakage occurs.

At this time, in the controller 600, when the pulse of the detection signal is not applied as shown in FIG. 6 (b), the power supply for heating is supplied to the first conductive line 310 or the second conductive line 320 and the third conductive line ( Heat is generated by the resistance of each conductive line 310, 320, 330, 340 by applying it through the 330 or the fourth conductive line 340.

Therefore, the controller 600 supplies power for heating to the third conductive line 330 or the fourth conductive line 340 when the sensing signal is supplied to the first conductive line 310 or the second conductive line 320. If not, the detection signal and power for heating are alternately supplied.

In addition, the controller 600 checks only the occurrence of leakage by applying a detection signal for detecting the leak as a pulse having a very short width and a low voltage, and by applying the power for the heating in a section other than the pulse of the detection signal. Make sure that you have enough heating.

Of course, in the case of a power supply for heating can be applied a large power supply with a long time.

In the controller 600, as shown in FIG. 5, the processor 610 controls the power supply unit 650 for a time set by the key input unit 620 from the user so as to control the first conductive line 310 or the second conductive line 320. The detection signal is applied to the third conductive line 330 to monitor whether the leakage is detected. If the detection signal flows from the third conductive line 330, the resistance value of the detection signal and the storage unit are detected. By comparing the resistance value according to the distance of the conductive lines 310, 320, 330, 340 which are preset and stored at 630, the leak generation position may be confirmed.

That is, when the leak 500 is generated, the resistance values of the first and second conductive lines 310 and 320 and the line resistance values up to the location of the leak 500 of the third conductive line 330 are added to the processor 610. Since the summation resistance value is compared with the resistance value according to the distance set in the storage unit 630, the leakage generation position can be confirmed as distance information according to the matching resistance value, and the processor simultaneously displays the display unit 640. ) Will tell you where the leak occurred and whether it will occur.

In addition, during heating, the processor 610 controls the power supply unit so that the heating power is supplied to the first conductive line 310 or the second conductive line 320, and the third conductive line 330 or the fourth conductive line 340. Will be supplied.

2 and 4 illustrate another embodiment of the present invention, in which the conductive line 300 is not formed of four conductive lines 310, 320, 330 and 340, as shown in FIG. 1, and two conductive lines 320 and 330. It may be formed, the end is connected to be electrically conductive.

At this time, the processor 610 controls the power supply unit 650 to apply a detection signal as shown in FIG. 6 (a) through the fifth conductive line 350, and detects whether the leak is generated through the sixth conductive line 360. Done.

The check of the occurrence and location of the leak by the processor 610 is the same as described above.

In addition, the processor 610 applies power for heating through the fifth conductive line 550 or the sixth conductive line 560 at the same timing as in FIG. 6 (b).

FIG. 7 is a view showing a third embodiment of the present invention, wherein a conductive line 370 formed of two conductive lines for detecting leakage in the longitudinal direction is formed on the upper surface of the base film layer 200 by a printing method. In the lower surface, a heating wire pattern 380 having a relatively higher resistance than the conductive line 370 is formed by a printing method for heating.

The upper layer of the base film layer 200 on which the hot wire pattern 380 is formed, the upper layer of the adhesion layer 100 is stacked, and the upper portion of the upper protection hole 410 formed at regular intervals at a position corresponding to the conductive line 370. The film layer 400 is laminated.

This is formed by separating the conductive line 370 and the hot wire pattern 380 into the upper and lower surfaces of the base film layer 200 so that the controller 600 alternately inputs a signal for detecting leakage and a power for heating. Instead, apply independently.

Therefore, the processor 610 controls the power supply unit 650 to supply power independently to the conductive line 370 and the hot wire pattern 380.

The hot wire pattern 380 may be printed such that two conductive lines are formed side by side like the conductive line 370, or may be printed in various patterns such as a zigzag shape or a refractive shape to generate high heat.

1 is a configuration diagram according to a first embodiment of the present invention.

2 is a configuration diagram according to a second embodiment of the present invention.

3 is a diagram showing the circuit configuration of FIG.

4 shows the circuit configuration of FIG.

5 is an internal circuit block diagram of the controller.

7 shows a control signal of a controller.

8 is a configuration diagram according to a third embodiment of the present invention.

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

100: adhesion layer 200: base layer

300: conductive line 400: upper protective film layer

410: hall

Claims (5)

A base film layer formed in a tape shape; A plurality of conductive lines having resistances formed side by side on an upper surface of the base film layer, and conductive lines having one end thereof electrically connected to each other; In the leak detection device comprising: an upper protective film layer laminated on top of the base film layer to protect the base film layer, a plurality of holes are formed corresponding to the position corresponding to the conductive line, And a controller for alternately applying a power supply for heating and a detection signal for detecting a leak on the other side of the conductive line constituting the conductive line. The controller comprising: A storage unit for storing a specific resistance value of the conductive line; A control signal is applied to the conductive line to alternately apply a sensing signal for detecting a leak and a power for heating, and when the sensing signal is applied, a resistance according to a distance stored in the storage unit by reading a detected voltage value from the conductive line. A processor which determines whether a leak occurs by comparing with a value; And a power supply unit for supplying power for sensing signals and heating to the conductive line under control of the processor. delete delete delete delete

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