KR101286316B1 - Cable and system for heat and liquid leakage sensing - Google Patents

Abstract

PURPOSE: A heat and fluidic leakage sensing cable and a system thereof are provided to sense the heat and a fluidic leakage of a target object simultaneously by forming a heat sensing wire and a fluidic leakage sensing wire into one cable, thereby reducing time required for installation and maintenance. CONSTITUTION: A heat and fluidic leakage sensing cable comprises a heat sensing wire (100), a first wire (200), an outer cover (300), a fluidic leakage sensing wire (400), and a second wire (500). The heat sensing wire includes: an insulator (110) which becomes molten if the temperature of a target object is over a predetermined level; a pair of first conductors (120) which is respectively covered by the insulator and causes a short circuit by being in contact with each other when the insulator is molten; an union member (130) uniting a plurality of the insulators; and a sealing member (140) which jacket-processes the union member. The first wire transmits short-circuit signals of the first conductor to a microcomputer (MICOM). The outer cover covers the heat sensing wire and the first wire. The fluidic leakage sensing wire includes: a hygroscopic insulator (410) in which moisture is absorbed or penetrated; and a second conductor (420) in which a resistance value is changed when moisture is absorbed or penetrated by/through the hygroscopic insulator.

Description

Cable and System for Heat and Liquid Leakage Sensing

The present invention relates to a heat and leak detection cable and a system thereof, and more particularly, a heat detection wire and a leak detection wire are configured in one cable to simultaneously perform heat detection and leak detection, a heat detection location and a leak detection location. Relates to a heat and leak detection cable and its system.

In general, the heat detection line and the leak detection line were used at the same time to detect heat or leaks from the sensing object in the industrial site, but the installation work has to be done separately because the heat detection line and the leak detection line must be installed separately. If the arrangement of the heat detection line and the leakage detection line is not neat in the process of installation and installation, it takes a lot of work time in the future maintenance work, and there was a problem that the line of other uses may be damaged during the maintenance process.

In this regard, Korean Patent No. 0540843 discloses an invention for a leaking and leaking oil detecting device, but since it detects only a leak but does not detect a change in temperature of the sensing object, it is separately provided for the temperature sensing of the sensing object. There was a problem that the heat detection wire should be installed.

An object of the present invention devised to solve the above problems is to integrate the heat detection line and the leakage detection line into a single cable to simultaneously detect the heat and leakage of the sensing object, reducing installation time and maintenance time, installation The aim is to provide heat and leak detection cables and systems that can reduce costs and maintenance costs.

In addition, it is to provide a heat and leakage detection cable and a system capable of quickly responding to the heat generation and leakage of the detection object by simultaneously confirming the heat detection position and the leakage detection position of the detection object in real time.

In addition, by simultaneously checking the heat detection and leakage detection of the sensing object, to provide a heat and leakage detection cable and system that can be performed at a time without performing the heat detection confirmation and leak detection separately.

According to a feature of the present invention for achieving the above object, the heat and leakage detection cable of the present invention, the insulator is melted when the temperature of the sensing object is raised by a certain level; A first conductor composed of a pair, each surrounded by an insulator, the first conductor being shorted in contact with each other when the insulator is melted; And association means for associating a plurality of insulators. A heat sensing line comprising a sealing means for jacketing the associated means; A first line for transmitting a short signal of a plurality of first conductors to the microcomputer; An envelope surrounding the heat sensing line and the first line; Hygroscopic insulator through which moisture passes or is absorbed; And a second conductor configured to be adjacent to each other, surrounded by a hygroscopic insulator, and having a resistance changed when moisture passes or is absorbed through the hygroscopic insulator; and a leakage detection line attached to an outer circumferential surface of the outer shell; And a second line attached to an outer circumferential surface of the outer shell and transmitting the changed resistance values of the plurality of second conductors to the microcomputer.

In addition, the leakage amount detection line is attached to the outside of the outer skin, detect the leakage amount to generate a leakage amount signal to transmit the leakage amount signal to the microcomputer.

The first line may include a first power source and a communication plus line, and a first power source and a communication minus line.

The second line may include a second power source and a communication plus line, and a second power source and a communication minus line.

The heat and leakage detection system of the present invention, the insulator is melted when the temperature of the sensing object is raised above a certain level; A first conductor composed of a pair, each surrounded by an insulator, the first conductor being shorted in contact with each other when the insulator melts; And association means for associating a plurality of insulators. A heat sensing line comprising a sealing means for jacketing the associated means; A first line for transmitting a short signal of a plurality of first conductors to a sensing controller; An envelope surrounding the heat sensing line and the first line; Hygroscopic insulator through which moisture passes or is absorbed; And a second conductor configured to be adjacent to each other, surrounded by a hygroscopic insulator, and having a resistance changed when moisture passes or is absorbed through the hygroscopic insulator; and a leakage detection line attached to an outer circumferential surface of the outer shell; A second line attached to an outer circumferential surface of the outer shell and transmitting a changed resistance value of the plurality of second conductors to the sensing controller; It is connected to the heat detection line and the leak detection line, generates the position of the heat detection line where the short signal is generated as a fire position signal and transmits it to the first line, and generates the position of the leakage detection line where the changed resistance value is generated as the leaking position signal. A sensing controller for transmitting to two wires; A master controller connected to the sensing controller, receiving a fire position signal through a first line, and receiving a leak position signal through a second line; And a microcomputer connected to the master controller, receiving and storing a fire position signal and a leak position signal from the master controller and displaying the same on the display means.

The first line may include a first power source and a communication plus line, and a first power source and a communication minus line.

The first power source and the communication plus line and the first power source and the communication minus line may be configured to form a closed loop connected to the sensing controller using the master controller as the start point and the end point.

The second line may include a second power source and a communication plus line, and a second power source and a communication minus line.

The second power source and the communication plus line and the second power source and the communication minus line may be configured to form a closed loop connected to the sensing controller using the master controller as the start point and the end point.

In addition, the heat and leakage detection system includes two or more detection controllers, and each of the detection controllers is characterized in that the thermal detection line, the first line, the leakage detection line and the second line, respectively.

The apparatus may further include a leakage amount detection line attached to an outer surface of the envelope and detecting a leakage amount to generate a leakage amount signal to transmit a leakage amount signal to a detection controller. The detection controller may further include a leakage leaked from the leakage amount detection line. The amount signal is transmitted to the second line, the master controller receives the leakage amount signal through the second line, the microcomputer receives the leakage amount signal from the master controller, characterized in that the storage and display on the display means.

According to the present invention as described above, by integrating the heat detection line and the leakage detection line into a single cable to simultaneously detect the heat detection and leakage of the sensing object, reducing the installation time and maintenance time, and reduce the installation cost and maintenance cost It is possible to provide a heat and leak detection cable and a system thereof.

In addition, it is possible to provide a heat and leakage detection cable and a system capable of quickly responding to heat generation and leakage of the detection object by simultaneously checking the heat detection position and the leakage detection position of the detection object in real time.

In addition, by simultaneously checking the heat detection and leakage detection of the sensing object, it is possible to provide a heat and leakage detection cable and system that can be performed at a time without performing the heat detection confirmation and leak detection separately.

1 is a cross-sectional view of a heat and leak detection cable according to Embodiment 1 of the present invention,
2 is an enlarged view of a first line of FIG. 1 of the present invention;
3 is an enlarged view of a second line of FIG. 1 of the present invention;
Figure 4 is a block diagram of a heat and leak detection system according to a second embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, the present invention will be described with reference to the drawings for describing a heat and leakage detecting cable and a system thereof according to embodiments of the present invention.

Heat and leakage detection cable according to the first embodiment of the present invention, as shown in Figures 1 to 3, the heat detection line 100, the first line 200, the outer shell 300, the leakage detection line 400 , A second line 500 and a leakage amount detecting line 600.

The thermal sensing line 100 includes an insulator 110, a first conductor 120, an association means 130, and a sealing means 140.

The insulator 110 is melted when the temperature of the sensing object rises by a predetermined level or more so that the plurality of first conductors 120 are shorted. Such an insulator 110 is preferably composed of a thermoplastic resin.

The first conductor 120 is composed of a pair, each of which is surrounded by the insulator 110, and when the insulator 110 is melted, the first conductor 120 is in contact with each other and shorted. For example, when the temperature of the sensing object is 70 ° C. or more, the insulator 110 is melted and the plurality of first conductors 120 are exposed to the outside of the insulator 110 to be in contact with each other, thereby providing a plurality of first conductors 120. Are shorted to each other.

Association means 130 is a combination of a plurality of insulators 110, it is preferable that the heat transfer from the sealing means 140 to be described later is a material so that the transfer to the insulator 110, for example, poly Polyester tapes may be used.

Sealing means 140 is a jacketing process for the union means 130, the thermal stabilizer, filler (plasticizer), plasticizer, the pigment (pigment) is mixed and processed into a polyester elastomer (PSE) all the properties of the insulation with thermoplastic It is preferable that it is a raw material to have.

The first line 200 transmits a short signal of a plurality of first conductors 120 to the microcomputer, and includes a first power source and communication plus line 210 and a first power source and communication minus line 220.

The envelope 300 surrounds the heat sensing line 100 and the first line 200.

The leak detection line 400 includes a hygroscopic insulator 110 and a second conductor 420.

The hygroscopic insulator 110 surrounds the second conductor 420 so that the surrounding moisture passes or is absorbed so that the moisture contacts the second conductor 420. Here, the hygroscopic insulator 110 is hygroscopic, when water is in direct contact with water, the water passes through the second conductor 420, and when the ambient humidity is high and the amount of moisture in the air is high, the moisture in the air is increased. This is to allow the absorbed moisture to contact the second conductor 420.

The second conductor 420 is composed of a pair so as to be adjacent to each other, surrounded by the hygroscopic insulator 410, the resistance value changes when the moisture passes or is absorbed through the hygroscopic insulator 410. As such, the resistance value of the second conductor 420 changed in contact with moisture is transmitted to the microcomputer through the second line 500 to be described later.

The second line 500 is attached to the outer circumferential surface of the outer shell 300 and transmits the changed resistance values of the plurality of second conductors 420 to the microcomputer. The second power source and the communication plus line 510 and the second power source are provided. And a communication minus line 520.

The leakage amount detecting line 600 is attached to the outside of the outer shell 300, detects the leakage amount, generates a leakage amount signal, and transmits the leakage amount signal to the microcomputer.

As such, the heat and leak detection cable integrates the heat detection line 100 and the leak detection line 400 into one cable to simultaneously detect the heat and leak of the sensing object, thereby reducing installation time and maintenance time, and installing The cost and maintenance cost can be reduced, and the heat detection position and the leakage detection position of the detection object can be checked simultaneously in real time, so that the heat generation and leakage of the detection object can be quickly responded.

Hereinafter, the heat and leakage detection system according to Embodiment 2 of the present invention will be described with reference to FIG. 4.

As shown in FIG. 4, the heat and leakage detection system may include a heat detection line 100, a first line 200, an envelope 300, a leakage detection line 400, a second line 500, and a leakage amount detection. The line 600, the sensing controller 700, the master controller 800, and the microcomputer 900 are included.

The thermal sensing line 100 includes an insulator 110, a first conductor 120, an association means 130, and a sealing means 140.

The insulator 110 is melted when the temperature of the sensing object rises by a predetermined level or more so that the plurality of first conductors 120 are shorted. Such an insulator 110 is preferably composed of a thermoplastic resin.

The first conductor 120 is composed of a pair, each of which is surrounded by the insulator 110, and when the insulator 110 is melted, the first conductor 120 is in contact with each other and shorted. For example, when the temperature of the sensing object is 70 ° C. or more, the insulator 110 is melted and the plurality of first conductors 120 are exposed to the outside of the insulator 110 to be in contact with each other, thereby providing a plurality of first conductors 120. Are shorted to each other.

Association means 130 is a combination of a plurality of insulators 110, it is preferable that the heat transfer from the sealing means 140 to be described later is a material so that the transfer to the insulator 110, for example, poly Polyester tapes may be used.

Sealing means 140 is a jacketing process for the union means 130, the thermal stabilizer, filler (plasticizer), plasticizer, the pigment (pigment) is mixed and processed into a polyester elastomer (PSE) all the properties of the insulation with thermoplastic It is preferable that it is a raw material to have.

The first line 200 transmits a short signal of a plurality of first conductors 120 to the sensing controller 700. The first power line and the communication plus line 210 and the first power line and the communication minus line 220 are provided. It includes.

Here, the first power source and communication plus line 210 and the first power source and communication minus line 220 form a closed loop connected to the sensing controller using the master controller 800 as a start point and an end point.

The envelope 300 surrounds the heat sensing line 100 and the first line 200.

The leak detection line 400 includes a hygroscopic insulator 110 and a second conductor 420.

The hygroscopic insulator 110 surrounds the second conductor 420 so that the surrounding moisture passes or is absorbed so that the moisture contacts the second conductor 420. Here, the hygroscopic insulator 110 is hygroscopic, when water is in direct contact with water, the water passes through the second conductor 420, and when the ambient humidity is high and the amount of moisture in the air is high, the moisture in the air is increased. This is to allow the absorbed moisture to contact the second conductor 420.

The second conductor 420 is composed of a pair so as to be adjacent to each other, surrounded by the hygroscopic insulator 410, the resistance value changes when the moisture passes or is absorbed through the hygroscopic insulator 410. As such, the resistance value of the second conductor 420 changed in contact with moisture is transmitted to the sensing controller 700 through the second line 500 to be described later.

The second line 500 is attached to the outer circumferential surface of the outer shell 300, and transmits the changed resistance value of the plurality of second conductors 420 to the sensing controller 700, and the second power source and the communication plus line 510. And a second power supply and communication minus line 520.

Here, the second power source and communication plus line 510 and the second power source and communication minus line 520 form a closed loop connected to the sensing controller using the master controller 800 as a starting point and an end point.

The leakage amount detecting line 600 is attached to the outside of the outer shell 300, detects the leakage amount, generates a leakage amount signal, and transmits the leakage amount signal to the detection controller 700.

The detection controller 700 is connected to the heat detection line 100 and the leakage detection line 400 and generates a position of the heat detection line 100 where the short signal is generated as a fire position signal to the first line 200. In addition, the position of the leakage detecting line 400 having the changed resistance value is generated as the leakage position signal and transmitted to the second line 500.

In addition, the detection controller 700 transmits the leakage amount signal received from the leakage amount detection line 600 to the second line 500.

As described above, two or more detection controllers 700 are included in the heat and leakage detection system, and each of the detection controllers 700 includes a thermal detection line 100, a first line 200, a leakage leakage detection line 400, and a second detection liquid 700. Lines 500 are each connected.

The master controller 800 is connected to the detection controller 700, receives the fire position signal through the first line 200, and receives the leak position signal and the leak amount signal through the second line 500.

The microcomputer 900 is connected to the master controller 800, and receives the fire position signal, the leakage position signal and the new liquid amount signal from the master controller 800, and stores it on the display means.

As such, the heat and leak detection system integrates the heat detection line 100 and the leak detection line 400 into a single cable to simultaneously detect the heat and leak of the sensing object, thereby reducing installation time and maintenance time, and installing The cost and maintenance cost can be reduced, and the heat detection position and the leakage detection position of the detection object can be checked simultaneously in real time, so that the heat generation and leakage of the detection object can be quickly responded.

In addition, the heat and leak detection system has the advantage that can be performed at once without performing the heat detection check and leak detection by checking the heat detection and leakage detection of the sensing object at the same time.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

100: heat detection line 110: insulator
120: first conductor 130: association means
140: sealing means
200: first line 210: first power supply and communication plus line
220: first power and communication minus wire
300: sheath
400: leak detection line
410: hygroscopic insulator 420: second conductor
500: 2nd line 510: 2nd power supply and communication plus line
520: second power supply and communication minus wire
600: leaking liquid detection line
700: detection controller
800: master controller
900: microcomputer

Claims (11)

An insulator that melts when the temperature of the sensing object rises above a certain level; A first conductor composed of a pair, each surrounded by the insulator, the first conductor being shorted in contact with each other when the insulator is melted; And association means for associating a plurality of said insulators. And a heat sealing means for jacketing the associating means;
A first line for transmitting a short signal of a plurality of first conductors to the microcomputer;
An outer shell surrounding the heat sensing line and the first line;
Hygroscopic insulator through which moisture passes or is absorbed; And a second conductor configured to be adjacent to each other, surrounded by the hygroscopic insulator, and having a resistance changed when water passes through or is absorbed through the hygroscopic insulator, and includes a leakage detecting line attached to an outer circumferential surface of the outer shell. ; And
And a second wire attached to an outer circumferential surface of the outer shell and transmitting a changed resistance value of a plurality of second conductors to the microcomputer.
The method of claim 1,
And a leakage amount detection line attached to the outside of the outer shell and detecting a leakage amount to generate a leakage amount signal to transmit the leakage amount signal to the microcomputer.
The method of claim 1, wherein the first line,
A heat and leakage detection cable comprising a first power source and communication plus wire and a first power source and communication minus wire.
The method of claim 1, wherein the second line,
And a second power supply and communication plus wire and a second power supply and communication minus wire.
An insulator that melts when the temperature of the sensing object rises above a certain level; A first conductor composed of a pair, each surrounded by the insulator, the first conductor being shorted in contact with each other when the insulator is melted; And association means for associating a plurality of said insulators. And a heat sealing means for jacketing the associating means;
A first line for transmitting a short signal of a plurality of first conductors to a sensing controller;
An outer shell surrounding the heat sensing line and the first line;
Hygroscopic insulator through which moisture passes or is absorbed; And a second conductor configured to be adjacent to each other, surrounded by the hygroscopic insulator, and having a resistance changed when water passes through or is absorbed through the hygroscopic insulator, and includes a leakage detecting line attached to an outer circumferential surface of the outer shell. ;
A second line attached to an outer circumferential surface of the outer shell and transmitting a changed resistance value of a plurality of second conductors to the sensing controller;
The position of the heat detection line is connected to the heat detection line and the leakage detection line, and generates the position of the heat detection line where the short signal is generated as a fire position signal, and transmits it to the first line. A sensing controller for generating a leakage position signal and transmitting it to a second line;
A master controller connected to the detection controller, receiving the fire position signal through the first line, and receiving the leaking position signal through the second line; And
And a microcomputer connected to the master controller and receiving and storing the fire position signal and the leakage position signal from the master controller and displaying the displayed position on a display means.
The method of claim 5, wherein the first line,
And a first power and communication plus line and a first power and communication minus line.
The method according to claim 6,
And the first power source and communication plus line and the first power source and communication minus line form a closed loop connected to the detection controller using the master controller as a start point and an end point.
The method of claim 5, wherein the second line,
And a second power and communication plus line and a second power and communication minus line.
9. The method of claim 8,
The second power supply and communication plus line and the second power supply and communication minus line form a closed loop connected to the detection controller using the master controller as a starting point and an end point. .
10. The system of claim 5, wherein the heat and leak detection system is
And at least two sensing controllers, wherein the thermal sensing line, the first line, the leakage detecting line, and the second line are connected to each sensing controller, respectively.
The method of claim 5,
A leakage amount detection line attached to an outside of the envelope and detecting a leakage amount to generate a leakage amount signal to transmit the leakage amount signal to the detection controller;
The detection controller transmits a leakage amount signal received from the leakage amount detection line to the second line,
The master controller receives the leakage amount signal through the second line,
The microcomputer is a heat and leakage detection system, characterized in that for receiving and storing the leakage signal from the master controller and display on the display means.

Images