KR101132124B1 - Apparatus for sensing leaking oil - Google Patents

Abstract

PURPOSE: An apparatus for sensing the leakage of oil is provided to overcome and manage oil leakage problems by defining the sections of an oil pipe based on a sensing unit surrounding the oil pipe and verifying the oil leaking position of the oil pipe. CONSTITUTION: An apparatus for sensing the leakage of oil includes an outer case(110), a swelling member(120), a porous supporting member(130), a heating member(140), carbon nano-tube(150), polymer(160), a center supporting part(170), and controllers(180). Leaked oil is penetrated into the outer case. The swelling member is arranged at the inner side of the outer case and is swelled based on the leaked oil. The porous supporting member is arranged at the inner side of the swelling member and limits the swelling state of the swelling member. The heating member generates heat based on the stimulation of the swelling member. The carbon nano-tube is in contact with the heating member and conducts the heat from the heating member. The polymer is in contact with the inner lateral side of the carbon nano-tube, and the form of the polymer is changed based on the heat.

Description

Oil leak detection device {Apparatus for Sensing Leaking Oil}

The present invention relates to an oil leak detecting apparatus, and more particularly, to an oil leak detecting apparatus capable of quickly and accurately detecting leaking oil leaking from an oil pipe, and detecting the occurrence of oil leak simply and accurately.

In general, crude oil transportation is largely by sea transportation or land transportation. Ocean transportation uses oil tankers, and land transportation uses oil pipes or vehicles.

The pipeline, first used in the United States at the end of the 19th century, is called the subterranean highway for crude oil delivery and is considered the most modern means of transportation not affected by traffic conditions.

The most important thing in managing the oil pipe is to prevent leakage, and oil leakage of the oil pipe may be caused by various causes. For example, there may be a case in which the pipeline for oil pipeline leaks due to aging such as corrosion, leakage of the pipeline due to ground change such as an earthquake, or the pipeline is damaged due to vibration in a nearby construction site.

The spillage of crude oil is also a great economic loss due to leakage, but flows into the area where the pipeline is buried, which will have a big adverse effect on environmental problems.

Therefore, in order to properly manage the oil pipe, there is an urgent need for the development of technology for accurately and quickly detecting leakage and location of oil leakage.

The present invention has been made to solve the conventional problems,

SUMMARY OF THE INVENTION An object of the present invention is to provide a leaky oil detecting device capable of detecting a leaked oil leaked from an oil pipe quickly and accurately as well as detecting a location of the leaked oil easily and accurately.

Another object of the present invention is to first detect the leakage of oil leaked from the duct to generate a warning sound, and to detect the progress of the second leakage to generate an alarm sound to more accurately grasp the progress of the leakage, the first warning sound and It is to provide a leak detection device that can determine the speed of leak and the amount of leak using the time difference of the second alarm sound.

Leakage detection device according to an embodiment of the present invention provided to achieve the above object is an outer case through which the leaked oil; A swelling member provided inside the outer case and swelling when the leaked oil penetrated into the outer case is absorbed; A porous support member provided inside the swelling member to limit an expanded state of the swelling member; A heating element provided inside the porous support member to generate heat through the stimulation of the swelling member which is extended and pushed into the hole of the porous support member; Carbon nanotubes (CNT) which are in contact with the heating element to quickly conduct heat of the heating element; A polymer polymer in contact with the inner surface of the carbon nanotubes and the shape of which is changed by heat transfer of the carbon nanotubes; A center support part spaced apart from an inner surface of the polymer polymer and positioned at the center of the polymer polymer, wherein the shape of the polymer polymer changes and contacts the outer surface to generate a leak detection signal; And a controller configured to receive the leak detection signal of the central support unit to determine the leak, generate an alarm sound, and display the leak location.

Here, the polymer polymer is provided with a sensing line for generating a warning signal when the outer surface is spaced apart from the inner surface of the carbon nanotube while the shape is changed by heat transfer of the carbon nanotube, the sensing line is connected to the control unit The control unit may be configured to generate a warning sound by receiving a warning signal from a detection line.

The signal generated on the detection line is a warning signal that primarily detects the leakage of crude oil from the oil pipe, and the leakage detection signal generated from the central support is a signal indicating that the second detection of the leakage of crude oil, It is an alarm signal for ascertaining the occurrence of the risk and informs the danger, characterized in that the approximate speed of leakage and the amount of leakage can be estimated using the time difference between the primary warning signal and the secondary warning signal.

The sensing line detects that the polymer polymer is disconnected from the sensing line while being spaced apart from the inner surface of the carbon nanotube to generate a first warning signal. The center support part may detect the high polymer polymer being grounded on the outer surface of the center support part, and generate a second alarm signal.

The high molecular polymer is made of magnetic nanoparticle-reinforced shape memory polymer, and has a spiral body having a spiral width and a spiral of a predetermined size.

In addition, the oil leakage detecting apparatus according to another embodiment of the present invention is the outer case in which the oil leakage; A swelling member provided inside the outer case and swelling when the leaked oil penetrated into the outer case is absorbed; A porous support member provided inside the swelling member to limit an expanded state of the swelling member; A signal transmission member which is provided inside the porous support member and whose shape is changed by the pressure of the swelling member leaking into the hole of the porous support member; A center support part spaced apart from an inner side surface of the signal transmission member and positioned at the center of the signal transmission member and generating a leak detection signal when the shape of the signal transmission member changes and contacts the outer surface; And a controller configured to receive the leak detection signal of the central support unit to determine the leak, generate an alarm sound, and display the leak location.

Here, the signal transmission member is provided with a detection line for generating a warning signal when the shape is changed by the pressure of the swelling member, the detection line is connected to the control unit, the control unit generates a warning sound in response to the warning signal of the detection line Characterized in that.

The signal generated on the detection line is a warning signal that primarily detects the leakage of crude oil from the oil pipe, and the leakage detection signal generated from the central support is a signal indicating that the second detection of the leakage of crude oil, It is an alarm signal for ascertaining the occurrence of the risk and informs the danger, characterized in that the approximate speed of leakage and the amount of leakage can be estimated using the time difference between the primary warning signal and the secondary warning signal.

In addition, the signal transmission member is characterized in that the diaphragm having a conductivity elastically deformed by the pressure.

According to the leak detection apparatus of the present invention, by absorbing the leaked oil leaked from the milk pipe, the polymer polymer whose shape is changed by heat generated by the swelling of the swollen swelling member is used to quickly and accurately detect the occurrence of the leak, thereby improving the detection ability. have.

In addition, by absorbing the leaked oil by using a signal transmission member whose shape is changed by the pressure of the swelling member to swell, there is an effect of improving the detection ability by detecting the occurrence of the leaked oil quickly and accurately.

In addition, it is possible to determine a section by winding a leak detection device of a certain length in a spiral around the duct, and to identify the leak location of the duct according to the signal detected in the section, it is easy to solve and manage the leak problem.

In addition, by using the time difference between the first alarm sound and the second alarm sound generated when leaking oil leaks from the related pipes, the approximate speed and amount of leakage can be identified. There is an effect that can be minimized.

1 is a partial cutaway perspective view showing the configuration of the leak detection apparatus according to an embodiment of the present invention.
Figure 2 is an enlarged cross-sectional view showing the constituent parts of the leak detection apparatus according to an embodiment of the present invention.
Figure 3 is a cross-sectional view showing a state in which leakage is detected in the leak detection apparatus according to an embodiment of the present invention.
Figure 4 is a partially cutaway perspective view showing the configuration of the leak detection apparatus according to another embodiment of the present invention.
Figure 5 is an enlarged cross-sectional view showing the main portion of the structure of the leak detection apparatus according to another embodiment of the present invention.
Figure 6 is a cross-sectional view showing a state in which leakage is detected in the leak detection apparatus according to another embodiment of the present invention.
Figure 7 is a side view showing a state in which the leak detection apparatus according to the present invention is used in the milk pipe.
Figure 8 is an enlarged cross-sectional view showing the main portion of the structure of the leak detection apparatus according to another embodiment of the present invention.
Figure 9 is a cross-sectional view showing a state in which leaking oil is detected in the leak detection apparatus according to another embodiment of the present invention.

The above objects, features and other advantages of the present invention will become more apparent by describing the preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, an oil leakage detecting apparatus according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings. For the purposes of this specification, like reference numerals in the drawings denote like parts unless otherwise indicated.

1 is a partially cutaway perspective view illustrating a structure of an oil leakage detecting apparatus according to an exemplary embodiment of the present invention, and FIG. 2 is an enlarged cross-sectional view illustrating main components of an oil leakage detecting apparatus according to an embodiment of the present invention. Is a cross-sectional view showing a state in which leakage oil is detected in the oil leakage detecting apparatus according to an embodiment of the present invention.

As shown in Figures 1 to 3, one embodiment of the present invention, the oil leakage detecting apparatus 100 includes an outer case 110 through which oil leakage penetrates; A swelling member (120) provided inside the outer case (110) to swell when oil leaked into the outer case (110) is absorbed; A porous support member 130 provided inside the swelling member 120 to limit an expanded state of the swollen swelling member 120; A heating element (140) provided inside the porous support member (130) to generate heat through the stimulation of the swelling member (120) extending and pushing into the hole of the porous support member (130); A carbon nanotube (CNT) 150 in contact with the heating element 140 to quickly conduct heat of the heating element 140; A polymer polymer 160 in contact with the inner surface of the carbon nanotubes 150 and whose shape is changed by heat transfer of the carbon nanotubes 150; A center support part 170 spaced apart from an inner surface of the polymer polymer 160 and positioned at the center of the polymer polymer 160, wherein the shape of the polymer polymer 160 changes and contacts the outer surface to generate a leak detection signal; Receiving the leakage detection signal of the central support unit 170 to determine the leakage, generates an alarm sound, and includes a controller 180 for displaying the location of the leakage.

Here, the outer case 110 is made of a structure surrounding the outer side of the swelling member 120 to prevent the leakage of crude oil is passed through, the inner swelling member 120 to swell outward.

The swelling member 120 is provided between the outer case 110 and the porous support member 130 and swells by causing a chemical reaction with the crude oil passing through the outer case 110.

The porous support member 130 partially restricts the swelling swelling member 120 from extending inward to induce it to extend only through the hole 131 formed in the support member 130.

The heating element 140 is provided at a position corresponding to the hole 131 of the support member 130 at the inner side of the support member 130, and the magnetic pole of the swelling member 120 extended and pushed out of the hole 131. It generates heat through.

In addition, the carbon nanotubes 150 in contact with the heating element 140 conduct heat rapidly generated by the heating element 140.

Here, the carbon nanotube (CNT) 150 has high tensile strength and electrical conductivity, and the like, the strength is 100 times better than steel, the electrical conductivity is similar to copper, and the thermal conductivity is the same as diamond. That is, it has excellent thermal conductivity and electrical conductivity.

The polymer 160 is made of a spiral body having a spiral width and a spiral of a predetermined size and is in contact with the inner surface of the carbon nanotubes 150.

Here, the polymer polymer 160 is made of magnetic nanoparticles reinforced shape memory polymer.

The magnetic nanoparticle reinforced shape memory polymer has a characteristic of expanding and contracting the diameter of the spiral body by using the shape memory effect of temperature.

Polyurethane as a material of the shape memory polymer having the shape memory effect can be synthesized in various ways according to the raw materials constituting the soft segment, hard segment, etc., a mixture of glycol and a chain extender of the polyurethane (Mixture) And a ONE-SHOT method for reacting polyisocyanate at a time and a prepolymer method for chain-extending the prepolymer again after reacting the polyisocyanate in excess. Here, the shape memory effect is represented by the glass transition temperature of the soft segment, and the vitrification temperature may be determined by the low melting point and molar ratio of the polymer constituting the soft segment.

The magnetic nanoparticle-reinforced shape memory polymer can remember the shape that changes with temperature, and thus can control the minute shape change, and it is easy to control, and thus has excellent ability to detect the occurrence of leakage quickly and accurately. .

Therefore, when the polymer polymer 160 receives heat from the heating element 140 by the carbon nanotubes 150, the diameter thereof is reduced in itself.

In addition, the polymer polymer 160 is provided with a sensing line 161 on a contact surface of the carbon nanotube 150, that is, an outer surface thereof, and the sensing line 161 is connected to the controller 180.

The sensing line 161 is short-circuit when the polymer polymer 160 receives heat transfer and is reduced in diameter so that the outer surface of the polymer polymer 160 is spaced apart from the inner surface of the carbon nanotube 150. Detect the alarm and generate a warning signal. Then, the controller 180 electrically connected to the high polymer polymer 160 receives a warning signal from the sensing line 161 to generate a warning sound. At this time, the generated warning sound is a signal indicating that the primary detection of the leakage of crude oil in the milk pipe (P).

Subsequently, when the leakage of oil continues to occur, the swelling member 120 causing the chemical reaction with the crude oil is further expanded to increase the calorific value of the heating element 140 and increase the internal temperature of the polymer polymer. 160 is the diameter of the spiral body is gradually reduced under the influence of the temperature is wrapped around the outer surface of the central support portion 170 to tighten.

Then, the center support unit 170 detects that the polymer polymer 160 is grounded on the outer surface and generates a leak detection signal.

In addition, the controller 180 electrically connected to the center support part receives an oil leakage detection signal of the center support part 170 to generate an alarm sound. At this time, the generated alarm sound is a signal for notifying that the occurrence of leakage is secondary, it is a signal for confirming the occurrence of leakage and informing of danger.

In addition, the controller 180 may be connected to the central control unit (not shown) by wire or wirelessly to monitor the leakage point and leakage, the time difference between the primary warning sound and the secondary alarm sound.

Here, using the time difference between the primary warning sound and the secondary alarm sound, it is possible to estimate the approximate speed of leakage and the amount of leakage. For example, as the time difference between the first warning sound and the second warning sound is narrower, the heat generation amount of the heating element 140 and the carbon nanotube 150 is larger, which indicates that the amount of oil leakage is high and the speed of the oil leakage is faster. On the contrary, as the time difference between the first warning sound and the second warning sound increases, the heat generation amount of the heating element 140 and the carbon nanotube 150 is smaller, which indicates that the amount of leakage is small and the progress of the leakage is slow.

As described above, an embodiment according to the present invention uses the polymer polymer 160 whose shape is changed by the heat generated by the stimulation of the swelling member 120 that swells when absorbing the leakage of oil leaked from the oil pipe P. It can be detected quickly and accurately.

In addition, by using the time difference between the first alarm sound and the second alarm sound generated when leakage leaked from the oil pipe P is detected, the approximate speed and amount of the oil leak can be grasped. By doing so, damage can be minimized.

4 is a partially cutaway perspective view illustrating a structure of an oil leakage detecting apparatus according to another exemplary embodiment of the present invention, and FIG. 5 is an enlarged cross-sectional view illustrating main components of an oil leakage detecting apparatus according to another exemplary embodiment of the present invention. Are each a cross-sectional view showing a state in which leakage is detected in the leak detection apparatus according to another embodiment of the present invention.

As shown in Figure 4 to Figure 6 another embodiment of the present invention leak detection device is an outer case 210 through which the leaked oil; A swelling member (220) provided inside the outer case (210) and swelling when the oil leaked into the outer case (210) is absorbed; A porous support member 230 provided inside the swelling member 220 to limit an expanded state of the swelling member 220 that is swollen; A signal transmission member 240 provided inside the porous support member 230 and whose shape is changed by the pressure of the swelling member 220 extending and pushing into the hole of the porous support member 230; A center spaced apart from an inner side surface of the signal transmission member 240 and positioned at the center of the signal transmission member 240 and generating a leak detection signal when the shape of the signal transmission member 240 changes and contacts the outer surface; Branch 250; The controller 260 receives the leak detection signal of the center support part 250 to determine the leak, generates an alarm sound, and displays a leak location.

Here, the outer case 210, the swelling member 220, the porous support member 230 is made of the same configuration as the outer case 110, swelling member 120, porous support member 130 of the embodiment. . Therefore, duplicate descriptions of the same configuration will not be given.

The swelling member 220 that swells due to chemical leakage and leakage of oil penetrated into the outer case 210 is limited to being expanded by the outer case 210 and the porous support member 230, but the porous support member ( Expansion is possible only through the holes 231 of 230. That is, since the swelling member 220 swells only through the hole 231 of the porous support member 230, the swelling pressure becomes strong.

Here, the signal transmission member 240 is provided inside the porous support member 230 is subjected to the pressure of the swelling member 220 is extended to the hole 231 of the porous support member 230 and pushed out.

In addition, the signal transmission member 240 is provided with a detection line 241 for generating a warning signal when the shape is changed by the pressure of the swelling member 220, and the detection line 241 is connected to the control unit 260. Connected.

When the signal transmission member 240 is subjected to the pressure of the swelling member 220, warpage occurs in the portion under pressure, and the sensing line 241 is the signal transmission member 240 is the expansion member 220 Under the pressure of), it detects the moment when bending occurs and generates a warning signal. Then, the control unit 260 receives the warning signal of the sensing line 241 and generates a warning sound. At this time, the generated warning sound is a signal indicating that the primary detection of the leakage of crude oil in the milk pipe (P).

Subsequently, as the leakage continues, the swelling member 220 causing the chemical reaction with the crude oil expands more and more through the hole 231 of the porous support member 230, and the pressure becomes stronger. In addition, the signal transmission member 240 which is increasingly subjected to the strong pressure from the swelling member 220 has a greater deformation, that is, a greater deflection, and comes into contact with the outer surface of the center support part 250.

Then, the center support unit 250 detects that the signal transmission member 240 is in contact with the outer surface for a predetermined time to generate a leak detection signal.

In addition, the controller 260 receives an oil leakage detection signal of the center support part 250 to generate an alarm sound. At this time, the generated alarm sound is a signal for notifying that the occurrence of leakage is secondary, it is a signal for confirming the occurrence of leakage and informing of danger.

In addition, the control unit 260 may be connected to the central control unit (not shown) by wire or wireless to monitor the leakage point and leakage, the time difference between the primary warning sound and the secondary alarm sound.

 Here, as in an embodiment, when the time difference between the first warning sound and the second alarm sound is used, an approximate speed of leakage and an amount of leakage can be predicted.

 For example, the narrower the time difference between the primary warning sound and the secondary warning sound, the stronger the expansion pressure of the swelling member 220 and the faster the deformation of the signal transmission member 240. It can be seen that. On the contrary, as the time difference between the first warning sound and the second warning sound increases, the deformation of the signal transmission member 240 is slower, which indicates that the amount of leakage is small and the progress of the leakage is slow.

As described above, another embodiment according to the present invention uses the signal transmission member 240 whose shape is deformed by the pressure of the swelling member 220 that swells when absorbing the leakage of oil leaked from the oil pipe P. It can be detected accurately.

In addition, the first warning sound at the time when the deformation of the signal transmission member 240 and the signal transmission member 240 are greatly deformed in contact with the center support part when detecting leakage of leakage from the oil pipe P. By using the time difference from the car alarm, the approximate speed of leakage and the amount of leakage can be identified, so that the damage can be minimized by taking quick and efficient measures quickly.

FIG. 7 is a side view illustrating a state in which an oil leak detecting apparatus according to an embodiment of the present invention is used for an oil pipe. FIG.

As shown in FIG. 7, the oil leakage detecting device 100 having the above configuration spirally wound the oil leakage detecting device 100 having a predetermined length formed in a cable type in a spiral shape around the oil pipe P. Determine c). That is, the first oil leakage detecting device 100a of a predetermined length is wound in a section a spiral, the second oil leakage detecting device 100b of a predetermined length is wound in a section b in a spiral shape, and the third oil leakage detection of a predetermined length is wound. The device 100c is wound around the c section in a spiral shape so that the leak location of the oil pipe P can be determined according to the leak detection signal detected in the a, b, and c sections. This makes it easy to identify the location of the leaked milk of the milk pipe (P) to easily solve the problem of oil leakage, to efficiently manage long milk pipes, it is possible to shorten the working time.

FIG. 8 is an enlarged cross-sectional view illustrating a main part of an oil leak detecting apparatus according to still another embodiment of the present invention, and FIG. 9 is a cross-sectional view showing a state in which oil leak is detected in the oil leak detecting apparatus according to another embodiment of the present invention. to be.

As shown in Figures 8 and 9, another embodiment of the present invention leak detection device is made of the same configuration as the other embodiment of the present invention, provided with the leak detection device in the point type to select the necessary portion in the milk pipe It is to be attached to be used or to be arranged at regular intervals.

As shown in FIG. 8, the outer case 210 into which leakage of oil pipes penetrates; A swelling member (220) provided on the inner surface of the outer case (210) in contact with the oil pipe and swelling when the oil leaked into the outer case (210) is absorbed; A porous support member 230 provided outside the swelling member 220 to limit an expanded state of the swollen swelling member 220; A signal transmission member 240 provided outside the porous support member 230 and whose shape is changed by the pressure of the swelling member 220 which is extended and pushed out of the hole of the porous support member 230; A center support part 250 spaced apart from the outer surface of the signal transmission member 240 and generating an oil leakage detection signal when the shape of the signal transmission member 240 changes and contacts the outer surface; The controller includes a controller 260 that receives the leak detection signal of the central support to determine the leak, generates an alarm sound, and displays a leak location.

In this case, the center support unit 250 is electrically connected to the control unit 260 to transmit a signal in a wired manner, or the center support unit 250 is provided with a transceiver unit 260 to wirelessly communicate with the control unit 260. Can be passed.

As shown in FIG. 9, the oil leakage detecting device according to another embodiment having the above configuration has the swelling member 220 being subjected to a chemical reaction when crude oil leaked from the oil pipe is absorbed by the swelling member 220 through the outer case 210. Inflate by pushing through the hole of the support member 230 to apply pressure to the signal transmission member 240, the signal transmission member 240 receives the pressure of the expansion member 220 at the moment the bending occurs It detects and generates a warning signal. Then, the control unit 260 receives the warning signal of the signal transmission member 240 to generate a warning sound. At this time, the generated warning sound is a signal indicating that the primary detection of the leakage of crude oil in the milk pipe (P).

Subsequently, as the leakage continues, the swelling member 220 causing the chemical reaction with the crude oil expands more and more through the hole 231 of the porous support member 230, and the pressure becomes stronger. In addition, the signal transmitting member 240 which is increasingly subjected to the strong pressure from the swelling member 220 is caused to have a larger deformation, that is, a greater warpage, to come into contact with the outer surface of the center support part 250.

Then, the center support unit 250 detects that the signal transmission member 240 is in contact with the outer surface for a predetermined time to generate a leak detection signal. In this case, the generated leak detection signal is transmitted to the controller 260 by wireless or wired, the controller 260 receiving the leak detection signal of the central support unit 250 determines the leak to generate an alarm sound. At this time, the generated alarm sound is a signal for notifying that the occurrence of leakage is secondary, it is a signal for confirming the occurrence of leakage and informing of danger.

As described above, another embodiment of the present invention includes the oil leakage detecting device as a point type to be selectively attached to a required portion of the oil pipe, and to be controlled by wire or wirelessly, thereby improving practicality.

While preferred embodiments of the present invention have been described above, the present invention is not limited to the above-described specific embodiments. That is, those skilled in the art to which the present invention pertains can make many changes and modifications to the present invention without departing from the spirit and scope of the appended claims, and all such appropriate changes and modifications Equivalents should be considered to be within the scope of the present invention.

100: oil leak detection device P: oil pipe
110,210: outer case 120,220: swelling member
130,230: porous support member 131,231: hole
140: heating element 150: carbon nanotube
160: polymer polymer 161,241: detection line
170,250: center support portion 180,260: control unit
240: signal transmission member 270: transceiver

Claims (9)

An outer case through which oil leaks;
A swelling member provided inside the outer case and swelling when the leaked oil penetrated into the outer case is absorbed;
A porous support member provided inside the swelling member to limit an expanded state of the swelling member;
A heating element provided inside the porous support member to generate heat through the stimulation of the swelling member which is extended and pushed into the hole of the porous support member;
Carbon nanotubes (CNT) which are in contact with the heating element to quickly conduct heat of the heating element;
A polymer polymer in contact with the inner surface of the carbon nanotubes and the shape of which is changed by heat transfer of the carbon nanotubes;
A center support part spaced apart from an inner surface of the polymer polymer and positioned at the center of the polymer polymer, wherein the shape of the polymer polymer changes and contacts the outer surface to generate a leak detection signal; And
And a control unit configured to receive the leak detection signal of the central support unit to determine the leak, generate an alarm sound, and display a leak location. The method of claim 1,
The polymer polymer is provided with a sensing line for generating a warning signal when the outer surface is spaced apart from the inner surface of the carbon nanotube while the shape is changed by heat transfer of the carbon nanotube, and the sensing line is connected to the controller. The controller is a leakage detection device, characterized in that for generating a warning sound in response to the warning signal of the detection line. The method of claim 2,
The signal generated in the detection line is a warning signal indicating that the primary detection of the leakage of crude oil in the related pipe,
The leak detection signal generated from the central support is a signal indicating that the oil is leaked secondarily, a warning signal confirming the occurrence of leaks and informing of danger.
Leakage detection device characterized in that it is possible to predict the speed of leakage and the amount of leakage by using the time difference between the primary warning signal and the secondary alarm signal. The method of claim 2,
The sensing line detects that the polymer polymer is disconnected from the sensing line while being spaced apart from the inner surface of the carbon nanotube to generate a first warning signal.
The central support unit detects that the polymer polymer is grounded on the outer surface of the central support unit to detect a leakage of oil, characterized in that to generate a second alarm signal. The method of claim 1,
The polymer polymer is composed of magnetic nano-particle-reinforced shape memory polymer, oil leakage detection device, characterized in that consisting of a spiral body having a spiral width, a spiral of a certain size. An outer case through which oil leaks;
A swelling member provided inside the outer case and swelling when the leaked oil penetrated into the outer case is absorbed;
A porous support member provided inside the swelling member to limit an expanded state of the swelling member;
A signal transmission member which is provided inside the porous support member and whose shape is changed by the pressure of the swelling member leaking into the hole of the porous support member;
A center support part spaced apart from an inner side surface of the signal transmission member and positioned at the center of the signal transmission member and generating a leak detection signal when the shape of the signal transmission member changes and contacts the outer surface; And
And a control unit configured to receive the leak detection signal of the central support unit to determine the leak, generate an alarm sound, and display a leak location. The method of claim 6,
The signal transmission member is provided with a detection line for generating a warning signal when the shape is changed by the pressure of the swelling member, the detection line is connected to the control unit, the control unit receives a warning signal of the detection line to generate a warning sound Leakage detection device characterized in that. The method of claim 7, wherein
The signal generated in the detection line is a warning signal indicating that the primary detection of the leakage of crude oil in the related pipe,
The leak detection signal generated from the central support is a signal indicating that the oil is leaked secondarily, a warning signal confirming the occurrence of leaks and informing of danger.
Leakage detection device characterized in that it is possible to predict the speed of leakage and the amount of leakage by using the time difference between the primary warning signal and the secondary alarm signal. The method of claim 6,
The signal transmission member is a leak detection apparatus, characterized in that the diaphragm having a conductivity elastically deformed by the pressure.

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