KR20120128477A - Oil leakage detecting apparatus for explosion-proof area - Google Patents

Abstract

PURPOSE: An oil leakage sensing device in an explosion district is provided to rapidly sense leaked oil to the ground by being installed in an explosion district, thereby preventing the pollution of soil and underground water. CONSTITUTION: An oil leakage sensing device in an explosion district comprises a pipe(200) and a sensor assembly(300). A bored portion(200) is formed along the circumference of the pipe. A portion of the pipe where the bored portion is formed becomes buried in the underground. A controlling device(100) is mounted on the top of a portion of the pipe being exposed to the ground. The sensor assembly is installed in an inner side of the pipe along a longitudinal direction. The sensor assembly senses oil flowing through the bored portion. The sensor assembly comprises a supporting bar(310), an oil leakage sensor(320), and a cover unit(330).

Description

Oil leakage detecting apparatus for explosion-proof area {Oil leakage detecting apparatus for explosion-proof area}

The present invention relates to an oil leak detecting apparatus, and more particularly, to an oil leak detecting apparatus in an explosion-proof area that is embedded in the ground of a facility that is likely to cause an explosion such as an oil reservoir and detects leakage of oil.

Since oil tanks installed on the ground or buried underground contain highly flammable oils, the oil reservoir area where the oil tanks are installed is set as explosion-proof area.

Since oil tanks installed in this way may leak due to cracks, corrosion, external impacts, etc., they may cause serious pollution of surrounding soil and groundwater along with the risk of explosion.

In order to check the leakage of oil, a lot of methods of sampling the surrounding soil are used, but this is a method that is not easily carried out except in special cases because the soil samples are collected by digging a certain depth from the ground surface.

In addition, since it is impossible to check immediately when leakage occurs, the contamination of soil and groundwater has already occurred, and in particular, the risk of explosion is greatly increased due to the considerable leakage of leakage.

The present invention is to buried in the ground in the explosion-proof area to solve this problem to immediately detect the leakage, and to provide a leakage detection device of the explosion-proof area to facilitate the maintenance of the sensor for detecting leakage. have.

The present invention for achieving the above object,

A perforated portion is formed along the perimeter, a portion in which the perforated portion is formed is buried in the ground, and a pipe is equipped with a controller on top of the portion exposed to the ground;

It is installed along the longitudinal direction from the inside of the pipe, consisting of a sensor assembly for detecting the oil flowing through the perforation,

The sensor assembly,

A support bar inserted into the inside of the pipe and having a flat portion that is flat in the longitudinal direction;

A leaky oil sensor for detecting oil flowing into the flat portion of the support bar in a longitudinal direction;

It covers the exposed portion of the support bar, the cover portion formed with a plurality of holes to pass the oil; characterized in that consisting of.

In addition, the leak detection sensor

A base film layer in tape form;

Conductive lines printed in a longitudinal direction on an upper surface of the base film layer;

A conductive polymer line attached side by side to the conductive line at an upper surface of the base plume layer;

An upper protective film layer attached to an upper surface of the base film layer and having a plurality of holes formed at predetermined intervals in a longitudinal direction at a position where conductive lines are printed.

The present invention is installed in the explosion-proof area to quickly detect the oil leaked to the ground to prevent explosion, soil and groundwater contamination, and also has the advantage of very easy maintenance of the leakage sensor.

1 is an exploded view of the present invention.
2 is a cross-sectional view of the combination of the present invention.
Figure 3 is a cross-sectional view of the AA portion of the present invention.
4 is a cross-sectional view of the leak detection sensor.
Figure 5 is a perspective view showing the oil leakage sensor separated by each floor.
Fig. 6 shows the positional relationship between the conductive line and the hole.
7 is a view showing a process of changing the leak detection sensor to detect when the leak occurs.
8 is a view showing another embodiment of a leak detection sensor.
9 is an internal circuit block diagram of the controller.
Figure 10 illustrates another form of the present invention.

The present invention configured as described above will be described in detail with reference to the accompanying drawings.

Figure 1 is an exploded view of the present invention, the box-shaped controller 100, the lower side is buried in the ground and the upper end of the pipe 200 is installed in conjunction with the controller 100, and in the longitudinal direction inside the pipe The sensor assembly 300 is inserted and installed.

The controller 100 has a built-in circuit portion for determining the leakage of oil by the signal input from the sensor assembly 300 therein.

Pipe 200 is formed with a perforation portion 220 consisting of a plurality of holes in the site buried in the ground, the controller 100 is coupled to the top by a flange (210).

The sensor assembly 300 is inserted in the lengthwise direction from the inside of the pipe 200, the support bar 310 is provided in the form of a straight bar to fix the film type oil leakage sensor 320 long in the longitudinal direction. And, the oil leakage sensor 320 is attached to the support bar 310 is fixed.

The support bar 310 has a length corresponding to the length of the pipe 200 and has a flat portion 311 which is long in the longitudinal direction in order to easily attach the oil leakage sensor 320.

In addition, the wall 312 is formed to be bent to both sides along the longitudinal direction of the support bar 310, the height of the wall 312 is formed higher than the height of the leakage sensor 320, the wall 312 The cover portion 330 is covered at the top of the.

The cover portion 330 has a length corresponding to that of the pipe 200, and a plurality of holes are formed in a portion corresponding to a portion where the perforation portion 220 is formed.

The oil leakage sensor 320 is fixed while being isolated from the inside of the pipe 200 by the support bar 310 and the cover 330, and also supplies power to the oil leakage sensor 320, and senses the sensed signal. A cable 329 transmitting to the controller is connected to the controller 100 by a connector.

Figure 2 is a view showing the installation state for detecting the leaking oil by embedding the lower portion of the ground in the ground, the controller 100 is coupled to the top of the pipe 200 by the flange 210, and the cable ( 329 is introduced into the controller 100 through the wire inlet 101 formed at the bottom of the controller 100 is connected to the circuit portion.

In addition, the side of the controller 100 is connected to the conduit 110 is inserted into the wire is extended to the ground is configured to receive power and communication with the neighboring controller or the central control panel.

In addition, the lower side of the pipe 200, that is, the portion in which the perforated portion 220 is formed is buried in the form of standing in the ground, wherein the length of the oil leakage sensor 320 has the same or similar length as the portion buried in the ground. .

3 is a cross-sectional view of the AA portion of FIG. 2, in which the sensor assembly 300 is inserted into the pipe 200, and the sensor assembly 300 has a space 230 in the pipe 200. As shown in FIG. While being installed, the space 230 is filled with a filler such as sand or oil absorption cloth is fixed while maintaining the sensor assembly 300, the filler is introduced through the punching section 220 of the pipe 200 It will absorb the oil component.

In addition, the leak detection sensor 320 attached to the support bar 310 is fixed to the cover 330 by the wall 312 to maintain a predetermined interval, which is filled in the space 230 by such a gap. Since the filler does not directly contact the leakage sensor 320, damage may be prevented.

For example, when sand is filled in the space 230, the grains of sand block the sensing hole of the oil leakage sensor 320, which will be described later, so that oil may not be detected smoothly or the conductive line may be damaged. The gap is maintained by 312 so that the filler does not directly contact.

In addition, the space separated by the support bar 310 and the cover 330 is preferably filled with an oil absorption cloth so that the absorbed oil can be easily diffused into the oil leak detection sensor 320.

Therefore, when leakage occurs, oil flows into the space portion 230 through the puncturing portion 220 of the pipe 200, and the introduced oil diffuses into the sensor assembly 300 to detect the leakage of oil. By detecting it, the controller detects it.

Figure 4 is a cross-sectional view of the oil leak detection sensor 320 applied in the present invention, it is in the form of a tape to be attached to the flat portion 311 of the support bar 310, the adhesive layer 321, the lower The protective film layer 322, the base layer 324 printed on the lower surface of the conductive line 323, and the upper protective film layer 325 are sequentially stacked upward from the bottom surface.

In addition, the upper protective film layer 325 has holes 326 formed at regular intervals.

The adhesive layer 321 is a layer for attaching to the support bar and is configured in the form of an adhesive tape such as a double-sided tape.

The lower protective film layer 322 is a layer for protecting the lower surface of the base layer 324, is formed of a film such as PET, PE, PTFE, PVC, conductive lines printed on the lower surface of the base layer 324 323 to protect.

The base layer 324 is a layer on which the conductive line 323 is printed on the bottom surface, and is formed as a porous polymer to absorb and expand oil, and the porous polymer is a conductive line 323 printed on the bottom surface. ) Is insulated.

The conductive line 323 is printed on the lower surface of the base layer 324 by a printing method, which is printed in at least one line along the longitudinal direction of the base layer 324, the conductive line 323 is conductive It is printed by a silver compound or pure conductor ink having 0 to 20?

The upper protective film layer 325 is formed of a film such as PET, PE, PTFE, PVC, such as the lower protective film layer 322 to protect the upper surface of the base layer 324, the conductive line 323 In the formed position, a plurality of holes 326 are formed at regular intervals along its longitudinal direction.

The hole 326 is formed to have a long groove, a circular groove, or other shape, the interval between the holes 326 is preferably formed to have a gap of 0.5 ~ .5cm.

5 is an exploded perspective view showing the tape-shaped leak detection sensor 320 for each layer. The conductive line 323 is printed on the lower surface of the base layer 324 in the longitudinal direction. ) May be formed in one or more lines.

In addition, the upper protective film layer 325 is formed with a plurality of holes 326 in the longitudinal direction at regular intervals, as shown in Figure 6 holes 326 at the same position as the printed position of the conductive line 323 as possible Is preferably formed.

Therefore, the laminated layers are bonded by thermocompression bonding or ultrasonic welding, or an adhesive. At this time, it is preferable to bond the portions excluding the holes 326 and the conductive lines 323, and the lower portion of the base film 324 Moisture is introduced from the outside to the surface and the conductive line 323 is applied after applying a waterproofing solution so as not to detect this.

In other words, moisture should flow into the conductive line 323 to prevent malfunction.

To this end, since the base layer 324 is formed of a porous polymer, even if moisture is introduced through the holes 326 of the upper protective film layer 325, no change occurs in the base layer 324, and thus, the conductive line 323 is formed. Is not affected by moisture.

However, the base layer 324 detects the occurrence of leakage by changing the resistance value of the conductive line 323 in response to oil such as hydrocarbon liquid.

In addition, the cover portion 330 is preferably installed so as to face the direction in which leakage is expected to occur so that rapid leakage detection can be made.

7 is a diagram illustrating a process of changing the oil leakage sensor 320 when the oil leakage occurs to detect the oil leakage. When the oil 327 contacts the upper protective film layer 325 as shown in FIG. The oil 327 flows into the base layer 324 through 326.

The base layer 324 is formed by the porous polymer to absorb the oil 327, the expansion gradually occurs as shown in (b) by the absorption of the oil, thereby causing the conductive line 323 of the printed on the back The volume gradually increases.

At this time, fine cracks 323-1 are generated in the conductive line 323, the volume of which is gradually increased, and the resistance value per unit area increases, and when the limit point is reached, the crack 323-1 of the conductive line 323 is completely It is a case of breaking apart.

Therefore, by detecting the increase in the resistance of the conductive line 323 is to detect whether or not leakage occurs.

8 is an internal circuit diagram of the controller 100. The processor 120 controls the power supply unit 130 to supply a voltage of several V to the conductive line 323, and the voltage value through the conductive line 323. It is determined whether the leakage is received, if the voltage drop occurs because the resistance value of the conductive line 323 is increased to determine the leakage.

At this time, since the drop of the voltage input to the processor 120 according to the length of the leakage sensor 320 is inevitably generated, the set value is stored in the voltage drop value that can occur according to the installed length of the leakage sensor 320 If the voltage drop value detected from the conductive line 323 is greater than the set voltage drop value, the alarm generation signal is output to the display unit 150 and the warning sound generation unit 160. By doing so, the manager is notified of the leakage.

9 illustrates another embodiment of the leak monitoring sensor 320, in which a conductive polymer is used instead of the porous polymer used in one embodiment.

First, the conductive line 328-1 is formed by a silver compound or a pure conductor ink having 0 to 20Ω in the longitudinal direction on the base film layer 328 formed of a film such as PET, PE, PTFE, or PVC. After printing, the conductive polymer line 328-2 is attached to the conductive line 328-1 while being spaced apart from the conductive line 328-1 by a predetermined distance.

That is, as in the embodiment, the entire base film layer 328 is not composed of the porous polymer, but the cost is reduced by placing the porous polymer having conductivity only at the position where the oil of the base film layer 328 contacts. will be.

The conductive polymer line 328-2 detects the occurrence of leakage by changing the resistance value in response to oil such as a hydrocarbon liquid.

The conductive polymer line 328-2 may be attached to the base film layer 328 by various methods such as adhesive, ultrasonic welding, and thermocompression. The upper protective film may be disposed on the base film layer 328. When the layer is attached, it is possible to attach it in the same way as above.

An upper protective film layer 325 as shown in FIG. 7 is positioned above the base film layer 328. In the upper protective film layer 325, a plurality of holes 326 in the longitudinal direction are formed at predetermined intervals. And the hole 326 is formed at the same position where the conductive polymer line 328-2 is attached.

In addition, the laminated base film layer 328 and the upper protective film layer 325 are bonded by thermocompression bonding or ultrasonic welding, or an adhesive. At this time, the hole 326 and the conductive line 328-1 and the conductive polymer A portion excluding the line 328-2 may be bonded to each other, and an adhesive layer may be further attached to the bottom surface of the base film layer 328.

Therefore, when oil flows through the hole 326 of the upper protective film layer 325, the resistance value is increased due to the porosity of the conductive polymer line 328-2.

Therefore, the resistance change value is read from the controller 100 to determine whether leakage occurs, and the overall operation is the same as in the exemplary embodiment.

10 is a view showing another embodiment for supporting the leak detection sensor 320, in which a cylindrical support 340 is inserted into the inside of the pipe 200, and leak detection is performed around an outer circumference of the cylindrical support 340. A plurality of sensors 320 are attached in the form of a strip in the vertical direction, or one leak detection sensor 320 is attached in a spiral form.

In addition, a cylindrical network 350 is inserted between the inner surface of the pipe 200 and the outer surface of the cylindrical support 340 to which the oil leakage detecting sensor 320 is attached. The cylindrical mesh 350 is a leakage oil detecting sensor ( 320 is installed in contact with or close to.

The cylindrical mesh 350 is to prevent the filling material, such as sand filled in the inside of the pipe 200 to directly contact the leakage sensor 320 to prevent damage, the cylindrical mesh 350 is smaller than the size of the filler It is densely formed to have a hole.

100: controller 200: pipe
210: flange 220: perforated part
300: sensor assembly 310: support bar
311: Fengtan 312: wall
320: oil leakage sensor 321: adhesive tape layer
322: lower protective film layer 323: conductive line
324: base film layer 325: upper protective film layer
326: hall
330: cover 331: hole

Claims (7)

A perforated portion is formed along the perimeter, a portion in which the perforated portion is formed is buried in the ground, and a pipe is equipped with a controller on top of the portion exposed to the ground;
It is installed along the longitudinal direction from the inside of the pipe, consisting of a sensor assembly for detecting the oil flowing through the perforation,
The sensor assembly,
A support bar inserted into the inside of the pipe and having a flat portion that is flat in the longitudinal direction;
A leaky oil sensor for detecting oil flowing into the flat portion of the support bar in a longitudinal direction;
Covering the exposed portion of the support bar, the oil leakage detection device of explosion-proof area, characterized in that consisting of; cover portion formed with a plurality of holes to pass the oil.
The apparatus of claim 1, wherein the support bar has a wall formed on both sides of the flat part, the wall being higher than the thickness of the leak detection sensor, and a cover part is coupled to an upper end of the wall.
The oil leakage sensor of claim 1, wherein
A base film layer in tape form;
Conductive lines printed in a longitudinal direction on an upper surface of the base film layer;
A conductive polymer line attached side by side to the conductive line at an upper surface of the base film layer;
And an upper protective film layer attached to the upper surface of the base film layer and having a plurality of holes formed at predetermined intervals in the longitudinal direction at the position where the conductive line is printed.
The oil leakage sensor of claim 1, wherein
A base layer formed into a flat tape by a porous polymer;
Conductive lines printed along a longitudinal direction on a lower surface of the base layer;
A lower protective film layer to which the conductive line is attached to protect the lower surface of the printed base layer;
And an upper protective film layer attached to the upper surface of the base layer and having a plurality of holes formed at predetermined intervals in the longitudinal direction at the position where the conductive line is printed.
The oil leakage detecting apparatus of the explosion-proof area according to claim 4, wherein a waterproofing solution for waterproofing is applied to a lower surface of the base layer on which conductive lines are printed.
The apparatus of claim 1, wherein the power supply unit supplies power to the conductive line;
A processor that reads the detected voltage value from the conductive line and compares the detected voltage value with a voltage value stored in a set value storage unit to determine whether an alarm occurs;
And a display unit configured to display a warning under the control of the processor.
A perforated portion is formed along the perimeter, a portion in which the perforated portion is formed is buried in the ground, and a pipe is equipped with a controller on top of the portion exposed to the ground;
It is installed along the longitudinal direction from the inside of the pipe, consisting of a sensor assembly for detecting the oil flowing through the perforation,
The sensor assembly,
A cylindrical support inserted long into the pipe;
Leak detection sensor for detecting the flow of oil is attached in the form of a strip or spiral along the outer periphery of the cylindrical support;
Oil leakage detection device of explosion-proof area, characterized in that consisting of; a cylindrical mesh is covered to the outside of the cylindrical support attached to the oil leak detection sensor.

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