KR20200010828A - Complex type leak detecting sensor - Google Patents

Abstract

The present invention relates to a complex type leak detecting sensor, comprising: a sensor body extending in the longitudinal direction, wherein the width of an upper part is formed relatively larger than the width of a lower part, and formed of an insulating resin; and a first sensor unit which is formed on one side surface of the lower part of the sensor body, extends in the longitudinal direction of the sensor body, wherein the capacitance value or the resistance value changes due to leak. The first sensor unit includes: a first sensor forming groove formed on one side surface of the lower part of the sensor body; a first sensor line inserted inside the first sensor forming groove; and a second sensor line surrounding the periphery of the first sensor line and filling the first sensor forming groove.

Description

Complex type leak detecting sensor

The present invention relates to a sensor for detecting leakage of a drug or oil such as an acid, a base, an organic, and more particularly, to a complex leakage detection sensor that can be reused after leakage detection.

In general, many chemicals are used in the semiconductor manufacturing process. For example, the cleaning liquid used for the cleaning process after cutting and polishing the wafer, the photosensitive liquid used for the photosensitive process of the wafer, the developing solution used for the developing process of the wafer, the etching liquid used for the wafer etching process, and the like are used in the semiconductor manufacturing process. .

On the other hand, industrial facilities for general chemical or petrochemical and steel manufacturing are installed and operated outdoors with various kinds of acid and basic chemical storage facilities such as sulfuric acid, hydrofluoric acid, nitric acid and caustic soda, which are necessary for the production and processing of various kinds of products. .

These chemicals may leak to the outside due to unpredictable situations such as failure of transfer pipes or storage tanks, deterioration, overpressure or operation mistakes. Leaky chemicals can lead to explosions, fires, and adversely affect humans as well as other devices and components in the manufacturing site, so it is necessary to detect leaks and take action quickly.

Leakage detection in chemicals generally detects a change in the overall resistance value due to shorting due to the contact of a conducting solution between the two conductor wires, with the positive (+) conductor wires and the negative (-) conductor wires side by side or intersecting. .

Recently, sensors have been developed to detect leakage in response to specific chemicals such as acids, bases, organics, and oils, not water. Korean Patent No. 10-1799836 discloses a rainfall type leak detection sensor in which inflow holes are formed to guide leaked chemicals to the sensor layer, and dissolving films dissolved by a specific chemical are blocking the inflow holes. In addition, Korean Patent No. 10-1460020 discloses an acid solution leak detection apparatus applying a coating layer on the upper surface of the base film layer so that the conductive line is not exposed to the outside by a material dissolved by an acid solution.

However, these conventional leak detection sensors have to coat or attach a dissolving material that does not react to moisture and are only dissolved by the leaked chemicals, and after detecting the leaking solution, the dissolved material or the dissolving film is dissolved and it is impossible to reuse the sensor. There was a problem.

The present invention has been invented to solve the above problems, it does not react with water, can react only with chemicals or oils such as acids, bases, organics, etc. can detect the leakage of the drug, it is possible to reuse even after detection An object of the present invention is to provide a composite leak detection sensor.

In order to achieve the above object, the first embodiment of the present invention extends a predetermined length along the longitudinal direction, the width of the upper portion is formed relatively larger than the width of the lower, the sensor body made of an insulating resin; And a first sensor part formed on one side of the lower part of the sensor body, extending in the longitudinal direction of the sensor body, and wherein the capacitance value or the resistance value changes due to leakage. A first sensor forming groove formed on one side of the lower portion of the sensor body; A first sensor line inserted into the first sensor forming groove; And a second sensor line surrounding a periphery of the first sensor line and filling the first sensor forming groove.

Preferably, further comprising a second sensor portion formed on the other side of the lower portion of the sensor body, extending along the longitudinal direction of the sensor body, the capacitance value or the resistance value is changed by the leakage; The second sensor unit may include: a second sensor forming groove formed on the other side of the lower part of the sensor body; A third sensor line inserted into the second sensor forming groove; And a fourth sensor line surrounding the periphery of the third sensor line and filling the second sensor forming groove.

More preferably, further comprising a third sensor portion formed on the bottom surface of the lower portion of the sensor body, extending along the longitudinal direction of the sensor body, the capacitance value or the resistance value is changed by the leakage; The third sensor unit may include: a third sensor forming groove formed on a bottom surface of the lower portion of the sensor body; A fifth sensor line inserted into the third sensor forming groove; And a sixth sensor line surrounding the periphery of the fifth sensor line and filling the third sensor forming groove.

Preferably, the first sealing part is provided on one side of the lower part of the sensor body so that the second sensor line of the first sensor part is partially exposed to the outside; A second sealing part provided on the other side of the lower part of the sensor body such that the fourth sensor line of the second sensor part is partially exposed to the outside; And a third sealing part provided on the bottom surface of the lower part of the sensor body such that the sixth sensor line of the third sensor part is partially exposed to the outside.

The first sealing part, the second sealing part, and the third sealing part are made of an insulating material, and the second sensor line, the fourth sensor line, and the sixth sensor line are spaced apart at regular intervals along the longitudinal direction of the sensor body. Has a pattern to be exposed.

In addition, the first sensor line, the third sensor line, and the fifth sensor line may be formed of a core wire, a copper wire, or a braided wire, and the second sensor line, the fourth sensor line, and the sixth sensor line may be formed of resin, adhesive, and conductive ink. It is made of a mixed material.

A second embodiment and a third embodiment of the present invention, the sensor body extends a predetermined length along the longitudinal direction, the width of the upper portion is formed relatively larger than the width of the lower portion, made of an insulating resin; A sensor unit extending to both side surfaces of the lower part of the sensor body along a length direction of the sensor body, wherein the capacitance value or the resistance value changes due to leakage; A conductive common line formed along a longitudinal direction in a groove formed in a lower center of the sensor body; A sealing part for insulating sealing the sensor part so that the sensor part is partially exposed to the outside; And a wire embedded in an upper center of the sensor body along a length direction of the sensor body.

Fourth and fifth embodiments of the present invention, the sensor body extends a predetermined length along the longitudinal direction, made of an insulating resin; A groove formed on the bottom surface of the sensor body along a length direction and having a lower width than an upper portion thereof; Sensor parts each extending on both sides of the groove part along a length direction of the sensor body, and the capacitance value or the resistance value is changed by leakage; A sealing part for insulating sealing the sensor part so that the sensor part is partially exposed to the outside; And a wire embedded in the sensor body above the groove along the longitudinal direction of the sensor body.

Here, the wires disclosed in the third and fifth embodiments of the present invention are disposed adjacent to the groove so that a portion thereof is exposed to the outside, and a conductive material is injected or coated around the wire.

A sixth embodiment of the present invention, the sensor body extends a predetermined length along the longitudinal direction, made of an insulating resin; A pair of protrusions formed side by side spaced apart from each other on the bottom surface of the sensor body in the longitudinal direction of the sensor body; A first sensor line formed on an outer side of one of the pair of protrusions on a bottom surface of the sensor body along a longitudinal direction of the sensor body, the capacitance value or resistance value being changed by leakage; A second sensor line formed on an outer side of the other of the pair of protrusions on a bottom surface of the sensor body along a length direction of the sensor body, and the capacitance value or the resistance value changed by leakage; A common line formed between the pair of protrusions along a length direction of the sensor body; A wire embedded in the center of the sensor body along a length direction of the sensor body; And a sealing part for insulating sealing the first sensor line and the second sensor line to be partially exposed to the outside.

A seventh embodiment of the present invention includes a sensor body extending a predetermined length along the longitudinal direction, made of an insulating resin; A pair of grooves formed side by side spaced apart from each other on the bottom surface of the sensor body along the longitudinal direction of the sensor body; A first sensor line formed in one of the pair of grooves on a bottom surface of the sensor body along a length direction of the sensor body, and the capacitance value or the resistance value changed due to leakage; A second sensor line formed in the other one of the pair of grooves on the bottom surface of the sensor body along a longitudinal direction of the sensor body, the capacitance value or resistance value being changed by leakage; A common line formed between the pair of grooves along a length direction of the sensor body; A wire embedded in the center of the sensor body along a length direction of the sensor body; And a sealing part that insulates and seals the first sensor line and the second sensor line to be partially exposed to the outside.

Preferably, a controller that detects leakage based on a change in resistance value and capacitance value between the first sensor line and the common line, and a change in resistance value and capacitance value between the second sensor line and the common line. The controller may further include the change of the resistance value and the capacitance value between the first sensor line and the common line with a pre-input reference value to discriminate whether the leaked liquid is water, chemicals or oils. The controller compares the resistance value and the capacitance value change between the second sensor line and the common line with a pre-input reference value to discriminate whether the leaked liquid is water, a chemical, or an oil, and then the first and second Compare the result of the difference to determine the liquid leaked.

The composite leakage sensor according to the present invention can detect the leakage of the drug without the dissolution film or coating layer dissolved by the drug, thereby enabling the sensor to be reused even after the detection of the drug leakage.

1 is a cross-sectional view schematically showing a hybrid leak detection sensor according to a first embodiment of the present invention,
Figure 2a is a side view schematically showing a composite leak detection sensor according to a first embodiment of the present invention,
FIG. 2B is a side view schematically showing the hybrid leak detection sensor according to the first embodiment of the present invention in another direction; FIG.
FIG. 3 is a bottom view schematically showing a composite leak detection sensor according to a first embodiment of the present invention; FIG.
Figure 4 is a cross-sectional view schematically showing another form of the composite leakage detection sensor according to a first embodiment of the present invention,
FIG. 5 is a bottom view schematically showing another form of the composite leakage detection sensor according to the first embodiment of the present invention; FIG.
FIG. 6 is a cross-sectional view schematically showing a composite leak detection sensor according to a second exemplary embodiment of the present invention; FIG.
FIG. 7 is a cross-sectional view schematically illustrating a composite leak detection sensor according to a third exemplary embodiment of the present invention; FIG.
FIG. 8 is a cross-sectional view schematically showing a composite leak detection sensor according to a fourth exemplary embodiment of the present invention; FIG.
FIG. 9 is a cross-sectional view schematically illustrating a composite leak detection sensor according to a fifth exemplary embodiment of the present invention; FIG.
10 is a cross-sectional view schematically showing a composite leak detection sensor according to a sixth embodiment of the present invention;
11 is a bottom view of FIG. 10;
12 is a cross-sectional view schematically showing a composite leak detection sensor according to a seventh embodiment of the present invention;
FIG. 13 is a bottom view of FIG. 12; FIG.
FIG. 14 is a view schematically showing a leakage leakage detection circuit configuration of the complex leakage detection sensor according to the sixth or seventh embodiment of the present invention. FIG.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the hybrid leak detection sensor according to the present invention. For reference, in the following description of the present invention, terms referring to the elements of the present invention are named in consideration of the function of each element, and should not be understood as a meaning of limiting the technical elements of the present invention. Will be.

1 to 3, the composite leakage sensor according to the first exemplary embodiment of the present invention includes a sensor body 100 made of an insulating resin material and a first change in capacitance value or resistance value caused by leakage. The sensor unit 210 is included.

The sensor body 100 is made of an insulating resin material having a rectangular rod shape extending in a predetermined length along a length direction. Here, the insulating resin material may include, for example, a general resin such as PP, PE, PVC, POM, PC, PU, or a fluorine resin-based material such as PFA, PCTFE, ETFE, or FEP. In addition, the sensor body 100 is formed to have a relatively larger width than the upper width. Since the width of the upper portion of the sensor body 100 is formed to be relatively larger than the width of the lower portion, a space through which the leaked liquid may flow is formed on the outer side of the lower portion. This space serves to allow the leaked liquid to be easily guided to the first sensor unit 210 side.

The first sensor unit 210 is formed on one side of the lower portion of the sensor body 100 and extends along the length direction of the sensor body 100. The first sensor unit 210 includes a first sensor forming groove 211, a first sensor line 212, and a second sensor line 213. The first sensor forming groove 211 is formed along the longitudinal direction of the sensor body 100 on one side of the lower portion of the sensor body 100. The first sensor line 212 is inserted into the first sensor forming groove 211. The first sensor line 212 may be formed of, for example, a core wire, a copper wire, or a braided wire. The second sensor line 213 is disposed to surround the periphery of the first sensor line 212. In addition, the second sensor line 213 is disposed to fill the first sensor forming groove 211. Here, the second sensor line 213 may be made of a material mixed with a resin, an adhesive, and a conductive ink.

In addition, the composite leak detection sensor according to the first embodiment of the present invention further includes a second sensor unit 220 formed on the other side of the lower part of the sensor body 100. The second sensor unit 220 is formed on the other side of the sensor body 100 to face the first sensor unit 210. And, like the first sensor unit 210 extends along the longitudinal direction of the sensor body 100, it is configured to change the capacitance value or the resistance value by the leakage.

Here, the second sensor unit 220 includes a second sensor forming groove 221, a third sensor line 222, and a fourth sensor line 223. The second sensor forming groove 221 is formed along the longitudinal direction of the sensor body 100 on the other side of the lower portion of the sensor body 100. The third sensor line 222 is inserted into the second sensor forming groove 221. The third sensor line 222 may be formed of, for example, a core wire, a copper wire, or a braided wire. The fourth sensor line 223 is disposed to surround the periphery of the third sensor line 222. In addition, the fourth sensor line 223 is disposed to fill the second sensor forming groove 221. Here, the fourth sensor line 223 may be made of a material mixed with a resin, an adhesive, and a conductive ink.

In addition, the hybrid leakage detection sensor according to the first embodiment of the present invention further includes a third sensor unit 230 formed on the bottom surface of the lower portion of the sensor body 100. Like the first sensor unit 210 and the second sensor unit 220, the third sensor unit 230 extends in the longitudinal direction of the sensor body 100 and changes the capacitance value or the resistance value due to leakage. It is composed.

Here, the third sensor unit 230 may serve as a common line between the first sensor unit 210 and the second sensor unit 220, and the third sensor forming groove 231 and the fifth sensor line 232. ) And a sixth sensor line 233. The third sensor forming groove 231 is formed along the longitudinal direction of the sensor body 100 on the bottom surface of the lower portion of the sensor body 100. The fifth sensor line 232 is inserted into the third sensor forming groove 231. The fifth sensor line 232 may be formed of, for example, a core wire, a copper wire, or a braided wire. The sixth sensor line 233 is disposed to surround the periphery of the fifth sensor line 232. In addition, the sixth sensor line 233 is disposed to fill the third sensor forming groove 231. Here, the sixth sensor line 233 may be made of a material mixed with a resin, an adhesive, and a conductive ink.

In the composite leakage detection sensor according to the first exemplary embodiment of the present invention configured as described above, a detection area in which a capacitance value is changed by a fluid leaked on the outside of each sensor unit 210, 220, 230 is formed, and leakage detection is detected. By detecting the capacitance value according to the change of dielectric constant in the region, it is possible to detect the leakage of medicine by distinguishing it from water. In addition, each sensor unit 210, 200, 230 may change in resistance in contact with the leaked fluid. Therefore, leakage can be detected based on a change in capacitance value and / or a change in resistance value. In particular, when the composite leakage detection sensor according to the first embodiment of the present invention is configured to detect leakage based on a change in capacitance value, it is not necessary to form a separate dissolution film or coating layer dissolved by chemicals, It can be reused after detection.

Preferably, when the first sensor unit 210 is configured to detect leakage based on a change in capacitance value, the second sensor line 213 is partially exposed to the outside outside the first sensor unit 210. The first sealing part 310 may be provided at one side of the lower part of the sensor body 100 so as to be provided. Referring to FIG. 2A, the first sealing part 310 is an insulating member partially coated on one side of the lower part of the sensor body 100, and the second sensor line 213 of the first sensor part 210 is constant. Allow exposure at intervals. By the first sealing part 310, the capacitance value sensing region of the second sensor line 213 is locally divided.

Since the sensing areas formed by the first sensor unit 210 are divided into a plurality of local sensing areas spaced apart from each other, the change in capacitance value is remarkably changed in comparison with the relatively wide sensing areas. Therefore, it is possible to increase the leak detection capability of the sensor.

In addition, when the second sensor unit 220 is configured to detect leakage based on a change in capacitance value, the sensor may be partially exposed to the outside only on the outside of the second sensor unit 220. The second sealing part 320 may be provided on the other side of the lower part of the body 100. Referring to FIG. 2B, the second sealing part 320 is an insulating member partially coated on the other side of the lower part of the sensor body 100, and the fourth sensor line 223 of the second sensor part 220 is formed. Allow exposure at intervals. By the second sealing part 320, the capacitance value sensing region of the fourth sensor line 223 is locally divided, and thus the capacitance value changes remarkably.

Meanwhile, as shown in FIG. 3, the third sensor unit 230 may not be provided with a separate seal, and may be configured to detect leakage based on a change in resistance value. That is, the first sensor unit 210 and the second sensor unit 220 detect leakage based on the change in capacitance value, and the third sensor unit 230 is configured to detect leakage based on the change in resistance value. In addition, it is possible to detect leaks in combination.

4 and 5, the third sensor unit 230 may also be configured to detect leakage based on a change in capacitance value. Accordingly, the third sealing part 330 may be provided on the outer side of the third sensor unit 230, that is, the bottom surface of the sensor body 100. The third sealing part 330 is an insulating member partially coated on the bottom surface of the sensor body 100 to expose the sixth sensor line 233 of the third sensor part 230 at a predetermined interval.

As described above, the first sealing part 310, the second sealing part 320, and the third sealing part 330 are insulating materials, and the second sensor line 213, the fourth sensor line 223, and the sixth sealing part 330 are made of an insulating material. The sensor line 233 has a pattern to be locally exposed at regular intervals along the longitudinal direction of the sensor body 100. Accordingly, the capacitance detection area of each sensor unit 210, 220, 230 is divided locally to significantly change the capacitance value, thereby increasing the leak detection capability of the sensor.

6 and 7, the composite leakage sensor according to the second and third embodiments of the present invention has a sensor body 100 made of an insulating resin material, and a capacitance value changes due to leakage, or a resistance value. Buried in the sensor pair (240, 250), the conductive common line 260, the sealing portion (340, 350) and the sensor body 100 to partially insulate and seal the sensor unit (240, 250) Wire 270.

The sensor body 100 is made of an insulating resin material having a rectangular rod shape extending in a predetermined length along a length direction. In addition, the sensor body 100 is formed to have a relatively larger width than the upper width. This space serves to allow the leaked liquid to be easily guided to the sensor units 240 and 250.

The sensor units 240 and 250 are formed on both side surfaces of the lower part of the sensor body 100, respectively, and extend along the longitudinal direction of the sensor body 100. In the drawing, the first sensor line 241 is formed in a predetermined pattern on the left side of the sensor body 100, and the second sensor line 251 is formed in a predetermined pattern on the right side of the sensor body 100. These sensor lines 241 and 251 are arranged to be exposed on the side of the sensor body 100, respectively. Here, the first sensor line 241 and the second sensor line 251 may be formed of the same material or different materials.

The conductive common line 260 is disposed in the groove 110 formed at the center of the bottom surface of the sensor body 100, and when leakage occurs, the first sensor line 241 and the second sensor line 251 are energized. It serves as a common line.

The sealing parts 340 and 350 insulate and seal the sensor parts 240 and 250 so that the sensor parts 240 and 250 are partially exposed to the outside. In the case where the seals 340, 350 partially seal the sensor parts 240, 250, as described in the first embodiment above, the seals 340, 350 are provided on the side of the lower part of the sensor body 100. As a partially coated insulating member, the sensor lines 241 and 251 of the sensor units 240 and 250 are exposed to be spaced apart at regular intervals. By the sealing parts 340 and 350, the capacitive value sensing region of the sensor lines 241 and 251 is locally divided.

The wire 270 is embedded in the upper center of the sensor body 100 along the length direction of the sensor body 100. The wire 270 is formed of a core wire, a copper wire or a braided wire, and serves to maintain the tension of the sensor body 100 having a predetermined length. Accordingly, it is possible to solve the problem that the groove 110 of the sensor body 100 is deformed.

Meanwhile, the hybrid leak detection sensor (second embodiment) illustrated in FIG. 6 includes an unexposed wire in which the wire 270 is spaced apart from the common line 260 and is not exposed to the outside. In addition, the hybrid leak detection sensor (third embodiment) illustrated in FIG. 7 includes an exposed wire in which the wire 270 is connected to the common line 260 and exposed to the outside. Here, the exposed wire of FIG. 7 is disposed adjacent to the groove 110 so that a portion thereof is exposed to the outside, and additionally injected or coated with a conductive material into the groove 110 to prevent direct exposure when the wire is a metal wire. It is desirable for the conductive material to wrap wire 270. The conductive material may be made of the same material as the common line 260 or a material mixed with a resin, an adhesive, and a conductive ink.

8 and 9, the composite leak detection sensor according to the fourth and fifth embodiments of the present invention includes a sensor body 100 made of an insulating resin material and a groove formed on the bottom surface of the sensor body 100. 120, a pair of sensor parts 24 and 250 whose capacitance changes or a resistance value changes due to leakage, sealing parts 340 and 350 which partially insulate and seal the sensor parts 240 and 250; And a wire 270 embedded in the sensor body 100.

The sensor body 100 is made of an insulating resin material having a rectangular rod shape extending in a predetermined length along a length direction.

The groove 120 is formed along the longitudinal direction of the sensor body 100 on the bottom surface of the sensor body 100, the lower portion has a larger width than the upper portion. In the drawing, the groove portion 120 having a trapezoidal cross section whose upper side is smaller than the lower side is disclosed. The groove part 120 provides a space in which the leakage fluid flows and a space in which the sensor parts 240 and 250 are installed. In particular, the groove portion 120 is formed such that the lower portion has a larger width than the upper portion serves to prevent rain water, etc. is bound by the surface tension after flowing into the groove portion 120.

The sensor unit 240 includes a first sensor line 241 and a second sensor line 251 which extend along the longitudinal direction of the sensor body 100 on both side surfaces of the groove 120 facing each other.

The sealing parts 340 and 350 insulate and seal the sensor parts 240 and 250 so that the sensor parts 240 and 250 are partially exposed to the outside. In the case where the seals 340 and 350 partially seal the sensor parts 240 and 250, the seals 340 and 350 are insulating members partially coated on the side surface of the lower part of the sensor body 100. The sensor lines 241 and 251 of the parts 240 and 250 are exposed to be spaced apart at regular intervals. By the sealing parts 340 and 350, the capacitive value sensing region of the sensor lines 241 and 251 is locally divided.

The wire 270 is embedded in the upper center of the sensor body 100 along the length direction of the sensor body 100. The wire 270 is formed of a core wire, a copper wire or a braided wire, and serves to maintain the tension of the sensor body 100 having a predetermined length.

Meanwhile, the hybrid leak detection sensor (fourth embodiment) illustrated in FIG. 8 includes an unexposed wire, in which the wire 270 is spaced apart from the groove 120 and is not exposed to the outside. In addition, the hybrid leak detection sensor (the fifth embodiment) illustrated in FIG. 9 includes an exposed wire in which the wire 270 is disposed adjacent to the groove 120 and exposed to the outside. Here, in order to prevent direct exposure when the exposed wire 270 of FIG. 9 is a metal wire, the conductive material 280 is injected or coated around the wire 270 to surround the wire 270. desirable. In this case, the exposed wire 270 may serve as a common line through which the sensor lines 241 and 251 of the sensor units 240 and 250 of FIG. 8 are energized.

Referring to FIGS. 10 and 11, the complex leakage sensor according to the sixth exemplary embodiment may include a sensor body 100 made of an insulating resin material and a pair of protrusions 131 formed on the bottom surface of the sensor body 100. 132, a wire buried in the first sensor line 291 and the second sensor line 292, the conductive common line 260, and the sensor body 100 in which the capacitance value or the resistance value changes due to leakage 270 and seals 361 and 362 that partially insulate the sensor lines 291 and 292.

The sensor body 100 is made of an insulating resin material having a substantially semi-circular rod shape extending in a predetermined length along a longitudinal direction.

The pair of protrusions 131 and 132 have a semi-circular cross section and are formed side by side to be spaced apart from each other on a flat bottom surface of the sensor body 100. By the pair of protrusions 131 and 132, the bottom surface of the sensor body 100 has three flat surfaces.

The first sensor line 291 and the second sensor line 292 extend in the longitudinal direction of the sensor body 100 at the bottom surface of the sensor body 100. The first sensor line 291 is formed on a flat surface located outside of one of the pair of protrusions 132, for example on the right side in the figure. The second sensor line 292 is formed on a flat surface located outside of the other one of the pair of protrusions 131, for example, on the left side in the figure.

The conductive common line 260 is disposed along the longitudinal direction of the sensor body 100 at the center of the bottom surface of the sensor body 100, that is, between the pair of protrusions 131 and 132, and the wire 270 is connected to the sensor body 100. Buried in the center of the sensor body 100 along the longitudinal direction of the (100). The wire 270 is formed of a core wire, a copper wire or a braided wire, and serves to maintain the tension of the sensor body 100 having a predetermined length. In addition, the wire 270 may be disposed adjacent to the bottom surface of the sensor body 100 to expose a portion of the wire 270. The conductive material 280 may be injected or coated around the wire 270 to form a conductive common line. Configured to be connected with 260. When leakage occurs, it serves as a common line through which the first sensor line 291 and the second sensor line 292 are energized.

Seals 361 and 362 insulate the sensor lines 291 and 292 so that the sensor lines 291 and 292 are partially exposed to the outside. The seals 361 and 362 are insulating members partially coated on the lower side of the sensor body 100 to expose the sensor lines 291 and 292 spaced apart at regular intervals. By the seals 361 and 362, the capacitance lines of the sensor lines 291 and 292 are locally divided.

12 and 13, the hybrid leak detection sensor according to the seventh exemplary embodiment may include the same sensor body 100, the first sensor line 291, and the second sensor line 292 as the sixth exemplary embodiment. Conductive common line 260, wire 270, and seals 361 and 362. However, the seventh embodiment of the present invention includes a pair of grooves 133 and 134 instead of the pair of protrusions 131 and 132 of the sixth embodiment.

The pair of grooves 133 and 134 are formed side by side to be spaced apart from each other on the flat bottom surface of the sensor body 100. The pair of grooves 133 and 134 provide a space in which the first sensor line 291 and the second sensor line 292 may be formed. For example, a first sensor line 291 is provided in the right groove 134 illustrated in the drawing, and a second sensor line 292 is provided in the left groove 133. The common line 260 is provided on the bottom surface of the sensor body 100 positioned between the pair of grooves 133 and 134.

Preferably, referring to FIG. 14, the composite leak detection sensor according to the sixth and seventh embodiments of the present invention may include a capacitance value between the first sensor line 291 and the common line 260, and / or Or a controller 400 for detecting leakage based on a change in resistance value and a change in capacitance value and / or resistance value between the second sensor line 292 and the common line 260.

The controller 400 compares the resistance value and the capacitance value change between the first sensor line 291 and the common line 260 with a previously input reference value to determine whether the leaked liquid is water, chemical, or oil. Primary division (①). In addition, the controller 400 compares the resistance value and the capacitance value change between the second sensor line 292 and the common line 260 with a time difference after the first division, and the leaked liquid Secondly, water, chemical, or oil is used to determine the liquid leaked (②).

As such, the controller 400 can accurately distinguish water, chemicals, and oil by comparing the resistance value and the capacitance value change with the reference value over the second time interval.

The embodiments of the present invention described above are merely illustrative of the technical idea of the present invention, and the protection scope of the present invention should be interpreted by the following claims. In addition, one of ordinary skill in the art to which the present invention pertains will be capable of various modifications and variations without departing from the essential characteristics of the present invention, all technical ideas within the scope equivalent to the present invention of the present invention It should be interpreted as being included in the scope of rights.

Claims (12)

A sensor body extending a predetermined length along a longitudinal direction, the upper width of the sensor body being made relatively larger than the lower width, and formed of an insulating resin; And
A first sensor part which is formed on one side of the lower part of the sensor body, extends along the length direction of the sensor body, and the capacitance value or the resistance value is changed by leakage;
A first sensor forming groove formed on one side of the lower portion of the sensor body;
A first sensor line inserted into the first sensor forming groove; And
And a second sensor line surrounding a periphery of the first sensor line and filling the first sensor forming groove.
The method of claim 1,
A second sensor unit is formed on the other side of the lower part of the sensor body, extends along the longitudinal direction of the sensor body, and the capacitance value or the resistance value is changed by leakage.
A second sensor forming groove formed on the other side of the lower part of the sensor body;
A third sensor line inserted into the second sensor forming groove; And
And a fourth sensor line surrounding a periphery of the third sensor line and filling the second sensor forming groove.
The method of claim 2,
A third sensor part formed on a bottom surface of the lower part of the sensor body, extending in the longitudinal direction of the sensor body, and changing a capacitance value or a resistance value by leakage;
A third sensor forming groove formed on a bottom surface of the lower portion of the sensor body;
A fifth sensor line inserted into the third sensor forming groove; And
And a sixth sensor line surrounding a periphery of the fifth sensor line and filling the third sensor forming groove.
The method of claim 3,
A first sealing part provided on one side of the lower part of the sensor body such that the second sensor line of the first sensor part is partially exposed to the outside;
A second sealing part provided on the other side of the lower part of the sensor body such that the fourth sensor line of the second sensor part is partially exposed to the outside; And
And a third sealing part provided on a bottom surface of the lower part of the sensor body such that the sixth sensor line of the third sensor part is partially exposed to the outside.
The method of claim 4, wherein
The first sealing part, the second sealing part, and the third sealing part are made of an insulating material, and the second sensor line, the fourth sensor line, and the sixth sensor line are locally exposed at regular intervals along the longitudinal direction of the sensor body. Hybrid leak detection sensor with a pattern to make it possible.
The method of claim 3,
The first sensor line, the third sensor line, and the fifth sensor line are made of core wire, copper wire, or braided wire, and the second sensor line, the fourth sensor line, and the sixth sensor line mix resin, adhesive, and conductive ink. Combination leak detection sensor made of one material.
A sensor body extending a predetermined length along a longitudinal direction, the upper width of the sensor body being made relatively larger than the lower width, and formed of an insulating resin;
A sensor unit extending to both side surfaces of the lower part of the sensor body along a length direction of the sensor body, wherein the capacitance value or the resistance value changes due to leakage;
A conductive common line formed along a longitudinal direction in a groove formed in a lower center of the sensor body;
A sealing part for insulating sealing the sensor part so that the sensor part is partially exposed to the outside; And
Hybrid leak detection sensor including a wire buried in the upper center of the sensor body along the longitudinal direction of the sensor body.
A predetermined length extending in a longitudinal direction, the sensor body made of an insulating resin;
A groove formed on the bottom surface of the sensor body along a length direction and having a lower width than an upper portion thereof;
Sensor parts each extending on both sides of the groove part along a length direction of the sensor body, and the capacitance value or the resistance value is changed by leakage;
A sealing part for insulating sealing the sensor part so that the sensor part is partially exposed to the outside; And
And a wire embedded in the sensor body above the groove along the longitudinal direction of the sensor body.
The method according to claim 7 or 8,
The wire is disposed adjacent to the groove so that a portion is exposed to the outside, the composite leakage detection sensor is injected or applied to the conductive material around the wire.
A predetermined length extending in a longitudinal direction, the sensor body made of an insulating resin;
A pair of protrusions formed side by side spaced apart from each other on the bottom surface of the sensor body in the longitudinal direction of the sensor body;
A first sensor line formed on an outer side of one of the pair of protrusions on a bottom surface of the sensor body along a longitudinal direction of the sensor body, the capacitance value or resistance value being changed by leakage;
A second sensor line formed on an outer side of the other of the pair of protrusions on a bottom surface of the sensor body along a length direction of the sensor body, and the capacitance value or the resistance value changed by leakage;
A common line formed between the pair of protrusions along a length direction of the sensor body;
A wire embedded in the center of the sensor body along a length direction of the sensor body; And
And a sealing part to insulate and seal the first sensor line and the second sensor line to be partially exposed to the outside.
A predetermined length extending in a longitudinal direction, the sensor body made of an insulating resin;
A pair of grooves formed side by side spaced apart from each other on the bottom surface of the sensor body along the longitudinal direction of the sensor body;
A first sensor line formed in one of the pair of grooves on a bottom surface of the sensor body along a length direction of the sensor body, and the capacitance value or the resistance value changed due to leakage;
A second sensor line formed in the other one of the pair of grooves on the bottom surface of the sensor body along a longitudinal direction of the sensor body, the capacitance value or resistance value being changed by leakage;
A common line formed between the pair of grooves along a length direction of the sensor body;
A wire embedded in the center of the sensor body along a length direction of the sensor body; And
And a sealing part to insulate and seal the first sensor line and the second sensor line to be partially exposed to the outside.
The method according to claim 10 or 11,
And a controller for detecting leakage based on a change in resistance value and capacitance value between the first sensor line and the common line, and a change in resistance value and capacitance value between the second sensor line and the common line.
The controller compares the resistance value and the capacitance value change between the first sensor line and the common line with a previously input reference value to discriminate whether the leaked liquid is water, chemicals or oils.
The controller compares the resistance value and the capacitance value change between the second sensor line and the common line with a pre-input reference value to discriminate whether the leaked liquid is water, chemicals, or oil, and then, first and second. Complex leak detection sensor that determines the leaked liquid by comparing the difference results.

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