KR102657645B1 - Leakage detection sensor and method using the same - Google Patents

Abstract

The present invention has the following structure.
The lower sensor is divided into a first lower sensor and a second lower sensor.
The first lower sensor has two signal lines connected,
It consists of the second lower sensor to which two signal lines symmetrical to the first lower sensor are connected, and the upper sensor to connect signal lines of each of the first lower sensor and the second lower sensor, It is configured to combine and insert the first lower sensor, the second lower sensor, and the upper sensor so that the first lower sensor and the second lower sensor are not separated by an external lateral force, and the lower sensor is directed downward. Arrange so that
The upper sensor is arranged to face upward, and the lower part of the outer surface is configured to extend to the outer periphery. When receiving pressure from liquid leaking from the lower sensor, the upper sensor is separated from the lower sensor to cause a disconnection. It relates to a sensor enclosure, characterized in that it is configured.

Description

Leakage detection sensor and method using the same}

The present invention relates to a water leak detection sensor, and more specifically to a sensor enclosure, cushioning cover, and protective cover.

The water leak detection sensor of the background technology is shown in Figure 9 and may include a base part 10, a conductive line 20, a cover part 30, and a double-sided adhesive tape 50.

The water leak detection sensor includes a base portion 10, a conductive line 20 arranged in pairs on the upper surface of the base portion 10, a cover portion 30 located above the conductive line 20, and the cover portion. It includes a plurality of sensing holes 40 located at 30, and the conductive line 20 may include a coating layer applied to the surface of the conductive line 20 to prevent corrosion and malfunction.

The conductive lines 20 include two main conductive lines 21 arranged in the longitudinal direction of the base portion 10, and a plurality of sub-conductive lines 22 protruding from each main conductive line 21. may include.

The conductive lines 20 include two main conductive lines 21 arranged symmetrically in the longitudinal direction of the base portion 10, and two main conductive lines 21 arranged symmetrically, respectively. It includes a plurality of sub-conductive lines 22 protruding from the main conductive line 21, and the two base portions 10 are layers on which conductive lines 20, which will be described later, are disposed and may be made of an insulator.

The conductive lines 20 are conductors disposed in pairs on the upper surface of the base portion 10, and in the event of water leakage when electricity flows, they may short-circuit and serve to determine whether there is water leakage.

The conductive line 20 may include a main conductive line 21 and a sub-conductive line 22.

Two main conductive lines 21 are arranged in the longitudinal direction of the base portion 10 described above, and one end of the two main conductive lines 21 is connected with a conductor, etc., so that current can flow. For example, as can be seen in the example of FIG. 9, two main leading lines 21 may be positioned symmetrically to each other in the longitudinal direction of the base portion 100.

The sub-conductive line 22 is formed to protrude from the main conductive line 21, and a plurality of sub-conductive lines 22 can be disposed to more accurately and quickly detect water leaks. The sub-conductive line 22 may protrude inside the symmetrically arranged main conductive line 21.

The sub-conductive line 22 is arranged so that the sub-conductive line 22 protruding from the main conductive line 21 on one side and the sub-conductive line 22 protruding from the main conductive line 21 on the other side are alternately arranged one by one. It may protrude. The crossing pattern of the non-conductive lines (22) narrows the gap between the pair of conductive lines (200) so that even water leakage or a small amount of water flowing through only one conductive line (20) can be more easily detected by the non-conductive lines (22) on both sides. This can make water leak detection possible. Additionally, the crossing pattern of the non-conductive line 22 can serve to more accurately determine the location of water leakage passing through a single sensing hole 40, which will be described later.

The coating layer is applied to the surface of the conductive line 20 and can play a role in preventing corrosion and malfunction of the water leak detection sensor. If the conductive line 20 is not coated, it reacts sensitively to humidity, metal, metallic dust, or contact with the human body, and may malfunction due to water leakage even if it is not an actual water leak. Therefore, the coating layer plays a role in preventing this. You can.

In addition, the coating layer can prevent corrosion of the conductive line 20 from water leakage or humidity, protect the conductive line 20, and strengthen the durability of the conductive line 20.

However, the above-described configuration has disadvantages such as having to wind all of the pipe joints, complex configuration, poor workability, high cost, and low accuracy. The present invention was invented to solve such shortcomings.

Korea Intellectual Property Office Patent Registration No. 10-1074337 (2011.10.17) Korea Intellectual Property Office Patent Publication No. 10-2015-0136644 (2015.12.08) Korea Intellectual Property Office Patent Registration No. 10-1610053 (2016.04.07) Korea Intellectual Property Office Patent Publication No. 10-2008-0056531 (2008.06.23)

The first problem that the invention seeks to solve is to configure a check valve in the protective cover and a buffer inside the protective cover to insert the sensor enclosure, thereby achieving a sealing effect and a water leak detection sensor in the sensor enclosure formed in the cushioning material when receiving pressure due to leakage. The problem of immediately disconnecting the signal line was solved.

The second problem that the invention aims to solve is to solve the problem of increasing the accuracy and speed of work by connecting signal lines by connecting signal lines only by inserting them into each other without performing additional work to connect signal lines at the work site.

The third problem that the invention aims to solve is to configure the leaking liquid to apply pressure only from the lower sensor to the upper sensor, so that the point where the sensor is disconnected can be confirmed immediately after leakage, thereby minimizing damage due to leakage at pipe joints. It is about solving tasks that can be accomplished.

In order to solve the above problems, it has the following configuration.

lower sensor;

The lower sensor is divided into a first lower sensor and a second lower sensor,

The first lower sensor has two signal lines connected,

It consists of the second lower sensor connected to two signal lines symmetrical to the first lower sensor,

It consists of the upper sensor connecting signal lines of each of the first lower sensor and the second lower sensor,

It is configured to combine and insert the first lower sensor, the second lower sensor, and the upper sensor so that the first lower sensor and the second lower sensor are not separated by an external lateral force,

The lower sensor is arranged to face downward,

The upper sensor is arranged to face upward,

The lower part of the outer surface is configured to extend to the outer periphery,

It has a sensor housing portion configured to separate the upper sensor from the lower sensor and cause a disconnection when receiving pressure from liquid leaking from the lower sensor.

Here, the case combining the second lower sensor constitutes a coupling iron portion,

It is preferable that the case for coupling the first lower sensor is configured with coupling recesses so that they can be coupled to each other.

Here, each of the two signal lines disposed in the first lower sensor and the second lower sensor constitutes a signal 1 line terminal and a signal 2 line terminal at the end portion, respectively,

The upper sensor is configured to be inserted into the signal 1-line terminal and the signal 2-line terminal to correspond to the signal 1-line terminal and the signal 2-line terminal, thereby forming and combining the signal 1-line connection terminal and the signal 2-line connection terminal, respectively. Therefore, it is desirable to configure each signal line to be connected.

Here, the first lower sensor and the second lower sensor constitute an empty space of the first lower sensor liquid insertion portion and the second lower sensor liquid insertion portion, respectively, and the upper sensor is separated from the lower sensor by the pressure of the liquid being inserted. It is desirable to configure it so that there is a single line.

Here, the wall is configured to be tapered from the top to the bottom to prevent the lower sensor from moving to the bottom,

It is desirable to configure the top and bottom to be open.

A sensor enclosure insertion part is formed on the inner wall of the cover part, which is configured to detect water leakage from the sensor enclosure part of the preceding clause at the pipe joint,

Insert the sensor enclosure into the sensor enclosure insertion part,

The lower part of the sensor enclosure is configured to face inward,

The upper part of the sensor enclosure is configured to face outward,

When a water leak occurs at the pipe joint, the cushioning material cover is configured so that the upper sensor is separated from the lower sensor due to the pressure of the water leak, resulting in a disconnection.

It is configured on the outside of the cushioning material to protect the cushioning material cover on top of the cushioning material cover,

It has a protective cover forming a check valve insertion hole to form a check valve.

Here, the sensor housing formed in the cushioning cover allows liquid leaked from the pipe joint to pass through the lower sensor and apply pressure to the upper sensor, causing the upper sensor to separate from the lower sensor,

The leaked liquid causes the check valve configured outside the cushioning cover to open, and has a protective cover configured to open the check valve insertion hole when a certain pressure is applied to the check valve from the outside of the cushioning material cover.

The method of constructing the water leak detection sensor in the protective cover is as follows.

The water leak detection sensor is composed of an upper sensor and a lower sensor.

The lower sensor is divided into a first lower sensor and a second lower sensor,

A lower sensor combining step of combining the first lower sensor and the second lower sensor;

An upper and lower sensor combining step of combining with the upper sensor to connect signal lines of the first lower sensor and the second lower sensor, respectively;

A sensor housing unit insertion step of inserting the upper sensor configured to connect signal lines of the first lower sensor and the second lower sensor, respectively, into the sensor housing unit;

The lower part of the sensor enclosure is configured to expand in the outer peripheral direction, and the inner surface of the sensor enclosure is configured to be tapered from the top to the bottom and is coupled to the sensor enclosure insertion part of the cushioning cover,

A cushioning material cover coupling step of inserting the lower sensor so that it faces the inner direction of the cushioning material cover and the upper sensor faces the outer direction of the cushioning material cover formed at the pipe joint;

After the leakage pressure from the lower sensor in the cushioning material cover separates the upper sensor, it includes a check valve coupling step of engaging the check valve insertion hole portion of the protective cover configured to direct the leaked pressure to the outside through the check valve. It has a water leak detection sensor coupling method that inserts the water leak detection sensor into the sensor box and connects the cushioning cover and check valve to the protective cover.

The first effect of the invention is to configure a check valve in the protective cover and a cushioning material cover inside the protective cover to insert the sensor enclosure, thereby achieving a sealing effect and a water leak detection sensor in the sensor enclosure formed in the cushioning material cover when subjected to pressure due to leakage. This has the effect of immediately disconnecting the signal line.

The second effect of the invention is to increase the accuracy of connection of signal lines and the speed of work by connecting signal lines only by inserting them into each other without performing additional work to connect signal lines at the work site.

The third effect of the invention is that the leaking liquid is configured to apply pressure only from the lower sensor to the upper sensor, so that the point where the sensor is disconnected can be confirmed immediately upon leakage, thereby minimizing damage due to leakage of pipe joints. It works.

Figure 1a is a diagram showing that the lower sensors are spaced apart from each other.
Figure 1b is a diagram showing the first lower sensor and the second lower sensor being combined with each other.
Figure 2 is a diagram showing an upper sensor configured to be connected to signal terminals in the first lower sensor and the second lower sensor, respectively.
Figure 3a is a view of the sensor enclosure.
Figure 3b is a view showing the side of the sensor enclosure.
Figure 4a is a diagram showing the lower detection sensor inserted into the sensor housing.
Figure 4b is a view showing the back side of Figure 4a.
Figure 4c is a diagram showing the upper sensor combined with Figure 4a.
Figure 5a is a view showing the upper shock absorber cover.
Figure 5b is a diagram showing the lower shock absorber cover.
Figure 6a is a diagram showing pipes and pipe joints.
Figure 6b is a diagram showing the protective cover surrounding the cushioning cover.
Figure 6c is a diagram showing the protective cover.
Figure 6d is a diagram showing the sensor housing part inserted into the cushioning cover and the check valve inserted into the protective cover.
Figure 6e shows a state in which packing material is attached to the part of the protective cover that contacts the surface of the pipe to make it watertight.
Figure 7a is a diagram showing the appearance of the check valve.
Figure 7b is a view showing the upper surface of the check valve.
Figure 7c is a view showing the lower surface of the check valve.
Figure 8 is a diagram showing how to attach a water leak detection sensor to a pipe joint.
Figure 9 is a diagram that serves as background technology.

If explained in detail with reference to FIGS. 1A to 2, it is as follows.

The water leak detection sensor means combining the first lower sensor 100 and the second lower sensor 200, and combining the upper sensor 300 at the top.

The lower sensor means that the first lower sensor 100 and the second lower sensor 200 are combined.

The lower sensor is divided into a first lower sensor 100 and a second lower sensor 200.

The first lower sensor 100 is connected to two signal lines.

It consists of the second lower sensor 200, in which two signal lines symmetrical to the first lower sensor 100 are connected.

A water leak detection sensor is configured with the upper sensor 300 connecting the respective signal lines of the first lower sensor 100 and the second lower sensor 200.

According to the right side view of Figure 1a, the case combining the second lower sensor 200 constitutes coupling iron parts 230 and 240.

According to the left view of Figure 1a, it is preferable that the case for coupling the first lower sensor 100 is composed of coupling recesses 130 and 140 so that they are coupled to each other.

Between the coupling iron portions 230 and 240 and the coupling recessed portions 130 and 140, an interference fit method or a degree of preventing them from moving up and down is sufficient.

The first lower sensor 100 and the second lower sensor 200 are combined with the upper sensor 300 to connect a signal line,

Here, the two signal lines disposed in the first lower sensor 100 and the second lower sensor 200 form first signal line terminals 115 and 215 and second signal line terminals 125 and 225, respectively, at the end portions.

The upper sensor 300 has a configuration corresponding to the signal 1 wire terminal (115,215) and the signal 2 wire terminal (125,225). It consists of

In this configuration, it is preferable to configure and combine the signal 1-line connection terminals 315a and 315b and the signal 2-line connection terminals 325a and 325b, respectively, so that each signal line is connected.

As shown in the drawing, the signal 1-line connection terminals 315a and 315b are connected in an approximately U-shape, thereby connecting signal 1-line terminals 115 and 215.

As shown in the drawing, the signal 2-wire connection terminals 325a and 325b are connected in an approximately U-shape, thereby connecting the signal 2-wire terminals 125 and 225.

The upper sensor is connected to signal wires (315, 325) leading to each terminal to connect the signal wires of the lower sensor.

Instead of performing additional work to connect signal lines at a work site, the signal lines are connected simply by inserting them into each other, thereby increasing the accuracy of signal line connection and the speed of work.

Here, the lower sensor and the upper sensor 300, which are composed of the first lower sensor and the second lower sensor by the coupling recesses 130 and 140 and the coupling iron parts 230 and 240, are configured to be separated by the expansion pressure of the leaking liquid. desirable.

The expansion pressure of the leaking liquid is determined by the first lower sensor 100 and the second lower sensor 200 using the empty space of the first lower sensor liquid insertion portions 152 and 154 and the second lower sensor liquid insertion portions 252 and 254, respectively. It is configured to apply a force to separate the upper sensor configured at the top from the lower sensor by the pressure of the liquid being inserted, so that the upper sensor and the lower sensor are separated by the pressure of the liquid and are disconnected. As a result, the fact that fluid is leaking from the pipe joint is confirmed on the server, and the location of the accident is confirmed as soon as fluid leakage occurs, allowing for lateral follow-up measures.

So far, the water leak detection sensor has been explained.

3A to 7C, the water leak detection sensor is inserted into the sensor enclosure 400 and inserted into the sensor enclosure insertion part 715 formed on the inner circumferential surface of the cushioning cover 700 formed at the pipe joint. will be.

The protective cover 500 is sealed with a sealing member 540 so as to be in close contact with the cushioning material cover 700 and the outer surface of the pipe 800, so that liquid leaking from the pipe joint 810 must be removed from the lower sensor. The upper sensor 300 formed on the outer periphery of the cushioning cover 700 passes through the empty space of the first lower sensor liquid insertion part 152, 154 and the second lower sensor liquid insertion part 252, 254, and the liquid leaked thereafter is removed. It is configured to flow to the outside of the protective cover 500 through the check valve 600.

The protective cover 500 is configured to prevent moisture from entering from the outside to the inside.

When the upper sensor 300 is combined with the lower sensor, it is configured so that there is no empty space for leakage so that the pressure of the liquid leaking from the bottom of the lower sensor is applied.

That is, it is desirable that the lower sensors 100 and 200 be configured as a space so that leaking liquid flows, and the upper sensor 300 is configured to be watertight so that it receives only the pressure of the corresponding liquid.

The protective cover 500 combines semicircular protective covers 500 with each other to cover the cushioning material cover and the pipe joint.

In the present invention, it is composed of rubber packing or similar properties to make it watertight by screw connection.

The protective cover is bolted through the protective cover coupling bolt hole (550).

The water leak detection sensor configured in this way is configured to prevent the first lower sensor 100 and the second lower sensor 200 from being separated by an external lateral force. ) and a sensor housing unit 400 configured to couple and insert the upper sensor 300.

The sensor housing part has a wall that is tapered from the top to the bottom to prevent the lower sensor from falling off to the bottom, but the upper and lower parts are open. The lower sensor may also be configured in a tapered shape.

Constructed in this way, the sensor enclosure part 400 is inserted into the sensor enclosure insertion part 715 formed on the inner surface of the cushioning material cover, so it can be configured to be spaced to some extent from the pipe joint part 810, so that the lower sensor exerts downward force. It is necessary to configure it so that the lower sensor does not come off.

The cushioning cover 700 is required to be watertight from the pipe around the pipe joint 810.

That is, the lower part of the sensor enclosure 400 is attached to the sensor enclosure insertion part 715 of the cushioning cover 700, and the liquid (water, oil, chemicals, etc.) flowing out from the pipe joint 810 is exposed to pressure. When a force is applied to separate the upper sensor 300 from the lower sensor, the upper sensor 300 is located in the sensor housing insertion portion 715 of the cushioning cover 700. The upper sensor 300 is sufficiently separated. It is configured to have a sufficient separation distance between the inserted surface and the inner surface of the protective cover 500 surrounding the cushioning cover 700 to separate the upper sensor 300 so that it becomes a single line.

The sensor housing portion 400 is configured in the shape of a square pillar with the upper and lower portions open to insert the water leak detection sensor. It is inserted into the sensor housing insertion portion 715 of the cushioning material cover 700 and protects the cushioning material cover 700. The protective cover 500 is configured to secure a space for the check valve 600.

Here, after the lower sensor and the upper sensor 300 are combined and inserted into the sensor enclosure 400, they are configured to be attached to the sensor enclosure insertion part 715 of the cushioning cover 700, which is configured to detect water leakage, to prevent water leakage. Configure it to detect.

The cushioning cover 700 is composed of an upper cushioning cover 710 and a lower cushioning cover 720 and is combined.

A protective cover 500 is provided on the outside of the cushioning cover 700.

The inner diameter of the protective cover is smaller than the diameter of the outer cover of the cushioning material cover.

By configuring the cushioning cover to be more compact and tight, the cushioning material cover can be configured to be better watertight from the area around the pipe joint 810.

The protective cover 500 is also configured closely to the pipe 800 to require watertightness.

Here, it is desirable to provide a check valve insertion hole 510 in the protective cover 500 to form the check valve 600.

Check valve insertion hole portions 510 are formed on the inner peripheral surface of the protective cover 500, respectively.

Here, the sensor housing unit 400 allows the liquid from the pipe joint 810 to pass through the lower sensor and apply pressure to the upper sensor 300, causing the upper sensor 300 to separate from the lower sensor and leaking liquid. It is desirable to have a protective cover 500 that opens the check valve 600 formed in the protective cover 500 to prevent water from flowing in from the outside and opens when a certain pressure is applied from the inside to the outside.

When explained with reference to FIGS. 7A to 7C, it is as follows.

Corresponding to the check valve 600 of the present invention, the nozzle part 610 is a part inserted into the check valve insertion hole 510 of the protective cover.

The lower check valve 620, corresponding to the lower part of the check valve, is configured toward the inner surface, so that when the internal pressure of the protective cover reaches a certain level, the leaked liquid that escapes the upper sensor 300 is moved to the lower check valve 620. ) and when a certain pressure or more is applied to the liquid flow unit 630, the leaked liquid flows to the outside.

This configuration prevents external water pressure from flowing inside.

Another embodiment has the following method.

The water leak detection sensor is composed of an upper sensor 300 and a lower sensor.

The lower sensor is divided into a first lower sensor 100 and a second lower sensor 200.

There is a lower sensor combining step (S100) of combining the first lower sensor 100 and the second lower sensor 200.

There is an upper and lower sensor combining step (S200) of combining the upper sensor 300 to connect the signal lines of the first lower sensor 100 and the second lower sensor 200, respectively.

The sensor housing unit 400 insertion step (S300) of inserting the upper sensor 300, which is configured to connect the signal lines of the first lower sensor 100 and the second lower sensor 200, into the sensor housing unit 400. ) has.

The lower part of the sensor enclosure 400 is expanded to the outer peripheral edge of the enclosure 410, and the inner surface of the sensor enclosure 400 is configured to be tapered from the top to the bottom, so that the sensor enclosure of the cushioning material cover 700 is formed. It is coupled to the insertion portion (715).

The lower sensor is directed toward the inside of the cushion cover 700 and the upper sensor 300 is inserted toward the outside of the cushion cover 700 formed on the pipe joint 810 (S400). ) has.

A check of the protection cover 500 configured to direct the leaked pressure to the outside through the check valve 600 after the leakage pressure from the lower sensor in the cushion cover 700 separates the upper sensor 300. It has a water leak detection sensor coupling method that combines the water leak detection sensor, including the check valve coupling step (S500) coupled with the valve insertion hole portion 510, to the cushioning material cover 700 and the check valve 600 to the protective cover 500. .

Terms or words used in this specification and claims should not be construed as limited to their common or dictionary meanings, and the inventor may appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted with meaning and concept consistent with the technical idea of the present invention based on the principle that it is.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so at the time of filing this application, they can be replaced. It should be understood that various equivalents and variations may exist.

100: 1st lower sensor 110,210: 1 signal line 115,215: 1 signal line terminal
130,140: Coupling part 152,154: First lower sensor liquid insertion part
200: 2nd lower sensor 120,220: 2 signal wires 125,225: 2 signal wire terminals
230,240: Coupling iron part 252,254: Second lower sensor liquid insertion part
300: Upper sensor 315,325: Signal connection line
315a, 315b: 1-line signal connection terminal 325a, 325b: 2-line signal connection terminal
400: Sensor enclosure 410: Outer peripheral edge of enclosure
500: Protective cover 510: Check valve insertion hole 540: Sealing member
550: Protective cover combination bolt hole
600: Check valve 610: Nozzle part 620: Check valve lower part 630: Liquid flow passage
700: Cushioning material cover 710: Upper cushioning material cover 715: Sensor enclosure insertion part
720: Lower cushion cover 800: Pipe 810: Pipe joint

Claims (9)

lower sensor;
The lower sensor is divided into a first lower sensor and a second lower sensor,
The first lower sensor has two signal lines connected,
It consists of the second lower sensor connected to two signal lines symmetrical to the first lower sensor,
It consists of an upper sensor connecting signal lines of each of the first lower sensor and the second lower sensor,
The first lower sensor, the second lower sensor, and the upper sensor are configured to be combined and inserted into the sensor housing unit so that the first lower sensor and the second lower sensor are not separated by an external lateral force,
The lower sensor is arranged to face the lower part of the sensor housing,
The upper sensor is arranged to face the upper part of the sensor housing,
The lower part of the outer surface of the sensor enclosure is configured to extend to the outer periphery,
A water leak detection sensor, characterized in that the upper sensor is separated from the lower sensor to cause a disconnection when receiving pressure from liquid leaking from the lower sensor. The method of claim 1, wherein the case for coupling the second lower sensor constitutes a coupling iron portion,
A water leak detection sensor, characterized in that the case for combining the first lower sensor is composed of a coupling recess and configured to be coupled to each other. The method of claim 1, wherein each of the two signal lines disposed in the first lower sensor and the second lower sensor constitutes a first signal line terminal and a second signal line terminal at the end portions, respectively,
The upper sensor is configured to be inserted into the signal 1-line terminal and the signal 2-line terminal to correspond to the signal 1-line terminal and the signal 2-line terminal, thereby forming and combining the signal 1-line connection terminal and the signal 2-line connection terminal, respectively. A water leak detection sensor characterized in that it is configured so that each signal line is connected. The method of claim 1, wherein the first lower sensor and the second lower sensor constitute an empty space of the first lower sensor liquid insertion portion and the second lower sensor liquid insertion portion, respectively, and the upper sensor is activated by the pressure of the liquid being inserted. A water leak detection sensor characterized in that it is configured to separate from the lower sensor and become disconnected. The method of claim 1, wherein the sensor housing unit has a wall surface tapered from the top to the bottom to prevent the lower sensor from deviating to the bottom,
A water leak detection sensor characterized in that the upper and lower portions are open. The method according to any one of claims 1 to 5, wherein the sensor enclosure is configured to insert a sensor enclosure insert into the inner wall of the cushioning cover configured to detect water leakage at the pipe joint,
Insert the sensor enclosure into the sensor enclosure insertion part,
The lower part of the sensor housing portion is configured to face the inside of the cushioning material cover,
The upper part of the sensor enclosure is configured to face the outside of the cushioning material cover,
A water leak detection sensor, characterized in that when a water leak occurs at the pipe joint, the upper sensor is separated from the lower sensor due to the pressure of the water leak, resulting in a disconnection. The method of claim 6, wherein a protective cover is provided on the outside of the cushioning cover to protect the cushioning material cover,
A water leak detection sensor, characterized in that the check valve insertion hole is configured to configure a check valve in the protective cover. The method of claim 6, wherein the sensor housing formed in the cushioning cover allows liquid leaked from the pipe joint to pass through the lower sensor and apply pressure to the upper sensor, causing the upper sensor to separate from the lower sensor,
The leaked liquid causes the check valve configured on the outside of the cushioning cover to open, forming a protective cover on the outside of the cushioning cover, and a check valve on the protective cover to have a configuration that opens when a certain pressure is applied to the check valve. A water leak detection sensor characterized by forming an insertion hole. The water leak detection sensor is composed of an upper sensor and a lower sensor.
The lower sensor is divided into a first lower sensor and a second lower sensor,
A lower sensor combining step of combining the first lower sensor and the second lower sensor;
An upper and lower sensor combining step of combining with the upper sensor to connect signal lines of the first lower sensor and the second lower sensor, respectively;
A sensor housing unit insertion step of inserting the upper sensor configured to connect signal lines of the first lower sensor and the second lower sensor, respectively, into the sensor housing unit;
The lower part of the sensor enclosure is configured to expand in the outer peripheral direction, and the inner surface of the sensor enclosure is configured to be tapered from the top to the bottom and is coupled to the sensor enclosure insertion part of the cushioning cover,
A cushioning material cover coupling step of inserting the lower sensor so that it faces the inner direction of the cushioning material cover and the upper sensor faces the outer direction of the cushioning material cover formed at the pipe joint;
After the leakage pressure from the lower sensor in the cushioning material cover separates the upper sensor, it includes a check valve coupling step of engaging the check valve insertion hole portion of the protective cover configured to direct the leaked pressure to the outside through the check valve. A water leak detection sensor combination method that combines a water leak detection sensor with a cushioning cover and a check valve with a protective cover.