KR102366015B1 - Leak blocking system - Google Patents

Abstract

A water leakage blocking system, which can supply water to a water purification system through a bypass pipe when water leakage has occurred in a water purification pipe, includes: a water purification pipe that supplies water supplied from a raw water line to a water purification system; a sensing portion that is installed on the water purification pipe to sense a hydraulic pressure and flow rate of the water supplied to the water purification system; a water leakage determination device that determines water leakage that has occurred in the water purification pipe when at least one of the hydraulic pressure and the flow rate is less than each reference value; a bypass pipe that supplies the water supplied from the raw water line to the water purification system when the water leakage has occurred; and a bypass valve that includes a first conduit, a second conduit, and a third conduit, in which the water purification pipe is connected to the first conduit, the raw water line is connected to the second conduit, and the bypass pipe is connected to the third conduit, and performs an opening/closing operation of the first to third conduits when the water leakage has occurred.

Description

Leak blocking system

The present invention relates to a leak containment system.

Unless otherwise indicated herein, the contents described in this identification are not prior art to the claims of this application, and the description in this identification is not admitted to be prior art.

In general, a water purification system receives tap water supplied from a raw water line, purifies it through a filter, and then provides cold water or hot water to a user by a system provided therein. In order to supply water from the raw water line to such a water purification system, a water purification pipe is installed.

The water purification pipe supplies water to the water purification system from the raw water lines installed in households as well as multi-use facilities or business offices (restaurants, coffee shops, etc.). Therefore, when a water leak occurs in the purified water pipe, the water rate increases due to the water leak, and there is a problem that water seeps into the room. Furthermore, when external pollutants flow into the water purification pipe, the water supplied to the water purification system is contaminated.

In particular, when the distance from the raw water line to a specific location where the water purification system is installed is long, such as in a restaurant, the length of the water purification pipe is also relatively long, and it is often installed hidden along a duct or ceiling on the floor.

Therefore, as the length increases, the possibility of leakage in each part of the purified water pipe increases, but it is difficult to detect it at the beginning, and there is a problem that water supply cannot be automatically stopped while the damage is very large.

An object of the present invention is to provide a leak blocking system capable of supplying water to a water purification system through a bypass pipe when a water leak occurs in a purified water pipe.

In addition, an object of the present invention is to provide a leak blocking system capable of determining whether a leak has occurred.

In addition, an object of the present invention is to provide a leak blocking system capable of determining the point of occurrence of a leak.

A water leakage blocking system according to the present invention includes: a water purification pipe for supplying water supplied from a raw water line to the water purification system; a sensing unit installed in the water purification pipe to sense the hydraulic pressure and flow rate of water supplied to the water purification system; a water leak determination device for determining that the water leak has occurred in the purified water pipe when at least one of the hydraulic pressure and the flow rate is smaller than each reference value; a bypass pipe for supplying water supplied from the raw water line to the water purification system when the leakage occurs; and a first conduit, a second conduit, and a third conduit, wherein the purified water pipe is connected to the first conduit, the raw water line is connected to the second conduit, and the bypass pipe is connected to the third conduit. is connected, and a bypass valve that performs an opening/closing operation of the first to third pipelines to supply water to the water purification system through the bypass pipe when water leakage occurs.

According to the present invention, when a water leak occurs in the purified water pipe, water can be supplied to the water purification system through the bypass pipe, so that water can be continuously supplied and the water leakage occurring in the purified water pipe can be blocked.

In addition, the present invention has an effect that it is possible to determine whether a water leak has occurred, so that even if a minute leak occurs that an administrator cannot check, it is possible to quickly take action.

In addition, since the present invention can determine the point of occurrence of a leak, there is an effect that even a complexly arranged purified water pipe can be easily replaced.

1 is a view showing a leak blocking system according to an embodiment of the present invention.
2 is a view showing the configuration of the water leak determination device 130 according to an embodiment of the present invention.
3 is a view showing an example of a coupling portion and a bypass pipe according to the present invention.
4 is a view showing an example of a locking protrusion formed in the coupling portion.

In the present specification, it should be noted that, in adding reference numbers to the components of each drawing, the same numbers are provided to the same components as possible even though they are indicated on different drawings.

On the other hand, the meaning of the terms described in this specification should be understood as follows. The singular expression is to be understood as including the plural expression unless the context clearly defines otherwise, and the terms "first", "second", etc. are used to distinguish one element from another, The scope of rights should not be limited by these terms. It should be understood that terms such as “comprise” or “have” do not preclude the possibility of addition or existence of one or more other features or numbers, steps, operations, components, parts, or combinations thereof.

The term “at least one” should be understood to include all possible combinations from one or more related items. For example, “at least one of the first, second, and third items” means the first, second, or third items, respectively, as well as the first, second, and third items, respectively. It means a combination of all items that can be presented from two or more of them.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view showing a leak blocking system according to an embodiment of the present invention. The water leakage blocking system 100 according to the present invention may determine whether water supplied from the raw water line 2 to the water purification system 3 is leaking, and may block the leakage. Here, the raw water line 2 is a line connected to a water supply facility and means a line through which raw water is supplied. The water purification system 3 refers to a system for purifying raw water supplied from the raw water line 2 .

To this end, the water leak blocking system 100 is as shown in FIG. 1 , the purified water pipe 110 , the sensing unit 120 , the water leak determination device 130 , the bypass pipe 140 , the bypass valve 150 , and the remote It includes a management server 160 , and a user terminal 170 .

The purified water pipe 110 is a pipe for supplying water supplied from the raw water line 2 to the water purification system 3 . The purified water pipe 110 supplies water from the raw water line 2 to the purified water system 3 through the bypass valve 150 . One end of the purified water pipe 110 is connected to the first pipe line of the bypass valve 150 , and the other end of the purified water pipe 110 is connected to the water purification system. The purified water pipe 110 receives water from the raw water line 2 connected to the second pipe line of the bypass valve 150 and supplies it to the water purification system 3 .

The purified water pipe 110 includes a plurality of joints and a plurality of connecting pipes. Accordingly, the water purification pipe 110 can be repaired for water leakage by replacing the joint or connecting pipe at the point where the water leak occurs.

The sensing unit 120 senses hydraulic pressure and flow rate. Specifically, the sensing unit 120 is installed in the water purification pipe to sense the hydraulic pressure and flow rate of water supplied to the water purification system (3). To this end, the sensing unit 120 may include a flow rate sensor and a hydraulic pressure sensor.

The sensing unit 120 is installed at the other end of the water purification pipe 110 to sense the hydraulic pressure and flow rate of water supplied to the water purification system 3 .

The reason why the sensing unit 120 according to the present invention senses the hydraulic pressure and flow rate of water is that when a leak occurs, the hydraulic pressure and flow rate are reduced. Accordingly, the present invention determines whether leakage occurs based on the hydraulic pressure and flow rate.

The water leakage determination device 130 determines whether water leakage occurs based on the hydraulic pressure and flow rate sensed by the sensing unit 120 . In addition, when a leak occurs, the leak determination apparatus 130 according to the present invention may determine a point where the leak occurs.

Accordingly, the water leak determination device 130 allows the administrator to immediately check the water leak by determining the water leak that is difficult to visually check. In addition, the water leak determination device 130 determines the leakage point in the purified water pipe 110 composed of a plurality of joints and a plurality of connection pipes, so that the manager can perform maintenance on the water leakage point.

In particular, since the design method of the joint and connection pipe of the purified water pipe 110 varies according to the size or purpose of the building, even an expert related to the plumbing equipment cannot determine the leak or the point of the leak quickly.

However, since the present invention can determine the leak determination and the leak occurrence point through the leak determination device 130 , there is an effect that it is possible to quickly respond to water leakage even by a general rather than an expert.

2 is a view showing the configuration of the water leak determination device 130 according to an embodiment of the present invention.

As shown in FIG. 2 , the water leak determination device 130 includes a water leak determination unit 210 , a first solenoid valve 213 , a storage tank 215 , a second solenoid valve 217 , and a compressed air generator 220 . ), a third solenoid valve 225 , a noise sensor 230 , and a positioning unit 240 .

The water leak determination unit 210 determines that water leakage has occurred in the purified water pipe 110 when at least one of the hydraulic pressure and the flow rate is smaller than the respective reference values. For example, the water leak determination unit 210 determines that water leakage has occurred in the purified water pipe 110 when the hydraulic pressure is less than a predetermined reference oil pressure. The water leak determination unit 210 determines that water leakage has occurred in the purified water pipe 110 when the flow rate is less than a predetermined reference flow rate. The water leak determination unit 210 determines that water leakage has occurred in the purified water pipe 110 when the hydraulic pressure and the flow rate are smaller than the reference oil pressure and the reference flow rate, respectively.

The first solenoid valve 213 connects the water purification line 110 and the water purification system 2 . Accordingly, the other end of the water purification line 110 is connected to the first pipe line of the first solenoid valve 213 , and the water purification system 3 is connected to the second pipe line of the first solenoid valve 213 . When there is no leakage, the first solenoid valve 213 is opened to supply water from the water purification line 110 to the water purification system 3 . When it is determined that there is a leak, the first solenoid valve 213 is closed to block the water supplied from the water purification line 110 to the water purification system 3 .

The storage tank 215 is connected to the water purification pipe 110 through the second solenoid valve 217 . The storage tank 215 stores the water remaining in the purified water pipe 110 when a leak occurs. Specifically, when leakage occurs, the second solenoid valve 217 is opened, and the water remaining in the purified water pipe 110 moves to the storage tank 215 . The storage tank 215 stores the moved water. In one embodiment, the storage tank 215 maintains a negative pressure than the purified water pipe (110). Accordingly, the water remaining in the purified water pipe 110 is guided to the storage tank 215 by the pressure difference.

The second solenoid valve 217 connects the water purification pipe 110 and the storage tank 215 . The water purification pipe 110 is connected to the first pipe line of the second solenoid valve 217 , and the storage tank 215 is connected to the second pipe line of the second solenoid valve 217 . The second solenoid valve 217 is closed if there is no leakage. The second solenoid valve 217 is opened when leakage occurs. Accordingly, the second solenoid valve 217 causes the water remaining in the purified water pipe 110 to be supplied to the storage tank 215 .

The compressed air generating device 220 is connected to the purified water pipe 110 to inject compressed air into the purified water pipe 110 . Specifically, the compressed air generating device 220 is installed on the other side of the purified water pipe 110 and is connected through the third solenoid valve 225 . The compressed air generator 220 injects compressed air into the purified water pipe 110 through the third solenoid valve 225 when leakage occurs.

The third solenoid valve 225 connects the purified water pipe 110 and the compressed air generating device 220 . The purified water pipe 110 is connected to the first pipe line of the third solenoid valve 225 , and the compressed air generator 220 is connected to the second pipe line of the third solenoid valve 225 .

The third solenoid valve 225 is closed when there is no leakage. The third solenoid valve 225 is opened when leakage occurs. Accordingly, the third solenoid valve 225 causes the compressed air injected by the compressed air generating device 220 to be supplied to the purified water pipe 110 .

The noise sensor 230 senses noise. Specifically, the noise sensor 230 senses noise generated by the compressed air sprayed by the compressed air generating device 220 .

When leakage occurs, fine cracks or cracks are generated in the purified water pipe 110 . Accordingly, noise is generated as the compressed air is blown out through minute cracks or cracks.

The positioning unit 240 determines the point where the noise is generated as the point where the water leak occurs. Specifically, the positioning unit 240 determines a point where noise due to leakage of compressed air occurs among a plurality of joints and a plurality of connecting pipes of the purified water pipe 110 as a leak point.

In an embodiment, the positioning unit 240 may assign an identification code to each of a plurality of joints and a plurality of connecting pipes of the purified water pipe 110 . The location determination unit 240 may extract the identification code of the leak point and transmit it to the remote management server 160 .

The bypass pipe 140 supplies the water supplied from the raw water line 2 to the water purification system 3 when a leak occurs. Specifically, the bypass pipe 140 supplies water from the raw water line 2 to the water purification system 3 through the bypass valve 150 . One end of the bypass pipe 140 is connected to the third pipe line of the bypass valve 150 , and the other end of the bypass pipe 140 is connected to the water purification system 3 . The bypass pipe 140 receives water from the raw water line 2 connected to the second pipe line of the bypass valve 150 and supplies it to the water purification system 3 .

The bypass valve 150 causes water supplied to the purified water pipe 110 to be supplied to the bypass pipe 140 when a leak occurs. The bypass valve 150 includes a first conduit, a second conduit, and a third conduit. One end of the purified water line 110 is connected to the first pipe line of the bypass valve 150 . The raw water line 2 is connected to the second pipe line of the bypass valve 150 . One end of the bypass pipe 140 is connected to the third pipe line of the bypass valve 150 .

The bypass valve 150 opens the first conduit and the second conduit when there is no leakage, and closes the third conduit. Accordingly, the bypass valve 150 allows water to be supplied from the raw water line 2 connected to the second pipeline to the purified water pipe 110 connected to the first pipeline.

The bypass valve 150 closes the first conduit and opens the second conduit and the third conduit when it is determined that the water leak has occurred by the water leak determination device 130 . Accordingly, the bypass valve 150 allows water to be supplied from the raw water line 2 connected to the second pipeline to the bypass pipe 140 connected to the first pipeline.

Accordingly, in the present invention, when water leakage occurs, water can be supplied to the bypass pipe 140 through the bypass valve 150 to block the water leakage. In addition, in the present invention, even if water leakage occurs, water can be continuously supplied to the water purification system 3 through the bypass pipe 140 .

In one embodiment, the bypass valve 150 may be a three-way solenoid valve.

It has been described above that the bypass pipe 140 is connected to the bypass valve 150 in advance. However, the bypass pipe 140 according to the present invention may be built in the water purification system 3 . Accordingly, the leak blocking system 100 according to the present invention may further include a moving unit 155 . The moving unit 155 is installed on the bypass pipe 140 to move the bypass pipe 140 . Specifically, when it is determined that water leakage has occurred by the water leak determination device 130 , the moving unit 155 moves the bypass pipe 140 to the third pipe line of the bypass valve 150 .

According to this embodiment, a coupling portion may be formed in the third pipe line of the bypass valve 150 to be coupled to the bypass pipe 140 . 3 is a view showing an example of a coupling portion and a bypass pipe according to the present invention. As shown in FIG. 3 , the coupling portion is formed to extend to the second conduit of the bypass valve 150 . In one embodiment, the coupling part may have a separation groove formed in the longitudinal direction of the coupling part to open according to the insertion of the bypass pipe 140 . A plurality of separation grooves may be formed. A plurality of separation grooves are formed at the end of the coupling part, so that the coupling part opens outward according to the insertion of the bypass pipe.

In one embodiment, the coupling portion may have a locking protrusion formed along the inner circumferential surface. For example, as shown in FIG. 4 , a locking jaw may be formed. According to this embodiment, the bypass pipe 140 may have a locking groove formed at one end inserted into the coupling portion as shown in FIG. 3 . The engaging groove of the bypass pipe 140 is formed along the outer circumferential surface of the bypass pipe 140 . When the locking groove of the bypass pipe 140 is inserted into the coupling part by the moving unit 155, it is coupled with the locking jaw formed along the inner circumferential surface of the coupling part.

The bypass pipe 140 is moved to the third pipe line of the bypass valve 150 by the moving unit 155 and is inserted into the coupling part of the third pipe line. When the bypass pipe 140 is inserted into the coupling part, the coupling part is opened by the separation groove, and the locking groove formed on the outer circumferential surface of the bypass pipe 140 and the locking jaw formed on the inner circumferential surface of the coupling part are coupled. In one embodiment, the locking groove and the locking jaw may be fitted. The locking groove and the locking jaw are fitted together due to the stress generated when the coupling part is opened by the separation groove.

The remote management server 160 receives water leakage information from the water leakage determination device 130 . Here, the leak occurrence information means information indicating that a leak has occurred, and the leak occurrence information may include an identification code of a point where the leak occurs. In an embodiment, the remote management server 160 may provide the user with the identification code received from the leak determination device 130 . For example, the remote management server 160 may provide a blueprint image showing the arrangement of a plurality of joints and a plurality of connecting pipes by marking a joint or connecting pipe mapped to an identification code so that the user can check it.

Accordingly, the user can check the leaked joint or connecting pipe in the design. In this way, the present invention allows to quickly perform countermeasures when a leak occurs.

In an embodiment according to the present invention, the leak blocking system 100 may further include an emergency valve 250 . Here, the emergency valve 250 is installed in the purified water pipe 110 and is installed between the purified water system 3 and the bypass valve 150 so that when an abnormality occurs in the bypass valve 150, the water leaks in the purified water pipe 110 to block In particular, the emergency valve 250 may be installed to be spaced apart by a predetermined distance along the direction in which water flows in the first pipe line of the bypass valve 150 to which the purified water pipe 110 is connected. Here, the emergency valve 250 according to the present invention is preferably installed consecutively with the bypass valve 150 at a point where the bypass valve 150 and the purified water pipe are connected.

The emergency valve 250 maintains an open state when there is no leakage, and water flowing in from the bypass valve 150 passes.

The emergency valve 250 may be controlled by the remote management server 160 .

When it is determined that an abnormality has occurred in the bypass valve 150 , the remote management server 160 may control the emergency valve according to a user input. The remote management server 160 controls the emergency valve 250 to block water leakage occurring in the purified water pipe.

As described above, the present invention primarily blocks water leakage through the bypass valve 150 , and when an abnormality occurs in the bypass valve 150 , secondarily blocks water leakage through the emergency valve 250 , thereby improving system reliability It has the effect of being able to do it.

In an embodiment, the remote management server 160 may close the emergency valve 250 when a request to close the emergency valve is received from the user. Here, the user may generate an emergency valve closing request through the user terminal 170 .

In an embodiment, the remote management server 160 controls the hydraulic pressure and flow rate from the sensing unit 120 when the bypass valve 150 causes water to be supplied to the water purification system 3 through the bypass pipe 140 . When at least one of these is sensed, it may be determined that an abnormality has occurred in the bypass valve 150 . Here, it may be determined that an abnormality has occurred in the opening/closing operation of the bypass valve 150 because the sensing of the hydraulic pressure or the flow rate means that water flows into the purified water pipe 110 . Accordingly, the remote management server 160 according to the present invention determines whether the bypass valve 150 is abnormal according to whether hydraulic pressure or flow rate is sensed.

The remote management server 160 may provide information about occurrence of an abnormality of the bypass valve 150 to the user. Here, the remote management server 160 may provide a message to the user terminal 170 or may provide a notification to an agent, application, program, etc. distributed to the user terminal 170 .

The user terminal 170 according to the present invention may receive a blueprint image from the remote management server 160 . In addition, the user terminal 170 according to the present invention may be provided with abnormal occurrence information of the bypass valve 150 provided from the remote management server 160 .

When the information about the occurrence of abnormality of the bypass valve 150 is received, the user terminal 170 provides it to the user. The user terminal 170 receives the user's input and transmits the user's input to the remote management server 160 . When receiving an input for closing the emergency valve 250 from the user, the user terminal 170 generates an emergency valve closing request. The user terminal 170 transmits an emergency valve closing request to the remote management server 160 .

In this case, the user terminal 170 may have a connection means such as an application, program, or agent distributed from the remote management server 160 may be installed. The user terminal 170 may access the remote management server 160 through an access means. Also, the user terminal 170 may access the remote management server 160 through the Internet.

Here, the user terminal 170 may include a PC, a laptop computer, a smart phone, a tablet PC, and the like, and refers to a terminal capable of Internet browsing and access through a wired/wireless network.

Although preferred embodiments of the present invention have been described with reference to the accompanying drawings, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and represent all of the technical spirit of the present invention. Therefore, it should be understood that there may be various equivalents and modifications that can be substituted for them at the time of filing the present application. Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and their All changes or modifications derived from the concept of equivalents should be construed as being included in the scope of the present invention.

Claims (10)

a water purification pipe for supplying water supplied from the raw water line to the water purification system;
a sensing unit installed in the water purification pipe to sense the hydraulic pressure and flow rate of water supplied to the water purification system;
a water leak determination device for determining that a water leak has occurred in the purified water pipe when at least one of the hydraulic pressure and the flow rate is smaller than each reference value;
a bypass pipe for supplying water supplied from the raw water line to the water purification system when the leakage occurs; and
a first conduit, a second conduit, and a third conduit, wherein the purified water pipe is connected to the first conduit, the raw water line is connected to the second conduit, and the bypass pipe is provided in the third conduit a bypass valve that is connected and performs an opening/closing operation of the first to third pipelines to supply water to the water purification system through the bypass pipe when leakage occurs; and
The water purification pipe includes a plurality of joints and a plurality of connecting pipes,
The leak determination device,
An identification code is given to each of a plurality of joints and a plurality of connecting pipes, and an identification code of a point where the leak occurs is extracted,
Further comprising a remote management server for receiving the extracted identification code and providing the identification code to a user,
Further comprising an emergency valve installed in the water purification pipe and opened to pass water flowing in from the bypass valve,
The remote management server,
When it is determined that an abnormality occurs in the bypass valve, the emergency valve is controlled according to a user's input to block water leakage occurring in the purified water pipe.
Leakage blocking system, characterized in that.
According to claim 1,
The bypass valve is
When it is determined that a leak has occurred, the first pipe line to which the water purification pipe is connected is closed, and the second pipe line and the third pipe line are opened so that the water is supplied to the water purification system through the bypass pipe. leak blocking system.
According to claim 1,
The water purification pipe includes a plurality of joints and a plurality of connecting pipes,
The leak determination device,
When it is determined that the water leak has occurred, it is characterized in that the water leakage point is determined among the plurality of joints and the plurality of connecting pipes,
The leak determination device,
a compressed air generating device installed in the purified water pipe and spraying compressed air into the purified water pipe; and
Leakage blocking system, characterized in that it comprises a position determining unit for determining a point where noise due to leakage of the compressed air is generated among the plurality of joints and the plurality of connection pipes as the leakage point.
delete According to claim 1,
The remote management server,
It is characterized in that marking a joint or connecting pipe mapped to the received identification code among the plurality of joints and a plurality of connecting pipes in a design drawing image in which the plurality of joints and a plurality of connecting pipes are arranged so that the user can check them, characterized in that leak blocking system.
delete According to claim 1,
The remote management server,
Leakage blocking system, characterized in that the emergency valve is closed when a request to close the emergency valve is received from the user.
According to claim 1,
The remote management server,
When the bypass valve supplies water to the water purification system through the bypass pipe, when at least one of hydraulic pressure and flow rate is sensed by the sensing unit, it is determined that an abnormality has occurred in the bypass valve. blocking system.
According to claim 1,
The bypass pipe is
Built in the water purification system,
Further comprising a moving unit for moving the bypass pipe to a third pipe to which the bypass pipe is connected,
The mobile unit is
When it is determined that the leak has occurred, the leakage blocking system, characterized in that the bypass pipe is moved to the third pipe to be coupled.
10. The method of claim 9,
An extended coupling part is formed in the third pipe line to be coupled to the bypass pipe,
The coupling part has a locking protrusion formed along the inner circumferential surface of the coupling part, and a separation groove is formed in the longitudinal direction of the coupling part to open according to the insertion of the bypass pipe,
At one end of the bypass pipe, a locking groove coupled to the locking jaw is formed along an outer circumferential surface, and is inserted into the coupling part according to the movement of the moving unit, and the locking groove is fitted to the locking jaw by the stress of the gaping coupling part. Leakage blocking system, characterized in that.

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