KR20060125151A - System for detecting water leakage of saddle ferrule - Google Patents

Abstract

A system for detecting a water leakage of a saddle water division valve is provided to drastically reduce an economic loss due to a leakage of a tap water through the saddle water division valve. In a system for detecting a water leakage of a saddle water division valve, a leaking sensor is placed at one surface of the saddle water division valve and generates a predetermined electric signal when the saddle water division valve is leaked. And, an RFID(Radio Frequency Identification) tag(30) is electrically connected to the leaking sensor and stores and transfers the leaking data as a digital value about an eigen fin number and an electric signal.

Description

Water leak detection system before saddle fountain {SYSTEM FOR DETECTING WATER LEAKAGE OF SADDLE FERRULE}

1a to 1d is a view for explaining the leak detection system before the saddle fountain in accordance with the present invention.

2A and 2B are views for explaining a leak sensor according to the present invention.

3 is a flow chart of the leak detection process before the saddle fountain in accordance with the present invention.

*** Explanation of symbols on the main parts of the drawing ***

10: water pipe 15: saddle fountain

20: leak sensor 22: housing

23 inlet hole 24 first absorbing layer

25 second absorbing layer 26

30: RFID Tag 40: Protective Cover

50: RFID reader 60: ground

The present invention relates to a leak detection system of a saddle fountain, and specifically, a leak of a saddle fountain that can detect leaks and locations of leaks in a saddle fountain in a water supply pipe buried underground using RFID, particularly an active RFID system. To a detection system.

Pipes used for running water are leaked due to damage to specific locations due to aging or corrosion over time after installation. However, these pipes are usually buried underground, so it is not easy to detect leaks and locate them.

As a conventional method for detecting a leak in a water supply pipe, a night minimum flow measurement method, a sound detection method, a correlation method using a sensor, a gas injection method, and a method using a temporal leak detection device are used. In addition, the Water Audit method based on Sonic Leak Detection and Mass Balance Analysis, which detects leaks by using a sound wave amplification device, was used. The method of using gas and dye was used. As the leak detection method most commonly used at present, there is a method of calculating a leak occurrence time using a difference in the propagation time of sound generated at the leak point.

However, such a conventional leak detection method has a problem that requires a large amount of time, manpower, and finances due to the large area of the survey area and repetitive circuit survey for leak check, and especially when a small amount of leak occurs There was a problem that it was difficult to detect the spot. Therefore, there is a problem that a huge economic loss due to leakage due to failure to repair or replace the damaged pipe in time.

On the other hand, most of the leaks from the water supply occurs in the saddle fountain, which is a connection for connecting the drain pipe and the water supply pipe. The saddle fountain is for branching the water supply pipe from the water supply drainage pipe, and after the hole is drilled through one side of the water supply pipe, the saddle fountain and the pipe to be branched are installed. Therefore, even if the saddle fountain is completely in contact with the water supply pipe and covered, the water leaks between the saddle fountain and the through hole due to aging or corrosion over time. In addition, the saddle fountain field is used when a new water supply pipe, such as a new building, is essential, so the use range is wide, so leak detection of the saddle fountain field is very important. However, in the related art, there is no method for detecting leaks before the saddle fountain, and the leak detection method of the pipe is difficult to apply before the saddle fountain due to its characteristics. There was a problem that could not be.

The present invention has been presented to solve the above problems, and an object of the present invention is to accurately detect leaks of saddle fountains in which most leaks occur in water supply network facilities, and comprehensively detect leaks of all saddle fountains installed in a certain area. In addition to providing a low cost, it is possible to provide a leak detection system for the saddle fountain.

In order to achieve the above object, the leak detection system before the saddle fountain according to the present invention, by using the RF (RFID: Radio Frequency Identification), the leak occurring in the saddle fountain before branching the drain pipe of the water supply to the water supply pipe A leak detection system for detecting a saddle fountain, which is disposed on one surface of the saddle fountain, is a leak sensor that generates a predetermined electrical signal when a leak occurs in the saddle fountain, and is electrically connected to the leak sensor, and has a unique pin number and an electrical signal. And an RFID tag for storing and transmitting leakage data, which is a digital value.

Preferably, the leak detection system before the saddle fountain further comprises an RFID reader for receiving pin number and leak data transmitted from the RFID tag, and a protective cover surrounding the saddle fountain and leak sensor. In this case, the RFID tag is disposed outside the protective cover, and the protective cover is made of reinforced glass fiber (FRP: Fiberglass Reinforced Plastics). In addition, the leak sensor has two conducting wires exposed to one surface, and when water flows into the inside, the two shorting wires are mutually shortened, and the RFID tag is electrically connected to the leaking sensor through the two conducting wires. At this time, the leak sensor is disposed in the housing, a plurality of inlet holes penetrating through one surface of the housing, adjacent to each inlet hole in the interior of the housing, the first absorption layer made of an absorbent material, the inside of the first absorption layer of the housing A second absorbent layer formed of an absorbent material and formed by absorbing an electrolyte reacting with water to ionize, and extending from the outside to the inside through one surface of the housing, and being formed to be spaced apart from each other by a predetermined distance. 2 include at least two conductors arranged in contact with the absorber layer. RFID tag receives active radio frequency tag or RF radio wave sent by RFID reader which has built-in battery and transmits pin number and leak data periodically, and transmits pin number and leakage data by using electric wave as power You can use passive RFID tags. In addition, the leak detection system before the saddle fountain, geographic information system (GIS: Geographic) that receives and stores the pin number and leak data received by the RFID reader, and provides information on the installation location and leakage of a plurality of saddle fountains Information System) is preferable.

Hereinafter, with reference to the accompanying drawings will be described in detail the advantages, features and preferred embodiments of the present invention.

Figure 1a to 1d is a view for explaining the leak detection system before the saddle fountain according to the present invention, Figure 1a is a perspective view of the saddle fountain 15 installed in the water supply pipe 10, Figure 1b is a saddle 1 is a perspective view of a state in which the leak sensor 20 and the RFID tag 30 are disposed in the fountain 15, and FIG. 1C is a perspective view of the saddle fountain wrapped with the protective cover 40, and FIG. 1D is an RFID reader ( Figure 50 shows an example of detecting leaks before the saddle fountain. As shown in FIGS. 1A to 1D, the leak detection system of the saddle fountain front according to the present invention is electrically connected to the leak sensor 20, the leak sensor disposed on one surface of the saddle fountain 15, and provides constant data. The RFID tag 30 periodically transmits, a protective cover 40 surrounding the saddle fountain and the leak sensor, and an RFID reader 50 receiving data transmitted from the RFID tag.

The saddle fountain 15 according to the present invention is used to branch the water supply drainage pipe into the water supply pipe, and then form a hole through one surface of the water supply pipe 10 to be mounted in close contact with the saddle fountain.

The leak sensor 20 according to the present invention is disposed on one surface of the saddle fountain 15 and is connected to the RFID tag 30 through two conductive wires exposed to the outside. As the leak sensor 20, a submerged leak sensor is used, and the two conductive wires are disposed to be separated from each other by a predetermined distance so as not to be electrically connected. The leak sensor 20 short-circuits two conductive wires spaced apart from each other when water leaks from the saddle fountain 15 and water is introduced therethrough. The configuration and operation of the leak sensor 20 will be described in detail below.

The RFID tag 30 according to the present invention is connected to the leak sensor 20 by two conductive wires, and stores leak data indicating whether the saddle fountain 15 leaks with a unique pin number. RFID (Radio Frequency Identification) system is a system using radio frequency communication and has a non-contact and invisible characteristic. An active RFID tag and a passive RFID tag may be used as an RFID tag. In the case of an active RFID tag, a battery is built in itself to periodically transmit certain data. On the other hand, since the passive RFID tag does not have its own battery, it receives the radio wave sent by the RFID reader 50 and transmits the data by using it as power. In particular, the active RFID tag provides a recognition distance of 1m to 30m or more. Preferably, it is preferable to use an active RFID tag as the RFID tag 30 in order to periodically transmit pin number and leak data without receiving a separate radio wave from the RFID reader 50.

The pin number stored in the RFID tag 30 is a unique identification code assigned to the corresponding RFID tag, so that the pin number can be identified and the position of the saddle fountain 15 in which the corresponding RFID tag is installed. do. Also, the leak data is data indicating whether the saddle fountain 15 leaks, and specifically, whether or not two wires of the leak sensor 20 are electrically connected to each other. That is, in the state in which no leakage occurs in the saddle fountain 15, since the two conductive wires are separated from each other to form an electrical connection, the leakage data has a value of '0'. However, when water leaks in the saddle fountain 15 and water flows into the leak sensor 20, the two wires are short-circuited, whereby the leak data is changed to '1'.

On the other hand, the RFID tag 30 is disposed outside the protective cover 40 in order to prevent a malfunction due to being flooded by the spilled water when a leak occurs in the saddle fountain 20. Preferably, a separate cover is placed on the RFID tag 30 to prevent the groundwater or moisture from contacting the RFID tag and to protect the RFID tag from external shocks. On the other hand, when the submerged RFID tag is used as the RFID tag 30 may be disposed in the protective cover 40, of course.

The protective cover 40 according to the present invention is a component surrounding the saddle fountain 15 and the leak sensor 20, and not only prevents external moisture from infiltrating, but also protects the leak sensor 20 from external shocks. Done. As the material of the protective cover, it is preferable to use any one selected from high pressure expanded polystyrene (EPS) resin, steel, reinforced FRP (Fiberglass Reinforced Plastics) and aluminum. In addition, both ends of the protective cover 40 and the contact surface of the water supply pipe are wrapped in close contact with a rubber band in order to more effectively block external moisture and the like.

The RFID reader 50 according to the present invention searches the RFID tag 40 embedded in the basement on the ground 60 and receives the pin number and the leak data. Accordingly, the RFID tag 30 may be identified and the position of the saddle fountain 15 may be identified based on the received pin number, and the leak of the saddle fountain may be determined through the leak data.

Meanwhile, the leak detection system of the saddle fountain front according to the present invention further includes a geographic information system (GIS: Geographic Information System, not shown) for providing information on the buried position and leakage of each saddle fountain 15. do. The geographic information system stores and stores a database of information on the installation location, leakage, and recovery of the entire saddle fountain 15 embedded in a predetermined area, and provides the information graphically on a predetermined map.

2A and 2B are diagrams for explaining a leak sensor according to the present invention, and FIG. 2A is a perspective view of the leak sensor, and FIG. 2B is a cross-sectional view of the leak sensor in the A-A 'direction. 2A and 2B, the leak sensor 20 according to the present invention includes a housing 22 surrounding the outside, a first absorbing layer 24 and a second absorbing layer 25 disposed inside the housing, and It includes two conductive wires 26 extending inward from the outside of the housing.

The housing 22 is preferably made of a synthetic resin material such as plastic that does not cause corrosion due to moisture, and a plurality of inflow holes formed to penetrate water into the housing when water leaks in the saddle fountain 15. 23 is provided. In addition, another surface of the housing 22 is formed with a through hole through which the two conductive wires 26 are exposed to the outside. On the other hand, in order to facilitate the assembly of the leak sensor 20 and effectively block moisture, the housing 22 is formed of a double wall structure in which the upper housing and the lower housing and both the upper housing and the lower housing have side walls. You may.

The first absorbent layer 24 is disposed outside the second absorbent layer 25, specifically, adjacent to the inlet 23 of the housing to absorb moisture introduced from the outside of the leak sensor 20. Therefore, unless a predetermined amount of water is introduced due to leakage of the saddle fountain 15, even if underground moisture or moisture due to rain or the like enters the inflow hole 23, the first absorption layer 24 is absorbed. 2, the absorption layer 25 can be prevented from absorbing moisture. As the first absorbent layer 24, a material having excellent absorbency is used, and preferably a sponge is used.

The second absorbing layer 25 is made of an absorbent material in which the electrolyte is absorbed. In this case, as the electrolyte to be absorbed, various kinds of electrolytes which react with water such as potassium hydroxide, sodium hydroxide and sodium chloride and ionize may be used. It is preferable to use a sponge material having excellent absorptivity in the second absorbent layer 25.

The conductive wires 26 are formed to extend from the outside of the housing 22 to the inside, and the exposed wires are configured to be covered and the conductive wires 26a inserted into the inside are made of only the conductors without the coating. The two conductive wires 26a inserted therein are not electrically connected to each other by a predetermined distance, and are arranged to be at least in contact with the second absorbing layer 25. Preferably, the two conductive wires 26a may be disposed in close contact with the second absorbing layer 25, and may be configured to be embedded in the second absorbing layer, respectively.

On the other hand, in the above description, an embodiment using a submerged sensor that short-circuites the conductive wire by reacting the water and electrolyte flowing in when leaking water before the saddle fountain, on the other hand, the electrical signal is detected by detecting the water pressure when the water leak in the saddle Of course, you can also use a pressure sensor to generate. In the case of using the pressure sensor as the leak sensor, the leak sensor and the RFID tag are electrically connected to each other through the conductive wires so that the electrical signal of the leak sensor is input to the RFID tag.

Referring to the operation of the leak sensor 20 according to the present invention.

When no leak occurs in the saddle fountain 15, even if a small amount of moisture or the like flows into the leak sensor 20, the first absorbing layer 24 is absorbed, so that the electrolyte of the second absorbing layer 25 reacts with water. You will not. Therefore, since the two conductive wires 26 are in an off state not electrically connected to each other, the leakage data of the RFID tag 30 connected to the two conductive wires is '0'.

However, when a leak occurs in the saddle fountain 15, a certain amount of water is absorbed by the leak sensor 20 through the plurality of inflow holes 23, and is absorbed by the first absorbing layer 24 and then the second absorbing layer. Up to (25). Therefore, since the electrolyte of the second absorbing layer 25 reacts with the water and ionizes, the electrolyte may flow. As a result, two mutually spaced conductive wires 26a disposed in close contact with the second absorbing layer 25 are short-circuited through the electrolyte and are in an electrically connected on state. Therefore, the leakage data of the two wires and the RFID tag 30 respectively connected to each other is changed to '1'.

3 is a flowchart of a leak detection process before the saddle fountain according to the present invention. Referring to Figure 3 describes the leak detection process of the saddle fountain before the present invention.

The RFID tag 30 according to the present invention periodically transmits the stored pin number and the leak data (ST100). The manager uses the RFID reader 50 to search the RFID tag 30 buried underground above the ground 60. If the RFID reader 50 is adjacent to the RFID tag 30, the received pin number and the leak data are received, and the received leak data is read (ST110 and ST120).

When the read leak data is '0', since no leak occurs in the saddle fountain 15, the manager continues to search for another RFID tag 30 (ST130 and ST140).

On the other hand, if a leak occurs before the saddle fountain, water is introduced into the inlet 23 of the leak sensor 20, and the introduced water is absorbed to the second absorbing layer 25 through the first absorbing layer 24 ( ST150, ST160). Accordingly, the electrolyte of the second absorbing layer 25 reacts with the water to ionize the two conductive wires 26a closely contacted with the second absorbing layer (ST170). As a result, since the two conductive wires 26a are electrically connected to each other, the leakage data of the RFID tag 30 connected to the conductive wires 26 is changed to '1' (ST180).

At this time, when the manager receives and reads the pin number and the leak data from the RFID tag 30 through the RFID reader 50, the leak data becomes '1' and thus leaks occur in the corresponding saddle fountain 15. Then, the saddle fountain is repaired or replaced (ST100 to ST130, ST190).

On the other hand, ST120 to ST140, and ST190 may be performed by a geographic information system. In this case, the RFID reader 50 transmits the received pin number and the leaked data to the geographic information system or inputs the data stored in the RFID reader into the geographic information system after the search of the RFID tag 30 is completed. . The geo-information system refers to the RFID tag having the pin number obtained by the RFID reader 50 by referring to a matching table that matches the pin number of each RFID tag 30 with the position of the RFID tag (installation position before the saddle fountain). The installation position of the saddle fountain 15 where 30 is installed is calculated. In addition, through the leak data acquired by the RFID reader 50, the information on whether or not the corresponding saddle fountain 15 leaks. That is, when updating the database for storing the leak before the saddle fountain, and graphically providing the location and leakage of each saddle fountain before the predetermined map, the graphic information is also updated. If there is a leaked saddle fountain 15, the saddle fountain is restored or replaced, and the information indicating whether the saddle fountain is restored is updated.

As described above, the saddle fountain leak detection system according to the present invention can not only accurately detect the leak of the saddle fountain water leak occurs most of the water supply network facilities, but also has a significant effect that can be built at a low cost.

In other words, the leak detection system before the saddle fountain according to the present invention,

First, since an RFID tag is installed for each saddle fountain buried underground and pin number and leak data are received from the RFID tag, it is easy to determine whether or not each saddle fountain leaks from the ground.

Secondly, since the leaked data is transmitted / received through an RFID method having excellent data transmission / reception rate within a certain distance, it is possible to prevent the loss of data and the omission of leak detection.

Third, when using an active RFID tag, the RFID tag periodically transmits pin number and leakage data through the built-in battery, thereby improving the detection (retrieval) rate and data reception rate of the RFID tag.

Fourth, because the water flowing into the leak sensor before the saddle fountain changes the leakage data by shorting the wire, it is possible to build a significantly lower accuracy and at a lower cost than the conventional leak detection method,

Fifth, by forming a plurality of inlet holes on one surface of the leak sensor so that the water flows smoothly into the leak sensor when the leak before the saddle fountain, it is possible to accurately detect the leak of the saddle fountain,

Sixth, by placing the first absorbent layer outside the second absorbent layer where the electrolyte is absorbed, even if a small amount of moisture, such as a leak before the saddle fountain, flows into the leak sensor, the leak sensor is prevented from being absorbed by the second absorbent layer. It can prevent the malfunction

Seventh, the protective cover is used to cover the leak sensor, preventing rainwater or underground moisture from entering the leak sensor and protecting the leak sensor from external shocks.

Eighth, there is no need to dig or invest in additional equipment to detect leaks in the saddle fountain, greatly reducing maintenance costs and manpower.

Finally, by providing pin number and leak data acquired through RFID reader to geographic information system, comprehensive information and collective management of leaks of all saddle fountains in a certain area can be provided. Economic losses due to leakage can be significantly reduced.

While preferred embodiments of the present invention have been described using specific terms, such descriptions are for illustrative purposes only and it is understood that various changes and modifications may be made therein without departing from the spirit and scope of the following claims. You must lose.

Claims (10)

A leak detection system at the saddle fountain using RF ID (RFID) to detect leaks in the saddle fountain before branching to the water supply pipe. A leak sensor disposed on one surface of the saddle fountain and generating a predetermined electrical signal when the leak occurs before the saddle fountain; And Saddle fountain leak detection system electrically connected to the leak sensor, and comprises a unique RFID number (RFID Tag) for storing and transmitting the leak data that is a digital value for the electrical signal. The method of claim 1, The leak detection system before the saddle fountain, Saddle fountain leak detection system further comprises an RFID reader for receiving the pin number and the leak data transmitted from the RFID tag. The method of claim 1, The leak detection system before the saddle fountain, Saddle fountain and leak detection system further comprises a protective cover surrounding the leak sensor. The method of claim 3, wherein And the RFID tag is disposed outside the protective cover. The method of claim 3, wherein Saddle fountain leak detection system, characterized in that the protective cover made of reinforced FRP (Fiberglass Reinforced Plastics). The method of claim 1, The leak sensor has two conductive wires exposed to one surface, and when water is introduced into the leakage sensor, the two conductive wires are short-circuited to each other. And the RFID tag is electrically connected to the leak sensor through the two conductive wires. The method of claim 6, The leak sensor, housing; A plurality of inflow holes formed through one surface of the housing; A first absorbent layer disposed adjacent to each of the inflow holes in the housing and made of an absorbent material; A second absorbent layer disposed inside the first absorbent layer of the housing and made of an absorbent material and formed by absorbing an electrolyte that reacts with water and ionizes; And The two saddles are formed extending from the outside to the inside through one surface of the housing, the areas extending in the interior are at least in contact with the second absorbing layer spaced apart from each other by a predetermined distance. Leak Detection System. The method of claim 1, The RFID tag is The leak detection system of the saddle fountain, characterized in that the battery is an active RFID tag that transmits the pin number and the leak data periodically. The method of claim 2, The RFID tag is And a passive RFID tag which receives a predetermined radio wave sent by the RFID reader, and transmits the pin number and the leak data by using the radio wave as power. The method of claim 2, The leak detection system before the saddle fountain, It further includes a geographic information system (GIS) for receiving and storing the pin number and the leak data received by the RFID reader, and provides information on the installation location and leak of the plurality of saddle fountains. The leak detection system before the saddle fountain.

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