KR101696675B1 - System for checking leakage of underground pipe - Google Patents

Abstract

The present invention relates to a water leakage detection system, and more particularly, to a water leakage detection system that includes a data collection unit installed in a pipeline embedded in the ground to store unique information of the pipeline and collect sensing information; A reader unit for receiving unique information and sensing information collected by the data collecting unit; And a central server for receiving the unique information and the sensing information from the reader unit and detecting the leakage / leakage of the pipe to determine the position of the pipe in the event of leakage / leakage, so that the leakage / leakage amount lost in the large- The present invention relates to a leak detection system for a buried piping, which is capable of preventing a large accident caused by gas or oil leakage.

Description

SYSTEM FOR CHECKING LEAKAGE OF UNDERGROUND PIPE

More particularly, the present invention relates to a leakage detection system, and more particularly, to a leakage detection system that is installed in a buried pipeline or a newly installed upper, drainage piping, and various oil pipelines to detect leakage or leaking, Thereby enabling immediate maintenance and the like to be carried out.

In the context of increasing unevenness of rainfall due to climate change and increasing population and water usage due to urbanization, the disparity of supply and demand is intensifying. Therefore, management of water supply network is one of the most basic and important matters in the management of tap water It is one.

In general, the water supply network accounts for about 70% of the water supply facilities, but the maintenance of the water supply network is inadequate. In Korea, the amount of water leakage during the process of supplying water is 640 million ㎥ (2.1 times that of Namkang dam in 2010), and the amount of water leaked in the last 10 years is 7.5 billion ㎥.

In addition, the reliability of tap water is deteriorating due to aging of pipe network and deterioration of water quality caused by improper supply system.

In addition, the management of leaks / leaks is essential to the prevention of large accidents as well as to reduce the loss of leaks / leaks on the network installed for gas and oil supply purposes.

In order to detect such leakage / leakage, various technologies have been proposed in the past. In particular, in the case of a water supply pipe, a leak sensor of Korean Patent Laid-Open No. 10-2007-0005234 has been proposed. However, The film is wound around the pipe to detect the leakage of the chemical. In such a case, the installation cost and the construction period are excessively required to be applied to a wide range of waterworks pipes, and a precise detection of the water leakage point A difficult problem remains.

Korean Patent Publication No. 10-2007-0005234

Accordingly, it is an object of the present invention to at least partially solve the problems in the conventional technology. Accordingly, it is an object of the present invention to provide an apparatus and method for detecting leaks in a large-scale water supply pipe network or a gas pipe, And to provide a leak detection system of a buried piping which can prevent a large accident caused by leakage.

According to an aspect of the present invention, there is provided a leak detection system for buried piping, comprising: a data collection unit installed in a pipeline buried in the ground to store unique information of the pipeline and collect sensing information; A reader unit for receiving unique information and sensing information collected by the data collecting unit; And a central server for receiving the unique information and the sensing information from the reader unit and detecting the leakage / leakage of the pipe, and determining the position of the pipe when leakage / leakage occurs.

At this time, the data collector may include an RFID tag storing unique information of a pipe; A sensing unit installed on an inner side or an outer side of the pipe to generate sensing information by measuring information of a surrounding environment; And a transmitter connected to the RFID tag and the detector to transmit the unique information and sensing information to the reader.

The detecting unit is characterized by being at least one of a temperature sensor, a humidity sensor, a pressure sensor, and a vibration sensor.

For example, the detecting unit is provided in a socket shape at a connection portion between one pipe of the pipe and another pipe, and is configured to measure the fluid pressure inside.

As another example, the detecting unit is configured to convert a vibration signal generated in a pipe through which a fluid flows, into a sensing information, which is an electrical signal, by a piezoelectric element.

Meanwhile, the transmitter is housed in a housing disposed at regular intervals along the pipe, and the RFID tag is installed in the housing or installed in the pipe.

At this time, the housing is spaced upward from the pipe, the housing is formed with a wire fixing part, and a wire part is disposed along the housing, and the wire part is bound to the wire fixing part.

In addition, the wire fixing part is fixed to the housing with a pair of mutually separated symmetrical structures, and a wire receiving groove is formed on the opposite surface of the wire fixing part to fasten the wire part to each other, A pair of securing clips formed with grooves; Wherein the guide groove has an inner width adjacent to the wire receiving groove smaller than a diameter of the wire receiving groove, and the pressure cover is engaged with the fixing clip And does not interfere with the wire receiving grooves in a state where the wire receiving grooves are in a state of being in contact with each other.

As one example, the housing is attached to the pipe.

Meanwhile, the housing is buried in the ground along the pipe, and is buried in a position close to the ground surface of the pipe.

In addition, the housing is embedded in the ground along the pipe, and the housing is configured to maintain a constant gap with the ground even when the depth of the pipe changes.

As described above, according to the leakage detection system of the buried piping according to the present invention, the data collection unit is installed at a predetermined interval in the pipe network, and the pipe specific information and sensing information are transmitted to the reader unit, Can be detected, and the position of the piping can be detected at the time of occurrence of leakage / leakage, so that immediate response is possible. As a result, it is possible to reduce leakage amount / leakage amount lost in a large scale pipe network, There is an effect of preventing an accident.

1 is a block diagram schematically showing a leak detection system for buried piping according to the present invention.
2 is a schematic view showing a data collecting unit which is an embodiment of the present invention;
3 is a view showing an embodiment of a data collecting unit which is an embodiment of the present invention.
4 is a diagram showing an embodiment of a detection unit which is a constitution of the present invention.
5 is a view showing another embodiment of the detection unit which is a constitution of the present invention.
6 is a schematic view showing an embodiment in which a housing is applied to a leakage detection system for buried piping according to the present invention.
7 is a schematic view showing an example in which a housing, which is an embodiment of the present invention, is applied.
8 is a view showing another embodiment of Fig.
9 is a diagram showing an example in which auxiliary antennas are constituted in a transmission section which is a constitution of the present invention.

In describing the present invention, terms and words used in the present specification and claims are to be construed in accordance with the principles of the present invention, on the basis that the inventor can properly define the concept of a term in order to best explain his invention It should be construed as meaning and concept consistent with the technical idea of.

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

FIG. 1 is a block diagram schematically showing a leakage detection system of buried piping according to the present invention, FIG. 2 is a schematic diagram showing a data collection unit which is a constitution of the present invention, FIG. 3 is a diagram showing a data collection unit Fig. Fig. 5 is a view showing another embodiment of the detection unit, which is a constitution of the present invention. Fig. 6 is a view showing the structure of the detection unit according to the present invention. Fig. Fig. 3 is a schematic view showing an embodiment in which a housing is applied to a leakage detection system. Fig. 7 is a schematic view showing an example in which a housing which is a constitution of the present invention is applied, and FIG. 8 is a view showing another embodiment of FIG.

The leak detection system for buried piping according to the present invention is configured to be applicable not only to the existing piping 10 but also to the newly installed piping 10 and it can measure the temperature, humidity, pressure, and vibration of the buried piping 10 Thereby detecting the occurrence of leakage of the piping 10, and precisely grasping the position of the piping 10 so as to promptly perform maintenance or the like.

The pipe 10 in the entirety of the present specification is a concept including all kinds of pipes 10 buried in the ground. The pipe 10 is made of a metal material such as polyethylene (PE), poly A synthetic resin material such as propylene (PP) or polystyrene (PS) can be formed into a tubular shape penetrating inside through a high-temperature / high-pressure extrusion process, and a fluid including water, sewage, gas, F) is configured to pass through.

As shown in FIG. 1, the leakage detection system of a buried pipe according to the present invention includes a data collection unit 100, a reader unit 200, and a central server 300.

The data collecting unit 100 is installed in a buried pipe 10 in the ground and stores unique information of the pipe 10 and collects sensing information about the surrounding environment of the pipe 10.

At this time, the unique information of the piping 10 refers to the maintenance date of the piping 10, such as the date of embedding of the piping 10, the buried organs, the depth of buried, the buried position, the direction of embedding, the material, The main information and the positional information of the piping 10 are included so that when the piping 10 leaks or leaks, the position of the piping 10 can be accurately grasped through the unique information, It is possible to instantly replace the material and the diameter of the pipe 10.

The sensing information refers to information obtained by measuring the temperature, humidity, or the pressure of the fluid F passing through the piping 10, for example, with respect to the surrounding environment of the buried piping 10, Leak / leakage / leakage of the specific piping 10 can be grasped.

The reader unit 200 is configured to receive unique information and sensing information collected by the data collecting unit 100. In the drawing, the reader unit 200 transmits information transmitted from a plurality of data collecting units 100 to one reader In the present invention, one reader unit 200 is configured in one data collecting unit 100 so that the data collecting unit 100 and the reader unit 200 correspond to each other in a one-to-one correspondence. It can be done.

In addition, the data collecting unit 100 and the reader unit 200 may be connected to each other using short-distance wireless communication. For example, one of RFID, Bluetooth, and Zigbee communication may be applied.

The central server 300 receives the unique information and sensing information from the reader unit 200 and detects leakage or leakage of the pipeline 10 to detect the leaked or leaked unique information of each pipeline 10 So that the position of the pipe can be grasped.

Hereinafter, the data collecting unit 100, which is an embodiment of the present invention, will be described in detail with reference to FIGS.

As shown in the figure, the data collecting unit 100 includes an RFID tag 110, a detecting unit 120, and a transmitting unit 130.

The RFID tag 110 stores unique information such as a date of burial of the relevant pipe 10, a buried organs, a depth of buried buried position, a buried direction, a material, a diameter and production information, Main information about the piping 10 at the time of maintenance is stored.

This is because, when replacing the piping 10, the main information such as the diameter, material, embedment direction, burial position, etc. of the piping can be known in advance based on the information of the piping 10 to be precisely constructed, .

The sensing unit 120 may be installed inside or outside the piping 10 and is configured to measure environmental information of the piping 10 to generate sensing information, which is a measured value.

2, the transmitting unit 130 transmits the unique information and sensing information to the reader unit 200 through at least one of RFID, Bluetooth, and ZigBee.

3A, the RFID tag 110 and the transmission unit 130, except for the detection unit 120, are connected to the pipe 10 The detecting unit 120 is disposed on the side of the pipe 10 so as to facilitate the measurement of various environmental information of the pipe, and the transmitting unit 130, which is buried in the ground, is spaced closer to the ground, The communication environment with the reader unit 200 of FIG.

The RFID tag 110 is connected to the transmitter 130 to transmit the unique information of the pipe to the transmitter 130. The RFID tag 110 is not limited in its position as shown in FIG. 3A or 3B, The tag 110 may be disposed adjacent to the transmitter 130 or the RFID tag 110 may be disposed adjacent to the pipe 10 as shown in FIG.

It is to be understood that the RFID tag 110 may be integrally formed with the transmitting unit 130 or may be integrally formed with the detecting unit 120 in each embodiment.

The sensing unit 120 may be a temperature sensor, a humidity sensor, a pressure sensor, or a vibration sensor. For example, when the temperature sensor or the humidity sensor is used as the sensing unit 120, The central server 300 can determine whether the pipe 10 is leaking or leaking through a change in the sensing information such as a decrease in temperature or a rise in humidity.

When the pressure sensor is applied to the detecting unit 120-1, the pressure of the fluid in the piping 10 during the flow of the gas F may be different from that of the central server 300, It is possible to determine whether the pipe 10 is leaking or leaking.

4A, the detecting unit 120-1 includes a detecting unit 120-1 disposed inside the pipe 10 and a data collecting unit 100 excluding the detecting unit 120-1 outside the pipe. So that the pressure inside the pipe 10 can be measured through the detecting unit 120-1 and the sensing information can be transmitted to the reader unit 200 through the transmitting unit 130. [

Another example of the detection unit 120-1 is configured by a socket structure (not shown) in which the one pipe 10 and the other pipe 10 are tightly coupled to the both sides, as shown in FIG. 4B, The RFID tag 110 and the transmitter 130 may be arranged outside the socket structure so as to measure the pressure of the fluid F when the fluid F flows. So that communication with the reader unit 200 can be smoothly maintained.

Power may be supplied to the RFID tag 110, the detection unit 120, and the transmission unit 130. An external power line may be connected to each configuration to supply power at all times. Alternatively, The RFID tag 110, the detection unit 120, and the transmission unit 130 may be supplied with power at all times by providing a battery to the collecting unit 100 and being connected to each configuration.

5 shows an example in which a vibration sensor is applied as another embodiment of the detection unit 120-2.

A piezoelectric element can be applied to the vibration sensor according to the present embodiment, and the piezoelectric element is configured to convert the vibration signal generated by the fluid F flowing in the pipe 10 into sensing information, which is an electrical signal.

As shown in the figure, a plurality of detection units 120-2 are installed at predetermined points in the pipe 10, and the sensing information, which is a vibration signal of the fluid F including gas flowing in the pipe 10, .

Piezoelectric, Piezo ceramic, Piezo quartz, etc. can be used as these piezoelectric elements. Since these piezoelectric elements are high in accuracy and relatively low in cost, It is possible to prevent the installation cost from being burdensome even if a plurality of units are installed.

When the fluid F flows into the pipe 10, the vibration signal of a certain frequency band is generated by the pressure. In this case, That is, when the fluid F does not flow into the pipe 10, the vibration signal is not generated. The magnitude of the vibration signal changes according to the amount of the flow when the fluid F flows. If the pipe 10 cracks If leakage / leakage / leakage occurs, the amount of fluid (F) flowing before passing through the leak / leaking / leaking point and after passing through the leaking / leaking / leaking point is changed, thereby causing a change in the vibration signal.

Therefore, when the vibration signal of the piping 10 is measured at all times, it is possible to detect whether the piping 10 is leaking, leaking or leaking.

Hereinafter, an embodiment in which the housing 140 is further constructed according to the present invention will be described with reference to FIG.

The housing 130 is embedded in the housing 140 and the housing 140 is embedded in the ground like the pipe 10 and is disposed at a predetermined interval along the pipe 10. [

The sensing unit 120 may be disposed at a corresponding position of the housing 140 and may be connected to the transmitter 130 to transmit the sensed sensing information to the reader unit 200 do.

In addition, the RFID tag 110 may be embedded in the housing or may be formed in the pipe 10 having the detecting unit 120 installed therein.

In addition, the housing 140 may be spaced upward from the pipe, or may be attached to the pipe 10.

At this time, it is preferable that the housing 140 is formed in the form of a hard casing so as to protect it from the earth pressure acting on the transmitter 130 or various external impacts.

The housing 140 must be disposed along the pipe 10 so as to accurately grasp the positional information of the pipe 10 so that the housing 140 can be detached from the ground or lost. May be disposed along the housing 140 and a wire fixing unit 150 may be integrally formed in the housing 140 to fasten the wire unit 160 and the housing 140.

At this time, although the wire part 160 is not specifically shown, it may be a wire made of metal, fiber, or synthetic resin. In this case, the wire may be formed by twisting a plurality of strands so as to improve rigidity. A coating film can be formed.

The wire portion 160 is disposed on the upper side of the pipe 10 so as to be spaced apart from the pipe 10. More specifically, the pipe portion 10 is embedded in the wire portion 160 and then the primary portion covering the pipe 10 is covered. The wire 160 may be disposed along the wire fixing part 150 and may be bound to the housing 140 through the wire fixing part 150. [

The wire fixing part 150 is composed of a pair of clip structures (not shown) fixed to the lower side of the housing 140 as shown in FIG. So that the housing 140 and the wire 160 can have a firm and easy coupling relationship. The clip structure is preferably made of an elastic material.

The wire fixing unit 150 may further include a fixing clip 151 and a pressing cover 155 as shown in FIG. 7, And the fixing clip 151 are fixed to the housing 140 with a symmetrical structure spaced apart from each other.

A wire receiving groove 152 is formed on the opposite surface of the fixing clip 151 so that the wire 160 is fastened to each of the guide grooves 152. The guide groove 152 extends from the wire receiving groove 152 toward the end thereof. 153 are formed.

That is, the guide groove 153 has an inclined surface 154 having a wide end and narrowed toward the center, which is the center of the inclined surface 154. Therefore, when the wire 160 and the wire fixing portion 150 are coupled with each other by the same principle as the funnel, 154 are guided along the wire receiving grooves 152 to be smoothly guided to the wire receiving grooves 152.

The pressing cover 155 is configured to press the pair of fixing clips 151 against each other to finish the pressing cover 155 so that the pressing cover 155 is firmly held between the wire portion 160 and the housing 140 in a state where the wire portion 160 is fitted inward. So that it is possible to prevent the housing 140 from being separated and lost.

The pressing cover 155 may have a screw-engaging structure with the fixing clip 151, or may be configured to be press-fitted.

Referring to FIG. 6 again, the housing 140 is embedded in the ground along the pipe 10, and a distance from the housing 140 to the ground is defined as 'a', and the distance from the pipe 10 to the housing A 'is preferably smaller than' b 'when it is defined as' b'. This is because when the distance from the ground of the housing 140 disposed on the upper side of the pipe 10 is smaller than the distance between the reader unit 200 And the transmitter 130 are difficult to communicate with each other, it is difficult to grasp the unique information and the sensing information in the reader 200.

Therefore, as described above, the housing 140 is held close to the ground so that a smooth communication environment is maintained between the reader 200 and the transmitter 130.

8, the depth of the pipe 10 may not be constant depending on the characteristics of the topography and the environment. As shown in FIG. 8, even if the pipe 10 is embedded deeply in the ground, A 'of the pipe 10 and the housing 140 can be kept constant so as to maintain a constant depth with the ground surface, that is, a smooth communication environment between the reader unit 200 and the transmitter 130 .

The piping 10 is buried as described above, and the first cover is horizontally installed. Then, the housing 140 is installed as in the above embodiment, and then the secondary cover and the floor finish are applied to the housing 140) and the ground surface are always kept at a constant spacing.

9 shows that the auxiliary antenna 170 is connected to the transmission unit 130. The auxiliary antenna 170 is connected to the housing 140 in the figure, The other end is exposed on the ground in a state of being connected to the transmitter 130 so that an optimal communication environment with the reader 200 on the ground can be established irrespective of the depths of the pipe 10 and the housing 140 do.

At this time, the auxiliary antenna 170 may be formed in a cable shape or in a wire form. In some cases, the auxiliary antenna 170 may be connected to the reader unit 200 by wire.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

10: piping 100: data collection unit
110: RFID tag 120:
130: transmitting unit 140: housing
150: wire fixing part 160: wire part
200: reader unit 300: central server

Claims (12)

A data collecting unit installed in a pipeline embedded in the ground to store unique information of the pipeline and collect sensing information; A reader unit for receiving unique information and sensing information collected by the data collecting unit; And a central server for receiving the unique information and the sensing information from the reader unit and detecting the leakage / leakage of the pipe to determine the position of the pipe when the leakage / leakage occurs, the leakage detection system comprising:
Wherein the data collection unit includes: an RFID tag storing unique information of a pipe; A sensing unit installed on an inner side or an outer side of the pipe to generate sensing information by measuring information of a surrounding environment; And a transmitter connected to the RFID tag and the detector to transmit the unique information and the sensing information to the reader,
The transmission unit is contained in a housing disposed at regular intervals along the pipe,
Wherein the housing is spaced upward from the pipe, the housing includes a wire fixing part, a wire part is disposed along the housing, the wire part is bound to the wire fixing part,
The wire fixing part is fixed to the housing in a symmetrical structure in which a pair of the fixing parts are mutually spaced apart. A wire receiving groove is formed on the opposite surface of the wire fixing part to fasten the wire part, A pair of securing clips formed; Wherein the guide groove has an inner width adjacent to the wire receiving groove smaller than a diameter of the wire receiving groove, and the pressure cover is engaged with the fixing clip The wire receiving grooves being configured so as not to interfere with the wire receiving grooves,
The wire portion is disposed on the upper side along the pipe. After the pipe is buried and covered with the pipe, the wire portion is disposed along the pipe, and then bound to the housing through the wire fixing portion. Wherein the water leakage detection system is embedded in a car ground.
delete The method according to claim 1,
The detecting unit
A temperature sensor, a humidity sensor, a pressure sensor, and a vibration sensor.
The method of claim 3,
The detecting unit
Wherein the pipe is installed in the form of a socket at a connection portion between one pipe of the pipe and the other pipe to measure the fluid pressure inside the pipe.
The method of claim 3,
The detecting unit
Wherein the piezoelectric element is configured to convert the vibration signal generated in the pipe through which the fluid flows into the electric signal sensing information.
delete delete delete delete delete The method according to claim 1,
Wherein the housing is embedded in the ground along the pipe,
Wherein the housing is configured to maintain a constant gap with the ground even if the depth of the pipe is changed.
The method according to claim 1,
The auxiliary antenna is connected to the transmitter,
Wherein the auxiliary antenna has one end connected to the transmitter and the other end exposed to the ground.

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