KR20160085117A - Monitoring system for checking leakage of water pipe - Google Patents

Abstract

The present invention relates to a monitoring system for detecting a leakage of a water pipe. Specifically, the monitoring system for detecting a leakage of a water pipe includes: a leakage detection device attached to a water pipe and generating and transmitting a detection signal generated in the water pipe; a main server collecting and storing the detection signal transmitted by the multiple leakage detection devices within a predetermined section and generating and transmitting warning data on the leakage detection device when the detection signal transmitted by the leakage detection device exceeds an allowance, by comparing the detection signal to the allowance of the stored detection signal; and an administrator terminal receiving and displaying the detection signal on the each leakage detection device on a display unit by connecting to the main server, and displaying information on the leakage detection device on the display unit when warning data is received from the main server. The monitoring system for detecting a leakage of a water pipe can immediately detect the leakage of the water pipe. Therefore, the monitoring system for detecting a leakage of a water pipe can improve reliability of tap water and can reduce a leakage amount leaked in a large water pipeline net.

Description

TECHNICAL FIELD [0001] The present invention relates to a monitoring system for detecting water leakage in a water pipe,

The present invention relates to a water leakage monitoring system, and more particularly, to a water leakage monitoring system using a water leakage detection device using a piezoelectric element to accurately detect a water leakage point in a case where a water leakage occurs in a pipe network, And more particularly to a monitoring system for detection.

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.

As a result, the total drinking rate of tap water is decreasing year by year, and the direct drinking rate is very low, around 2%. Effective maintenance and management of the pipe network is the most urgent task in order to reduce the amount of water leakage from the pipe network and to increase the reliability of tap water.

In the prior art, a water leakage sensor disclosed in Korean Patent Laid-open Publication No. 10-2007-0005234 has been proposed as a water leakage detection device for judging whether or not a water supply pipe is leaking. However, since a film capable of displaying the chemical composition can be wound around a pipe, In such a case, the installation cost and the construction period are excessively required to be applied to a wide range of waterworks pipe networks, and it is difficult to precisely detect the leakage point.

Korean Patent Publication No. 10-2007-0005234

Accordingly, it is an object of the present invention to provide a water supply system capable of instantly detecting a leakage point in a large-scale water supply pipe network, thereby reducing the amount of water lost in the water supply and drainage pipe network and improving the reliability of tap water. And to provide a monitoring system for leakage detection of pipes.

According to an aspect of the present invention, there is provided a monitoring system for detecting water leakage in a water supply pipe, comprising: a water leakage detection device attached to a water supply pipe to generate and transmit a detection signal generated in the water supply pipe; A detection signal transmitted from a plurality of leakage detection devices within a predetermined interval is collected and stored, and when the detection signal transmitted from the leakage detection device exceeds a tolerance value of a previously stored detection signal, A main server for generating and transmitting warning data; A main server, connected to the main server, for receiving a detection signal for each leakage detection device and displaying it on the display unit, and displaying the information on the leakage detection device on the display unit when the alarm data is received from the main server, And a terminal.

Here, the leakage detection device may include a housing having an upper casing and a lower casing that are coupled to each other to be watertightly coupled to each other, a pressure protrusion is formed on a bottom surface of the space, and a magnetic body is formed on an outer bottom surface thereof. A sensing unit configured to convert the vibration signal, which is formed in the space unit, from the water pipe to the housing into an electrical detection signal; And a communication module which is formed in the space unit and receives a detection signal from the sensing unit and transmits the detection signal to the outside.

The sensing unit may include: a weight attached to the housing to vertically vibrate in response to a vibration transmitted from the water pipe to the housing; And a signal generating unit which is disposed in close contact with the pressing protrusion and converts a vibration signal of the weight to a detection signal and transmits the sensing signal to the communication module.

The signal generating unit may include an assembly socket in which a hollow is formed at the center and one or more fastening grooves are formed on a side surface thereof; A piezoelectric element disposed in the hollow; A first electrode board fixed to an upper surface of the assembly socket, the upper surface of the first electrode board being in close contact with the pressure terminal of the weight and the lower surface being in close contact with the upper surface of the piezoelectric element to generate a first signal; And a second electrode board which is fixed to a lower surface of the assembly socket and has a lower surface closely contacted with the pressing protrusion and an upper surface thereof being in close contact with a lower end of the piezoelectric element to generate a second signal.

The signal generating unit may further include a calculating unit that receives the first signal and the second signal generated from the first and second electrode boards and analyzes the same to generate a third signal.

For example, the third signal is an average value of the first signal and the second signal.

As another example, the third signal is any one of a first signal and a second signal.

In the meantime, the assembling socket is constituted so as to have a frame extending portion whose edge extends upward, and the inner diameter of the frame extending portion corresponds to the outer diameter of the weight, so that the outer circumference of the weight is guided on the inner circumference of the frame extending portion And a guide jaw is provided on the inner peripheral edge of the lower casing so that one outer peripheral edge of the assembly socket is guided on the inner peripheral edge of the guide jaw.

At this time, at least one guide protrusion and a fastening protrusion are protruded from one side of the lower casing, and one or more guide grooves for inserting the guide protrusion are formed on one side of the weights, At least one fastening groove into which the fastening protrusion is fitted is provided to prevent the weight and the assembling socket from rotating in the housing.

The distance between the lower end of the communication module and the upper end of the weight is less than 5 mm.

As described above, the monitoring system for detecting water leakage in the water pipe according to the present invention can detect the leakage of the water pipe immediately by detecting the vibration signal in the water leakage detection device attached to the water supply pipe and transmitting it to the radio control device. , Thereby reducing the amount of water lost in a large-scale water supply and drainage network and improving the reliability of tap water.

1 is a schematic view of a monitoring system for detecting leakage of a water pipe according to the present invention.
2 is a cross-sectional view showing an embodiment of an apparatus for detecting water leakage in a water supply pipe according to the present invention.
3 is a schematic view schematically showing a signal generating section which is an embodiment of the present invention.
4 is a perspective view showing an embodiment of an assembly socket which is a constitution of the present invention.
5 is a perspective view illustrating an embodiment of a weight according to an embodiment of the present invention.
6 is a sectional view showing another embodiment of a water leakage detection device for a water supply pipe according to 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 schematic view of a monitoring system for detecting water leakage in a water supply pipe according to the present invention, FIG. 2 is a sectional view showing an embodiment of a water leakage detection device for a water supply pipe according to the present invention, Fig. 2 is a schematic view schematically showing the in-signal generating unit; Fig. 5 is a perspective view showing an embodiment of a weight according to an embodiment of the present invention. FIG. 6 is a perspective view of a water supply system according to the present invention. FIG. Sectional view showing another embodiment of the leakage detection device for pipes.

As shown in FIG. 1, the monitoring system for leakage detection according to the present invention includes a leakage detection device 10, a main server 1, and an administrator terminal 2.

At this time, the water leakage detection device 10 is attached to the water supply pipe P, converts the vibration signal generated in the water supply pipe P into a detection signal, and transmits the detection signal to the following main server 1, The main server 1 collects and stores detection signals transmitted from a plurality of leakage detection devices 10 within a predetermined interval, compares the detection signals with the tolerance values of the previously stored detection signals, and compares the detection signals transmitted from the leakage detection device 10 Warning data for the leakage detection device is generated and transmitted to the following administrator terminal 2.

The administrator terminal 2 is connected to the main server 1 and receives a detection signal for each leakage detection device 10 and displays it on a display unit (not shown) And when the data is received, displays information on the leakage detection device 10 on the display unit

Here, the predetermined period means a period in which the leakage detection devices 10, which are provided by one main server 1, are located.

The leakage detection device 10 is characterized in that it includes a housing 100, a sensing unit 200, and a communication module 300 as shown in FIG. 2 as an embodiment of the present invention.

The housing 100 has a structure in which the upper casing 110 and the lower casing 120, which are watertight structures, are coupled to each other. In order to prevent water from being injected into the space 130 formed in the housing 100, The packing member 150 can be constructed.

A pressing protrusion 122 protrudes from the bottom surface of the space 130 to press the bottom surface of the sensing unit 200, which will be described later in detail.

As shown in the figure, the housing 100 may have a magnetic body 126 having a magnetic property on its bottom surface. Due to the magnetism of the magnetic body 126, a water pipe P having a generally outer surface made of a steel material, Without any additional configuration.

6, the shape of the bottom surface and the magnetic body 126 of the housing 100 may be formed to have an arc-shaped groove corresponding to the outer diameter of the water pipe, so that the housing 100 and the water pipe P So that it is structurally stable.

The sensing unit 200 is formed in the lower casing of the space 130. When the housing 100 is attached to the water pipe P and water passes through the water pipe P, P is converted into a detection signal, which is an electrical signal, is transmitted to the following communication module 300.

Here, the reason why the vibration signal is measured by the sensing unit 200 for detecting the water leakage is that when water flows through the water pipe P, a vibration signal of a certain frequency band is generated by the water pressure.

That is, when water does not flow into the water pipe P, a vibration signal is not generated, and the magnitude of the vibration signal changes according to the amount of water flowing. If a crack occurs in the water pipe P, , The amount of water flowing after passing through the leak point and the flow rate after passing through the leak point will change, resulting in a change in the vibration signal.

Therefore, when the vibration signal of the water pipe P is measured at all times, it is possible to detect whether the water pipe P is leaked or not.

1, the communication module 300 transmits a detection signal received from the sensing unit 200 to the radio control unit 1 through the communication network 2 as shown in FIG. 1. When the leakage occurs, the radio control unit 1 The difference between the detection signals generated when water flows from the one leak detection device 10 to the neighboring leak detection devices 10 is compared based on the inherent code assigned to each of the predetermined leak detection devices 10, And can be immediately maintained.

Hereinafter, the sensing unit 200, which is an embodiment of the present invention, will be described in more detail with reference to FIGS. 2 to 5. FIG.

2, the sensing unit 200 includes a weight 210 and a signal generator 220. The weight 210 is connected to the housing 100 through a water pipe (P), it is configured to vibrate up and down in response to vibration generated when water flows through the water pipe (P).

As shown in the drawing, the weight 210 may include a pressure terminal 212 protruding from the bottom of the weight 210 so as to concentrate the pressure of the vibration signal transmitted from the signal generator 220. do.

The signal generating unit 220 is configured such that the upper surface thereof is in close contact with the pressing end 212 and the lower surface is in close contact with the pressing protrusion 122 so that water flows into the water pipe P and is transmitted to the housing 100 And the upper and lower pressing protrusions 122 receive the vibration signals on the upper and lower sides and convert the vibration signals into electrical signals as detection signals and transmit the detection signals to the communication module 300.

The signal generating unit 220 according to the present embodiment includes an assembly socket 221, a piezoelectric element 222, a first electrode board 223, and a second electrode board 224 The first electrode board 223 and the second electrode board 224 are spaced apart from each other and the piezoelectric element 222 is sandwiched between the first electrode board 223 and the second electrode board 224, As shown in FIG.

As shown in FIG. 5, the assembly socket 221 has a hollow 221-1 passing through the center thereof, and at least one coupling groove 221-2 is formed at a side thereof.

The piezoelectric element 222 is formed in a shape corresponding to the hollow 221-1 so that both ends of the piezoelectric element 222 are exposed at both ends of the hollow 221-1.

At this time, the piezoelectric element 222 is an element that converts mechanical energy into electrical energy, and the amount of change of the vibration pressure can be measured by a detection signal as an electrical signal.

Piezoelectric, Piezo ceramic, Piezo quartz, or the like can be used as the piezoelectric element 222. Since these piezoelectric elements 222 are high in accuracy and relatively low in cost, Even if a plurality of water pipes are installed in the local water pipe (P), the installation cost can be reduced.

The first electrode board 223 is fixed to the upper surface of the assembly socket 221. The first electrode board 223 may be fixed to the upper surface of the assembly socket 221 by bolting or unbonding, The upper surface of the first electrode board 223 is in close contact with the pressing end 212 of the weight 210 and the lower surface of the first electrode board 223 is in close contact with the upper end of the piezoelectric element 222.

In addition, the second electrode board 224 is fixed to the lower surface of the assembly socket 221. The fixing method may include bolting or unbonding as shown in FIG. 2, The lower surface of the second electrode board 224 is in close contact with the pressing protrusion 122 of the housing 100 and the upper surface of the second electrode board 224 is in close contact with the lower end of the piezoelectric element 222.

The vibration pressure generated by the vibration of the weight 210 is transmitted to the piezoelectric element 222 through the first electrode board 223 and the vibration pressure generated from the lower side of the housing 100 The first electrode board 223 is configured to be transmitted to the piezoelectric element 222 through the second electrode board 224 so that the first electrode board 223 can receive the first signal as the detection signal generated from the piezoelectric element 222, The second electrode board 224 generates a second signal 224a which is a detection signal generated from the piezoelectric element 222 to which the vibration pressure of the lower side is transferred, 1 signal 223a and the second signal 224a are transmitted to the communication module 300. [

In addition, as described above, since the weight 210 and the piezoelectric element 222 are formed in a close contact structure with no gap, the weight 210 can be transmitted only by the vibration without hitting the piezoelectric element 222 It is possible to prevent the piezoelectric element 222 from being broken and to minimize the error even in the change of the surrounding environment, thereby generating the detection value.

This is because the weight 210 is connected to the spring and the pressure generated in the weight 210 by the vibration is transmitted to the piezoelectric element 222. In this case, The vibration of the piezoelectric element 222 may damage the piezoelectric element 222 and the elastic modulus of the spring may change according to the temperature to cause an error in the pressure signal transmitted to the piezoelectric element 222 However, according to the leakage detection device 10 of the present invention, all of these problems can be solved.

Meanwhile, the first signal 223a and the second signal 224a generated as shown in FIG. 3 may be immediately transmitted to the communication module 300, but the first electrode board 223, the second electrode board 224a, A third signal 230a is generated by analyzing the first signal 223a and the second signal 224a by providing the calculating unit 230 with the communication module 300 connected to the first signal 224 and the communication module 300 connected to the second signal 224, And transmit the generated third signal 230a to the communication module 300. [

At this time, the third signal 230a calculated by the calculation unit 230 may be an average value of the first signal 223a and the second signal 224a, thereby minimizing a deviation from the detection signal value with respect to the vibration pressure More stable detection signal data can be calculated so that more precise diagnosis of leaks can be made.

As another example of the third signal 230a calculated by the calculation unit 230, the third signal 230a may be a signal selected from the first signal 223a and the second signal 224a For example, a signal having a small deviation of signal values among the signals is selected and transmitted to the communication module 300, thereby minimizing the deviation of the detection signal value with respect to the vibration pressure as in the above embodiment, The detection signal data is calculated so that it is possible to precisely diagnose the leak or not.

The edge of the assembly socket 221 has an edge extending to the upper side of the assembly socket 221. The edge of the edge of the assembly socket 221 has an inner diameter corresponding to the outer diameter of the weight 210, So that the weight 210 can only be vertically vibrated, so that a more accurate detection signal can be obtained.

2, a guide protrusion 124 is provided on the inner circumference of the lower casing 120 so that the outer circumferential edge of the assembly socket 221 is guided by the inner circumference of the guide protrusion 124 The upper and lower vibration pressures can be received in the state of being interposed in the pressing end 212 of the weight 210 and the pressing protrusions 122 of the lower casing 120 so that the vibration pressure is guided only in the vertical direction A more accurate detection signal can be obtained.

In addition, although not shown in the drawing, at least one guide projection (not shown) and a fastening protrusion (not shown) are formed on the inner side of the lower casing 120, At least one guide groove (214) in which the guide protrusion is fitted is provided on the side surface, and at least one coupling groove (221-2) for fitting the coupling protrusion is provided on one side of the assembly socket (221) The weight 210 and the assembly socket 221 do not rotate in the housing 100 even when a strong vibration occurs periodically, and this also provides means for obtaining a more accurate detection signal.

2, the interval a between the lower end of the communication module 300 and the upper end of the weight 210 is set to be within 5 mm so that when the vibration of the weight 210 is generated, It is possible to control the lift width of the piezoelectric device 222. This is because when the weight 210 is strongly vibrated and the lift width increases, the piezoelectric device 222 may be damaged by damaging the piezoelectric device 222, The distance (a) between the lower end of the communication module 300 and the upper end of the weight 210 can be narrowed.

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.

1: main server 2: administrator terminal
10: Water leakage detection device 100: Housing
200: sensing unit 300: communication module
500: Control center

Claims (10)

A water leakage detection device attached to the water supply pipe to convert a vibration occurring in the water supply pipe into a detection signal and transmit the detection signal;
A detection signal transmitted from a plurality of leakage detection devices within a predetermined interval is collected and stored, and when the detection signal transmitted from the leakage detection device exceeds a tolerance value of a previously stored detection signal, A main server for generating and transmitting warning data;
A main server, connected to the main server, for receiving a detection signal for each leakage detection device and displaying it on the display unit, and displaying the information on the leakage detection device on the display unit when the alarm data is received from the main server, Terminal;
And a monitoring system for detecting leakage of the water in the water pipe.

The method according to claim 1,
The water leakage detection device
A housing in which the upper casing and the lower casing are watertightly coupled to each other and a pressing protrusion is formed on the bottom surface of the space portion formed on the inner side and a magnetic body is formed on the outer bottom surface and attached to the water pipe;
A sensing unit configured to convert the vibration signal, which is formed in the space unit, from the water pipe to the housing into an electrical detection signal;
A communication module that is formed in the space unit and receives a detection signal from the sensing unit and transmits the detection signal to the outside;
And a monitoring system for detecting leakage of the water in the water pipe. 3. The method of claim 2,
The sensing unit
A weight attached to the housing to vertically vibrate in conjunction with a vibration transmitted from the water pipe to the housing, and a pressing end projecting from the bottom;
A lower surface of which is in close contact with the pressing end and a lower surface of which is in close contact with the pressing protrusion, converts a vibration signal of the weight to a detection signal,
And a monitoring system for detecting leakage of the water in the water pipe.
The method of claim 3,
The signal generator
An assembly socket in which a hollow is formed at the center and one or more fastening grooves are formed on a side surface thereof;
A piezoelectric element disposed in the hollow;
A first electrode board fixed to an upper surface of the assembly socket, the upper surface of the first electrode board being in close contact with the pressure terminal of the weight and the lower surface being in close contact with the upper surface of the piezoelectric element to generate a first signal;
A second electrode board fixed to the lower surface of the assembly socket, the lower surface of the second electrode board being in close contact with the pressing protrusion and the upper surface of the second electrode board closely contacting the lower end of the piezoelectric element to generate a second signal;
And a monitoring system for detecting leakage of the water in the water pipe.
5. The method of claim 4,
The signal generator
And a calculation unit for receiving a first signal and a second signal generated from the first electrode board and the second electrode board and analyzing the first signal and the second signal to generate a third signal. Monitoring system.
6. The method of claim 5,
Wherein the third signal is an average value of the first signal and the second signal.
6. The method of claim 5,
Wherein the third signal is a signal selected from a first signal and a second signal.
5. The method of claim 4,
The assembly socket
And a frame extending portion having a frame extending upward,
The inner diameter of the rim extending portion corresponds to the outer diameter of the weight, so that the outer rim of the weight is vertically vibrated while being guided by the inner rim of the rim extending portion,
Wherein a guide jaw is provided on an inner circumference of the lower casing so that one outer circumference of the assembly socket is guided on the inner circumference of the guide jaw.
In the fourth aspect,
The lower casing has one or more guide protrusions and a plurality of fastening protrusions protruding from one inner side surface thereof,
One or more guide grooves in which the guide protrusions are fitted may be formed on one side surface of the weights, and one or more fastening grooves may be formed on one side surface of the assembly socket to receive the fastening protrusions,
Wherein the housing is configured to prevent the weight and the assembly socket from rotating in the housing.
The method of claim 3,
Wherein a distance between a lower end of the communication module and an upper end of the weight is less than 5 mm.

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