KR20130057181A - System for detecting water leak location - Google Patents

Abstract

PURPOSE: A system for detecting water leaked positions is provided to simultaneously transmit detection start signals to detected waveform transmitting parts arranged within a predetermined range. CONSTITUTION: A system for detecting water leaked positions(1000) comprise a vibration waveform detecting part(1100), a detected waveform transmitting part(1200), a detection start signal transmitting part(1300), and a water leaked position calculating part(1400). The vibration waveform detecting part detects vibration waveforms transmitted from the water leaked positions of water pipes. The detected waveform transmitting part transmits vibration waveforms detected after a detection start signal is received from the outside. The detection start signal transmitting part transmits the detection start signal to the detected waveform transmitting part. The water leaked position calculating part compares the vibration waveforms transmitted from the detected waveform transmitting part to calculate the water leaked positions. [Reference numerals] (1000) System for detecting water leaked positions; (1100) Vibration waveform detecting part; (1200) Detected waveform transmitting part; (1300) Detection start signal transmitting part; (1400) Water leaked position calculating part; (1500) Water leaked position transmitting part; (1600) Water leakage generation information transmitting part

Description

System for detecting water leak location

The present invention relates to a system for detecting the location of leak points, and more particularly, to a system for detecting leaks and locations of leaks accurately without damaging the water supply line, so as to enable rapid repair of leak points.

People living in the modern age are supplied with water for daily living through water pipes buried in the ground.

These water pipes can be damaged due to various factors such as aging, and it is important to detect the leakage and the flow rate because valuable living water is lost from the damaged parts (currently, about 80 countries that make up 40% of the world's population Suffer from a severe water shortage).

The methods of detecting leaks and measuring leaks in water supply pipes are as follows: direct measurement, indirect measurement, and flow measurement (comparison of the total amount of flowmeters installed at the water treatment plant and main pipeline branch points and the total amount of water used after one month of multiple customers). And flow rate measurement.

Of these, the largest part of the method uses a measuring device, which measures the flow rate / flow rate by inserting the measuring device into an existing pipeline.

However, such a method has difficulty in inserting the measuring device into the pipeline, and when the measuring device is inserted, it is difficult to always check and replace the measuring device, and the price is also high, so it is only installed in some areas where the risk of leakage is high. As a result, there is a problem in that leak detection cannot be efficiently performed.

In addition, even if the leak occurs in the water supply pipe, the exact location of the leak can not be detected, the maintenance work on the entire water pipe to detect the leak is forced to repair.

The present invention has been made to solve such a conventional problem, and to provide a system that can reduce the difficulty of construction and the additional cost of construction, and to obtain accurate information about the leakage occurs and the leak location occurred. The purpose.

In order to achieve the above object, the leak detection position detection system according to the present invention includes a vibration waveform detector and a detection waveform transmitter. The vibration waveform detector is in contact with the water pipe, and detects the vibration waveform transmitted from the leak point on the water pipe. The detection waveform transmitter receives the detection start signal of the vibration waveform from the outside, and detects the vibration waveform detected after the detection start signal is received. Send to the outside.

As such, since only the vibration waveforms after the externally detected detection start signal are transmitted to the outside of the vibration waveforms transmitted from the leaking points, the exact position of the leaking points may be determined by comparing the vibration waveforms transmitted from different detection waveform transmitters. It becomes possible.

In addition, the position detection system of the leak point may further include a detection start signal transmitter and a leak point position calculator. The detection start signal transmission unit simultaneously transmits a detection start signal to a detection waveform transmission unit which contacts the water pipes before and after the leakage point, and the leakage point position calculation unit compares the vibration waveform transmitted from the communication unit to which the detection start signal is transmitted to the leakage point. Calculate the position of.

As described above, since the detection start signal is simultaneously transmitted to different detection waveform transmitters, the vibration waveforms can be compared more effectively.

In addition, the leak point position detection system may further include a leak point position transmission unit for receiving a leak position detection signal received from the outside and transmitting the position of the leak point to the outside.

By constructing the leak point position transmission unit between the detection waveform transmission unit and the central control system in this way, all the vibration waveform detection units do not need to be equipped with long distance communication, and simultaneously transmit the detection start signal to the detection waveform transmission units within a certain range. It is easy to do. In addition, since the plurality of vibration waveform detectors need only transmit the calculated leakage point position, compared to the case of transmitting the vibration waveform, the communication burden with the central control system is reduced.

The apparatus may further include a leak occurrence information transmitting unit configured to transmit a leak occurrence fact on the water supply line to the outside. This configuration allows the central control system to selectively check the leak location only for the pipeline where the leak occurred, rather than always checking the leak location for all water pipelines.

The apparatus may further include a sensor unit and a detection unit for detecting leakage occurrence. The sensor unit is in contact with the water supply pipe, and measures the vibration sound generated in the water supply pipe according to the preset measurement conditions, the detection unit sets the measurement conditions, and detects the magnitude of the minimum vibration sound of the magnitude of the vibration sound measured by the sensor unit.

With this configuration, a high accuracy and low cost leak detection device can be easily installed outside the water supply pipe without the need of inserting the leak detection device in the water supply line, thereby reducing the construction difficulty and the consumption of additional construction cost, and Accurate information for the detection can be obtained.

In addition, the detection unit may send a trigger event for notifying that the reference value is exceeded when the magnitude of the minimum vibration sound exceeds a preset reference value.

The detector may detect the magnitude of the minimum vibration sound exceeding the reference value when the magnitude of the minimum vibration sound exceeds the preset reference value.

Therefore, since only the information necessary for leak detection can be screened out from the measured magnitude of the vibration sound, the information transmission speed and the leak detection speed can be increased.

In addition, the detection unit may set the size of the minimum vibration sound exceeding the reference value as a new reference value, whereby, it is possible to check whether or not additional leakage from the size of the minimum vibration sound exceeding the newly set reference value.

In addition, the detector may store the minimum vibration sound level measured for each setting period included in the measurement condition in a nonvolatile memory for storing a preset period.

In addition, the detection unit may be connected to the manhole cover.

That is, since the antenna of the detection unit can be connected to the manhole cover, this can effectively transmit information from the detection unit to the outside.

According to the present invention, since only the vibration waveform after receiving the detection start signal received from the outside of the vibration waveform transmitted from the leak point is transmitted to the outside, the exact position of the leak point by comparing the vibration waveform transmitted from the different detection waveform transmitters Will be able to figure out.

In addition, since the detection start signal is simultaneously transmitted to different detection waveform transmission units, it is possible to compare vibration waveforms more effectively.

In addition, it is not necessary for all the vibration waveform detectors to be equipped with equipment for long distance communication, and it becomes easy to simultaneously transmit the detection start signal to the detection waveform transmitters within a certain range.

In addition, since the plurality of vibration waveform detectors need only transmit the calculated leakage point position, compared to the case of transmitting the vibration waveform, the communication burden with the central control system is reduced.

In addition, since the plurality of vibration waveform detectors need only transmit the calculated leakage point position, compared to the case of transmitting the vibration waveform, the communication burden with the central control system is reduced.

In addition, the central control system does not always check the location of leaks for all pipelines, but may selectively check the location of leaks only for the pipeline where the leak occurred.

In addition, it is possible to easily install a high-precision and low-cost leak detection device in the water supply pipe without the need to insert a leak detection device in the water supply pipe, thereby reducing construction difficulties and additional consumption of construction costs, and for leak detection Accurate information can be obtained.

In addition, since only the information necessary for leak detection can be screened out of the measured vibration sound volume and transmitted to the outside, information transmission speed and leak detection speed can be increased, and additional leakage can be checked from the size of the minimum vibration sound exceeding the newly set reference value. Can be.

1 is a schematic block diagram of one embodiment of a leak detection position detection system according to the present invention;
2 is a view schematically showing a state of use of the position detection system of the leak point of FIG.
FIG. 3 is a block diagram schematically illustrating an embodiment of a leak detection apparatus for the leak occurrence information transmitting unit of FIG. 1; FIG.
4 is a view showing in detail an embodiment of a sensor unit configuration.
5 is a diagram illustrating an embodiment of a PCB substrate included in a signal generator.
6 is a block diagram schematically showing an embodiment of the configuration of a detector.

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

1 is a schematic block diagram of an embodiment of a leak detection position detection system according to the present invention.

In FIG. 1, the position detection system 1000 of the leak point includes a vibration waveform detector 1100, a detection waveform transmitter 1200, a detection start signal transmitter 1300, a leak point position calculator 1400, and a leak point. And a location transmitter 1500 and a leak occurrence information transmitter 1600.

The vibration waveform detection unit 1100 contacts the water supply line, detects a vibration waveform transmitted from a leak point on the water supply line, and the detection waveform transmission unit 1200 receives a detection start signal of the vibration waveform from the outside and detects a detection start signal. The vibration waveform detected after reception is transmitted to the outside.

As such, since only the vibration waveforms after the externally detected detection start signal are transmitted to the outside of the vibration waveforms transmitted from the leaking points, the exact position of the leaking points may be determined by comparing the vibration waveforms transmitted from different detection waveform transmitters. It becomes possible.

The detection start signal transmitter 1300 simultaneously transmits a detection start signal to a detection waveform transmitter that contacts the water pipe before and after the leak point, and the leak point position calculator 1400 is transmitted from the communication unit to which the detection start signal has been transmitted. The position of the leakage point is calculated by comparing the obtained vibration waveforms.

As such, since the detection start signal is simultaneously transmitted to the different detection waveform transmitters 1200, the vibration waveforms can be compared more effectively.

In this case, the detection start signal transmission unit 1300 and the leak point position calculation unit 1400 may be integrally implemented with the central control system, and may be connected to the detection waveform transmission unit 1200 using remote wireless communication. It may be desirable to implement a separate device between the waveform transmitter 1200 and the central control system.

2 is a view schematically showing a state of use of the position detection system of the leak point of FIG.

In FIG. 2, the detection start signal transmitter 1300 and the leak point position calculator 1400 are implemented as a separate device between the detection waveform transmitter 1200 and the central control system 2000 to transmit the detection waveform. In the near field communication with the unit 1200, the central control system 2000 may check a state of communicating with each other using long range wireless communication.

In addition, the vibration waveform detection unit 1100 and the detection waveform transmission unit 1200 are formed integrally and are respectively installed on the water supply conduit 3000, and different vibration waveforms before and after the leak point 3100 of the water supply conduit 3000 It can be confirmed that the detection units 1100 are respectively installed.

In addition, it may be confirmed that the leak point position transmitter 1500 and the leak occurrence information transmitter 1600 are integrally formed together with the detection start signal transmitter 1300 and the leak point position calculator 1400. .

In FIG. 2, the detection start signal transmitter 1300 and the leak point position calculator 1400 are implemented in one sensor device, together with an integrally formed vibration waveform detector 1100 and a detection waveform transmitter 1200. Although it is implemented to be used, it may be implemented to be used together with three or more sensor devices (vibration waveform detector 1100 and detection waveform transmitter 1200) according to the use state.

In this case, one detection start signal transmitter 1300 simultaneously transmits a detection start signal to three or more detection waveform transmitters 1200 and detects each of the detection waveform transmitters 1200 to which the detection start signal is transmitted. The received vibration waveform is received.

As can be seen in FIG. 2, a vibration waveform is generated at the leak point, and the generated vibration waveform is transmitted to different vibration waveform detection units 1100 along the water conduit 3000.

However, since the arrival time of the vibration waveform varies with each vibration waveform detection unit 1100 due to the difference in distance between the leak point and each vibration waveform detection unit 1100, in the present invention, the detection start signal transmission unit 1300 is used to detect each detection waveform. Simultaneously transmitting the detection start signal to the transmitter 1200 and receiving the detected waveform after receiving the detection start signal, the leakage point position calculator 1400 calculates the exact position of the leakage point.

The leak point location transmitter 1500 receives a leak location detection signal received from the outside and transmits the location of the leak point to the outside.

In FIG. 2, a leak start position transmitter 1500 formed integrally with the detection start signal transmitter 1300, the leak point position calculator 1400, and the leak occurrence information transmitter 1600 is provided from the central control system 2000. An example of receiving a leak position detection signal and transmitting the position of the leak point calculated by the leak point position calculator 1400 to the central control system 2000 is illustrated.

As such, by configuring the leakage point position transmitter 1500 between the detection waveform transmitter 1200 and the central control system 2000, all the vibration waveform detectors 1100 do not need to be equipped with long distance communication. At the same time, it is easy to simultaneously transmit a detection start signal to the detection waveform transmitters 1200 within the range. In addition, since the plurality of vibration waveform detectors 1100 only need to transmit the calculated leakage point position as compared with the case of transmitting the vibration waveform, the communication burden with the central control system 2000 is reduced.

The leak occurrence information transmitting unit 1600 transmits a leak occurrence fact on the water supply line 3000 to the outside. This configuration allows the central control system 2000 not only to check the leak location for all the pipelines at all times, but also to selectively check the leak location only for the pipeline where the leak occurred.

In this case, the leak occurrence information may be generated by the leak generation detection module integrally formed, but may be transmitted from a separate device for leak detection.

3 is a block diagram schematically showing an embodiment of the configuration of the leak detection apparatus 100 for detecting the occurrence of a leak, the leak detection apparatus 100 includes a sensor unit 110 and the detection unit 120.

The sensor unit 110 contacts the water supply conduit 10, and measures the vibration sound generated by the water supply conduit 10 according to a preset measurement condition.

First, the reason for measuring the vibration sound in the sensor unit 110 for the leak detection, when water flows in the water supply pipe 10 will generate a vibration sound of a certain frequency band by the water pressure (in this case, the vibration sound frequency of the pipe Occurs differently depending on material properties).

That is, when water does not flow in the water supply pipe 10, the vibration sound does not occur, and when water flows, the magnitude of the vibration sound changes according to the amount of flowing water. Since the amount of water flowing before and after passing the leak point is changed, there is a change in the vibration sound.

Therefore, when constantly measuring the vibration sound of the water pipe 10 can detect whether the water pipe 10 is leaked.

At this time, if the water pipe 10 is constantly monitored for 24 hours, since a large amount of information is generated, a large amount of time and money is wasted in managing the information and analyzing the information to detect the leak.

Therefore, in the present invention, the vibration sound of the water pipe 10 is measured according to a preset measurement condition such as a time zone, a measurement interval (period), and the like.

That is, at a time interval set such as 5 seconds, 10 seconds, 60 seconds, or 10 minutes, the vibration sound is always measured only during a specific time period (for example, from 2 am to 5 am) that uses little water.

Next, the sensor unit 110 will be described in detail with reference to FIGS. 4 and 5.

4 is a view illustrating an embodiment of the configuration of the sensor unit 110 in detail, Figure 5 is a view showing an embodiment of a PCB substrate included in the signal generator 114.

The sensor unit 110 may include a vibrating sound detector 112 and a signal generator 114 as shown in FIG. 4. The vibrating sound detector 112 may include a mechanical structure, and may include a signal generator ( 114 may include a piezoelectric element and a PCB substrate.

When the fine vibration sound occurs up and down in the water supply pipe 10, the mass body placed on the spring having a constant elastic modulus in the vibration sound detecting unit 112 acts on the fine vibration sound of the water supply pipe 10 to move up and down.

The vertical motion of the mass causes a pressure change on the PCB substrate of the signal generator 114 positioned as shown in FIG. 2B, and the piezoelectric element attached to the PCB substrate converts the pressure change amount into an electrical signal to vibrate the water pipe 10. The size of can be measured.

Piezoelectric elements such as piezo electric, piezo ceramic, piezo quartz, etc. can be used, and since these piezoelectric elements have high accuracy and are relatively inexpensive, they can be used in large water supply lines (10). ) Can be installed without a burden on the installation cost.

Again, referring to FIG. 4, the vibration sound detecting unit 112 may be implemented inside the body of the cylindrical outer case (that is, a spring and a mass are inserted into the body of the cylindrical outer case), and the signal generator ( 114 may be located in the cover portion of the cylindrical outer case (ie, the PCB to which the piezoelectric element is attached is fastened to the cover portion of the cylindrical outer case with screw screws).

The output signal of the piezoelectric element is transmitted to the detection unit 120 through the signal cable through the waterproof pad, the body portion and the cover portion of the cylindrical case can be waterproofed using a waterproof rubber ring.

The detector 120 may set a measurement condition, detect a magnitude of the minimum vibration sound among the magnitudes of the vibration sound measured by the sensor 110, and transmit the measurement to the outside.

That is, the magnitude of the detected minimum vibration sound is transmitted to an external central control system, and the minimum vibration sound level is compared by comparing a reference value (or a predetermined range) with the minimum vibration sound level for detecting whether a leak is preset in the central control system. If the reference value is exceeded, a leak can be detected.

In this case, the reference value may be the size of the minimum vibration sound measured for the first time (for example, the size of the minimum vibration sound when the leakage measured immediately after installation of the water pipe 10 does not occur).

Since the magnitude of the minimum vibration sound is measured at a time when water is rarely used, if the leakage does not occur, the magnitude of the minimum vibration sound almost matches the reference value.

On the other hand, if a leak occurs, a change in the flow of water occurs, so the magnitude of the minimum vibration sound is greater than the reference value.

In this way, the central control system can detect whether there is a leak by comparing the reference value and the magnitude of the minimum vibration sound transmitted from the detection unit 120.

In addition, when the size of the minimum vibration sound exceeds a preset reference value, the detection unit 120 may detect the size of the minimum vibration sound exceeding the reference value, and transmit the information about this and a trigger event for notifying the fact that the reference value is exceeded.

That is, the detection unit 120 may set a reference value (same as the reference value of the central control system), and compare the magnitude of the minimum vibration sound measured by the detection unit 120 with the reference value, for the magnitude of the minimum vibration sound exceeding the reference value. Trigger events can be sent to an external central control system to inform you of information and thresholds (depending on settings, you can also send measurement dates, measurement points, etc., and generate alarm sounds).

That is, since the detection unit 120 can select only the information necessary for leak detection from the measured magnitude of the vibration sound and transmit it to the central control system, the information transmission speed can be increased due to the decrease in the amount of information transmitted, and the central control system can detect the detection unit ( 120 does not need to compare the size of the minimum vibration sound received from, because it detects the leakage immediately can increase the speed of leak detection can be possible to quickly repair work in real time.

In addition, the detector 120 may set the minimum vibration sound level exceeding the reference value as the reference value.

The generation of a minimum amplitude of vibrations above the reference value indicates a leak. In some situations, even if a leak occurs, the leak level is included in the safety range, so only a continuous leak check may be necessary without repair work.

In this case, if the leak is detected based on the existing reference value, the leak can be continuously detected, but it is difficult to know the increased amount of leak accurately, and thus, the time for repair work may be missed.

Therefore, the minimum vibration sound level exceeding the reference value at the time of occurrence of leakage is set as a new reference value, and the occurrence of additional leakage can be detected when the measured minimum vibration sound level exceeds the new reference value.

In addition, the detector 120 may store, in a nonvolatile memory, the minimum vibration sound level measured for each set period included in the measurement condition, by storing the information in the memory for a preset period (at least one year or more). This information can be provided in case of loss.

6 is a block diagram schematically illustrating an embodiment of the configuration of the detector 120.

Referring to FIG. 6, the detector 120 may include a signal detector 122, a power supply unit 124, a controller 126, and a communication unit 128.

The signal detector 122 may include a charger amplifier for amplifying a signal input through a sensor input terminal connected to a signal cable of the sensor unit 110 shown in FIG. 2A, a band pass filter for passing only a specific frequency band of the amplified signal, and a filter. An RMS detector converts the magnitude of the output signal into a DC signal, and an A / D converter converts the RMS detection signal into a digital signal.

The power supply unit 124 includes a battery and a power control unit. In order to use a small capacity battery for a long time, the power control unit controls the power of the signal detection unit 122 and the communication unit 128 according to a microprocessor control signal of the control unit 126. Performs On / Off function in.

In addition, the power supply unit 124 may be turned on only when the signal detection unit 122 measures the size of the signal to reduce battery consumption as much as possible, and the communication unit 128 may also intelligently turn on / off power by a microprocessor to reduce battery consumption. It can be reduced as much as possible.

The controller 126 may include a microprocessor and a storage memory.

The microprocessor controls the power of the signal detector 122 through the power supply unit 124, and periodically measures the magnitude of the signal by controlling the A / D converter of the signal detector 122.

In addition, the microprocessor stores the collected information in a nonvolatile storage memory, and transmits the information stored in the storage memory when there is a request for information from the outside through the communication unit 128.

The storage memory stores not only measurement values but also measurement conditions and reference values for the vibration sound measurement of the sensor unit 110 mentioned above.

In addition, depending on the setting, when the power supply is applied or initialized in the off state, the leak detection apparatus 100 may initialize and load information stored in the storage memory.

The communication unit 128 may include a wired communication unit and a wireless communication unit. Wired communication (eg, RS232, etc.) may be used for device setting and firmware upgrade, and wireless communication may be used for transmitting collection information.

The leak detection device 100 including the sensor unit 110 and the detection unit 120 as described above may be attached to the outside of the water supply conduit 10 using a permanent magnet as shown in FIG. 6.

In this case, the water supply pipe 10 is preferably composed of a cast iron pipe that can be attached to the permanent magnet, and, in addition, when using a permanent magnet to the antenna line connected to the communication unit 128 of the detection unit 120, the manhole antenna line Since it can be attached to the lid, communication efficiency can be improved.

With the configuration of the sensor unit 110 and the detection unit 120, the leak detection device 100 is easily installed outside the water supply conduit 10 without having to insert the leak detection device 100 into the water supply conduit 10. Therefore, it is possible to reduce the difficulty of construction and the additional cost of construction, and obtain accurate information for leak detection.

So far I looked at the center of the preferred embodiment for the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

1000: location detection system of leak point
1100: vibration waveform detection unit
1200: detection waveform transmission unit
1300: detection start signal transmission unit
1400: leak point position calculation unit
1500: leak point position transmission unit
1600: leak occurrence information transmission unit
2000: central control system
3000, 10: running water pipe
3100: leak point
110:
112: vibration detection unit 114: signal generator
120: detection unit
122: signal detector 124: power supply
126: control unit 128: communication unit

Claims (10)

A vibration waveform detection unit in contact with a water supply line and detecting a vibration waveform transmitted from a leak point on the water supply line; And
And a detection waveform transmission unit for receiving a detection start signal of the vibration waveform from the outside and transmitting the vibration waveform detected after the detection start signal is received to the outside. The method of claim 1,
A detection start signal transmission unit for simultaneously transmitting the detection start signal to the detection waveform transmission unit that respectively contacts the water pipes before and after the leak point; And
And a leakage point position calculation unit for comparing the vibration waveform transmitted from the detection waveform transmission unit to which the detection start signal is transmitted to calculate the position of the leakage point. The method of claim 2,
And a leak point location transmitter for receiving a leak location detection signal received from the outside and transmitting the location of the leak point to the outside. The method of claim 1,
Leakage point position detection system further comprises a leak generation information transmission unit for transmitting the fact that the leakage occurs on the water supply pipe to the outside. 5. The method of claim 4,
A sensor unit in contact with the water pipe line and measuring vibration sounds generated from the water pipe line according to preset measurement conditions; And
A detector configured to set the measurement condition and detect a magnitude of a minimum vibration sound among the magnitudes of vibration sounds measured by the sensor unit; Position detection system of the leak point further comprising a. 6. The method of claim 5,
The detection unit,
And when the magnitude of the minimum vibration sound exceeds a preset reference value, a trigger event for notifying that the reference value has been exceeded is transmitted to the outside. 6. The method of claim 5,
The detection unit,
And when the magnitude of the minimum vibration sound exceeds a preset reference value, detecting the magnitude of the minimum vibration sound exceeding the reference value. 8. The method of claim 7,
The detection unit,
Leak point position detection system, characterized in that for setting the minimum vibration sound level exceeding the reference value as a new reference value. 6. The method of claim 5,
The detection unit,
The location of the leak point detection system, characterized in that for storing in the non-volatile memory for storing for a predetermined period the size of the minimum vibration sound measured for each set period included in the measurement conditions. 6. The method of claim 5,
The detection unit,
A leak detection position detection system, characterized in that connected to the manhole cover.

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