JP3263044B2 - Water leak monitoring device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water leakage monitoring device, and more particularly to a method for converting acoustic vibration transmitted to a water pipe into an electric signal and presenting data for judging whether or not there is water leakage based on the electric signal. The present invention relates to a water leakage monitoring device.

[0002]

2. Description of the Related Art === Social Background === Water used for drinking water and the like is supplied to each house through a water supply pipe branched from a water distribution pipe. The distribution / supply pipes (water pipes) for water supply are severely decrepit, and the resulting water leakage has become a serious social problem. At present, it is said that the amount of water leakage has reached 10% or more of the amount of water taken and distributed as clean water. Then, in summer, water shortages occur mainly in urban areas. In order to make up for the amount of water lost due to water leakage, a new water source must be developed, which is enormously expensive. In addition, it will have a significant impact on the natural environment of the water source.

[0003] Therefore, it is necessary to repair the water leakage point of the water pipe as soon as possible to eliminate the loss of precious water resources due to the water leakage. For that purpose, it is important to sequentially monitor the condition of the water pipes over a wide range and quickly detect leaks.

=== Conventional Water Leak Monitoring / Detection Technique === Conventionally, water leaks in water pipes have been detected by humans hearing acoustic vibrations transmitted directly to the water pipes. Water leakage inspections are performed during late hours, such as late at night, when traffic and traffic are low and water usage is reduced, so as to eliminate as much as possible noise and confusing acoustic vibrations caused by normal running water. Then, following the water pipe buried underground according to the laid map, a specialized technician listens to the acoustic vibration transmitted through the water pipe with a stethoscope on the ground or directly on the surface of the water pipe to determine whether there is water leakage. is there.
However, this method has a limited working time, and the range of water pipes that can be inspected is extremely narrow. Therefore, it takes an enormous amount of time to identify the leak location from the vast survey target area. This cannot keep up with the aging of water pipes, which is steadily progressing year after year. Also, depending on the skill of the inspector, it may not be possible to reliably detect water leakage.

Therefore, Japanese Patent Laid-Open Publication No. Hei 5-296824 (conventional example 1), Japanese Unexamined Utility Model Publication No. Hei 6-125564 (conventional example 2), Japanese Patent Laid-Open Publication No. Hei 6-146346 (conventional example 3), etc. Discloses a technology of a water leak monitoring device that can be detected.

The conventional example 1 converts vibration transmitted through a pipe flow path such as a water pipe into an electric signal, and adds an allowable range to the electric signal corresponding to the vibration in a state where no fluid flows in the pipe flow path. The pattern of the electric signal is stored in advance as a noise component. Then, by comparing the electric signal pattern when the fluid is flowing in the pipe flow path with that of the noise component, and recognizing that the electric signal pattern is different from the normal flowing liquid state, it is determined that there is water leakage. .

In the prior art 2, the amount of water flowing through the water pipe indicated by the water meter attached to the water supply pipe of each house is compared with a predetermined amount of water leakage, and the amount of water indicated by the meter determines the set value of the amount of water leakage. When exceeded, it is judged as leak.
Furthermore, Conventional Example 3 monitors the amount of water output from the water meter and the vibration caused by running water flowing through the water pipe,
When the meter does not show the consumption, that is, when the vibration of the water pipe is detected when the water is not used, it is determined that there is water leakage.

[0008]

The prior art 1 is basically a water leakage monitoring device in a water pipe for cooling water of a plant, in which a signal pattern of environmental noise is stored in a state where water is not flowing in advance. Need to be kept. Therefore, it is difficult to apply this technology to already installed water pipes. Further, complicated digital data processing such as signal pattern recognition is required, and the apparatus itself becomes expensive. If a large number of such devices are installed in order to identify a leak location from a wide water pipe laying area, enormous costs will be incurred.

Conventional example 2 is a technique for monitoring water leakage when a person is away from home in a villa or the like for a long period of time, and is based on the premise that water is not used during absence. Then, the water meter detects water leakage from the water pipe on the indoor side. Therefore, the present invention cannot be applied to the detection of water leakage in a general water pipe, which is a problem in the present invention.

Conventional example 3 is based on the premise that when the water meter does not indicate running water, there is no environmental vibration caused by surrounding noise or traffic. Conversely, water may be used even at midnight when environmental vibrations are low. Therefore, the probability of detecting a water leak is small, and it is difficult to take a quick response. In addition, if it is desired to accurately separate environmental vibration and vibration caused by water leakage, complicated signal processing and expensive equipment are required as shown in the first conventional example.

Here, when considering these conventional water leak detection methods, it is understood that the conventional method is based on the idea of obtaining some information due to the water leak and judging that there is a water leak based on the information. . However, in the current social environment, water is used day and night, and noise and vibration due to traffic and the like are rarely interrupted for a long time. For this reason, it is difficult to achieve a water leakage monitoring device that detects water leakage over a wide area at a low cost, accurately, quickly, by using the conventional water leakage detection technology.

[0012]

Accordingly, the present inventor has stated that the water leakage is continuous without stopping at a constant water volume, and that the normal water flow due to noise or tap water is intermittent / irregular. I paid attention to. If the water pipe is in a normal state, the vibration transmitted through the water pipe is intermittent / irregular, and if a state without vibration can be detected for a short time of several seconds, water leakage may have occurred. It was inferred that the sex could be judged to be extremely low, and many experiments confirmed that the technique was appropriate. As a result, the following invention was made.

According to a first aspect of the present invention, an oscillating electric converting means for converting acoustic vibration transmitted to a water pipe into an electric signal, and processing an output signal of the oscillating electric converting means so that a signal in a predetermined band exceeds a predetermined continuation condition. continuously leak by counting the signal discrimination means for generating a sound interruption detection signal indicating the possibility of not water leakage by detecting the number of occurrences of the sound interruption detecting signal that falls below a predetermined level Te Not possible
A water leakage monitoring device provided with a counting means for obtaining a count value indicating the size .

Further, in the first invention, a water leakage monitoring apparatus having a display means for displaying and outputting the count value of the counting means is provided as a second invention, and the count value of the counting means is output in the form of a data signal. A third aspect of the present invention is a water leak monitoring device provided with a signal output means for performing the above.

Further, a fourth aspect of the present invention is the water leakage monitoring device according to any one of the first to third aspects, further comprising a manual reset means for resetting the counting means in response to a switch operation or the like by a human. In any one of the fourth to fourth aspects, the clock circuit means for measuring time and the automatic reset means for storing the count value of the counting means in a predetermined memory area and resetting the counting means at every predetermined monitoring cycle. The water leakage monitoring device provided is a fifth invention.

Further, in the first invention, clock circuit means for measuring time, water leakage determination means for determining whether or not water leakage has occurred based on the number of occurrences of the sound interruption detection signal in a predetermined monitoring cycle; Determination result storage means for storing the determination result of the determination means in a predetermined memory area for a predetermined monitoring cycle, and determination result output means for outputting the determination result stored in the storage means in the form of a display output or a data signal The sixth aspect of the present invention is a water leakage monitoring device having the following.

According to a seventh aspect of the present invention, in the first aspect, a clock circuit means for measuring time, and determining that there is no water leakage when the number of occurrences of the sound interruption detection signal in a predetermined monitoring cycle is equal to or more than a predetermined number. Water leak determining means for determining that water has leaked when the number of occurrences of the sound interruption detection signal is less than the predetermined number of times in a continuous predetermined number of monitoring cycles. The water leakage monitoring device includes a determination result storage unit that stores the determination result in a predetermined memory area, and a determination result output unit that outputs the determination result stored in the storage unit in the form of a display output or a data signal.

According to an eighth aspect of the present invention, in any one of the first to seventh aspects, the clock circuit means which always operates and measures time, and the clock circuit means which always operates together with the clock circuit means and is based on a predetermined time plan. An intermittent operation control means for intermittently supplying operating power to another circuit means to activate the other circuit means.

In the eighth aspect of the present invention, a water leakage monitoring apparatus comprising a control means for terminating the operation of the monitoring cycle to a pause cycle when the sound interruption detection signal is detected a predetermined number of times during a certain monitoring cycle. Is the ninth invention.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS === Outline of Water Leakage Monitoring Device === In a water pipe, vibration caused by flowing water due to normal consumption of water, vibration caused by flowing water due to water leakage, and surrounding noise Various acoustic vibrations such as environmental vibrations are transmitted. If these acoustic vibrations are interrupted, it can be determined that there was no running water due to water leakage in the water pipe.
The water leakage monitoring device according to the present invention presents a material for determining the presence or absence of water leakage by outputting the frequency of interruption of vibration transmitted to a water pipe in an appropriate data format.

=== Configuration and Operation of Water Leakage Monitoring Device === FIG. 1 is a schematic diagram showing the configuration of a water leakage monitoring device according to an embodiment of the present invention. This water leak monitoring device (hereinafter, device) 1 is installed and used in a water pipe that is piped door to door. In this embodiment, a water pipe is provided near a water meter on a water supply side. Of course, it can also be installed in a drain pipe on the drain side to monitor leakage in the sewage flow path.

The device 1 has a built-in power supply
The circuit configuration is such that the digital circuit section 20 that always operates according to the signal form to be processed and the signal processing function.
And the analog circuit section 10 which operates intermittently under the control of the digital circuit section 20. Further, a liquid crystal display (LCD) 30 for displaying and outputting data corresponding to the monitoring result of the water pipe and an operation panel 40 for performing various setting inputs (described later) to the apparatus 1 are provided.

In the present embodiment, each of the analog circuit section 10 and the digital circuit section 20 is formed of a one-chip IC, but the circuit elements of the analog and digital signal processing systems are incorporated in the one-chip IC. It is also possible to adopt a different configuration. Of course, some or all of the circuit elements can be configured by individual elements. Next, a specific circuit configuration and operation will be described.

<Analog Circuit> The vibration sensor 11 is attached to the surface of a water pipe and converts acoustic vibration transmitted through the water pipe into a weak electric signal (sound signal). The analog circuit section 10 is a processing system for the acoustic signal. Vibration sensor 1
The acoustic signal output from 1 is amplified by the amplifier 12. The frequency filter 13 cuts a signal in a frequency band that is not necessary for discriminating a water flow sound such as a high frequency band in the amplified signal. The rectifier circuit 14 performs envelope detection on the acoustic signal that has passed through the filter 13. This detection output Vs is applied to the voltage comparator 1
At 5, the value is compared with a predetermined reference voltage value Vr. And V
When s> Vr, predetermined voltage (High level: H)
The signal Vout is output, and when Vs <Vr, Lo
W level (L) Vout is output. In addition, since the occurrence or stop of instantaneous vibration is not related to the occurrence or stop of vibration in detecting water leakage, an appropriate time constant is set and the instantaneous change of the acoustic signal is ignored. May be provided.

<Digital Circuit Unit> Digital Circuit Unit 10
Controls the analog circuit unit 10 according to a predetermined time schedule, counts the number of times the vibration transmitted through the water pipe is interrupted based on the Vout signal output from the analog circuit unit 10, and displays the count value on the LCD 30.
Output as data to be displayed on

The calendar circuit 23 includes a clock generator 22.
Driven by clock pulses from the current date and time are monitored. The controller 24 stores data corresponding to a plurality of times in a register, and acquires time data from the calendar circuit 23 to intermittently close the switch 60 according to a predetermined schedule corresponding to the plurality of time data. I do.

Accordingly, the analog circuit section 10 operates by being supplied with power every time the controller 24 closes the switch. In the present embodiment, one day (24 hours) is defined as one monitoring cycle, and three hours from 2:00 am to 5:00 am, when it is considered that ordinary running water and environmental vibrations are relatively small, are measured. An operation time of 2 seconds is set at minute intervals. That is, every day at 2:00 am
It operates for 2 seconds, pauses for 2 minutes and 58 seconds, and also operates for 2 seconds.
And a pause of 2 minutes 58 seconds ... This operation is repeated until 5:00 am to complete the measurement on that day (monitoring cycle).
The same operation is performed again at 2:00 am the next day. The controller 24 also performs an operation of setting the control signal Vc to H in conjunction with the operation of closing the switch 60.

The timer 21 measures time by counting clock pulses from the clock generator 22, and outputs one pulse as a sound interruption detection signal when measuring a preset time. Then, the counter 25 is incremented by this pulse. In this embodiment, the number of clock pulses for about 2 seconds is stored in the register of the timer 21. When the number of pulses is counted, the counter 25 is incremented. Further, an operation of receiving a reset signal Vres of L level via the AND circuit 26 and resetting the time measurement is also performed. In this embodiment, AND
The circuit 26 inputs the inverted signal of Vout and Vc, and when Vc is H and the Vout signal is L, the reset signal becomes H and the timer 21 counts clock pulses. Therefore,
When the vibration transmitted to the water pipe is maintained at a predetermined level or less during the operation time of 2 seconds of the analog circuit section 10, the timer 21 outputs a sound interruption detection signal, and the counter 24 is incremented. The number of clock pulses stored in the register of the timer 21 is determined by the delay time from the start of the operation of the analog circuit unit 10 to the output of Vout or the actual clock pulse after Vres becomes L. Considering the delay time before counting
The predetermined time is set slightly shorter than the second.

<User interface> Water leakage monitoring device 1
Has an LCD 30 and an operation panel 40 as a user interface. The LCD 30 is a digital circuit unit 2
The data transferred from 0 is converted into display data and output as appropriate. The operation panel 40 is provided with various keys, and inputs an input signal corresponding to the key operation to the digital circuit 20.
To the respective circuits in the above.

For example, when a predetermined key operation is performed on the operation panel 40, the count value accumulated in the counter 24 is displayed on the LCD 30. Further, the operation panel 40 accepts a user input for resetting the accumulated count value or resetting the measurement schedule and the current date and time, and changes the time data stored in the controller 24 and the calendar circuit 23. Then, the set time data and the like are appropriately displayed on the LCD 30.

=== Operation of Water Leakage Monitoring Device and Determination of Water Leakage === As described above, if the vibration transmitted through the water pipe during the operation period of 2 seconds of the analog circuit section 10 is below a predetermined level, the counter 24 Is accumulated as the number of times the vibration is interrupted. In the present embodiment, whether or not there is water leakage in the water pipe is determined by a person based on the numerical value accumulated in the counter 24. For example, an inspection is provided at predetermined intervals such as once a month, and a person in charge comes to the installation location of the apparatus 1 and displays the count value on the LCD 30 at the time of the inspection. This person checks the accumulated count value and resets the counter 24. If water leaks, the timer 21 cannot increment the counter 24 because the analog circuit section 10 outputs the H level Vout signal almost continuously during the operation. Therefore, if the count value is smaller than that at the time of the previous inspection, it can be determined that there is water leakage in a water pipe near the device 1. Alternatively, when the count value is equal to or less than a predetermined value, a rule such as water leakage is provided, and the determination is performed according to the rule. If it is determined that there is a water leak in this way, it is known that there is a water leak point in an extremely narrow range near the device 1, and the subsequent work such as identification work and repair of the water leak point can be promptly performed.

=== Modified Example, Application Example === In the above-described embodiment, the water leakage monitoring device of the present invention is used for detecting water leakage in a water pipe for water supply. It can also be applied to the detection of water leakage (liquid leakage) in the pipe flow path.

In the above embodiment, the analog circuit is operated intermittently in order to reduce power consumption. This eliminates the need for long-term (7 to 8 years) power supply replacement and realizes maintenance-free equipment. Of course, if an IC or the like specially designed for each circuit element is used, the power consumption can be extremely reduced, and the operation can be continuously performed during the measurement time or can be continuously performed at all times. The operation schedule of the analog circuit section can be freely set by appropriately changing the time data stored in the controller.

[0034] The sound interruption detection signal output by the timer may be fed back to the controller, and the controller may stop the closing operation of the switch according to the signal. For example, when the sound interruption detection signal is output twice (when the counter 24 is incremented by 2), the operation at the measurement time is terminated, and the analog circuit unit is stopped until the measurement time of the next monitoring cycle comes. Thereby, power consumption can be further reduced. Also, the measurement opportunity corresponds to the number of occurrences of the sound interruption detection signal, and when the number of occurrences is displayed at the time of inspection, dividing the number by a predetermined number of times for pausing causes the number of days in which vibration is interrupted (the number of monitoring cycles). I understand.

In the above embodiment, the number of occurrences of the sound interruption detection signal is displayed on the LCD at the time of inspection, and the presence or absence of water leakage is determined by a person. In addition to simply presenting the number of occurrences of the sound interruption detection signal, it is also possible to present data closer to the determination of the presence or absence of water leakage. For example, if a sound interruption detection signal is detected a predetermined number of times or more in one monitoring cycle, it is determined that there is no water leakage, and if less than that, it is determined that there is water leakage. Alternatively, it is determined that there is water leakage unless the sound interruption detection signal is detected a predetermined number of times or more in any of continuous monitoring cycles such as two to three cycles.
Further, such a determination result is stored in an appropriate storage unit. At this time, it may be associated with the occurrence date and time of the sound break detection signal. Then, if the contents stored in the storage unit are displayed on the LCD at the time of inspection, the number of days in which there is no water leakage, the tendency of generation of a sound breakage detection signal, and the like can be known, so that the presence or absence of water leakage can be further confirmed.

It is also possible to record the occurrence of the sound interruption detection signal and the judgment result for a predetermined monitoring cycle, and to automatically reset the count number and the judgment result. Thereby, the specific monitoring status of the water pipe at the time of inspection can be presented as a history.

The processing and operation for judging water leakage and recording its history can be easily achieved by configuring a digital circuit section by combining appropriate logic ICs. Of course, the CPU, RAM, RO
A microcomputer including M can also be used. In this case, a program describing the output conditions of the sound interruption detection signal (data) and the control schedule of the analog circuit section is written in the ROM, and the CPU detects the sound interruption detection signal according to the program, and stores the detection date and time in the RAM. Record. Further, the presence or absence of water leakage is determined according to this record, and the determination is transferred to the LCD according to a user input from the operation panel.

In the above embodiment, the number of occurrences of the sound interruption detection signal is displayed on the LCD, but the display is not limited to the LCD. An electronic display such as an LED or an EL or a mechanical display such as a magnetic reversal display using a solenoid can be appropriately substituted. It should be noted that power consumption can be suppressed by a method in which display output is manually performed only at the time of inspection.

In addition, it is also possible to output data of a predetermined format without displaying the data. The leak monitoring device is provided with a communication interface for data output, and this interface is connected to the portable terminal of the person in charge of inspection, and the received data is displayed on the display of the terminal or is stored in the storage device of the terminal. It can also be used as a storage mode. Of course, an operation of transferring the information to another information processing device via a network such as a telephone line at regular intervals is also possible.

[0040]

The water leakage monitoring device of the present invention utilizes the fact that water leakage is continuous without stopping at a fixed water volume, and that normal running water due to noise and tap water is intermittent / irregular. When the vibration transmitted through the water pipe is continuously reduced to a predetermined level or less, a sound interruption detection signal is output and the number of times is counted. Then, the criterion for determining the presence or absence of water leakage is presented based on the counted number. Therefore, even if vibrations due to ambient noise and consumed running water occur in the water pipe regardless of day and night, as long as the vibrations may be interrupted, it is reliably detected that there is no vibration due to water leakage Therefore, it is possible to determine that there is water leakage. Therefore, water leakage can be accurately detected even with a simple and inexpensive circuit configuration.

If the number of occurrences of the sound interruption state is displayed and output, a person who inspects water leakage can directly determine the number of occurrences of water leakage by looking at the number of times. If data is output in a predetermined format, the data can be appropriately used, processed, or transferred.

By providing means for resetting the count number of the sound interruption detection signal, the count number at each inspection can be checked. In addition, if the count number for a predetermined monitoring cycle is recorded and then the count number is automatically reset, there is no need to manually perform a reset operation at the time of inspection, and the history of the sound interruption state can be confirmed every predetermined period. Can be.

By judging the presence or absence of water leakage based on the number of counts in each monitoring cycle, it is possible to directly confirm water leakage at the time of inspection. Also, when the count number for one monitoring cycle is less than a predetermined value, it is determined that there is water leakage due to continuous vibration caused by noise such as construction work by judging that there is water leakage after seeing the result of the predetermined monitoring cycle. It is also possible to prevent erroneous recognition.

The clock circuit means that operates constantly intermittently activates other circuit means based on a predetermined time plan, thereby reducing power consumption and eliminating the need for battery replacement for a long period of time, thus making maintenance free. Can be realized. Further, if the operation of the monitoring cycle is aborted in the middle of the monitoring cycle when the sound interruption detection signal is detected a predetermined number of times during a certain monitoring cycle, the power consumption can be further reduced.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a water leakage monitoring device according to an embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Leakage monitoring apparatus 10 Analog circuit part 11 Vibration sensor 12 Amplifier 15 Voltage comparator 20 Digital circuit part 21 Timer 22 Clock generator 23 Calendar circuit 24 Controller 25 Counter 30 LCD 50 Built-in power supply

Continuation of front page (58) Fields investigated (Int.Cl. ⁷ , DB name) G01M 3/24 E03B 7/00 G01H 17/00

Claims (9)

(57) [Claims] 1. An oscillating electric converting means for converting acoustic vibration transmitted to a water pipe into an electric signal, and processing an output signal of the oscillating electric converting means so that a signal in a predetermined band continuously exceeds a predetermined continuation condition. Detecting a drop below a certain level
Shown in the leakage and the sound indicating the possibility uninterrupted signal discrimination means for generating a detection signal, the possibility of a size not leak by counting the number of occurrences of the sound interruption detecting signal
A water leakage monitoring device comprising: a counting means for obtaining a count value . 2. The water leakage monitoring device according to claim 1, further comprising display means for displaying and outputting the count value of said counting means. 3. The water leakage monitoring device according to claim 1, further comprising signal output means for outputting the count value of said counting means in the form of a data signal. 4. The water leakage monitoring device according to claim 1, further comprising a manual reset unit that resets the counting unit in response to a switch operation by a human or the like. 5. The clock circuit according to claim 1, wherein the count value of the counting means is stored in a predetermined memory area at each predetermined monitoring cycle, and the counting means is reset. A water leak monitoring device, comprising: 6. A water leak determining means according to claim 1, further comprising: clock circuit means for measuring time; water leak determining means for determining whether or not water leak has occurred based on the number of occurrences of said sound interruption detection signal in a predetermined monitoring cycle; Determination result storage means for storing the determination result of the determination means in a predetermined memory area for a predetermined monitoring cycle, and determination result output means for outputting the determination result stored in the storage means in the form of a display output or a data signal A leakage monitoring device comprising: 7. A clock circuit according to claim 1, further comprising: a timer circuit for measuring time; and determining that there is no water leakage when the number of occurrences of the sound interruption detection signal in a predetermined monitoring cycle is equal to or more than a predetermined number. Water leak determining means for determining that water has leaked even if the number of times the sound interruption detection signal is generated is less than the predetermined number of times in the monitoring cycle of the number of times, and a determination result of the determining means is stored in a predetermined memory for a predetermined monitoring cycle. A water leakage monitoring device comprising: a determination result storage unit that stores the determination result in an area; and a determination result output unit that outputs the determination result stored in the storage unit in the form of a display output or a data signal. 8. The clock circuit means according to claim 1, wherein said clock circuit means always operates and measures time, and said clock circuit means always operates together with said clock circuit means to other circuit means based on a predetermined time plan. Intermittent operation control means for intermittently supplying operating power to activate the other circuit means. 9. A control device according to claim 8, further comprising a control means for terminating the operation of the monitoring cycle and setting a pause cycle when the sound interruption detection signal is detected a predetermined number of times during a certain monitoring cycle. Leakage monitoring device.