JP2017075892A - Water leakage detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water leakage detector which allows a user to perform determination of water leakage in a manner not to overlook the movement of an indicating mark in a short time of water meter reading, even if the amount of leaked water is very small.SOLUTION: An imaging section 21 images an indicating mark of a water meter. A water leakage determination section 26 determines that water leakage exists in a measurement object range of the water meter when angles of the indicating marks in a plurality of images which are picked up at different points of time by the imaging section 21 are different. A leaked water amount calculation section 25 calculates the amount of leaked water on the basis of the difference between the angles of the indicating marks in the plurality of images.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a water leakage detection device used for water leakage detection.

Currently, water pipes constructed in the era of high economic growth have become obsolete and are in the process of being renewed. According to the trial calculation, it costs about 1 trillion yen or more annually to renew all the water pipelines that should be renewed. On the other hand, the annual income of the water supply business is about 3 trillion yen in total nationwide. For this reason, only about one third of the water pipelines to be updated can be updated due to a lack of budget. In 2020, the proportion of old pipelines is predicted to exceed 40% on a national average.
Aging water pipes increases the possibility of water leakage. Leaving water leaks can lead to serious accidents such as personal injury. For this reason, it is necessary to detect water leaks as soon as possible and deal with them appropriately.

There are two types of water leakage: water leakage on public roads and water distribution pipes on the public road, and residential water leakage downstream from the water meter. The water meter has a pilot mark that rotates when water flows. The water meter inspector determines that there is a possibility of leakage in the home if the pilot mark is rotating even though the water is not being used.
However, since the meter box is normally buried in the ground, it may be necessary to read the display with a tight posture. In addition, there are cases where it is difficult to read the display because the display section is dirty or the surroundings are dim, such as in the winter evening. For this reason, there is a possibility that the water meter reader may miss the water leak.
Patent Document 1 describes a water meter meter bar having a mounting member such as a magnifying glass member or a lighting member.

JP 2006-208059 A

However, when the amount of water leakage is very small, the pilot mark moves slowly. For this reason, the pilot mark hardly moves in a short time at the time of water meter reading. Therefore, no matter how much the display is magnified by the magnifying glass member or the display is illuminated by the illuminating member, there is a possibility that the pilot mark may be mistakenly recognized by visual judgment.
An object of the present invention is to make it possible to determine the leakage of water without overlooking the movement of a pilot mark during a short time at the time of water meter reading even when the amount of water leakage is very small.

The water leakage detection device according to the present invention is configured such that the angle of the pilot mark in the plurality of images captured by the imaging unit at different times differs from the imaging unit that captures the pilot mark of the water meter. A water leakage determination unit that determines that there is water leakage within the measurement target range.
It is preferable to provide a water leakage amount calculation unit that calculates the amount of water leakage based on the difference in angle between the pilot marks in the plurality of images.
Furthermore, it is preferable to provide the water leak notification part which notifies an operator of the determination result by the said water leak determination part.
It is preferable to have a sensor device that can be placed on a display unit of the water meter and that includes the imaging unit, and a portable terminal device that can be carried by a worker and includes the water leakage notification unit.
The imaging unit further photographs a direct reading type instruction unit of the water meter, further analyzes an image captured by the imaging unit, and extracts a portion of the image where the direct reading type instruction unit is reflected. It is preferable to include an image extracting unit.
It is preferable that the imaging unit captures the individual identification number of the water meter in the same image as the image obtained by capturing the direct-reading instruction unit.
The system according to the present invention includes the water leakage detection device and a recording device that records an image captured by the imaging unit in order to provide evidence when a doubt occurs in the meter reading result.
Furthermore, it is preferable that a vibration detection unit that detects a nearby vibration is provided in parallel with photographing by the imaging unit.
Furthermore, it is preferable to provide a vibration storage unit that stores the vibration detected by the vibration detection unit in association with information for identifying the water meter.
The system according to the present invention includes the water leakage detection device, and further analyzes a vibration detected by the vibration detection unit to determine whether there is a nearby water leakage, and a nearby water leakage determination unit. A water leakage map creating unit for marking a place on the map where there is a possibility of water leakage based on the determination result.

According to the water leakage detection device according to the present invention, since it is determined that there is water leakage when the angles of the pilot marks appearing in a plurality of images taken at different times are different, the water leakage is very small, and the movement of the pilot mark is determined. Even if it is difficult to distinguish visually, it is possible to correctly determine the presence or absence of in-home water leakage.
If the amount of water leakage is calculated based on the difference in angle between pilot marks in a plurality of captured images, an appropriate countermeasure based on the amount of water leakage can be taken.
If the result of the water leakage determination is notified to the worker, when there is a possibility of water leakage, it is possible to take a countermeasure such as conducting a further detailed water leakage inspection, so that the home water leakage can be detected early.
If it has a sensor device that can be placed on the display of a water meter and a portable terminal device that can be carried by a worker, it is possible to detect water leakage with an easy posture and to reduce the burden on the worker. Can be reduced.
If a portion where the direct-reading instruction section is extracted from the photographed image, the meter reading can be performed using the extracted image, so that the occurrence of erroneous meter reading can be prevented.
If the direct-reading instruction unit and the individual identification number are photographed in the same image, it can be used as evidence when doubt occurs in the meter reading result.
If vibration in the vicinity is detected in parallel with photographing by the imaging unit, vibration data for determining the presence or absence of water leakage can be collected.
If the vibration data is stored in association with the identification information of the water meter, the correspondence between the vibration data and the water meter becomes clear even when a plurality of vibration data is stored.
If the vibration data is analyzed to determine the presence or absence of nearby water leaks, and the determination result is marked on a map, it can be used to conduct a water leak investigation and early detection of water leaks.

The perspective view which shows a water meter. The top view which shows a display part. The perspective view which shows a water meter-reading apparatus. The block diagram which shows a sensor apparatus. The block diagram which shows a portable terminal device. The top view which shows a display screen. The block diagram which shows a server apparatus.

As shown in FIG. 1, the water meter 90 includes a display unit 91. The display unit 91 is a display panel that displays the accumulated usage amount of water and the like, and is covered with a transparent plate such as glass.
As shown in FIG. 2, the display unit 91 has the following configuration.
<Direct-reading instruction unit 92>: A number representing the accumulated usage amount of water supply is displayed.
<Circle-reading instruction units 93 and 94>: The digits of 10 liters and 1 liter of the accumulated usage amount of water are indicated by rotating needles. The needle of the circular reading instruction unit 93 makes one rotation with 100 liters of water flow. The needle of the circular reading instruction unit 94 makes one rotation with 10 liters of water flow.
<Pilot mark 95>: A rotation indicator that rotates by passing water. The amount of rotation varies depending on the diameter of the water pipe. For example, when the nominal diameter is 13 mm, 0.09 liter makes one revolution, 20 mm or 25 mm, 0.15 liter makes one revolution, and 30 mm makes 0.36 liter. Is one rotation.
<Individual identification number 96>: A number that uniquely identifies the water meter 90 and is used for management of the water meter 90. Since the individual identification number 96 is displayed on the display unit 91, when the display unit 91 is photographed, the direct-reading instruction unit 92 and the individual identification number 96 can be copied onto the same image.

As shown in FIG. 3, the water meter reading device 10 (an example of a “water leakage detection device”) includes a sensor device 12 and a mobile terminal device 13. The sensor device 12 is a multifunctional terminal sensor that can be placed on the display unit 91 of the water meter 90 and collects information displayed on the display unit 91. The portable terminal device 13 is a handy terminal that can be carried by a water meter reader (an example of a “worker”). For example, an input device such as a button or a touch panel for inputting operations by a water meter meter, and a display for displaying information. And a printing device such as a printer for printing a meter reading result.
The sensor device 12 and the mobile terminal device 13 transmit and receive information by wireless communication such as Bluetooth (registered trademark) or other communication.

  As shown in FIG. 4, the sensor device 12 has the following configuration. Note that these components may be configured using a dedicated LSI or other hardware, or may be realized by hardware such as a general-purpose CPU executing software such as a program. Good.

  <Imaging unit 21>: The display unit 91 of the water meter 90 is photographed, and image data including the direct reading type instruction unit 92, the circular reading type instruction units 93 and 94, the pilot mark 95, and the individual identification number 96 is generated. For example, a camera using a CMOS image sensor or a CCD image sensor, an illumination device such as an LED, and a transparent plate for protecting the camera and the illumination device are provided. The transparent plate is provided on the bottom surface of the sensor device 12. When the sensor device 12 is placed on the display unit 91, the illumination device illuminates the display unit 91 via the transparent plate, and the camera images the display unit 91 via the transparent plate. The image captured by the imaging unit 21 may be a still image or a moving image.

  <Image Extraction Unit 22>: Analyzes the image captured by the imaging unit 21, and extracts an image of a portion where the direct-reading instruction unit 92 is reflected. For example, the image data generated by the imaging unit 21 is acquired, the orientation of the display unit 91 is determined, and the image is rotated so that the number of the direct reading instruction unit 92 is in an upright direction. This is because the display unit 91 is circular, so when the sensor device 12 is mounted on the display unit 91, the display unit 91 is not necessarily mounted in the correct orientation. Then, from the rotated image, an image of a portion where the direct-reading instruction unit 92 is captured is cut out, and image data representing the cut-out image is output.

  <Character recognition unit 23>: Analyzes the partial image extracted by the image extraction unit 22, and interprets the numerical value displayed on the direct reading instruction unit 92. For example, from the image data output from the image extraction unit 22, a numerical value indicated by the direct reading instruction unit 92 is recognized using a character recognition function, and character string data representing the recognized numerical value is output.

<Water leakage determination unit 26>: Based on the image captured by the imaging unit 21, the presence or absence of water leakage (so-called “home leakage”) in the measurement target range of the water meter 90 is determined. For example, the first image captured by the image capturing unit 21 is compared with the second image captured by the image capturing unit 21 at a time different from the time when the first image is captured, and the pilot reflected in the two images. When the angle of the mark 95 is different, it is determined that there is water leakage. If there is no water leakage, the pilot mark 95 does not move, so the angles of the pilot mark 95 match. On the other hand, if there is water leakage, the pilot mark 95 moves, so the angles of the pilot mark 95 do not match.
For example, when the pilot mark 95 rotates once with 0.09 liters of water, the pilot mark 95 rotates about 4 degrees with 1 ml of water. If the interval at which the image capturing unit 21 captures two images is about 5 seconds, the water flow rate per second is only 0.2 milliliters. If the water meter reader visually determines, there is a possibility of missing such a minute water leak. On the other hand, when the water leakage determination part 26 determines the presence or absence of water leakage, it is possible to prevent such a minute water leakage from being overlooked.

Even if the pilot mark 95 is actually moving, such as when the pilot mark 95 has just made one rotation, the angles of the pilot mark 95 may coincide. Therefore, if the angle of the pilot mark 95 is the same, the angle of the needle of the circular reading instruction unit 94 is further compared, and if the angle of the needle of the circular reading instruction unit 94 is different, it is determined that there is water leakage. It may be configured to.
For example, when the pilot mark 95 makes one rotation with a water flow of 0.09 liter, the needle of the circular reading instruction unit 94 moves about three degrees while the pilot mark 95 makes one rotation. Therefore, the presence / absence of water leakage can be correctly determined simply by comparing the two images. There is no need to observe the pilot mark 95 continuously, such as shooting a moving image.

  The water leakage determination unit 26 calculates the rotation angle of the pilot mark 95 that has moved while the imaging unit 21 captures an image. For example, the water leakage determination unit 26 calculates the angle of the pilot mark 95 shown in each image, and obtains the difference between the calculated angles. Then, when the rotation angle of the pilot mark 95 is not 0, it is determined that there is water leakage.

<Water leakage amount calculation unit 25>: The amount of water leakage is calculated based on the difference in angle between the pilot marks 95 shown in a plurality of images taken by the imaging unit 21. For example, the amount of water leakage per unit time is calculated from the interval at which the imaging unit 21 captures images and the rotation angle of the pilot mark 95 calculated by the water leakage determination unit 26.
For example, in the case where the pilot mark 95 rotates once with 0.09 liters of water flow, if the pilot mark 95 has a rotation angle of 4 degrees, the amount of water leakage during that period is 0.09 × 4 ÷ 360 = 0.001. Liter (ie 1 milliliter). If the image capturing interval is 5 seconds, the amount of water leakage per hour is 0.001 ÷ 5 × 3600 = 0.72 liters.
In addition, the structure which determines the type of the water meter 90 from the image image | photographed by the imaging part 21, and calculates the water flow amount when the pilot mark 95 makes one rotation based on the determined type may be sufficient.

<Vibration detection unit 27>: The vibration transmitted through the water meter 90 is detected when the sensor device 12 is placed on the display unit 91. For example, a vibration sensor is provided, and vibration data representing a vibration waveform detected by the vibration sensor is generated. By analyzing the generated vibration data, the presence or absence of nearby water leakage can be determined. In addition, in order for the vibration detection unit 27 to easily detect vibration due to water leakage, the sensor device 12 is preferably configured to be placed in direct contact with the transparent plate that covers the display unit 91.
<Vibration storage unit 28>: For example, vibration data generated by the vibration detection unit 27 using a storage medium such as a USB memory or other storage device is used as information for identifying the water meter 90 such as a meter number or a faucet number. Link and remember. Thereby, even if the vibration storage unit 28 stores a plurality of vibration data, the correspondence between the water meter 90 and the vibration data becomes clear. The vibration data stored in the vibration storage unit 28 is read by, for example, removing the storage medium and connecting it to a reading device when the water meter reader returns to the office.

<Communication unit 29>: Communicates with the mobile terminal device 13. For example, a measurement start signal is received from the mobile terminal device 13.
When the communication unit 29 receives the measurement start signal, first, the vibration detection unit 27 starts recording the vibration, and the imaging unit 21 captures the first image. The communication unit 29 transmits the first image to the mobile terminal device 13. The image extraction unit 22 analyzes the first image to generate an extracted image, and the character recognition unit 23 reads the indication value of the direct reading type instruction unit 92. The communication unit 29 transmits the instruction value of the direct reading type instruction unit 92 read by the character recognition unit 23 to the mobile terminal device 13.
When a predetermined time (for example, 5 seconds) elapses after the first image is taken, the vibration detection unit 27 ends the vibration recording, and the imaging unit 21 takes the second image. The image extraction unit 22 analyzes the second image to generate an extracted image, and the water leakage determination unit 26 determines the presence or absence of water leakage. If it is determined that there is water leakage, the water leakage amount calculation unit 25 calculates the water leakage amount. The communication unit 29 transmits the determination result determined by the water leakage determination unit 26 and the water leakage amount calculated by the water leakage amount calculation unit 25 to the mobile terminal device 13.

The interval at which the imaging unit 21 captures an image is not limited to 5 seconds, and may be longer or shorter. The longer the shooting interval, the smaller the amount of water leakage that can be detected, but the longer the measurement takes. Considering the efficiency of meter reading, it is preferably 10 seconds or less. Conversely, the shorter the imaging interval, the higher the possibility of missing a slight amount of water leakage, so it is preferably 3 seconds or longer. Considering the balance between water leakage detection accuracy and meter reading efficiency, 5 seconds is the most preferable. Moreover, you may comprise so that it can set to arbitrary intervals.
The number of images taken by the imaging unit 21 is not limited to two, and may be larger. In that case, it is preferable that the intervals at which the imaging unit 21 captures images are different. For example, the shooting interval from the first image to the second image is 2 seconds, and the shooting interval from the second image to the third image is 3 seconds. If it does so, the possibility of missing a leak can be suppressed.
The start time and end time when the vibration detection unit 27 records vibration may be different from the time when the imaging unit 21 captures an image.

The communication unit 29 preferably receives identification information for identifying the water meter 90 from the portable terminal device 13 together with the measurement start signal. Then, the identification information received by the communication unit 29 can be stored in the vibration storage unit 28 in association with the vibration data.
Alternatively, a part in which the individual identification number 96 is captured is extracted from the image captured by the imaging unit 21, the individual identification number 96 is read, and the read individual identification number 96 is linked to the vibration data by the vibration storage unit 28. May be stored.

  Note that the communication unit 29 may be configured to transmit the vibration data generated by the vibration detection unit 27 to the mobile terminal device 13. In that case, the vibration storage unit 28 may be omitted. However, since vibration data is relatively large data, it takes time to transmit. For this reason, the configuration in which vibration data is not transmitted during meter reading and is stored in the vibration storage unit 28 does not have to wait for the end of communication, and the efficiency of meter reading can be increased. The configuration may be such that the communication unit 29 transmits vibration data to the mobile terminal device 13 during the movement from the end of the meter reading to the start of the next meter reading.

  As shown in FIG. 5, the mobile terminal device 13 has the following configuration. Note that these components may be configured using a dedicated LSI or other hardware, or may be realized by hardware such as a general-purpose CPU executing software such as a program. Good. For example, you may make it function as the portable terminal device 13 by installing an application in a smart phone, a tablet, etc.

  <Short-range communication unit 31>: Communicates with the sensor device 12. For example, when the water meter reader presses the start button of the mobile terminal device 13, a measurement start signal is transmitted to the sensor device 12. As described above, identification information such as a meter number and a faucet number may be transmitted to the sensor device 12 together with the measurement start signal. Further, from the sensor device 12, the whole image captured by the imaging unit 21, the partial image extracted by the image extraction unit 22, the instruction value recognized by the character recognition unit 23, the determination result determined by the water leakage determination unit 26, the water leakage amount calculation unit 25 receives data such as the amount of water leakage calculated.

<Captured image display unit 32>: The entire image captured by the imaging unit 21 is displayed on the display screen of the mobile terminal device 13.
<Extracted image display unit 33>: The partial image extracted by the image extracting unit 22 is enlarged and displayed on the display screen of the mobile terminal device 13.
<Indicated value input unit 34>: An instruction value of the water meter 90 read by the water meter inspector is input. The water meter reader may directly read the instruction value by directly viewing the direct reading instruction unit 92 of the water meter 90, but it is easier to read from the image of the direct reading instruction unit 92 displayed by the extracted image display unit 33. The reading can be read correctly even if the area is dim. The water meter reader inputs the read instruction value by, for example, pressing a numeric button of the mobile terminal device 13.
<Input value display unit 35>: The instruction value (input value) input by the instruction value input unit 34 is displayed on the display screen of the mobile terminal device 13. When the instruction value input unit 34 has not yet input the instruction value, the instruction value recognized by the character recognition unit 23 is displayed on the display screen of the mobile terminal device 13. Thereby, when the instruction value displayed on the input value display unit 35 is correct, the input of the instruction value can be omitted, and the efficiency of meter reading can be improved. If the character recognition unit 23 cannot correctly recognize the instruction value, such as when the display unit 91 is dirty, the instruction value can be corrected to a correct value by manual input.

<Water leakage notification unit 37>: Notifies the water meter reader of the determination result by the water leakage determination unit 26 and the water leakage amount calculated by the water leakage amount calculation unit 25. For example, when the water leakage determination unit 26 determines that there is water leakage, this is displayed on the display screen of the mobile terminal device 13, an alarm is sounded, or the mobile terminal device 13 is vibrated. Further, the amount of water leakage is displayed on the display screen of the mobile terminal device 13. As a result, it is possible to take measures such as conducting a more detailed water leakage inspection, and to detect in-house water leakage at an early stage.
For example, if the water supply contractor is at home, the water meter inspector will check if the water supply is in use, and if it is in use, stop using it. get. Then, the presence / absence of water leakage is determined again. If it is still determined that there is water leakage, the contractor is informed that there is water leakage.
If there is water leakage, it is necessary to take measures such as identifying and repairing the water leakage location. However, when the amount of water leakage is very small, it may be better to look at the situation for a while in consideration of the cost for inspection and repair for identifying the water leakage location.
Since the amount of water leakage calculated by the water leakage amount calculation unit 25 is notified to the water meter inspector, the amount of water leakage can be communicated to the contractor and advice on how to deal with it can be provided. Can cope with it.

  <Far communication unit 39>: Communicates with a server device 40 provided in a data analysis center of a water station or the like. For example, the entire image captured by the imaging unit 21, the instruction value displayed by the input value display unit 35 (the value recognized by the character recognition unit 23 or the value input by the instruction value input unit 34), the determination result by the water leakage determination unit 26, The leakage amount calculated by the leakage amount calculation unit 25 is transmitted to the server device 40. In this way, if the meter reading result is transmitted to the server device 40 each time, it is not necessary to store the meter reading result in the water meter reading device 10, and it is possible to prevent leakage of personal information due to the loss of the water meter reading device 10. it can. Since the water meter inspector can permit the water meter meter 10 to be taken home, the water meter inspector can go straight to the site and increase the efficiency of meter reading.

  As shown in FIG. 6, the display screen of the mobile terminal device 13 includes an entire image 62 displayed by the captured image display unit 32, an enlarged partial image 63 displayed by the extracted image display unit 33, and an input value display unit 35. An input value 65 (instruction value) to be displayed is displayed. The input value display unit 35 displays the input value 65 at a position adjacent to the partial image 63. Thereby, it becomes easy to compare the instruction value of the direct-reading instruction unit 92 with the input value 65, and input errors can be prevented. Since the partial image 63 and the input value 65 are normally horizontally long, the input value display unit 35 preferably displays the input value 65 above or below the partial image 63.

  As described above, the water meter reader simply turns on the power of the sensor device 12, places the sensor device 12 on the display unit 91, and presses the start button of the mobile terminal device 13. Interpretation, determination of leakage in the house, and collection of vibration data are performed automatically. The water meter inspector confirms the instruction value recognized by the character recognition unit 23 and inputs the instruction value only when it is not recognized correctly. Thereby, the labor concerning a meter-reading and a water leak test | inspection can be reduced significantly. By greatly reducing the load on the water meter reader, it is possible to prevent human errors such as input errors and judgment errors due to fatigue.

  Note that some or all of the image extraction unit 22, the character recognition unit 23, and the water leakage determination unit 26 may not be included in the sensor device 12 but may be included in the mobile terminal device 13. The water meter reading device 10 is not divided into the sensor device 12 and the portable terminal device 13, but may be an integrated device.

As shown in FIG. 7, the server device 40 has the following configuration.
<Communication unit 41>: Communicates with the water meter reading device 10. For example, the mobile terminal device 13 receives the entire image captured by the imaging unit 21, the instruction value displayed by the input value display unit 35, the determination result by the water leakage determination unit 26, and the like. In addition, vibration data stored in the vibration storage unit 28 of the sensor device 12 is received from a reading device or the like.
The recording device 49 stores the data received by the communication unit 41. Since the whole image photographed by the imaging unit 21 includes the direct-reading instruction unit 92 and the individual identification number 96, by recording this in the recording device 49, evidence when the meter reading result is in doubt. Can be used as

<Near water leakage determination unit 42>: Analyzes vibration data to determine the presence or absence of water leakage in the vicinity. For example, if the vibration data includes a vibration pattern peculiar to water leakage, it is determined that there is water leakage in the vicinity. Since advanced skills are not required for determination of water leakage, it is not necessary for a veteran engineer to go to the site, and water leakage can be easily determined based on data collected at the time of water meter reading. As a result, it is possible to determine the leakage of water at a much higher frequency (for example, about once every two months) than in the past (for example, about once every three years). Occurrence can be prevented in advance.
Since the recording device 49 stores the raw vibration data, when it is determined that there is water leakage, it is possible to perform a more advanced analysis to increase the determination accuracy.
The recording device 49 records the determination result by the near water leakage determination unit 42. Thereby, a meter-reading result and a water leak determination result can be managed centrally.

<Leakage map creation unit 43>: Creates a water leak map based on the determination result of the nearby water leakage determination unit 42. For example, the recording device 49 is a map relating to a water network such as a geographical map such as a geographical information system (GIS), a general map of terrain, administrative divisions, buildings, etc., a water meter, and a distribution pipe and a water pipe on a public road Data representing such as is stored in advance. The water leakage map creation unit 43 acquires the determination result of the near water leakage determination unit 42 recorded by the recording device 49, and when it is determined that there is water leakage in the vicinity, the water distribution pipe connected to the water meter 90 is leaked. Mark on the map as a possible location.
The location of water leakage may be narrowed down by combination with other data. For example, when there is water leakage in the vicinity of the water meter 90 where there is no water leakage in the house, the water leakage point is considered to be upstream from the water meter 90. Further, when there is a water leak in the vicinity of a plurality of water meters 90 that are close to each other, the water leak location is considered to be closer to the water meter 90 with the larger amplitude of the vibration pattern peculiar to the water leak. Thereby, the efficiency of a water leak investigation can be improved.

The water leak map created by the water leak map creation unit 43 is transmitted in the form of electronic data to, for example, the mobile terminal of the water leak investigator. The leaking investigator's portable terminal displays the received leak map, and the leak investigator conducts a leak check according to the leak map displayed on the portable terminal. Paper resources can be saved because there is no need to print a leak map.
Since a leak map can be created every time a water meter is read, a leak map can be created at a high frequency, for example, once every two months. By conducting a field survey using this, it is possible to detect a water leak at an early stage, so that a serious accident can be prevented.

  The water meter reading device 10 may include a nearby water leakage determination unit, and may analyze the vibration data collected by the vibration detection unit 27 to determine the presence or absence of nearby water leakage. Then, the determination result is notified to the water meter inspector on the spot, and when there is water leakage, it is possible to take measures such as conducting a more detailed water leakage inspection, and to detect water leakage at an early stage. However, even in that case, it is preferable to store raw vibration data in the vibration storage unit 28 and perform a more advanced analysis than the water meter reading device 10 in the vicinity water leakage determination unit 42 of the server device 40.

  The embodiment described above is an example for facilitating understanding of the present invention. The invention is not limited thereto, but includes various modifications, changes, additions or removals without departing from the scope defined by the appended claims. This can be easily understood by those skilled in the art from the above description.

  DESCRIPTION OF SYMBOLS 10 Water meter-reading apparatus, 12 Sensor apparatus, 13 Portable terminal device, 21 Imaging part, 22 Image extraction part, 23 Character recognition part, 25 Water leak amount calculation part, 26 Water leak determination part, 27 Vibration detection part, 28 Vibration memory part, 29 , 41 Communication unit, 31 Near field communication unit, 32 Captured image display unit, 33 Extracted image display unit, 34 Instruction value input unit, 35 Input value display unit, 37 Water leak notification unit, 39 Long distance communication unit, 40 Server device, 42 Near leak detection unit, 43 Leak map creation unit, 49 Recording device, 62 Whole image, 63 Partial image, 65 Input value, 90 Water meter, 91 Display unit, 92 Direct reading type instruction unit, 93, 94 Circular reading type instruction unit , 95 Pilot mark, 96 Individual identification number.

Claims (10)

An imaging unit for photographing a pilot mark of a water meter;
A water leakage determination unit that determines that there is water leakage in the measurement target range of the water meter when the angle of the pilot mark in the plurality of images captured by the imaging unit at different times is different,
A water leakage detection device. A water leakage amount calculation unit for calculating the amount of water leakage based on a difference in angle between the pilot marks in the plurality of images;
The water leakage detection device according to claim 1. Furthermore,
A water leakage notification unit for notifying workers of the determination result by the water leakage determination unit;
The water leakage detection device according to claim 1. A sensor device that can be placed on a display unit of the water meter and includes the imaging unit;
A portable terminal device that is portable by an operator and includes the water leakage notification unit;
The water leakage detection device according to claim 3. The imaging unit further shoots the direct-reading instruction unit of the water meter,
Furthermore,
An image extracting unit that analyzes an image captured by the imaging unit and extracts a portion of the image in which the direct-reading instruction unit is reflected;
The water leakage detection device according to any one of claims 1 to 4. The imaging unit photographs the individual identification number of the water meter in the same image as the image obtained by photographing the direct-reading instruction unit,
The water leakage detection device according to claim 5. A water leakage detection device according to claim 6;
In order to provide evidence when doubt occurs in the meter reading result, a recording device for recording an image taken by the imaging unit,
Having a system. Furthermore,
In parallel with imaging by the imaging unit, a vibration detection unit that detects nearby vibrations is provided.
The water leakage detection device according to any one of claims 1 to 6. Furthermore,
A vibration storage unit that stores the vibration detected by the vibration detection unit in association with information for identifying the water meter;
The water leakage detection device according to claim 8. The water leakage detection device according to claim 8 or 9,
Furthermore,
Analyzing the vibration detected by the vibration detection unit, a near water leak determination unit for determining the presence or absence of water leak in the vicinity,
Based on the determination result of the nearby water leakage determination unit, a water leakage map creation unit for marking a place on the map where there is a possibility of water leakage,
A system comprising: