JP7132109B2 - Meter reading device - Google Patents

Description

An embodiment of the present invention relates to a meter reading device used for meter reading of a water meter.

Leakage investigations to determine whether or not there is water leakage in water pipes have been carried out for some time. It was done by listening. However, in order for an investigator to accurately determine the presence or absence of water leakage using this method, a considerable degree of skill is required to distinguish the characteristic sounds that occur when water leaks. It is a rare and valuable presence in the whole country. In addition, even a skilled investigator can handle only about 100 cases per day. Therefore, in a building with many houses, it takes a very long time to conduct a water leakage investigation.

On the other hand, the vibration sound is captured from the water meter, and the vibration sound is recorded as vibration signal data. There is a method for determining

According to this method, meter readers who read the same water meter are given vibration signal data for water leakage investigation when they read the water meter once every two months. It is possible to reduce the burden on the water leakage investigators by having them obtain it from

JP-A-6-146346 JP-A-61-213647 JP-A-64-25025

However, meter readers visually read the readings of the water meter and input the readings into the handy terminal for meter reading. As a result, there are concerns about an increase in the workload of meter readers and a decrease in the reliability of the results of each task. rice field.

The problem to be solved by the present invention is to provide a meter reading device that can more reliably perform both meter reading of a water meter and acquisition of vibration signal data required for water pipe leakage investigation. That is.

A meter reading device of an embodiment includes a light source, a polarizing section, an imaging section, a blocking section, a converting section, and a diffusion plate . The light source provides light for illuminating the display of the water meter, on which a numerical value relating to the amount of water flowing through the water pipe is displayed. The polarizing section guides linearly polarized light out of the light supplied by the light source to the display section. The imaging section captures an image of the display section illuminated by the linearly polarized light. The blocking section blocks specularly reflected light of the linearly polarized light that has been specularly reflected by the display section so as not to be guided to the imaging section. The conversion unit converts the numerical value related to the amount of water included in the image of the display unit captured by the imaging unit into text information using an OCR function. The diffusion plate is provided between the light source and the display section, and diffuses the light supplied by the light source to illuminate the entire surface of the display section.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram illustrating the meter reading device of the first embodiment together with the relationship between a water meter and a meter reading handy terminal; 1 is a perspective view showing the outline of a typical water meter; FIG. It is a sectional view showing a detailed example of composition of a meter reading device of a 1st embodiment, and a top view of a diffuser plate and a polarizing plate which are applied to the meter reading device. FIG. 2 is a side view showing typical dimension values of the meter reading device shown in FIG. 1; FIG. 4 is a cross-sectional view showing a state in which the meter reading device is correctly arranged in the water meter; It is a block diagram which shows the functional structural example of the meter-reading apparatus of 1st Embodiment. It is a schematic diagram which shows an example of the imaged display part. It is a flowchart which shows an example of the operation|movement at the time of the meter-reading work of a meter-reading numerical value. It is a schematic diagram explaining the positional relationship of a camera, LED, and a polarizing plate. It is a schematic diagram for demonstrating the effect|action of a linearly-polarizing plate. It is an image which shows an example of the imaging result by the meter-reading apparatus of 1st Embodiment. It is an image which shows an example of the imaging result by the meter-reading apparatus which is not provided with the linear polarizing plate. FIG. 10 is a flowchart showing an example of operation during acquisition of vibration signal data required for water leakage investigation; FIG. It is a perspective view which shows the structural example of a circularly-polarizing plate. It is a figure explaining the principle by which light is polarized by a circularly-polarizing plate.

Below, the meter-reading apparatus of each embodiment of this invention is demonstrated with reference to drawings.

In addition, in the following description of the embodiments, the same reference numerals are used to denote the same parts to avoid redundant description.

(First embodiment)
A meter reading device of the first embodiment will be described.

FIG. 1 is a schematic diagram illustrating the meter reading device (upper right side and center right side) of the present embodiment together with the relationship between the water meter (lower right side) and the handy terminal for meter reading (upper left side).

The meter reading device 10 performs both meter reading work of reading the meter reading value displayed on the display unit 115 of the water meter 110 and acquisition work of vibration signal data required for water leakage investigation of the water pipe 150 and the water stop valve 160. (hereinafter also referred to as "both operations") at the same time with high reliability and automatically. Since both of these works are carried out by a meter reader visiting each individual house, the meter reader 10 has a size that can be carried by the meter reader and a shape that can be easily held by the meter reader.

FIG. 1 also shows the water meter box 100 housing the water meter 110 connected to the water pipe 150 and the water stop valve 160 viewed from above (bottom right).

FIG. 1 also shows a bottom view (upper right side) of the meter reading device 10 and a side cross-sectional view (middle right side) along line XX in the bottom view.

When the meter reader performs both of the above-described operations, the meter reader arranges the meter reader 10 so as to cover the display unit 115 of the water meter 110 of each individual house, as indicated by the arrow in FIG.

FIG. 2 is a perspective view showing the outline of a typical water meter 110. As shown in FIG.

The water meter 110 is provided with a display portion 115 which is arranged in a concave shape and is low with respect to a metallic cylindrical peripheral convex portion 117 forming the main body of the water meter. The inner diameter size of the peripheral end protrusion 117 is, for example, 56 (mm) to 64 (mm). The surface of the display unit 115 is covered with a transparent glass surface.

On the other hand, the meter reading device 10 includes a camera 12 , an LED 13 , a vibration sensor 14 , a diffuser plate 15 , a linearly polarizing plate 16 , a convex portion 17 and a data processing section 18 .

When the meter reading device 10 is correctly arranged to cover the display section 115 of the water meter 110 and the imaging surface 12a of the camera 12 faces the display surface 115a of the display section 115, the camera 12 displays on the display section 115. Take an image of the meter reading value. A scanner may be used instead of the camera 12 .

The LED 13 is a light source that supplies light for illuminating the display unit 115 , and a plurality of LEDs 13 are arranged in the circumferential direction of a circle around the camera 12 so as to surround the camera 12 .

FIG. 3 is a side cross-sectional view (lower) showing a configuration example of the meter reading device of the present embodiment, and a plan view of a light scattering plate (upper left) and a polarizing plate (upper right) applied to the same meter reading device.

The linear polarizing plate 16 and the diffuser plate 15 are laminated in order on part of the bottom plate 11 .

The diffuser plate 15 is made of, for example, a milky-white plastic, has an annular shape, and has a circular hollow portion 15a around the center point A of the annular ring. The outer diameter size of the hollow portion 15 a substantially matches the outer diameter size of the imaging surface 12 a of the camera 12 .

The linear polarizing plate 16 is composed of a combination of an annular linear polarizing plate 16a and a disc-shaped linear polarizing plate 16b. The linear polarizing plate 16b is fitted in the hollow portion of the linear polarizing plate 16a. That is, the hollow portion of the linear polarizing plate 16a and the linear polarizing plate 16b have circular shapes with the same size, and both are arranged with the center point D as the center.

Furthermore, the diffuser plate 15 and the linear polarizing plate 16 are arranged so that the central axis B extending from the center G of the imaging surface 12a perpendicularly to the imaging surface 12a passes through the central points A and D. FIG. Since the central axis B coincides with the imaging direction F, which is the front direction of the imaging surface 12a, the diffuser plate 15 and the linear polarizing plate 16 are orthogonal to the imaging direction F and arranged with the central axis B as the center. will be

4 is a side view of the meter reading device shown in FIG. 1. FIG. FIG. 4 also shows specific dimensional ranges.

A cylindrical projection 17 is provided so as to cover the outer peripheries of the diffusion plate 15 and the linear polarizing plate 16 . In other words, the convex portion 17 is provided so as to surround the imaging direction F. As shown in FIG. Furthermore, the tip of the convex portion 17 protrudes in the imaging direction F from the bottom surface 11a. This protrusion amount T1 is, for example, ₂ (mm) to 3 (mm), as shown in FIG.

The vibration sensor 14 is arranged on the outer peripheral side of the convex portion 17 and has a detection surface 14 a at its tip for detecting at least one of minute vibrations and sound propagating through the water pipe 150 and the water stop valve 160 . That is, the detection surface 14a is provided at the tip of the vibration sensor 14 so as to protrude in the imaging direction F from the _bottom surface 11a. It is 5 (mm) to ₁ (mm), which is smaller than the projection amount T1 of the convex portion 17 .

The vibration sensor 14 can detect at least one of vibration and sound on the detection surface 14a. When vibration is detected, an electrical signal corresponding to the detected vibration is generated and output as a vibration electrical signal. Further, when sound is detected, an electric signal corresponding to the detected sound is generated and output as an acoustic electric signal. Note that a microphone can be used instead of the vibration sensor 14 . When a microphone is used, the microphone detects a minute sound propagating through the water pipe 150 or the water stop valve 160, generates an electrical signal corresponding to the detected sound, and outputs it as acoustic electrical signal data.

The outer diameter size of the convex portion 17 is, for example, about 55 (mm). Also, the shortest distance S between the central axis B and the detection surface 14a is, for example, 28 (mm) to 32 (mm). Further, the vibration sensor 14 is arranged such that the distance L from the central axis B to the farthest part is in the range of 45 (mm) to 60 (mm).

FIG. 5 is a side cross-sectional view showing a state in which the meter reading device 10 is correctly arranged on the water meter 110. As shown in FIG.

As described above, the convex portion 17 has _a protrusion amount T1 of 2 (mm) to 3 (mm) in the imaging direction F from the bottom surface 11a. The outer diameter size of the convex portion 17 is, for example, 55 (mm), which is slightly smaller than the inner diameter size of the peripheral end convex portion 117 of 56 (mm) to 64 (mm). As a result, when the meter reading device 10 is correctly positioned so as to cover the display portion 115 of the water meter 110 for meter reading, the convex portion 17 is formed inside the circumferential end convex portion 117 as shown in FIG. recess 118. At the same time, a portion of the bottom surface 11a that is closer to the outer periphery than the protrusion 17 contacts the peripheral end protrusion 117 .

Rubber, plastic resin, or the like is provided on the surface of the bottom surface 11a in order to absorb the impact when the needle-detecting device 10 is arranged on the peripheral end convex portion 117 and to prevent the needle-detecting device 10 from wobbling after being arranged. there is

Further, as illustrated in FIG. 1 , a vibration sensor 14 is arranged on a portion of the outer peripheral side of the convex portion 17 . 4, the shortest distance S from the central axis B to the detection surface 14a is 28 (mm) to 32 (mm), and the distance L to the farthest part of the detection surface 14a is 45. (mm) to 60 (mm). Further, the projection amount T2 of the vibration sensor 14 in the imaging direction F with respect to the _bottom surface 11a is 0.5 (mm) to 1 (mm).

As is clear from the above dimensional relationships, when the meter reading device 10 is correctly placed on the water meter 110 for meter reading, the detection surface 14a of the vibration sensor 14 is inevitably brought into contact with the peripheral convex portion 117. become.

As shown in FIG. ₄ , the protrusion amount T2 of the vibration sensor 14 is approximately 0.5 (mm) to 1 (mm), which is approximately _half the protrusion amount T1 of the convex portion 17. As shown in FIG. Therefore, the protrusion of the vibration sensor 14 with respect to the bottom surface 11 a does not prevent the protrusion 17 from being positioned within the recess 118 when the meter reading device 10 is correctly placed on the water meter 110 .

Furthermore, the outer diameter size of the convex portion 17 is slightly smaller than the inner diameter size of the peripheral end convex portion 117 . Therefore, when the meter reading device 10 is correctly arranged in the water meter 110, when the meter reading device 10 is moved in the radial direction, the outer side of the convex portion 17 collides with the inner side of the circumferential end convex portion 117. By confirming the collision, it is possible to sensuously recognize that the meter reading device 10 is correctly arranged on the water meter 110 .

Next, the hardware configuration of the meter reading device 10 will be described in detail.

That is, the meter reading device 10 illuminates the LED 13 when correctly placed on the water meter 110 . The light illuminated by the LEDs 13 enters the diffuser plate 15 , is diffused over the entire surface of the diffuser plate 15 by the diffuser plate 15 , and enters the linearly polarizing plate 16 . That is, the diffuser plate 15 supplies light to the linearly polarizing plate 16 in a donut shape except for the portion facing the imaging surface 12 a of the camera 12 .

That is, the light diffused by the diffuser plate 15 is supplied to the linear polarizer 16a of the linear polarizers 16. As shown in FIG.

The polarizing axis of the linear polarizing plate 16a and the polarizing axis of the linear polarizing plate 16b are perpendicular to each other at 90 degrees. For example, the polarizing axis of the linear polarizing plate 16a is horizontal, and the polarizing axis of the linear polarizing plate 16b is vertical.

When the polarization axis of the linear polarizing plate 16 a is horizontal, only the horizontal linearly polarized light of the light supplied by the diffuser plate 15 passes through the linear polarizing plate 16 a and reaches the display section 115 .

Since the surface of the display unit 115 is covered with a transparent glass surface, the light reaching the display unit 115 is specularly reflected on the transparent glass surface, becomes specularly reflected light, and travels toward the linear polarizing plate 16. . Further, the light reaching the display section 115 is diffusely reflected on the transparent glass surface of the display section 115 to illuminate the entire display section 115 .

Note that when the meter reading device 10 is correctly placed on the water meter 110, as illustrated in FIG. Circumferential light is prevented from entering the side. Therefore, the display section 115 is not illuminated by the ambient light.

The specularly reflected light specularly reflected on the transparent glass surface of the display unit 115 is horizontal linearly polarized light, and therefore cannot pass through the linear polarizing plate 16b having a vertical polarization axis. That is, the linear polarizing plate 16b functions as a blocking section that blocks specularly reflected light from being guided to the imaging surface 12a of the camera 12. FIG. The light diffusely reflected on the transparent glass surface of the display unit 115 passes through the linear polarizing plate 16b and is guided to the imaging surface 12a.

As a result, specularly reflected light due to specular reflection on the transparent glass surface of the display section 115 is blocked by the linear polarizing plate 16b and does not reach the imaging surface 12a. As a result, the camera 12 can capture an image of the meter reading value on the display unit 115 without including an image that flashes.

Next, a configuration example of the data processing unit 18 will be described.

FIG. 6 is a block diagram showing a functional configuration example of the meter reading device of this embodiment.

As illustrated in FIG. 6 , the data processing section 18 includes an analog circuit section 20 , a control section 30 , a recording section 40 and a data transmission/reception section 50 .

The analog circuit section 20 includes an amplification/filter section 21 and an A/D conversion section 22 .

For example, although not shown, the control unit 30 includes a CPU (Central Processing Unit), and ROM (Read Only Memory) and RAM (Random Access Memory) that store application programs and data for the CPU to execute processing. etc. The control unit 30 causes the CPU to execute an application program stored in the ROM using the RAM, thereby performing an LED control unit 31, an image capturing unit 32, a measurement control unit 33, an OCR (optical character recognition) processing unit 34. , and the functions of the recording unit 35 are realized.

The recording unit 40 includes, for example, a semiconductor memory or the like, and has recording areas for an image recording unit 41 , a meter reading value recording unit 42 , and a sound recording result recording unit 43 .

The data transmission/reception unit 50 can wirelessly communicate with the meter reading handy terminal 200 . When the meter reader correctly places the meter reading device 10 on the water meter 110 , the meter reader can operate the meter reading handy terminal 200 to give an instruction to start imaging.

When instructed to start imaging, the meter reading handy terminal 200 transmits a start command r to the meter reading device 10 .

The start command r is received by the data transmitter/receiver 50 . The data transmission/reception unit 50 outputs the received start command r to the measurement control unit 33 .

The measurement control unit 33 outputs a start command r to the LED control unit 31, the image pickup unit 32, and the sound recording unit 35.

When the measurement control unit 33 outputs the start command r, the LED control unit 31 outputs a lighting command s for lighting the LED 13 to the LED 13 . The LED 13 is lit according to the lighting command s from the LED control section 31 .

When the measurement control unit 33 outputs the start command r, the image capturing unit 32 outputs the image capturing command t to the camera 12 . The camera 12 captures an image of the display unit 115 in response to an image capturing command t from the image capturing unit 32, and captures the image data a0 together with the image capturing time information b via an interface such as a parallel bus or a serial bus. Output to unit 32 . The imaging time information b can also be used as an identification number for the image data a0.

The image capturing section 32 outputs the image data a 0 and the capturing time information b output from the camera 12 to the image recording section 41 and the OCR processing section 34 , and also outputs the capturing completion signal d to the LED control section 31 .

The LED control unit 31 outputs an extinguishing command u for extinguishing the LED 13 to the LED 13 in response to the imaging completion signal d from the image imaging unit 32 . The LED 13 is extinguished in response to an extinguishing instruction u from the LED control section 31 .

In this way, the LED 13 is lit only when the camera 12 takes an image, and is turned off immediately after the image is taken, so that it is possible to save the power of the battery (not shown) that supplies power to the meter reading device 10. .

The image recording unit 41 records the image data a0 and the image capturing time information b output from the image capturing unit 32 in association with the customer information.

The OCR processing unit 34 uses an OCR (optical character recognition) function to convert the meter reading numerical value (m ³ ), which is generally four to six digits, captured in the image data a0 from the image capturing unit 32 into character information. do. For example, when the meter reading value "01260" is imaged in the image data a0 as shown in FIG. Output to unit 42 .

Since the inner diameter size of the peripheral end protrusion 117 is larger than the outer diameter size of the protrusion 17, a gap 119 (119a+119b) exists between the peripheral end protrusion 117 and the protrusion 17. 17 can move radially within recess 118 by gap 119 even when positioned within recess 118 . Moreover, since the convex portion 17 has a cylindrical shape, it can also rotate inside the concave portion 118 . Therefore, even if the meter reading device 10 is correctly placed on the water meter 110, the positional relationship between the meter reading value displayed on the display unit 115 and the imaging surface 12a of the camera 12 is generally It is different each time it is arranged in 110 .

However, as long as the meter reading device 10 is correctly arranged on the water meter 110, the OCR processing section 34 recognizes the top, bottom, left, and right of the display section 115 regardless of the positional relationship between the meter reading value and the imaging surface 12a. Converts numeric value to character information h.

The meter reading value recording unit 42 records the character information h and the imaging time information b output from the OCR processing unit 34 .

On the other hand, while the meter reading device 10 is correctly placed on the water meter 110 for imaging, as shown in FIG. Since it is in contact with the convex portion 117 , minute vibrations and sounds propagating from the water pipe 150 and the water stop valve 160 can be reliably captured.

When the vibration sensor 14 detects vibration on the detection surface 14a, the vibration sensor 14 converts the detected vibration into an electrical signal corresponding to the vibration and generates a vibration electrical signal. Similarly, when sound is detected, it is converted into an electrical signal corresponding to the detected sound to produce an acoustic electrical signal.

The vibration sensor 14 thus outputs the vibration electric signal and/or the acoustic electric signal to the amplifier/filter section 21 together with the detection time information e. The detection time information e can also be used as the identification number of the vibration electric signal c0. Note that a microphone can be used instead of the vibration sensor 14 . When a microphone is used, the microphone detects a minute sound propagating through the water pipe 150 or the water stop valve 160, converts the detected sound into an electrical signal, and outputs an acoustic electrical signal. 14 detects vibration and outputs an oscillating electrical signal c0.

The amplifier/filter unit 21 amplifies the oscillating electric signal c0 output from the vibration sensor 14, and further performs filter processing such as low-frequency noise removal such as vehicle and pedestrian traffic and anti-aliasing to amplify and filter the signal. A vibration electric signal c1 that has been completed is generated, and is output to the A/D converter 22 together with the detection time information e.

The A/D conversion unit 22 samples the electric vibration signal c1 output from the amplification/filter unit 21 at a constant cycle, thereby converting the electric vibration signal c1 into vibration signal data c2, which is a digital signal. , and output to the recording unit 35 together with the detection time information e.

The recording unit 35 becomes operable in response to the start command r from the measurement control unit 33, and records the vibration signal data c2 output from the A/D conversion unit 22 together with the detection time information e in the recording result recording unit 43. Let

The recording result recording unit 43 records the vibration signal data c2 output from the recording unit 35 in the audio file format in association with the detection time information e.

The data transmission/reception unit 50 has a function of wirelessly communicating with the meter reading handy terminal 200 . Then, image data a0 and imaging time information b recorded in the image recording unit 41, character information h and imaging time information b recorded in the meter reading value recording unit 42, and vibration signal data c2 recorded in the recording result recording unit 43. and detection time information e can be transmitted to the meter reading handy terminal 200 .

The meter reading handy terminal 200 stores the transmitted information in association with the identification number of the water meter 110 . The identification number of the water meter 110 can be recognized, for example, based on the positional information obtained by the built-in GPS function of the meter reading handy terminal 200 . Alternatively, a meter reader may read the identification number attached to the water meter 110 and input it into the handy terminal 200 for meter reading so that the handy terminal 200 for meter reading can recognize it.

The meter-reading handy terminal 200 calculates the previous meter-reading time from the difference between the current meter-reading value grasped based on the character information h and the previous meter-reading value of the same water meter stored in the meter-reading handy terminal 200. Calculate tap water consumption from Furthermore, the water charge may be calculated from the usage amount, and a slip on which the calculated water charge is described may be printed.

On the other hand, the vibration signal data c2 transmitted to the meter reading handy terminal 200 is used for water leakage determination. The water leakage determination is performed by, for example, having a skilled investigator actually listen to the vibration signal data c2. Alternatively, analysis by a personal computer or the like is also possible. In analysis by a personal computer, for example, the ratio of signals exceeding a predetermined judgment reference voltage value in the vibration signal data c2 in a unit time is obtained as a time integral rate, and when the value exceeds a certain level, water leakage I judge.

In the above description, the meter reading device 10 and the meter reading handy terminal 200 are described as separate pieces of hardware. However, it is interpreted as the meter reading device 10 in the present invention.

Next, an operation example of the meter reading device of this embodiment configured as described above will be described.

By the meter reading device 10, both the meter reading work of reading the meter reading displayed on the display unit 115 and the work of acquiring the vibration signal data required for the leakage investigation of the water pipe 150 and the water stop valve 160 are performed. First, the meter reading device 10 needs to be correctly placed on the water meter 110 .

In the needle detection device 10, a cylindrical protrusion 17 having an outer diameter slightly smaller than the inner diameter of the peripheral end protrusion 117 protrudes in the imaging direction F from the bottom surface 11a. When the meter reading device 10 is correctly placed on the water meter 110 , the convex portion 17 is positioned inside the circumferential end convex portion 117 of the water meter 110 .

In this state, when the meter reader moves the meter reading device 10 in the radial direction, the meter reader confirms that the outer side of the convex portion 17 collides with the inner side of the circumferential end convex portion 117 , thereby confirming that the meter reading device 10 is attached to the water meter 110 . Correct placement can be intuitively recognized.

In addition, since the inner diameter size of the peripheral end convex portion 117 is larger than the outer diameter size of the convex portion 17 , the convex portion 17 is positioned in the concave portion 118 but is radially spaced apart from the gap 119 in the concave portion 118 . can be moved by minutes. Moreover, since the convex portion 17 has a cylindrical shape, it can also rotate inside the concave portion 118 . Therefore, even if the meter reading device 10 is correctly placed on the water meter 110, the positional relationship between the meter reading value displayed on the display unit 115 and the imaging surface 12a of the camera 12 is generally It is different each time it is arranged in 110 .

However, as long as the meter reading device 10 is correctly arranged on the water meter 110, the OCR processing section 34 recognizes the top, bottom, left, and right of the display section 115 regardless of the positional relationship between the meter reading value and the imaging surface 12a. To correctly convert numerical values into character information h. In this way, the meter reading work is performed with high reliability.

Further, when the meter reading device 10 is correctly placed on the water meter 110, the detection surface 14a of the vibration sensor 14 inevitably comes into contact with the metal peripheral convex portion 117 which is a part of the water meter 110. The vibration sensor 14 reliably captures minute vibrations and sounds propagating from the pipe 150 and the water stop valve 160 . Thereby, the operation of acquiring vibration signal data required for water leakage investigation is also performed with high reliability.

Next, an example of operation during meter reading work will be described.

FIG. 8 is a flowchart showing an example of the operation during meter reading work of the meter reading value.

After confirming that the meter reading device 10 is correctly placed on the water meter 110, the meter reader operates the meter reading handy terminal 200 and instructs to start imaging. The meter reading handy terminal 200 instructed to start imaging transmits a start command r to the meter reading device 10 (S1).

When the meter reading device 10 is correctly placed on the water meter 110, as illustrated in FIG. 5, the peripheral light is blocked from entering the display section 115, so the display section 115 is illuminated by the peripheral light. never

The start command r is received by the data transmission/reception unit 50 of the meter reading device 10, is output from the data transmission/reception unit 50 to the measurement control unit 33, and is further transmitted from the measurement control unit 33 to the LED control unit 31, the image capturing unit 32, and the sound recording unit. 35.

The LED control unit 31 generates a lighting command s for lighting the LED 13 according to the start command r output from the measurement control unit 33 and outputs the lighting command s to the LED 13 . In response to this lighting command s, the LED 13 is lit (S2).

As illustrated in FIG. 9 , a plurality of LEDs 13 are arranged in the circumferential direction of a circle around the camera 12 so as to surround the camera 12 . The light from the LEDs 13 is incident on an annular diffuser plate 15 which is positioned directly below the LEDs 13 and has a hollow portion 15a facing the imaging surface 12a of the camera 12 .

The light incident on the diffuser plate 15 is diffused over the entire surface of the diffuser plate 15 by the diffuser plate 15 , and then enters the linear polarizing plate 16 a integrally laminated on the diffuser plate 15 .

FIG. 10 is a schematic diagram for explaining the action of the linear polarizing plate 16. FIG.

The linear polarizing plate 16a has a horizontal polarization axis, and as shown in FIG. 10, of the light La supplied by the diffuser plate 15, only the horizontal linearly polarized light Lb passes through the linear polarizing plate 16a. and reaches the display unit 115 (S3).

Since the surface of the display unit 115 is covered with a transparent glass surface, the linearly polarized light Lb that has reached the display unit 115 is specularly reflected on the transparent glass surface, becomes specularly reflected light (linearly polarized light) Lc, and becomes a linear light. It proceeds toward the polarizing plate 16 . A portion of the linearly polarized light Lb reaching the display unit 115 is also diffusely reflected by the entire transparent glass surface of the display unit 115 to become diffusely reflected light Ld, which travels toward the linearly polarizing plate 16 .

The specularly reflected light Lc specularly reflected on the transparent glass surface of the display unit 115 is horizontal linearly polarized light, and therefore cannot pass through the linear polarizing plate 16b having a vertical polarization axis. That is, the linear polarizing plate 16b functions as a blocking section that blocks the specularly reflected light Lc from being guided to the imaging section 12a. The diffusely reflected light Ld diffusely reflected on the transparent glass surface of the display section 115 can illuminate the entire surface of the display section 115, pass through the linear polarizing plate 16b, and reach the imaging section 12a.

As a result, specularly reflected light Lc due to specular reflection on the transparent glass surface of the display unit 115 is blocked by the linear polarizing plate 16b and does not reach the imaging unit 12a (S4). (S5).

The image capturing unit 32 outputs an image capturing command t to the camera 12 in response to the start command r output from the measurement control unit 33 . In response to this imaging command t, an image of the meter reading value on the display section 115 is imaged by the camera 12, and the image data a0 is output to the image imaging section 32 together with the imaging time information b (S6).

As described above, specularly reflected light Lc due to specular reflection on the transparent glass surface of the display section 115 is blocked by the linear polarizing plate 16b and does not reach the imaging section 12a. As a result, the image of the meter reading value on the display unit 115 does not become a flashing image, and is clearly captured by the camera 12 .

FIG. 11A is an image showing an example of imaging results by the meter reading device 10 of the present embodiment.

FIG. 11B is an image showing an example of imaging results by a meter reading device that does not include the linear polarizing plate 16 .

FIG. 11B shows a shining image in which a flash is captured by the specularly reflected light Lc being incident on the imaging unit 12a. It can be seen that

The image data a0 and the image capturing time information b output from the camera 12 to the image capturing unit 32 are further output from the image capturing unit 32 to the image recording unit 41 and the OCR processing unit 34, and are also output from the image capturing unit 32 to LED control. An imaging completion signal d is output to the unit 31 .

The LED control unit 31 generates an extinguishing instruction u for extinguishing the LED 13 in response to the imaging completion signal d from the imaging unit 32 and outputs it to the LED 13 . The LED 13 is extinguished in response to the extinguishing instruction u from the LED control section 31 (S7).

The image recording unit 41 records the image data a0 and the image capturing time information b output from the image capturing unit 32 (S8).

In this way, the LED 13 is lit only when the camera 12 takes an image, and is immediately turned off after the image is taken, so that the power of the battery (not shown) that supplies power to the meter reading device 10 is saved.

In the OCR processing unit 34, the meter reading numerical value (m ³ ) of usually 4 to 6 digits captured in the image data a0 from the image capturing unit 32 is converted into character information using the OCR (optical character recognition) function. (S9). For example, when the meter reading value "01260" is imaged in the image data a0 as shown in FIG. It is output to the meter reading value recording unit 42 .

The meter reading value recording unit 42 records the character information h and the imaging time information b output from the OCR processing unit 34 (S10).

Next, an example of operation at the time of acquiring vibration signal data required for water leakage investigation will be described.

FIG. 12 is a flow chart showing an example of the operation at the time of acquiring vibration signal data required for water leakage investigation.

As described above, while the meter reading device 10 is correctly placed on the water meter 110 and the meter reading operation is being performed, the detection surface 14a of the vibration sensor 14 is part of the water meter 110, as shown in FIG. Since it is always in contact with the metal peripheral protrusion 117 , the vibration sensor 14 reliably captures minute vibrations propagating from the water pipe 150 and the water stop valve 160 .

Therefore, in the meter reading device 10, while the meter reading work is being performed, the acquisition work of the vibration signal data required for the water leakage investigation is also performed at the same time.

In the vibration sensor 14, when vibration is detected on the detection surface 14a, the detected vibration is converted into an electric signal to generate an electric vibration signal c0, which is output to the amplification/filter unit 21 together with the detection time information e. (S21).

The amplifier/filter unit 21 amplifies the oscillating electrical signal c0 output from the vibration sensor 14, and further performs filter processing such as low-frequency noise removal such as vehicle and pedestrian traffic and anti-aliasing. An amplified and filtered oscillating electric signal c1 is generated and output to the A/D converter 22 together with the detection time information e (S22).

In the A/D converter 22, the oscillating electric signal c1 output from the amplifying/filtering unit 21 is sampled at a constant cycle, so that the oscillating electric signal c1 is converted into oscillating signal data, which is a digital signal. c2 and output to the recording unit 35 together with the detection time information e (S23).

The recording unit 35 becomes operable in response to the start command r from the measurement control unit 33, and the vibration signal data c2 output from the A/D conversion unit 22 is recorded in the recording result recording unit 43 together with the detection time information e. be done.

In the recording result recording unit 43, the vibration signal data c2 output from the recording unit 35 is recorded in the audio file format in association with the detection time information e (S24).

Image data a0 and imaging time information b recorded in the image recording unit 41, character information h and imaging time information b recorded in the meter reading value recording unit 42, vibration signal data c2 recorded in the sound recording result recording unit 43, and detection The time information e is transmitted from the data transmitter/receiver 50 to the meter reading handy terminal 200 by wireless communication.

The meter-reading handy terminal 200 uses the difference between the current meter-reading value ascertained based on the character information h and the previous meter-reading value of the water meter stored in the meter-reading handy terminal 200 to determine the value from the previous meter reading. is calculated (S25). Furthermore, the water charge is calculated from the amount of water used, and if necessary, a slip on which the water charge is described is printed.

On the other hand, the vibration signal data c2 transmitted to the meter reading handy terminal 200 will be used later for water leakage determination (S26). Judgment of water leakage is performed, for example, by actually listening to the vibration signal data c2 by a skilled investigator or by analysis using a personal computer or the like. In analysis using a personal computer, for example, the ratio of signals exceeding a predetermined judgment reference voltage value in the vibration signal data c2 within a unit time is obtained as a time integration rate, and when the value exceeds a certain level is determined to be leaking.

As described above, according to the meter reading device 10 of the present embodiment, both the meter reading work and the vibration signal data acquisition work can be performed at the same time. Further, the meter reader can intuitively recognize that the meter reading device 10 is correctly arranged on the water meter 110 . Then, if the meter reading device 10 is correctly arranged on the water meter 110, the meter reading device 10 can always catch the meter reading value on the display unit 115 in the field of view. Moreover, in addition to blocking the peripheral light from entering the display section 115 by the peripheral convex section 117, the imaging surface 12a uses only the light from the LED 13 controlled by the diffuser plate 15 and the linear polarizer 16 as a light source. Since the image of the display unit 115 can be captured, a clear image without flash or the like can be obtained. As a result, character recognition accuracy is improved, and it is also possible to improve meter reading accuracy.

Furthermore, when the meter reading device 10 is correctly placed on the water meter 110 , the detection surface 14 a of the vibration sensor 14 always comes into contact with the circumferential end projection 117 of the water meter 110 . As a result, minute vibrations and sounds propagating from the water pipe 150 and the water stop valve 160 can be reliably captured, so that vibration signal data and acoustic signal data can be reliably acquired.

As described above, according to the meter reading device 10, both the meter reading work and the vibration signal data acquisition work can be automatically performed at the same time with high reliability.

(Second embodiment)
A meter reading device of a second embodiment will be described.

Since the meter-reading device of the second embodiment is a modified example of the meter-reading device of the first embodiment, different points will be described, and duplicate description will be avoided by attaching the same reference numerals to the same parts.

The meter reading device of this embodiment has a configuration in which the linear polarizing plate 16 of the meter reading device 10 of the first embodiment is replaced with a circular polarizing plate 19 .

FIG. 13 is a perspective view showing a configuration example of the circularly polarizing plate 19. As shown in FIG.

The circularly polarizing plate 19 is constructed by stacking a disc-shaped quarter-wave plate 19a and a linearly polarizing plate 19b.

Thus, the circularly polarizing plate 19 formed by overlapping the quarter-wave plate 19a and the linearly polarizing plate 19b is a common one.

14A and 14B are diagrams for explaining the principle of how light is polarized by the circularly polarizing plate 19. FIG.

The circularly polarizing plate 19 may be rotated clockwise or counterclockwise, but in FIG. 14, for the sake of explanation, it is assumed to be rotated clockwise.

The light Le emitted from the LED 13 is incident on an annular diffuser plate 15 which is positioned directly below the LED 13 and has a hollow portion 15a at a portion facing the imaging surface 12a of the camera 12 .

The light Le incident on the diffuser plate 15 is diffused over the entire surface of the diffuser plate 15 by the diffuser plate 15 , and then enters the circularly polarizing plate 19 integrally laminated on the diffuser plate 15 .

The light Le incident on the circularly polarizing plate 19 becomes circularly polarized light Lf right-rotated by the circularly polarizing plate 19 , reaches the display section 115 , and illuminates the display section 115 .

Since the surface of the display unit 115 is covered with a transparent glass surface, the circularly polarized light Lf (right-rotation) that reaches the display unit 115 is specularly reflected on the transparent glass surface, and the counter-rotation, that is, the counterclockwise rotation of the circle It becomes polarized light Lg and travels toward the circularly polarizing plate 19 . Part of the circularly polarized light Lf reaching the display section 115 also becomes diffusely reflected light Lh that is diffusely reflected on the entire transparent glass surface of the display section 115 to illuminate the entire display section 115 .

Circularly polarized light (left direction) Lg traveling from the transparent glass surface of the display unit 115 toward the circular polarizer 19 is incident on the circular polarizer 19. Since the circular polarizer 19 rotates clockwise, the circularly polarized light Lg is cannot pass. That is, the circularly polarizing plate 19 functions as a blocking section that blocks the circularly polarized light Lg from being guided to the imaging surface 12a. The diffusely reflected light Lh diffusely reflected on the transparent glass surface of the display unit 115 illuminates the entire surface of the display unit 115, passes through the circularly polarizing plate 19, and can reach the imaging unit 12a.

As a result, specularly reflected light Lg due to specular reflection on the transparent glass surface of the display unit 115 is blocked by the single-structured circularly polarizing plate 19 and does not reach the imaging unit 12a, and only the diffusely reflected light Lh is reflected by the imaging unit. 12a will be reached.

Thus, even if the circularly polarizing plate 19 is applied in place of the linearly polarizing plate 16 in the meter reading device 10 of the first embodiment, the same effects as those of the first embodiment can be obtained.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and spirit of the invention, as well as the scope of the invention described in the claims and equivalents thereof.

10 Meter reading device 11 Bottom plate 11a Bottom surface 12 Camera 12a Imaging surface 14 Vibration sensor 14a Detection surface 15 Diffusion plate 15a Hollow part , 16 linearly polarizing plate 16a linearly polarizing plate 16b linearly polarizing plate 17 convex portion 18 data processing unit 19 circularly polarizing plate 19a quarter wave plate , 19b... linear polarizing plate, 20... analog circuit section, 21... amplification/filter section, 22... A/D conversion section, 30... control section, 31... LED control section, 32... image pickup Section 33 Measurement control section 34 OCR (optical character recognition) processing section 35 Recording section 40 Recording section 41 Image recording section 42 Meter value recording section 43 Recording result recording unit 50 Data transmission/reception unit 100 Water meter box 110 Water meter 115 Display unit 115a Display surface 117 Convex portion 118 Concave portion 119 Gap 150 Water pipe 160 Water stop valve 200 Handy terminal for meter reading B Central axis F Imaging direction G Center of imaging surface L Maximum Distance to far part, S: shortest distance, T ₁ , T ₂ : amount of protrusion.

Claims (8)

a light source for supplying light for illuminating a display portion of the water meter on which a numerical value relating to the amount of water flowing through the water pipe is displayed;
a polarizing unit that guides linearly polarized light from the light supplied by the light source to the display unit;
an imaging unit that captures an image of the display unit illuminated by the linearly polarized light;
a blocking unit that blocks specularly reflected light that is specularly reflected by the display unit from the linearly polarized light so as not to be guided to the imaging unit;
a conversion unit that converts the numerical value related to the amount of water included in the image of the display unit captured by the imaging unit into text information using an OCR function;
A meter reading device comprising: the light source; and a diffuser plate provided between the display section and diffusing the light supplied by the light source in order to illuminate the entire surface of the display section . a light source for supplying light for illuminating a display portion of the water meter on which a numerical value relating to the amount of water flowing through the water pipe is displayed;
a polarizing unit that guides linearly polarized light from the light supplied by the light source to the display unit;
an imaging unit that captures an image of the display unit illuminated by the linearly polarized light;
a blocking unit that blocks specularly reflected light that is specularly reflected by the display unit from the linearly polarized light so as not to be guided to the imaging unit;
a conversion unit that converts the numerical value related to the amount of water included in the image of the display unit captured by the imaging unit into text information using an OCR function;
a convex portion that protrudes in the imaging direction from a bottom surface that is provided to be orthogonal to the imaging direction of the imaging unit and is provided so as to surround the imaging direction;
a detection unit having a detection surface for detecting at least one of vibration and sound generated in the water pipe on the outer peripheral side of the convex portion. The polarizing portion is a first linear polarizing plate having a first polarizing axis,
The meter reading device according to claim 1 or 2 , wherein said blocking section is a second linear polarizing plate having a second polarization axis orthogonal to said first polarization axis. a light source for supplying light for illuminating a display portion of the water meter on which a numerical value relating to the amount of water flowing through the water pipe is displayed;
A circularly polarizing plate that guides circularly polarized light from the light supplied by the light source to the display unit;
an imaging unit that captures an image of the display unit illuminated by the circularly polarized light;
a conversion unit that converts the numerical value related to the amount of water included in the image of the display unit captured by the imaging unit into text information using an OCR function ;
a diffuser plate provided between the light source and the display unit for diffusing the light supplied by the light source in order to illuminate the entire surface of the display unit ;
The needle reading device, wherein the circularly polarizing plate blocks specularly reflected light of the circularly polarized light specularly reflected on the display unit so as not to be guided to the imaging unit. a light source for supplying light for illuminating a display portion of the water meter on which a numerical value relating to the amount of water flowing through the water pipe is displayed;
A circularly polarizing plate that guides circularly polarized light from the light supplied by the light source to the display unit;
an imaging unit that captures an image of the display unit illuminated by the circularly polarized light;
a conversion unit that converts the numerical value related to the amount of water included in the image of the display unit captured by the imaging unit into text information using an OCR function;
a convex portion that protrudes in the imaging direction from a bottom surface that is provided to be orthogonal to the imaging direction of the imaging unit and is provided so as to surround the imaging direction;
A detection unit having a detection surface for detecting at least one of vibration and sound generated in the water pipe on the outer peripheral side of the convex portion,
The needle reading device, wherein the circularly polarizing plate blocks specularly reflected light of the circularly polarized light specularly reflected on the display unit so as not to be guided to the imaging unit. The meter reading device according to any one of claims 1 to 5 , further comprising a control section that controls the light source so that the display section is illuminated when an image is captured by the imaging section. The display unit is arranged in a concave shape lower than the peripheral convex portion in the main body of the measuring device, and the imaging surface of the imaging unit faces the display surface of the display unit in relation to the measuring device. When the convex portion is positioned inside the peripheral convex portion, a part of the bottom surface on the outer peripheral side of the convex portion and the detection surface are in contact with the peripheral convex portion. 6. The meter reading device according to Item 2 or 5 . In relation to the measurement device, when the imaging surface of the imaging unit faces the display surface of the display unit and the convex portion is positioned inside the peripheral convex portion, the display unit is The meter reading device according to claim 7, shielded from ambient light.

Images