KR200449378Y1 - Meter for detecting quantity - Google Patents

Abstract

The meter for detecting the flow rate of the present invention includes a rotating body which rotates by a flow rate and includes a magnetic body having numeric pads on a circumferential surface and having a predetermined magnetic strength corresponding to a specific numeric pad among the numeric pads; A sensing unit having a pair of hall sensors corresponding to the number pads, respectively, and detecting a magnetic field value with the magnetic material by the hall sensors; And a controller configured to display a rotation value of the rotating body corresponding to the flow rate using the magnetic field value.

Description

Meter for detecting quantity

The present invention relates to a flow rate detection meter, and more particularly, to a flow rate detection meter that mechanically reads a measured value accurately by a non-contact method using a magnetic value and displays it numerically.

The flow rate measuring meter generally used is to measure the amount of water consumed by a house or various buildings and to charge an appropriate fee according to the amount of water used. It can be divided into a mechanical meter or an electronic meter.

Such a mechanical meter is configured to mechanically count the rotation of a rotating body which is disposed in the main body and rotates according to the flow of the flow through the gear units arranged in the metering unit. Although there is an advantage, it is not easy to check the metered water usage because it is installed in the form of landfill in the wall or floor of a house or various buildings for the metering of the flow rate, and it is not possible to display the exact water consumption according to the mechanical counting. have.

In addition, since the electronic meter detects the rotational force of the rotating body as a sensor and displays it on the liquid crystal panel, the electronic meter can be manufactured compactly by integrating the internal circuit of the metering unit, and also has high reliability, stable and remote detection of the reading value. It has the advantage of being possible, but it has the disadvantage of being expensive and easily causing a breakdown.

In addition, recently, a meter using a substrate or a hall sensor has been proposed to detect a more accurate flow rate, and such a meter is displayed by counting the rotation of the rotating body by the flow rate to display the usage amount or the rotating body detected by the hall sensor. Displays the usage amount by classifying the rotation detection value of each step. However, the meter using the substrate or the Hall sensor is inaccurate detection of rotation of the rotating body, in particular, as the meter is installed in a buried form, malfunction occurs due to humidity, and the rotation detection of the rotating body is incorrectly performed. As the rotation of the rotating body is not accurately sensed, and the classification width of the rotating sensing value is wide, there is a problem in that the actual water consumption cannot be accurately displayed due to a large error between the actual rotating body and the rotating value displayed on the meter. Next, a general flow rate detection meter will be described with reference to FIG. 1.

1 is a view showing a general mechanical water meter. Here, FIG. 1 is a view showing a water meter installed in a buried form on the floor of a house or various buildings.

Referring to FIG. 1, the meter 120 is installed in the form of a buried hole 110 formed in the bottom 100, and the first rotating body 122 and the first rotating body rotating by a flow rate according to water use. And second to fifth rotating bodies 124, 126, 128, and 130 rotating step by step in correspondence with the rotation of 122. The circumferential surfaces of the rotating bodies 122, 124, 126, 128, and 130 include numeric pads on which numbers from 0 to 9 are recorded.

As the meter 120 is installed in the wall 100 as described above in the form of a buried, it is not easy to read the number recorded on the circumferential surface of the rotating bodies (122, 124, 126, 128, 130) for the water usage check is troublesome water usage check It is. In addition, when the sensor detects and displays the recorded number or the rotation of the rotating bodies 122, 124, 126, 128 and 130 for easy reading of the numbers recorded on the circumferential surfaces of the rotating bodies 122, 124, 126, 128 and 130, external environmental factors For example, a malfunction of the sensor due to humidity or the like may occur, thereby incorrectly detecting the sensor, and the sensor may not accurately detect rotation of the rotors 122, 124, 126, 128, and 130, and thus may not reliably read water usage. In addition, an error between the rotation of the actual rotating bodies 122, 124, 126, 128, and 130 and the rotation displayed on the display unit may not accurately display the actual water usage.

Accordingly, an object of the present invention is to provide a flow rate measuring meter that can easily check the measured value by accurately detecting the rotation of the rotating body corresponding to the flow rate in a non-contact manner using a magnetic display.

Meter for detecting the flow rate according to the present invention for achieving the above objects, the rotation corresponding to the flow rate, a plurality of number pads provided on the circumferential surface, at least one of the plurality of number pads A rotating body including correspondingly located magnetic bodies; A plurality of conductors corresponding to each of the plurality of numeric pads, a plurality of resistors connected between the plurality of conductors so that the plurality of conductors have different voltage values, and the plurality of conductors A sensing unit including a plurality of Hall sensors respectively corresponding to and a switching conductor connected to one of the plurality of conductors by the corresponding Hall sensor when the magnetic bodies are adjacent to each other; A control unit for calculating a rotation value of the rotating body using the voltage value provided by the switching conductor of the sensing unit; And a display unit for displaying the generated rotation value.

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Accordingly, the present invention accurately detects the rotation of the rotating body according to the flow rate by using a magnet to eliminate the error between the rotating value of the rotating body and the weighing value displayed on the meter, and accurate meter reading is possible. As the number is displayed, the measured value of the mechanical meter embedded in the floor can be easily checked from the outside. In addition, the present invention can prevent the malfunction of the meter due to external environmental factors such as humidity, etc. by detecting the rotation of the rotating body using a magnetic, it can easily replace the existing meter at low cost.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. In the following description, only parts necessary for understanding the operation according to the present invention are described, and it should be noted that the description of other parts will be omitted so as not to distract from the gist of the present invention.

The present invention proposes a meter for detecting flow rate. Here, in the embodiment of the present invention to be described later described as an example for a water meter, the meter proposed in the present invention is applicable to all meters for detecting the flow rate. In addition, the present invention proposes a meter that accurately detects the rotation of the rotating body rotated by the flow rate, and accurately displays the detected rotation detection value numerically so as to be easily identified without errors.

At this time, the meter according to the embodiment of the present invention, the Hall sensor using a magnet accurately detects the rotation of the rotating body rotated by the flow rate of water, the user easily checks the rotation detection value detected by the Hall sensor without error Numbers should be as accurate as possible. In addition, the meter according to an embodiment of the present invention, the Hall sensor using a magnet to detect the rotation of the rotating body in a non-contact manner in order to prevent malfunction due to the external environmental factors, such as humidity and thereby incorrect detection, Hall sensor Accurately display the actual usage by minimizing the error between the rotation of the rotor and the rotation value displayed on the meter by accurately displaying up to one unit or less by using the detected values. Next, the meter according to the embodiment of the present invention will be described in more detail with reference to FIG. 2.

2 is a view schematically showing a meter according to an embodiment of the present invention.

Referring to FIG. 2, as described above with reference to FIG. 1, the meter includes a mechanical meter 220 having rotating bodies rotating by a flow rate according to water use, and the measured value of the mechanical meter 220, that is, the The sensing unit 230 for detecting the rotation of the rotating body, the control unit 240 to display the rotation value of the rotating body on the display unit 250 by using the detected value of the sensing unit 230, and the control unit ( And a display unit 250 for displaying the weighing value of the rotating meter of the rotating bodies, that is, the mechanical meter 220 by 240. Here, the rotating bodies include numeric pads each having a number from 0 to 9 recorded on the circumferential surface, and the mechanical meter 220 and the sensing unit 230 are embedded in the hole 210 formed in the bottom 200. Furnace installation, that is, the detector 230 is installed in the same place as the mechanical meter (220). In addition, the control unit 240 may be installed in the hole 210 or may be installed outside the floor 200, and the display unit 250 may be installed in a place where water usage can be easily checked. Next, the structure of the meter according to the embodiment of the present invention will be described with reference to FIG. 3.

3 is a view conceptually showing the structure of a meter according to an embodiment of the present invention.

Referring to FIG. 3, the meter includes a magnetic body 310 in which a specific number pad of the rotating bodies has a predetermined magnetic strength to detect rotation of the rotating bodies provided in the mechanical meter, and the magnetic body 310. The magnetic field formed by the first hall sensor 320 and the second hall sensor 330 senses and transfers the magnetic field value to the corresponding coupling part, that is, the first coupling part 340 and the second coupling part 350. Then, the coupling units 340 and 350 transmit the magnetic field values received from the hall sensors 320 and 330 to the control unit 240, and the control unit 240 uses the magnetic field value to transmit the rotation values of the rotating bodies by the flow rate. Display unit 250 to display.

Here, the sensing unit includes a pair of Hall sensors corresponding to the respective numeric pads of the rotating body, and the pair of Hall sensors transmit the magnetic field values sensed by one coupling unit. Therefore, when the first hall sensor 320 and the second hall sensor 330 are hall sensors corresponding to the same numeric pad, the first coupling part 340 and the second coupling part 350 are the same coupling part. The magnetic body 310 is positioned to correspond to two Hall sensors. In addition, the magnetic body 310 may be included in a specific number pad of the first rotating body 122 of FIG. 1, that is, the rotating body corresponding to the lowest unit number among the rotating bodies 122, 124, 126, 128, and 130, or the rotating bodies ( Among the 122, 124, 126, 128, and 130, the specific number pad of two or more rotors including the first rotor 122 may be included, and the detector 230 may be included in the meter in correspondence with the rotor including the magnetic body 310. Next, the structure of the meter according to the embodiment of the present invention will be described in more detail with reference to FIG. 4.

4 is a view schematically showing the structure of a meter according to an embodiment of the present invention.

Referring to FIG. 4, the meter may include a rotating body 400 that rotates by a flow rate, a sensing unit 230 that detects rotation of the rotating body 400, and a detection value of the sensing unit 230. And a controller 240 for displaying the rotation of the rotating body by the flow rate using the display unit 250.

The rotating body 400 may have a predetermined magnetic strength corresponding to the number pads 402, 404, 406, 410 in which the numbers from 0 to 9 are recorded, and the number pad 406 corresponding to, for example, 0 among the number pads 402, 404, 406, 410. Magnetic material 412 having a. In addition, the detector 230 may include hall sensors 422,... 460, respectively, for detecting the magnetic field formed with the magnetic body 412 when the magnetic body 412 of the rotating body 400 corresponds to the magnetic body 412. Control units (462, ..., 480) for coupling the sensed values detected by the Hall sensors (422, ..., 460) and output values of the coupling units (462, ..., 480) through an output line. And an output unit 482 for transmitting to 240. Then, the controller 240 displays the water usage on the display unit 250 using the detected values detected by the hall sensors 422,... 460 transmitted through the output unit 482.

The rotor 400 rotates by the flow rate, and the magnetic body 412 rotates as the number pads 402, 404, 406, 408, and 410 rotate by the rotation of the rotor 400. In this case, the magnetic body 412 is positioned to correspond to the two Hall sensors of the Hall sensors (422, ..., 460) of the sensing unit 230. Then, each Hall sensor corresponding to the magnetic body 412 detects a magnetic field with the magnetic body 412 and transfers the magnetic field value to the coupling unit, and the magnetic field value transmitted to the coupling unit is an output line and an output unit 482. The control unit 240 is transmitted through the control unit 240, the control unit 240 receives the magnetic field value accurately calculates the rotation value of the rotating body 400 corresponding to the flow rate using the magnetic field value and transmits it to the display unit 250.

Here, two Hall sensors equally connected to one coupling part correspond to one number pad among the number pads 402, 404, 406, 408 and 410 of the rotating body 400, and thus, between the pair of Hall sensors and the magnetic body 412. In the same environment, magnetic fields of the same size are formed. In addition, as the pair of Hall sensors correspond to one numeric pad, magnetic fields having different magnitudes are formed between the Hall sensors and the magnetic body 412 corresponding to different coupling portions, respectively, by a predetermined value in the same environment. That is, a pair of Hall sensors corresponding to one coupling portion transmits the magnetic field values of the same size to the coupling portion when the magnetic body 412 is correspondingly positioned in the same environment, and each Hall sensor corresponding to the different coupling portion is the same environment. In the case where the magnetic body 412 correspondingly transfers the magnetic field values having different sizes by the predetermined value to the coupling unit. In the embodiment of the present invention, the sensing unit 230 has been described as including a pair of Hall sensors corresponding to one numeric pad, but it is also possible to include one Hall sensor corresponding to one numeric pad.

Here, when the magnetic body 412 is positioned in correspondence with the Hall sensors corresponding to the same coupling portion, the control unit 240 receives a magnetic field value from one coupling portion, the number corresponding to the magnetic field value To be displayed. In this case, when the relative value of the magnetic field value corresponding to each number of the number pads (422, ..., 460) is digitized, it may be expressed as shown in Table 1 below. The magnetic field values corresponding to the numbers shown in Table 1 may be changed by the user, and the numerical display operation according to the magnetic field values sensed and transmitted by the range of the magnetic field values and hall sensors described later may also be changed by the user.

number 0 One 2 3 4 5 6 7 8 9 Magnetic field value 10 30 50 70 90 110 130 150 170 190

The Hall sensors 422,... 460 of the detector 230 correspond to the numbers from 0 to 9, and the magnetic body 412 corresponds to the Hall sensors 422,..., 460. If it is located, it detects the magnetic field value within the range of the magnetic field value of the corresponding number and delivers it to the coupling unit. In more detail, the pair of Hall sensors 422 and 424 corresponding to 0 detect the magnetic field value within the magnetic field value range of 0 to 20 and transmit the detected magnetic field value to the coupling unit 462. When the position is correct, the magnetic field value of 10 is transmitted to the coupling unit 462, and the control unit 240 displays the rotation value of the rotating body 400 corresponding to the flow rate as zero. In addition, the pair of Hall sensors 426 and 428 corresponding to 1 detect a magnetic field value within a magnetic field value range of 20 to 40 and transmit the detected magnetic field to the coupling unit 464, and the magnetic body 412 is correspondingly positioned. The magnetic field value of 30 is transmitted to the coupling unit 464, and the control unit 240 displays the rotation value of the rotating body 400 corresponding to the flow rate as 1.

In addition, the pair of Hall sensors 430 and 432 corresponding to 2 detect the magnetic field value within the magnetic field value range of 40 to 60 and transmit the magnetic field value to the coupling unit 466, and the magnetic body 412 is correspondingly positioned. The magnetic field value of 50 is transmitted to the coupling unit 466, and the control unit 240 displays the rotation value of the rotating body 400 corresponding to the flow rate as 2. The pair of Hall sensors 434 and 436 corresponding to 3 sense the magnetic field value within the magnetic field value range of 60 to 80 and transmit it to the corresponding coupling unit 468. When the magnetic body 412 is correspondingly positioned, 70 The magnetic field value of the coupling unit 468 is transmitted to the coupling unit 468, and the control unit 240 displays the rotation value of the rotating body 400 corresponding to the flow rate as 3. In addition, the pair of Hall sensors 438 and 440 corresponding to 4 detect a magnetic field value within a magnetic field value range of 80 to 100 and transmit the detected magnetic field to the corresponding coupling unit 470, and the magnetic body 412 is correspondingly positioned. The magnetic field value of 90 is transmitted to the coupling unit 470, and the control unit 240 displays the rotation value of the rotating body 400 corresponding to the flow rate as 4.

And, a pair of Hall sensors 442, 444 corresponding to 5 detects the magnetic field value within the magnetic field value range of 100 ~ 120, and transfers it to the coupling unit 472, when the magnetic body 412 correspondingly positioned The magnetic field value of 110 is transmitted to the coupling unit 472, and the control unit 240 displays the rotation value of the rotating body 400 corresponding to the flow rate as 5. The pair of Hall sensors 446 and 448 corresponding to 6 detect a magnetic field value within a magnetic field value range of 120 to 140 and transmit the detected magnetic field to the coupling unit 474. When the magnetic body 412 is positioned correspondingly, 130 The magnetic field value of the coupling unit 474 is transmitted, and the control unit 240 displays the rotation value of the rotating body 400 corresponding to the flow rate as 6. In addition, the pair of Hall sensors 450 and 452 corresponding to 7 detect a magnetic field value within a magnetic field value range of 140 to 160 and transmit the detected magnetic field to the coupling unit 476, and the magnetic body 412 is correspondingly positioned. It transmits a magnetic field value of 150 to the coupling unit 476, the control unit 240 to display the rotation value of the rotating body 400 corresponding to the flow rate of 7.

In addition, the pair of Hall sensors 454 and 456 corresponding to 8 detect a magnetic field value within a magnetic field value range of 160 to 180 and transmit the detected magnetic field to the coupling unit 478, and the magnetic body 412 is positioned correspondingly. The magnetic field value of 170 is transmitted to the coupling unit 478, and the control unit 240 displays the rotation value of the rotating body 400 corresponding to the flow rate as 8. The pair of Hall sensors 458 and 460 corresponding to 9 detect a magnetic field value within a magnetic field range of 180 to 200 and transmit the detected magnetic field value to the coupling unit 180, and when the magnetic body 412 is positioned correspondingly, 190. The magnetic field value of the coupling unit 180 is transmitted to the coupling unit 180, and the control unit 240 displays the rotation value of the rotating body 400 corresponding to the flow rate as 9.

In addition, when the magnetic body 412 is located corresponding to each Hall sensor corresponding to a different number, for example, the magnetic body 412 is located corresponding to each of the Hall sensors 138, 440, 442, 444 corresponding to 4 and 5. In this case, the Hall sensor 440 corresponding to 4 adjacent to the Hall sensors 442 and 444 corresponding to 5 transmits the magnetic field value within the magnetic field value range of 90 to 100 to the coupling unit 470 and the Hall sensor corresponding to the 4. Hall sensor 442 corresponding to 5 adjacent to 138 and 440 transmits a magnetic field value within a range of 100 to 110 to the corresponding coupling unit 472. The magnetic field values are transmitted to the controller 240, and the controller 240 displays the numerical values up to one unit or less by using the magnetic field value, for example, the Hall sensor 440 corresponding to 4 senses the magnetic field value of 94. When the transmission and the hall sensor 442 corresponding to 5 detect and transmit the magnetic field value of 104, the controller 240 displays the rotation value of the rotor 400 corresponding to the flow rate as 4.4. In addition, each of the Hall sensors 422,..., 460 is greater than or equal to a threshold value, for example, the Hall sensor 440 corresponding to 4 senses and transmits a magnetic field value of 112, or the Hall sensor 442 corresponding to 5 is 97. When the magnetic field value is detected and transmitted, the control unit 240 determines that the magnetic field values sensed and transmitted by the hall sensors 440 and 442 are error values so as not to display the rotation value of the rotating body 400. Then, with reference to Figure 5 will be described in more detail the operation of the meter according to an embodiment of the present invention.

5 is a view schematically showing an operating state of the meter according to an embodiment of the present invention.

Referring to FIG. 5, the meter is a pair in which a magnetic body 412 having a predetermined magnetic strength corresponds to a number pad of four, in which the rotating body 400 rotates according to a flow rate so as to correspond to the number pad 406 of zero. If it is positioned in correspondence with the Hall sensors 438 and 442, the magnetic field value of 90 is transmitted to the coupling unit 470, and the magnetic field value of 90 is transmitted to the control unit 240. ) Denotes 4 corresponding to the magnetic field value of 90, that is, to indicate the rotation value of the rotating body 400 corresponding to the flow rate as 4.

In addition, when the rotor 400 rotates by the flow rate and the magnetic body 412 is located corresponding to each of the Hall sensors 440 and 442 corresponding to 4 and 5, the rotor 400 is adjacent to the Hall sensor 442 corresponding to 5. The Hall sensor 438 corresponding to 4 transmits the magnetic field value within the magnetic field value range of 90 to 100 to the corresponding coupling unit 470, and the Hall sensor 442 corresponding to 5 adjacent to the Hall sensor 440 corresponding to 4. ) Transmits a magnetic field value within a magnetic field value range of 100 to 110 to the corresponding coupling unit 472. These magnetic field values are transferred to the control unit 240, and the control unit 240 displays the numbers up to one unit or less by using the magnetic field value, for example, the Hall sensor 438 corresponding to 4 senses the magnetic field value of 95. When the transmission and the hall sensor 442 corresponding to 5 sense and transmit the magnetic field value of 105, the control unit 240 displays the rotation value of the rotor 400 corresponding to the flow rate as 4.5.

Thus, the meter according to the embodiment of the present invention accurately detects the rotation of the rotating body 400 in a non-contact manner through a Hall sensor using a magnetic, in particular from 0 for displaying the rotation value of the rotating body 400 in number A pair of Hall sensors corresponding to each number up to 9 accurately displays rotation values of less than one unit. Then, with reference to Figure 6 will be described in more detail the structure of the meter according to another embodiment of the present invention.

6 is a view schematically showing the structure of a meter according to another embodiment of the present invention.

Referring to FIG. 6, the meter may include a rotating body 400 that rotates by a flow rate, a sensing unit 230 that senses rotation of the rotating body 400, and a detection value of the sensing unit 230. And a controller 240 for displaying the rotation of the rotating body by the flow rate using the display unit 250.

The rotating body 400 may correspond to the number pads 402, 404, 406, 408, 410 in which the numbers from 0 to 9 are recorded, and the number pad 406 corresponding to a specific number pad, for example, 0, among the number pads 402, 404, 406, 408, 410. It includes a magnetic body 412 having a predetermined magnetic strength. In addition, the detector 230 may connect the number conductors 542,..., 560 corresponding to the number pads 402, 404, 406, 410 of the rotating body 400, and the conductors 542,. By connecting the resistors 562,..., 578 having the same device characteristics, that is, the same resistance value, and the magnetic body 412 of the rotating body 400, the magnetic field formed with the magnetic body 412 is used. To switch the Hall sensors 522,... 540, and the Hall sensors 522... 540 to perform a switching function between the numeric conductors 542... 560 and the switching conductor 580. And a switching conductor 580 for outputting a value sensed by the controller 240.

Here, the number conductors 542,..., 560 each have a voltage corresponding to the number corresponding to the number conductors 542,. For example, when a voltage of 9 V is applied to the number conductor 550 corresponding to 9, the number conductor 548 corresponding to 8 is 8 V, and the number conductor 546 corresponding to 7 is 7 V and 6 the number conductor ( 544 is 6V, 5 corresponds to the number conductor 542 5V, 4 corresponds to the number conductor 560 is 4V, 3 corresponds to the number conductor 558 3 corresponds to 3V, 2 numeric conductor 556 The number conductor 554 corresponding to 2V, 1 has a voltage of 0V. The rotor 400 rotates by the flow rate, and the magnetic body 412 rotates as the number pads 402, 404, 406, 408, and 410 rotate by the rotation of the rotor 400. In this case, the magnetic material 412 is located in correspondence with a Hall sensor connected to a specific number conductor, that is, a Hall sensor and a switching conductor 580 corresponding to the specific number conductor. Then, a magnetic field having a specific magnitude is formed between the magnetic body 412 and the hall sensor by a specific voltage of the specific number conductor, and the hall sensor senses the formed magnetic field. In addition, the formed magnetic field is turned on between the Hall sensor and the switching conductor 580, and the voltage of the specific number conductor is transmitted to the controller 240 through the switching conductor 580. Then, the controller 240 accurately calculates the rotation value of the rotor 400 corresponding to the flow rate using the voltage value and transmits it to the display unit 250. In this case, the sensing unit 230 is provided with a predetermined circuit 500 corresponding to the position of the magnetic body 412 (see FIG. 6).

Here, the numeric conductors 542,..., 560 have different voltages corresponding to the number pads 402, 404, 406, 408, 410 of the rotating body 400, and the magnetic body 412 corresponds to a specific number. When located near the Hall sensors 522,..., 540, a magnetic field is formed between the magnetic body 412 and the Hall sensor. Accordingly, the Hall sensor is turned on so that the number conductor (the magnetic body is located). The voltage applied to the number conductor is transmitted to the controller 240 through the switching conductor 580. That is, when the magnetic body 412 is positioned in correspondence with any of the Hall sensors and the switching conductor 580, the control unit 240 receives the voltage value of the numeric conductor through the switching of the Hall sensor, the display unit The display unit 250 displays a number corresponding to the voltage value.

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On the other hand, in the detailed description of the present invention has been described with respect to specific embodiments, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the embodiments described, but should be defined by the utility model registration claims as described below and equivalents to the utility model registration claims.

1 shows a general mechanical water meter.

2 is a view schematically showing a meter according to an embodiment of the present invention.

3 conceptually illustrates a structure of a meter according to an embodiment of the present invention;

4 is a view schematically showing the structure of a meter according to an embodiment of the present invention.

5 is a view schematically showing an operating state of the meter according to an embodiment of the present invention.

6 is a view schematically showing the structure of a meter according to another embodiment of the present invention.

Claims (14)

delete delete delete delete delete delete delete delete delete In the flow rate detection meter, A rotating body rotating in response to the flow rate, the rotating body including a plurality of numeric pads provided on a circumferential surface, and a magnetic body positioned corresponding to at least one specific numeric pad among the plurality of numeric pads; A plurality of number conductors corresponding to each of the plurality of number pads, a plurality of resistors connected between the plurality of number conductors so that the plurality of number conductors have different voltage values, and the plurality of number conductors A sensing unit including a plurality of Hall sensors respectively corresponding to the N number conductors, and a switching conductor connected to one of the plurality of number conductors by the corresponding Hall sensor when the magnetic body is adjacent to each other; A control unit for calculating a rotation value of the rotating body using the voltage value provided by the switching conductor of the sensing unit; And Meter comprising a display unit for displaying the generated rotation value. The method of claim 10, And said plurality of resistors have the same characteristics. The method according to claim 10 or 11, wherein The plurality of Hall sensors, characterized in that having the same characteristics. delete delete

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