KR101228427B1 - Digital meter capable of modifying flow and automatic modifying system for the same digital meter - Google Patents

Abstract

PURPOSE: A digital meter capable of a precise correction of a measured flux and an automatic correction system thereof are provided to correct the measured flux on a real time basis by correcting an instantaneous flux based on an average value of the information of flux errors and to automatically correcting errors of the digital meter. CONSTITUTION: A digital meter capable of a precise correction of a measured flux comprises a flux detecting unit(20), a flux information acquisition unit(310), an error rate information storage unit(40), a flux information calculation unit(320), and a flux display unit(50). The flux detecting unit detects the number of the rotation of an impeller based on a flow. The flux information acquisition unit obtains first flux information based on the sensed number of the rotation of the impeller. The average information of a flux error rate, which is an average value of the information of flux errors in a flux section per each unit hour, is stored in the error rate information storage unit. The flux information calculation unit reads the average information of the flux error rate of the flux section corresponding to the obtained first flux information and calculates accumulated flux information based on second flux information corresponding to the read average information of the flux error rate. The flux information calculation unit displays the calculated the accumulated flux information. [Reference numerals] (10) Flux chamber; (20) Flux detecting unit; (310) Flux information acquisition unit; (320) Flux information calculation unit; (40) Error rate information storage unit; (50) Flux display unit; (60) Communication interface unit; (70) Power unit; (AA) Fluid flow

Description

DIGITAL METER CAPABLE OF MODIFYING FLOW AND AUTOMATIC MODIFYING SYSTEM FOR THE SAME DIGITAL METER

The present invention relates to a digital meter. More particularly, the present invention relates to a digital meter capable of precisely correcting a measured flow rate and an automatic calibration system thereof.

Conventional digital water meter is mounted inside the flow chamber and the rotor blade (or impeller) sealed by the flow path is rotated by the flow flowing along the pipeline, the flow rate sensor mounted on the upper flow cover to detect the rotation of the blade flow rate information The flow rate is measured by calculating and digitally converting the signal into digital display and displaying it on the flow rate display part mounted on the upper part of the flow chamber.

Such a conventional digital water meter has a different flow rate error rate for each flow section per unit time when measuring the flow rate, which shows a large metering error, especially for a small amount of flow rate or a large amount of flow rate.

This is due to the fact that the rotation of the vanes according to the flow rate per unit time does not have a precise correlation with each other, and the raw material non-uniformity error of the flow chamber and the vane, the lot error of casting production, the processing error of the meter, the internal components of the flow chamber including the vane This is due to nonlinear causes such as assembly errors.

Therefore, the conventional water meter calibration test is to check how much the flow rate information measured by each test meter flows through the water pipes installed in series with the meter to be tested, and the flow rate information measured by each test meter matches the flow rate of the test water. Test through verification process. In addition, the meters displaying the flow rate outside the error range was troublesome to disassemble the meter, manually calibrate it, and reassemble it and repeat the test.

Moreover, even if the water meter passed the calibration test, the flow rate measurement test was not carried out correctly in all the flow intervals per unit time, so there was still a flow error and there was a problem in that it could not be calibrated for each flow interval per unit time. .

The present invention has been made to solve the above problems, the first object of the present invention to provide a digital meter capable of real-time correction of the measured flow rate in the flow rate section per unit time.

It is a second object of the present invention to provide a digital meter capable of real-time correction of a measured flow rate by correcting an instantaneous flow rate based on an average value of flow error information.

It is a third object of the present invention to provide an automatic calibration system for a digital meter that can automatically correct an error of the digital meter.

An object of the present invention as described above is a digital meter for measuring the flow rate, the flow rate sensing means for detecting the number of revolutions of the blade based on the flow of the flow rate; Flow information obtaining means for obtaining first flow rate information based on the detected number of revolutions of the van; Error rate information storage means for storing average flow rate error rate information, which is an average value of flow rate error information per unit time period; Flow rate information calculating means for reading the flow rate error rate average information in the flow rate section per unit time corresponding to the obtained first flow rate information and calculating the cumulative flow rate information based on the second flow rate information corresponding to the read flow rate error rate average information; And a flow rate display means for displaying the calculated cumulative flow rate information.

In addition, the present invention digital meter may further include a communication interface unit and a power supply unit. In particular, the communication interface 60 may be connected to a meter reading terminal (not shown) outside the meter to transmit accumulated flow rate information to the outside and receive flow rate error rate average information to be stored in the error rate information storage means from the outside. have.

The flow rate sensing means may be any one of an MR sensor, a hall sensor, an inductor sensor, and an optical sensor. The inductor sensor may include an inductive sensor and a capacitive sensor.

The first flow rate information may be obtained as flow rate information per unit time or sensor signal number information per unit time.

In addition, the flow rate error rate average information may be error rate lookup table information according to the flow rate section per unit time.

The flow error information is the difference value between the measured flow rate and the actual flow rate obtained by testing in the flow rate per unit time selected from all the flow rate per unit time, and the average error rate of the flow rate is repeatedly tested in the selected flow rate per unit time It may be an average value of the obtained flow error information.

On the other hand, when the flow rate section per unit time corresponding to the obtained first flow rate information is the non-test flow rate section, the flow rate information calculating means interpolates the read flow rate error rate average information to calculate the flow rate error rate correction value to thereby calculate the second flow rate information. It may be to calculate.

The flow rate error rate average information may be the flow rate error rate average information corrected at a constant rate in all flow sections including the test flow section and the non-test flow section.

In addition, an object of the present invention, the train test bench is provided with a plurality of digital meter is connected in series with the flow path pipe and provided with an inlet valve and an outlet valve at both ends of the flow path pipe; A first water storage tank connected to one end of the train test bench to supply fluid; A second water storage tank connected to the other end of the train test bench, the second water storage tank having a discharge valve for storing fluid flowing out of the flow path tube and for retracting the stored fluid; Reference flow rate measuring means mounted to a second storage tank and measuring a reference flow rate based on a weight or a water level of the fluid; A valve control unit controlling opening and closing of the inlet valve, the outlet valve, and the discharge valve based on the reference flow rate and the predetermined instantaneous flow rate to pass through the flow path pipe; A terminal box connected to a communication line of each digital meter and connected by giving an ID to each digital meter; And a flow error calculation means connected to the terminal box and calculating flow error information based on the measured flow rate information received from each digital meter, the measured reference flow rate, and the set instantaneous flow rate. This can be achieved by.

According to one embodiment of the present invention as described above, there is an effect capable of real-time correction of the measured flow rate in the flow interval per unit time based on the flow rate error rate average information in the metering of the digital meter.

In addition, the flow rate error rate average information used in the embodiment of the present invention can reduce the flow rate error rate more precisely through interpolation, thereby increasing the accuracy of the error correction.

In addition, by automatically calculating the flow rate error information of the digital meter, it provides an automatic calibration system of the digital meter that can automatically calibrate a large number of digital meters, thereby improving productivity and analyzing the flow error pattern and casting according to the injection deformation of mechanical parts. It is possible to analyze the flow error pattern according to the deviation, and to analyze the measurement error distribution by flow rate when developing new products, and to attach the precise measurement performance report for each production lot or individual meter to improve the reliability of the product.

1 is a block diagram showing a configuration according to an embodiment of a digital meter capable of correcting the measured flow rate of the present invention,
2 is a view showing a measurement error example table before and after correction in a specific test flow interval according to an embodiment of the present invention, the digital meter capable of correction of the measured flow rate;
3 is a view for explaining an interpolation calculation method used in an embodiment of a digital meter capable of correcting the measured flow rate of the present invention;
Figure 4 is a measurement of the weighing correction process according to an embodiment of the present invention, a digital meter capable of correction of the measured flow rate of the measurement error before correction (a), the error correction value (b) and the post-correction measurement error (c) Graphical drawing,
Figure 5 is a block diagram showing the configuration of an embodiment of an automatic calibration system of the present invention digital meter.

<Digital meter which can correct measurement flow rate>

1 is a block diagram showing a configuration according to an embodiment of a digital meter capable of correcting the measured flow rate of the present invention. As shown in Figure 1, one embodiment of the present invention digital meter for measuring the flow rate flow rate sensing means 20, flow rate information acquisition means 310, error rate information storage means 40, flow rate information calculation means 320 And a flow rate display means (50).

According to the present embodiment, when the flow rate information acquiring means 310 obtains the first flow rate information based on the number of revolutions of the vane detected by the flow rate sensing means 20, the flow rate information calculating means 320 may include the error rate information storing means ( The flow rate error rate average information stored in 40 is read and the cumulative flow rate information is calculated as the second flow rate information. As a result, since the second flow rate information is a value in which the flow rate error is corrected in all the flow rate sections per hour, the accumulated flow rate information in which the second flow rate information is accumulated and displayed is displayed on the flow rate display means 50 so that the flow rate can be accurately measured.

Here, the first flow rate information is individual flow rate information measured in real time without correction, and the basic flow coefficient (for example, flow rate signal 1) is determined by the number of flow rate signals per unit time or the number of flow rate signals per unit time generated according to the rotor blade rotation. Flow rate information per unit time applied to a flow rate value of 20 ml per piece). As a result, the accumulated flow rate information measured without correction may be calculated as a total number of flow rate signals or a cumulative total of flow rate information per unit time.

In addition, although the second flow rate information is individual flow rate information, either the number of flow rate signals per unit time is corrected based on the flow rate error rate average information or the basic flow rate coefficient is corrected, and the flow rate error is corrected.

In addition, since the flow error rate average information is an average value of the flow error information obtained by the repetitive test in the flow rate period of a particular unit selected from the flow rate period per unit time, there is no choice but to consist of discontinuous values in the flow rate period per unit time. Therefore, it is preferable that the flow rate error rate average information read out in accordance with the period for calculating the second flow rate information by the flow rate information calculating means 320 is stored as granular data.

However, since the flow rate error rate average information cannot be obtained by testing in the flow rate section for every unit time, the flow rate rate unit for each unit time is divided into a plurality of discontinuous flow sections. Can be saved and used. In this case, it is possible to cover the flow rate section per unit time, and to increase the accuracy of the second flow rate information by subdividing and increasing a plurality of discrete flow rate sections. Alternatively, an interpolation calculation method may be used to reduce the number of data corresponding to the flow rate error average information, which will be described below with the flow information calculating means 320.

Hereinafter, the configuration of this embodiment will be described in detail with reference to FIG. 1.

The flow rate sensing means 20 serves to detect the number of revolutions of the van based on the flow of the flow rate. The vane (or impeller) may be configured to rotate about the rotation axis by the flow rate having a rotation axis inside the flow chamber. In addition, the flow path cover is mounted to the upper part of the vane to be sealed to prevent leakage of the flow rate flowing through the flow path tube, and the flow rate sensing means 20 is mounted thereon to detect the number of revolutions of the vane.

The flow rate detecting means 20 may be any one of an MR sensor (magnetic resistance effect sensor), a hall sensor, a inductor sensor, and an optical sensor. In the case of the inductor sensor, an inductive sensor ( Inductive sensors or capacitive sensors can be used.

The flow rate information acquiring means 310 serves to acquire first flow rate information based on the detected rotor speed. Here, the first flow rate information may be obtained in the form of flow rate information per unit time or flow rate signal number information per unit time. In addition, the flow rate information acquisition means 310 may be mounted in the form of a microcomputer (MCU), the first flow rate information corresponding to the number of revolutions of the blades by the central processing unit and the flow rate calculation program input to the EEP-ROM Can be obtained.

The error rate information storage means 40 serves to store the flow rate error rate average information based on the average value of the flow rate error information in the flow rate section per unit time. Here, the flow error information is the difference value information between the measured flow rate and the actual flow rate obtained by testing in any one flow rate period selected from the unit of the flow rate per unit time, and the average error rate of the flow rate is repeated in the selected flow rate per unit time Average value of flow error information obtained by testing.

Generally, digital meters have different measurement characteristics, but digital meters produced through a certain manufacturing process by a specific manufacturer have almost similar flow measurement characteristics. Therefore, by repeatedly testing a digital meter produced by a specific manufacturer can obtain the average information of the flow rate error rate in the flow section per unit time.

The flow error rate average information thus obtained is composed of values based on measured flow rates obtained by repeated tests in the test flow section, but may be stored as averaged flow error rate information corrected by values estimated by interpolation calculation in the non-test flow section. In addition, a certain ratio (for example, the + 1.5% correction command is applied to the basic flow coefficient + 1.5% of the correction flow coefficient over the entire flow interval is corrected by applying the correction flow coefficient) in all flow intervals including the test flow interval and the non-test flow interval. The corrected flow error rate average information may be stored.

On the other hand, the flow rate error rate average information is composed of error rate lookup table information corresponding to a plurality of flow rate per unit time may be stored in the error rate information storage means 40, such as ECOM-ROM or FLASH MEMORY of the microcomputer.

The flow rate information calculating means 320 reads out the flow rate error rate average information from the flow rate section per unit time corresponding to the obtained first flow rate information and calculates the accumulated flow rate information based on the second flow rate information corresponding to the read flow rate error rate average information. It plays a role.

That is, from the flow rate error rate average information (corrected value and corrected flow rate coefficient in the table of FIG. 2) as shown in the table shown in FIG. 2, the specific flow rate error rate average information in the flow rate section per unit time corresponding to the first flow rate information is obtained from the second. The new cumulative flow rate information is calculated by accumulating the existing cumulative flow rate information using the flow rate information.

Here, the first flow rate information and the second flow rate information, as described above, the first flow rate information is the number of flow signal per unit time or the number of flow signal per unit time is the basic flow coefficient (for example, flow rate value 20 per one flow signal flow rate information per unit time using ml), and the second flow rate information is flow rate information in which a flow rate error is corrected as an individual flow rate.

In the table shown in FIG. 2, 14 flow intervals of 10 l / h to 10000 l / h were shown as a total test flow interval. However, the flow rate interval per unit time is further illustrative. If the test flow interval is sufficiently increased, a large number of discrete flow intervals in a specific range can be formed to cover the flow interval per unit time, and the representative values of the flow error rate average information are uniformly used in the specific range. You can do that.

Representative values of the mean error information of the flow rate may be an intermediate value in the adjacent discontinuous flow section. For example, from 110 l / h to 120 l / h, the average flow error rate information is 19.6 and the flow error rate average information from 130 l / h to 140 l / h is 120 l / h. From 130 l / h, the average error rate of the flow error can be determined with the calibrated flow coefficient 19.7.

When representative values are used for a number of non-combustible flow sections that can cover the entire flow section per unit time, the computational speed is improved because there is no need to perform extra interpolation calculation to calculate the flow rate error correction value in the non-test flow section. Can be.

On the other hand, the flow rate information calculating means 320 calculates a flow rate error rate correction value by interpolating the read flow rate error rate average information when the flow rate section per unit time corresponding to the obtained first flow rate information is a non-test flow rate section. The calculated flow rate error rate correction value may be used as the second flow rate information.

3 is a view for explaining an interpolation calculation method used in an embodiment of a digital meter capable of correcting the measured flow rate of the present invention. As shown in FIG. 3, the interpolation calculation of the flow rate information calculating unit 320 is the mean flow error rate average information y1 in the non-test flow rate section x between the flow rate sections x1 and x2 per unit time, which is the test flow rate section. , based on y2), an unknown flow rate error correction value y can be calculated by linear interpolation.

Accordingly, the flow rate information calculating means 320 reads information on x1, x2, y1, and y2 from the error rate information storing means 40 based on the obtained first flow rate information, and thus the flow rate error rate correction value as the second flow rate information ( y) is calculated. Here, although the interpolation operation is taken as an example of linear interpolation, the interpolation operation may be performed using various interpolation functions according to the type of discrete data. When the flow rate information calculating means 320 is configured to perform the interpolation operation, the amount of data of the flow rate error rate average information stored in the error rate information storing means 40 can be reduced.

The flow rate display means 50 serves to display the accumulated flow rate information in which the second flow rate information is added. The flow rate display means 50 may be configured as a flat panel display device such as an LCD panel and may be configured to be mounted on the upper outer shell of the flow chamber. In addition, functions such as battery status display of the power supply unit 70 may be implemented in addition to the accumulated flow rate information.

In addition, the digital meter of the present embodiment may further include a communication interface unit 60 and a power supply unit 70. In particular, the communication interface 60 is connected to the meter reading terminal (not shown) outside the meter to transmit the accumulated flow rate information to the outside, and at the same time, the flow rate error rate average information to be stored in the error rate information storage means 40 from the outside. May be received.

Figure 4 is a measurement of the weighing correction process according to an embodiment of the present invention, a digital meter capable of correction of the measured flow rate of the measurement error before correction (a), the error correction value (b) and the post-correction measurement error (c) It is a graph shown. As shown in Figure 4 (a), in general, the metering error according to the flow rate section per unit time is shown in the entire flow section. The flow rate section may be divided into a minimum flow section (Q ₁ ), a transition flow section (Q ₂ ), a maximum flow section (Q ₃ ) and an overload flow section (Q ₄ ), which is used as a reference for the flow rate correction. The interval is the maximum flow interval (Q ₃ ) and the flow error is generally larger in other sections. And as shown in Figure 4 (b), if the flow rate error rate average information is used in all of the flow section can be removed in all the flow rate as shown in Figure 4 (c).

<Automatic Calibration System of Digital Meter>

Figure 5 is a block diagram showing the configuration of an embodiment of an automatic calibration system of the present invention digital meter. As shown in FIG. 5, the automatic calibration system of the digital meter according to the present embodiment includes a train test bench 1000, a first storage tank 2000, a second storage tank 3000, a reference flow measuring unit 4000, and a valve control unit. And a reference flow rate measuring means 4000.

According to the present embodiment, the flow rate error information can be automatically obtained by accurately grasping the flow rate errors of the plurality of digital meters 1.

Hereinafter, the configuration of the present embodiment will be described in detail with reference to FIG. 5.

Train test bench 1000 for testing the mechanical error is provided with a plurality of digital meter (1) is connected in series to the flow pipe (1100) and the inlet valve 1200 and the outlet valve (1300) at both ends of the flow pipe (1100) Is provided.

The first reservoir tank 2000 is connected to the flow pipe 1100 to one end of the train test bench 1000 and serves to supply fluid. The volume of the reservoir tank should be ensured so that the target test flow rate can be determined and stored.

In addition, the second reservoir tank 3000 is connected to the other end of the train test bench 1000 to the flow pipe 1100 to store the fluid flowing out of the flow pipe 1100 and the discharge valve 3100 for the discharge of the stored fluid is It is provided.

In addition, the reference flow rate measuring means 4000 is mounted to the second reservoir tank serves to measure the reference flow rate based on the weight or the water level of the fluid. The reference flow rate measuring means 4000 may be provided as an electronic balance or a water level sensor to measure an accurate instantaneous flow rate through opening and closing of the inlet valve 1200 and the outlet valve 1300.

The valve control unit 5000 serves to control the opening and closing of the inlet valve 1200, the outlet valve 1300, and the discharge valve 3100 based on the reference flow rate and the predetermined instantaneous flow rate to pass through the flow path tube 1100. In particular, the valve control unit 5000 controls the test flow rate to vary the inlet valve 1200 and the outlet valve 1300 based on the reference flow rate information received by the reference flow rate measuring means 4000 to reach the instantaneous flow rate.

That is, when the test flow rate and the instantaneous flow rate are input and set through the following control device 8000, the inlet valve is variable and repeatedly adjusted through the valve control unit 5000 to receive the instantaneous flow rate data and reach the input instantaneous flow rate. . Then, when the input instantaneous flow rate is adjusted, the opening and closing control of the inlet valve 1200 is fixed at the position, and the outlet valve 1300 is locked and the discharge valve 3100 is locked. The intake valve 3100 receives information on the reference flow rate from the electronic balance or the like and after confirming that all of the fluids have been emptied.

The terminal box 6000 is connected to a communication line of each digital meter 1 and is connected by giving an ID (identification mark) to each digital meter 1. Through this, the flow rate information measured by each digital meter 1 can be classified and received.

The flow rate error calculation unit 7000 is connected to the terminal box 6000 and calculates flow rate error information based on the measured flow rate information received from each digital meter 1, the measured reference flow rate, and the set instantaneous flow rate. The calculated flow error information is again inputted to the corresponding digital meter 1 distinguished by ID through the control device 8000, so that the flow rate correction of the digital meter may be performed. That is, when the error of weighing by each ID of the digital meter 1 obtained in the test is positive, the negative value of the error rate is added, and when the error rate is negative, the positive value of the error rate is added to obtain a result of "0". Modify and transmit to the digital meter (1) of the corresponding ID.

Precise calibration at the first test flow rate and instantaneous flow rate is already completed. If additional correction is made according to the calibration result, the more accurate flow error can be corrected by repeating the same procedure.

Here, the valve control unit 5000 and the flow rate error calculation unit 7000 may be integrated into one control device, and may be configured as a PC including a central processing unit and a memory device.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood that the invention may be practiced. Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all aspects. In addition, the scope of the present invention is indicated by the appended claims rather than the detailed description above. Also, all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

1: digital meter
10: flow chamber
20: flow rate sensing means
30:
40: error rate information storage means
50: flow rate display means
60: communication interface unit
70: power supply
310: flow information acquisition means
320: flow information calculation means
1000: train test bench
1100: Euro tube
1200: inlet valve
1300: outlet valve
2000: first reservoir tank
3000: second reservoir tank
3100: discharge valve
4000: reference flow measurement means
5000: valve control unit
6000: terminal box
7000: flow error calculation means
8000: controller

Claims (8)

In the digital meter for measuring the flow rate,
A flow rate sensing means for sensing the rotational speed of the vane based on the flow rate of the flow rate;
Flow information obtaining means for obtaining first flow information based on the detected number of revolutions of the van;
Error rate information storage means for storing average flow rate error rate information, which is an average value of flow rate error information per unit time period;
Flow rate information calculating means for reading the flow rate error rate average information in the unit flow rate section corresponding to the obtained first flow rate information and calculating cumulative flow rate information based on second flow rate information corresponding to the read flow rate error rate average information; ; And
And flow rate display means for displaying the calculated accumulated flow rate information.
The first flow rate information is obtained as flow rate information per unit time or sensor signal number information per unit time,
The flow rate error information is the difference value information between the measured flow rate and the actual flow rate obtained by testing in any one flow rate section selected from the flow rate section per unit time, and
The flow rate error rate average information is a digital meter capable of correction of the measured flow rate, characterized in that the average value of the flow rate error information obtained by repeatedly testing in the flow rate section per unit time. The method of claim 1,
The flow rate sensing means is a digital meter capable of correction of the measured flow rate, characterized in that any one of MR sensor, Hall sensor, inductor sensor and optical sensor. delete The method of claim 1,
The flow rate error rate average information is a digital meter capable of correction of the measured flow rate, characterized in that the error rate lookup table information according to the flow rate section per unit time. delete The method of claim 1,
The flow rate information calculation means,
When the flow rate section per unit time corresponding to the obtained first flow rate information is a non-test flow rate section, the second flow rate information is calculated by interpolating the read flow rate error rate average information to calculate a flow rate error rate correction value. Digital meter which can correct measurement flow rate to be. The method of claim 1,
The flow rate error rate average information is a digital meter capable of correction of the measured flow rate, characterized in that the flow rate error rate average information corrected at a constant rate in all flow intervals including the test flow rate section and the non-test flow rate section. A train test bench 1000 having a plurality of digital meters connected in series to the flow pipe and having inlet and outlet valves at both ends of the flow pipe;
A first water storage tank 2000 connected to one end of the train test bench to supply fluid;
A second water storage tank (3000) connected to the other end of the train test bench and configured to store the fluid flowing out of the flow path pipe and to discharge the stored fluid;
Reference flow rate measuring means (4000) mounted to the second reservoir tank to measure a reference flow rate based on the weight or the water level of the fluid;
A valve control unit 5000 for controlling the opening and closing of the inlet valve, the outlet valve and the discharge valve based on the reference flow rate and a predetermined instantaneous flow rate to pass through the flow path pipe;
A terminal box 6000 connected to a communication line of each digital meter and connected to each digital meter by giving an ID to each digital meter; And
And a flow rate error calculating means (7000) connected to the terminal box and calculating flow rate error information based on the measured flow rate information received from the digital meter, the measured reference flow rate, and the set instantaneous flow rate.
The digital meter, flow rate sensing means for detecting the number of revolutions of the blade based on the flow of the flow rate; Flow information obtaining means for obtaining first flow information based on the detected number of revolutions of the van; Error rate information storage means for storing average flow rate error rate information, which is an average value of flow rate error information per unit time period; Flow rate information calculating means for reading the flow rate error rate average information in the unit flow rate section corresponding to the obtained first flow rate information and calculating cumulative flow rate information based on second flow rate information corresponding to the read flow rate error rate average information; ; And flow rate display means for displaying the calculated accumulated flow rate information.
The first flow rate information is obtained by the flow rate information per unit time or the number of sensor signals per unit time, the flow error information is the measured flow rate and actual obtained by testing in any one of the flow rate section selected from the flow rate section per unit time And a difference value information with a flow rate, and the flow rate error rate average information is an average value of flow rate error information obtained by repeatedly testing the selected flow rate per unit time.

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