JPH08136323A - Flow-rate compensating device of gas meter - Google Patents

Abstract

PURPOSE: To eliminate the need for a complex mechanical compensation treatment and accurately compensate flow rate even if the operating speed of a mechanical movable part changes within one cycle when the flow rate is constant. CONSTITUTION: A circular plate 51 rotates at a rate in response to gas flow rate, pulses for one rotation of the circulate plate 51 are generated by a waveform-shaping circuit 57, and a pulse with a cycle corresponding to the flow rate is generated by a waveform-shaping circuit 59. A flow-rate compensation device measures the time of one rotation of the circular plate 51 by an operation frequency cycle measurement part 61 and calculates a compensation coefficient corresponding to the time by a compensation coefficient calculation part 63. Also, the cycle of the pulse outputted from the waveform-shaping circuit 59 is measured by a pulse cycle measurement part 64 and the compensated flow rate is calculated based on the pulse cycle measured by the pulse cycle measurement part 64 and a compensation coefficient.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flow rate correction device for a gas meter for correcting different instrumental differences depending on the flow rate.

[0002]

2. Description of the Related Art Generally, in a gas meter, if the flow rate (flow velocity) passing through the gas meter is different, the instrumental difference is different. Here, the instrumental error refers to the difference between the indicated flow rate of the reference instrument and the indicated flow rate of each gas meter, expressed as a percentage of the indicated flow rate of each gas meter. Further, in the gas meter, a measurement error due to the mechanism also occurs depending on the fluid passage amount during the test. Therefore, for gas meters, conduct a test with the flow rate (verification flow rate) and passage rate according to the maximum usable flow rate or number indicated on the gas meter, and correct the gas meter so that the instrumental error is within the verification tolerance. It is defined by the Measurement Law.

FIG. 8 is a characteristic diagram showing the test tolerance. As shown by the diagonal lines in this figure, the test tolerance is 2.5% for the flow rate of 1/20 or more and less than 1/5 of the maximum flow rate, and 1. for the flow rate of 1/5 or more and less than 4/5 of the maximum flow rate. 5
%, And 2.5% for a flow rate of 4/5 or more of the maximum flow rate.

Therefore, conventionally, the instrumental difference is measured at two points of the maximum flow rate and the verification flow rate (about 30% of the maximum flow rate), and the number of teeth and the rotation timing of the gear in the mechanical movable part that moves according to the flow rate are measured. The gas meter was manufactured by making mechanical corrections such as changing.

[0005]

However, the above-described correction method requires a step of performing a complicated mechanical correction process such as gear replacement for correcting the instrumental error on the manufacturing line, and thus the gas meter. In addition to the increase in cost, there is a risk that defective products may be generated due to incorrect operation.

Further, as a method for measuring the flow rate in a gas meter having a mechanically movable portion such as a membrane gas meter, one cycle of the operation of the mechanically movable portion is disclosed, for example, as disclosed in JP-A-5-107096. A disk that makes one rotation in conjunction with the disk is provided, and a plurality of magnets provided on the disk and a magnetoresistive element provided in the vicinity of the disk are used during one cycle of the operation of the mechanical movable part. To output multiple pulses,
There is a method of calculating the flow rate from the frequency and period of this pulse. And, in the gas meter that measures the flow rate in this way, the period of the pulse is measured, and for each period of this pulse,
It is conceivable to calculate a correction coefficient according to the flow rate and use this correction coefficient to calculate the corrected flow rate for each pulse cycle.

However, in a membrane gas meter or the like, even if the flow rate is constant, the speed of the disk interlocking with the mechanically movable portion may change during one rotation, for mechanical reasons. In such a case, even if the flow rate is constant, the pulse period changes, so that an appropriate correction coefficient according to the flow rate cannot be obtained. Therefore, there is a problem in that even if the flow rate is corrected in each pulse cycle as described above, the flow rate cannot be corrected accurately.

The present invention has been made in view of the above problems, and an object of the present invention is to eliminate the need for complicated mechanical flow rate correction processing in a gas meter having a mechanically movable portion, and when the flow rate is constant. An object of the present invention is to provide a flow rate correction device for a gas meter that enables highly accurate flow rate correction processing even when the operating speed of the mechanically movable portion changes in one cycle.

[0009]

According to a first aspect of the present invention, there is provided a gas meter flow rate correction device for correcting a measured flow rate in a gas meter having a mechanically movable portion that periodically operates at a speed according to the flow rate. The flow rate correction device of claim 1, wherein the operation cycle measuring means for measuring the time of one or a plurality of cycles of the operation of the mechanical movable part, and the correction for calculating the flow rate correction information according to the time measured by the operation cycle measuring means Information calculation means, pulse output means for outputting pulses at a plurality of positions in one cycle of the operation of the mechanically movable part, pulse cycle measurement means for measuring the cycle of the pulse output from the pulse output means, The corrected flow rate is calculated based on the pulse cycle measured by the pulse cycle measurement means and the flow rate correction information calculated by the correction information calculation means. Is obtained by a that the correction flow rate calculating means.

In this gas meter flow rate correction device, the operation cycle measuring means measures the time of one or a plurality of cycles of the operation of the mechanical movable portion, and the flow rate correction information corresponding to this time is calculated by the correction information calculating means. It Further, the pulse output means outputs pulses at a plurality of positions in one cycle of the operation of the mechanical movable portion, and the cycle of this pulse is measured by the pulse cycle measuring means.
Then, the corrected flow rate calculating means calculates the corrected flow rate based on the pulse cycle measured by the pulse cycle measuring means and the flow rate correction information calculated by the correction information calculating means.

According to a second aspect of the present invention, there is provided a flow rate correction device for a gas meter according to the first aspect, wherein the correction information calculating means has one or a plurality of cycles of operation of the mechanical movable portion and the flow rate correction information. There is a table showing the relationship with the flow rate correction information, and the flow rate correction information is calculated with reference to this table.

A gas flow rate correction device according to a third aspect of the present invention is the gas flow rate correction device according to the first or second aspect, wherein the flow rate correction information is an instrumental error.

[0013]

Embodiments of the present invention will now be described in detail with reference to the drawings. 1 to 5 relate to a first embodiment of the present invention.

FIG. 1 is a sectional view showing a schematic structure of a membrane gas meter as a gas meter including the flow rate correction device of the present embodiment. As shown in the figure, the gas meter has a case body 10, and a gas inlet portion 11 and a gas outlet portion 12 are provided on the upper portion of the case body 10. In addition, inside the case body 10, the front weighing chamber 20 and the rear weighing chamber 3 are provided.
0 is provided.

A membrane 21 is provided in the front measuring chamber 20 at the center in the front-rear direction (the left side in the drawing is the front side), and a membrane plate 22 is attached to the membrane 21. Here, the space in front of the membrane 21 in the front measuring chamber 20 is defined as a chamber, and the space in the rear is defined as a chamber. A gas inlet / outlet portion 23 that communicates with the chamber and a gas inlet / outlet portion 24 that communicates with the chamber are provided at the upper portion of the front measuring chamber 20. A blade shaft 26 is connected to the membrane plate 22 via a blade 25. Wing shaft 2
The reference numeral 6 is adapted to rotate as the membrane 21 moves in the front-rear direction. The blade shaft 26 penetrates through the front measuring chamber 20 and projects upward.

Similarly, in the rear measuring chamber 30, a film 31 is provided at the center in the front-rear direction, and a film plate 32 is provided on the film 31.
Is attached. Here, the space in front of the membrane 31 in the rear measurement chamber 30 is defined as a chamber, and the space in the rear is defined as a chamber. A gas inlet / outlet portion 33 that communicates with the chamber and a gas inlet / outlet portion 34 that communicates with the chamber are provided on the upper portion of the rear measuring chamber 30. A blade shaft 36 is connected to the film plate 32 via a blade. The blade shaft 36 is adapted to rotate as the film 31 moves in the front-rear direction. The blade shaft 36 penetrates the rear measurement chamber 30 and projects upward.

The gas outlet pipe 13 is provided between the gas inlet / outlet portions 23 and 24 and between the gas inlet / outlet portions 33 and 34, respectively.
Is provided. The gas outlet pipe 13 is connected to the gas outlet portion 12. Also, the gas inlet / outlet part 2
A valve 14 is provided on the upper side of 3, 24. The valve 14 has a state in which both the gas inlet / outlet portions 23 and 24 are closed, a state in which the gas inlet / outlet portion 23 and the gas outlet pipe 13 are in communication, and a state in which the gas inlet / outlet portion 24 and the gas outlet pipe 13 are in communication. You can choose. Similarly, the valve 15 is provided above the gas inlet / outlet portions 33 and 34.
Is provided. The valve 15 has a state in which both the gas inlet / outlet portions 33 and 34 are closed, a state in which the gas inlet / outlet portion 33 and the gas outlet pipe 13 are in communication, and a state in which the gas inlet / outlet portion 3 is connected.
4 and the gas outlet pipe 13 are communicated with each other.

An elbow 27 is connected to the upper end of the blade shaft 26, and an elbow 37 is connected to the upper end of the blade shaft 36. These elbows 27 and 37 are connected to the adjusting plate 42 by pins 41. A crank arm 44 and valve arms 45 and 46 are connected to the adjusting plate 42 via a crank pin 43. The crank arm 44 is connected to a crank shaft 47 and is configured to rotate the crank shaft 47. Also, the valve arms 45, 4
6 is connected to the valves 14 and 15, respectively, and moves the valves 14 and 15. A disc 51 (FIG. 3) described later is attached to the crankshaft 47 via a worm and a worm wheel (not shown).

An outline of the operation of the gas meter shown in FIG. 1 will be described with reference to FIG. Weighing room 20,
The introduction of gas into 30 and the discharge of gas from the measuring chambers 20 and 30 are performed by the interlocking action of the valves 14 and 15 and the membranes 21 and 31. The driving force of the movement of the membranes 21 and 31 is the pressure difference between the gas at the gas inlet 11 and the gas outlet 12. In the state shown in FIG. 2A, the valve 14 closes both the gas inlet / outlet portions 23 and 24, and the valve 15 connects the gas inlet / outlet portion 33 and the gas outlet pipe 13. In this state, the gas entering the chamber through the gas inlet / outlet portion 34 pushes the membrane 31 toward the chamber due to the pressure difference, and the gas in the chamber passes through the gas inlet / outlet portion 33, the valve 15 and the outlet pipe 13 in this order, and the gas outlet portion. It is discharged from 12. The movement of the membrane 31 is transmitted in the order of the blade shaft 36, the elbow 37, the adjusting plate 42, and the valve arms 45 and 46, and as shown in FIG. 2B, the valve 14 is moved to the gas inlet / outlet portion 24 and the gas outlet pipe. 1
The valve 15 is moved to a state where it communicates with the valve 3, and the valve 15 is moved to a state where both the gas inlet / outlet portions 33 and 34 are closed. At this time, the gas in the room is the gas inlet / outlet part 23 and the valve 1.
4, the gas passes through the outlet pipe 13 in order and is discharged from the gas outlet 12. Thereafter, similarly, the motion of returning to the state of (a) through the states of FIGS. 2 (c) and (d) is repeated. Further, the crank arm 44 and the crank shaft 47 rotate due to the above movement. Then, the rotation of the crankshaft 47 causes a disc 51 (FIG. 3) described later to rotate via a worm and a worm wheel (not shown).

FIG. 3 is a block diagram showing the circuit configuration of a gas meter including the flow rate correction device of this embodiment. In this figure, reference numeral 51 indicates a disc connected to the crankshaft 47 as described above. The disk 51 is adapted to make one rotation corresponding to one cycle of mechanical operation of the gas meter shown in FIG. One magnet 52 is attached to the disk 51 in the vicinity of the outer peripheral portion, and a plurality of, for example, five magnets 53 are attached to the position inside the magnet 52 at equal intervals along the circumferential direction. Has been. The gas meter further includes a magnetoresistive element 54 provided at a position facing the magnet 52 and a magnetoresistive element 55 provided at a position facing the magnet 53. These magnetoresistive elements 54 and 55 detect changes in the magnetic field due to the approach and separation of the magnets 52 and 53 as changes in the resistivity. The gas meter further includes an analog amplifier 56 for amplifying the output signal of the magnetoresistive element 54, a waveform shaping circuit 57 for shaping the output signal of the analog amplifier 56 to generate a pulse, and an output signal of the magnetoresistive element 55. An analog amplifier 58 for amplifying and a waveform shaping circuit 59 for shaping the output signal of the analog amplifier 58 to generate a pulse are provided.

The gas meter further measures the cycle of the pulse output from the waveform shaping circuit 57 to measure the time of one cycle of operation of the gas meter (hereinafter referred to as the operation cycle), and an operation cycle measuring section 61. A correction table 62 that stores the relationship between the operation cycle and the correction coefficient, and the correction table 62
Referring to, a correction coefficient calculation unit 63 that calculates a correction coefficient as flow rate correction information according to the operation cycle, a pulse cycle measurement unit 64 that measures the cycle of the pulse output from the waveform shaping circuit 59, and this pulse A flow rate calculation unit 65 that calculates the corrected flow rate and the integrated flow rate based on the pulse period measured by the period measurement unit 64 and the correction coefficient calculated by the correction coefficient calculation unit 63, and this flow rate calculation unit 6
And a display unit 66 that displays the integrated flow rate obtained by the method of FIG. Operation cycle measuring unit 61, correction table 6
2, the correction coefficient calculation unit 63, the pulse period measurement unit 64, and the flow rate calculation unit 65 are realized by, for example, the microcomputer 60.

The relationship between the operating cycle and the correction coefficient will be described with reference to FIG. FIG. 4 shows an example of the relationship between the flow rate before correction and the correct flow rate. This relationship can be obtained from the indicated flow rate of the gas meter before correction and the indicated flow rate of the reference device. Since the pulse cycle measured by the pulse cycle measuring unit 64 corresponds to the gas flow rate, the gas flow rate can be obtained as “k / pulse cycle” when k is a correction coefficient. However, in order to obtain the correct flow rate from the relationship shown in FIG. 4, it is necessary to change the correction coefficient k according to the gas flow rate. On the other hand, since the operation cycle measured by the operation cycle measuring unit 61 also corresponds to the gas flow rate, the correct flow rate is determined according to the operation cycle (in other words, according to the gas flow rate before correction) from the relationship shown in FIG. The correction coefficient k for obtaining can be defined. The correction table 62 stores the relationship between the operation cycle and the correction coefficient k thus obtained from the relationship shown in FIG.

Next, the operation of the flow rate correction device of this embodiment will be described with reference to the flow charts of FIGS.
The gas meter performs the operation shown in FIG. 2 at a speed corresponding to the gas flow rate, and along with this operation, the gas meter operates at a speed corresponding to the gas flow rate as shown in FIG.
The disk 51 shown in FIG. Then, as the magnet 52 provided on the disk 51 approaches and separates, the magnetoresistive element 54
The output signal of the magnetoresistive element 54 is amplified by the analog amplifier 56, and the waveform is shaped by the waveform shaping circuit 57, so that the disc 51 is rotated once, that is, every cycle of the operation of the gas meter. A pulse (hereinafter referred to as an operation cycle pulse) is generated. On the other hand, 5 provided on the disk 51
The output of the magnetoresistive element 55 changes as the two magnets 53 approach and separate, and the output signal of the magnetoresistive element 55 is amplified by the analog amplifier 58 and waveform-shaped by the waveform shaping circuit 59, depending on the flow rate. Periodic pulses are generated.

FIG. 5 is a flow chart showing the operation of calculating the correction coefficient in the flow rate correction device. In this operation, the flow rate correction device first determines whether or not an operation cycle pulse has been input to the operation cycle measurement unit 61 (step S10).
1). If no operation cycle pulse is input (N),
Move to other processing (return). If the operation cycle pulse is input (Y), it is determined whether or not it is the first operation cycle pulse (step S102). In the case of the first operation cycle pulse (Y), the operation cycle measurement unit 61 starts measuring the operation cycle (step S103) and shifts to other processing. If it is not the first operation cycle pulse (N), the operation cycle measuring unit 61 measures the operation cycle, which is the time from the previous operation cycle pulse input to the current operation cycle pulse input (step S104). Next, the correction coefficient calculation unit 63 calculates the correction coefficient k from this operation cycle by referring to the correction table 62 (step S105). Then, the correction coefficient k output to the flow rate calculation unit 65 is updated (step S106), and the process proceeds to another process. Since the correction coefficient according to the operation cycle is not calculated until the operation cycle pulse is input twice, the correction coefficient calculation unit 63, until then, sets a predetermined initial value as the correction coefficient to the flow rate calculation unit 65. Output.

FIG. 6 is a flow chart showing the operation of calculating the corrected flow rate in the flow rate correction device. In this operation, the flow rate correction device causes the pulse period measuring unit 64 to
The period of the pulse output from the waveform shaping circuit 59 is measured (step S201), and then the flow rate calculation unit 65 calculates the pulse period measured by the pulse period measurement unit 64 and the correction coefficient calculation unit 63. The corrected flow rate is calculated based on the correction coefficient k (step S20).
2). Then, the integrated flow rate obtained by integrating the corrected flow rates is displayed on the display unit 66.

As described above, according to the present embodiment, the operation cycle which is the time of one cycle of the mechanical operation of the gas meter is measured, the correction coefficient corresponding to this operation cycle is calculated, and the operation of the gas meter is performed. Since the cycle of the pulse output at a plurality of positions in one cycle of is measured, and the corrected flow rate is calculated based on the cycle of this pulse and the correction coefficient, the instrumental error on the manufacturing line is The process of performing complicated mechanical correction processing such as gear replacement to correct the gas is not required, and the cost of the gas meter can be reduced, and defective products due to erroneous operation can be prevented. Will be easier.

Further, in this embodiment, the operation cycle is measured for each operation cycle of the gas meter, the correction coefficient corresponding to the operation cycle is calculated, and the correction coefficient is calculated during the next operation cycle. Is used to calculate the corrected flow rate for each pulse period. Therefore, even if the flow rate is constant, even if the pulse period changes during one cycle of operation for mechanical reasons, it is possible to calculate an appropriate correction coefficient according to the flow rate, and during one cycle of operation. The flow rate can be accurately corrected without changing the correction coefficient.

Further, in this embodiment, since the correction coefficient is calculated by referring to the correction table 62, it is easy to obtain any relationship between the uncorrected flow rate and the correct flow rate as shown in FIG. The flow rate can be corrected, and more accurate correction can be performed as compared with mechanical correction.

Next, a second embodiment of the present invention will be described. In this embodiment, the instrumental error is used as the correction coefficient. Therefore, in this embodiment, the correction table 62 in FIG. 3 stores the relationship between the operation cycle measured by the operation cycle measurement unit 61 and the instrumental error.

Here, the relationship between the operation cycle and the instrumental error will be described with reference to FIG. FIG. 7 shows an example of the relationship between the flow rate before correction and the instrumental error. This relationship can be obtained from the indicated flow rate of the gas meter before correction and the indicated flow rate of the reference device. As described above, since the operation cycle corresponds to the gas flow rate, the instrumental error can be determined according to the operation cycle from the relationship shown in FIG. The correction table 62 stores the relationship between the operation cycle and the instrumental error thus obtained from the relationship shown in FIG.

The correction coefficient calculation unit 63 includes a correction table 62.
With reference to, the instrumental error corresponding to the operation cycle measured by the operation cycle measuring unit 61 is calculated and output to the flow rate calculation unit 65. The flow rate calculation unit 65 calculates the corrected flow rate based on the pulse period and the instrumental error measured by the pulse period measurement unit 64. When the period measured by the pulse period measuring unit 64 is T and the instrumental error calculated by the correction coefficient calculating unit 63 is E, the corrected flow rate Y is calculated by the following equation. However, k ₀ is a predetermined coefficient.

[0032]

[Number 1] _{Y = (k 0 / T)} · (1-E / 100)

Other configurations, operations and effects are similar to those of the first embodiment.

The present invention is not limited to the above embodiments, and for example, in each embodiment, the correction coefficient (including the instrumental error) is obtained from the time of one cycle of the operation of the gas meter (operation cycle). It is also possible to measure the time of a plurality of operation cycles and obtain the correction coefficient from this time.

The method of calculating the correction coefficient is not limited to the method using a table. For example, a mathematical expression expressing the correction coefficient as a function of the operation cycle is stored, and the correction coefficient is calculated from the operation cycle using this mathematical expression. May be calculated.

Further, the magnets 52 and 53 and the magnetoresistive element 5
Instead of 4, 55, a magnet attached to the movable part of the gas meter and a reed switch that opens and closes depending on the approach and separation of the magnet may be used, or an optical rotary encoder or the like may be used.

Further, the flow rate correction device of the gas meter of the present invention is not limited to the film type gas meter, but can be applied to other types of gas meters having mechanically movable parts.

[0038]

As described above, according to the flow rate correction device of the gas meter of the present invention, the operation cycle measuring means allows
The time of one or a plurality of cycles of the operation of the mechanical movable portion is measured, the flow rate correction information corresponding to this time is calculated by the correction information calculation means, and at a plurality of positions in one cycle of the operation of the mechanical movable portion. The cycle of the output pulse is measured by the pulse cycle measuring means, and is corrected by the correction flow rate calculating means based on the pulse cycle measured by the pulse cycle measuring means and the flow rate correction information calculated by the correction information calculating means. Since the calculated flow rate is calculated, complicated mechanical flow rate correction processing is unnecessary, and even when the operating speed of the mechanical movable portion changes in one cycle when the flow rate is constant. There is an effect that a highly accurate flow rate correction process becomes possible.

[Brief description of drawings]

FIG. 1 is a sectional view showing a schematic configuration of a gas meter including a flow rate correction device according to a first embodiment of the present invention.

FIG. 2 is an explanatory diagram showing an outline of the operation of the gas meter shown in FIG.

FIG. 3 is a block diagram showing a circuit configuration of a gas meter including a flow rate correction device according to a first example of the present invention.

FIG. 4 is a characteristic diagram showing an example of a relationship between a flow rate before correction and a correct flow rate.

FIG. 5 is a flowchart showing an operation of calculating a correction coefficient in the flow rate correction device according to the first embodiment of the present invention.

FIG. 6 is a flowchart showing an operation of calculating a corrected flow rate in the flow rate correction device according to the first embodiment of the present invention.

FIG. 7 is a characteristic diagram showing an example of a relationship between a flow rate before correction and a device difference.

FIG. 8 is a characteristic diagram showing a test tolerance.

[Explanation of symbols]

 51 disk 52, 53 magnet 54, 55 magnetoresistive element 57, 59 waveform shaping circuit 61 operating period measuring unit 62 correction table 63 correction coefficient calculating unit 64 pulse period measuring unit 65 flow rate calculating unit

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Tsutomu Otani 6-7-9 Yurinokidai, Yachiyo-shi, Chiba (72) Inventor Takashi Ueki 1-1-11-3 Minamikyugahara, Ota-ku, Tokyo (72) Nobuo Negoro Kanagawa Prefecture 1704-2 Izumi-cho, Izumi-ku, Yokohama (72) Inventor Isao Kaneko 3-2-7-221 Takasago, Katsushika-ku, Tokyo (72) Inventor Kazuya Fujisawa 2-5-3-305 Nukii, Nerima-ku, Tokyo (72) ) Inventor Yoshio Yumida 2286-1 Kareshi, Ageo City, Saitama Prefecture (72) Inventor Kyonobu Sato 4-26-17-305 Tokumaru, Itabashi-ku, Tokyo (72) Inventor Kazuro Shimakawa 2-5 Honmachi Nishi, Yono City, Saitama Prefecture -7 (72) Inventor Mineyuki Amate 3-15-7 Asahi-cho, Funabashi City, Chiba Prefecture (72) Inventor Kaoru Maeda 2-8-16 Donobe Chuo, Kamagaya City, Chiba Prefecture (72) Noriyuki Watanabe Nagoya City, Aichi Prefecture 1-270 Millennial, Atsuta-ku Aichi clock Electric Machinery Co., Ltd. (72) Inventor Katsuhisa Hanaki 1-2-70, 1000, Atsuta-ku, Nagoya-shi, Aichi Aichi Clock Electric Co., Ltd.

Claims (3)

[Claims] 1. A gas meter having a mechanically movable part that periodically operates at a speed according to a flow rate, which is a flow rate correction device for a gas meter that corrects a measured flow rate. Operation cycle measuring means for measuring time of one or a plurality of cycles, correction information calculating means for calculating flow rate correction information according to the time measured by the operation cycle measuring means, and one cycle of operation of the mechanical movable portion. Pulse output means for outputting a pulse at a plurality of positions therein, pulse cycle measuring means for measuring the cycle of the pulse output from the pulse output means, and pulse cycle and correction information measured by the pulse cycle measuring means And a corrected flow rate calculating means for calculating the corrected flow rate based on the flow rate correction information calculated by the calculating means. Gas meter of the flow rate correction device. 2. The correction information calculation means has a table showing the relationship between the flow correction information and the time of one or a plurality of cycles of the operation of the mechanical movable portion, and the flow correction information is referred to by referring to this table. The flow rate correction device for a gas meter according to claim 1, wherein the flow rate correction device calculates. 3. The flow rate correction device for a gas meter according to claim 1, wherein the correction correction information is an instrumental error.