JP4751259B2 - Flow velocity measurement method, flow measurement method, flow meter, and flow meter - Google Patents

Description

  The present invention relates to a method and a flow meter for measuring a flow rate of a fluid, and more particularly to a flow velocity measuring method, a flow measuring method, a flow velocity meter, and a flow meter suitable for use in a gas meter, a water meter, a leak alarm device, and the like. .

  A gas meter, which is one of representative flow meters that measure the flow rate of fluid, has a flow meter that measures the flow rate of gas flowing through an internal flow path as the amount of gas used. The gas flow rate is measured by a flow rate sensor that has a heat source and a temperature sensor and is driven by a battery built in the gas meter, and the measured gas flow rate is multiplied by the cross-sectional area of the flow channel. , Configured to measure the flow rate of gas.

  By the way, a flow sensor which is one of the sensors used for measuring the flow velocity of gas on the flow path described above includes, for example, a heater as a heat source and a temperature sensor on a silicon substrate disposed in the flow path through which the gas passes. The thermopile is formed on the downstream side of the heater in the gas flow direction and spaced from the heater.

  In this flow sensor, when the heater is energized to release heat, the heat is transmitted to the thermopile by the gas in the flow path, and the thermoelectromotive force of the thermopile changes, but the heat transfer rate to the thermopile flows. Since it changes according to the flow velocity of the gas flowing through the path, the thermoelectromotive force of the thermopile changes according to the flow velocity of the gas in the flow path.

  Therefore, the flow sensor is configured to output an electric signal having a level corresponding to the thermoelectromotive force of the thermopile as a signal representing the flow velocity of the gas in the flow path by using this principle.

  As a heat source, in addition to a heater that changes the amount of heat released depending on the amount of energization, heat emission and absorption are switched depending on the direction of energization, and the amount of heat released or absorbed changes depending on the amount of energization. It is also possible to use a Peltier element, and as the temperature sensor, in addition to the thermopile, Pt, Pt film, Pn junction semiconductor, permalloy, doped Si can also be used.

  By the way, the offset value which is the value when the flow velocity of the fluid flowing through the flow path of the detection signal output from the temperature sensor such as the thermoelectromotive force of the thermopile described above is zero varies with the change in the ambient temperature of the temperature sensor. Therefore, in order to accurately measure the gas flow rate, the temperature sensor offset signal is compensated by canceling the drift due to the ambient temperature change in the temperature sensor offset value. There is a need.

To compensate for the temperature drift in the detection signal of the temperature sensor described above, temperature sensors are arranged at equal intervals from the heat source on the upstream side and downstream side of the fluid flow in the flow path, and the difference between the two detection signals is taken. It is possible to carry out the measurement by converting the flow velocity of the fluid from the difference between the levers, and canceling out the temperature drifts contained in the same volume in the detection signals of both temperature sensors (for example, Patent Document 1). 2).
JP-A-4-230808 Japanese Patent Laid-Open No. 11-64061

  However, the temperature drift accompanying the temperature change of the flow path is not only the detection signal of the temperature sensor, but also, for example, a differential amplifier used to take the difference between the detection signals of both the upstream and downstream temperature sensors, It also occurs in peripheral circuits such as A / D converters that are used when taking in a control device such as a microcomputer that converts and measures the fluid flow velocity from the difference between the two detection signals obtained by the amplifier. This cannot be done by taking the difference between the detection signals of both the upstream and downstream temperature sensors.

  For this reason, in the conventional temperature drift compensation method that compensates for changes in the detection signal output from the temperature sensor depending on the flow rate and flow rate of the gas depending on the flow path temperature, the accurate gas flow rate and There was still room for improvement in measuring and measuring the flow rate.

  Such problems are not limited to the measurement of gas flow rate and flow rate in a gas meter, but include the measurement of the flow rate and flow rate of tap water with a water meter, as well as the heat source in various devices such as leak alarms. And a temperature sensor can be used in common when performing flow rate or flow rate measurement.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to measure the flow rate or flow rate of a fluid using a flow rate sensor having a heat source and a temperature sensor. Flow rate measuring method and flow rate measuring method capable of compensating for not only the temperature drift occurring in the apparatus but also the temperature drift occurring in the subsequent elements, and the preferred anemometer and flow rate used in carrying out these methods It is to provide a total.

  In order to achieve the above object, the flow velocity measuring method according to the present invention described in claim 1 is configured such that heat generated by energization of a heat source disposed on a flow path of a fluid to be measured is upstream of the flow direction of the fluid in the flow path. The upstream and downstream detection signals corresponding to the detected heat temperature are detected by the upstream and downstream temperature sensors arranged at equal intervals on the side and the downstream side, respectively. When measuring the flow velocity of the fluid flowing through the flow path based on the difference between the detection signals on the upstream side and the downstream side, output from the temperature sensors on the upstream side, the downstream detection signal from the upstream detection signal A half value of the third difference, which is a difference between the first difference obtained by subtracting the detection signal and the second difference obtained by subtracting the upstream detection signal from the downstream detection signal, is set to the upstream side and the downstream side. The difference between the detection signals of 3 based on the half of the difference, characterized by being adapted to measure the flow rate of the fluid flowing through the flow channel.

Further, the flow rate measuring method of the present invention described in claim 2 is the flow rate measuring method of the present invention according to claim 1, the flow velocity of the fluid flowing through the flow channel, off the flow of the fluid in the flow channel The measurement is performed based on the third difference corrected by the temperature signal output according to the temperature of the location from the temperature sensor for correction arranged at the location.

  Furthermore, in order to achieve the above object, the flow rate measuring method of the present invention described in claim 3 is configured so that heat generated by energization of a heat source disposed on the flow path of the fluid to be measured is flow direction of the fluid in the flow path. Detected by upstream and downstream temperature sensors arranged at equal intervals on the upstream side and downstream side, respectively, and the upstream and downstream detection signals corresponding to the detected heat temperature And measuring the flow rate of the fluid flowing through the flow path based on the difference between the detection signals on the upstream side and the downstream side. The flow rate of the fluid flowing through the flow path is measured using the flow velocity of the fluid flowing through the flow path measured by the method and the known cross-sectional area of the flow path.

  Further, in order to achieve the above object, the current meter according to the fourth aspect of the present invention, as shown in the basic configuration diagram of FIG. 1, is energized by the heat source 5 disposed on the flow path S of the fluid to be measured. The generated heat is detected by the upstream and downstream temperature sensors 7 and 9 arranged at equal intervals on the upstream and downstream sides in the flow direction of the fluid in the flow path S, respectively. The upstream and downstream detection signals corresponding to the temperature are output from the upstream and downstream temperature sensors 7 and 9, respectively, and the upstream calculation means downstream of the upstream and downstream temperature sensors 7 and 9 are operated. 25 is a flowmeter that measures the flow velocity of the fluid flowing in the flow path S based on the difference between the detection signals on the upstream side and the downstream side obtained by the calculation unit 25, wherein the calculation means 25 includes the detection signal on the upstream side and Of the downstream detection signals, the first of the switching signals. In the state, the upstream detection signal is selectively output, and in the second state of the switching signal, the first signal selection means 15 that selectively outputs the downstream detection signal, the upstream detection signal, and the downstream A second detection signal that selectively outputs the downstream detection signal in the first state of the switching signal, and a second signal that selectively outputs the upstream detection signal in the second state of the switching signal. The first subtracting means 21 which receives the signal selection means 17 and the output signals of the first and second signal selection means 15 and 17 and generates first difference data indicating the difference between these output signals. And the difference indicated by the first difference data generated by the first subtraction means 21 in the first state of the switching signal, and the first subtraction means 21 generated in the second state of the switching signal. To do Second subtracting means A for generating second difference data indicating a difference from the difference indicated by the first difference data, and the difference indicated by the second difference data generated by the second subtracting means A. The half value is defined as a difference between the detection signals on the upstream side and the downstream side, and the flow velocity of the fluid flowing through the flow path S is measured based on the half value of the difference indicated by the second difference data.

Furthermore, the flow velocity meter of the present invention according to claim 5, in the flow meter of the present invention as set forth in claim 4, is disposed at a position deviated from the flow of fluid in the flow channel S, the flow paths S It further includes a correction temperature sensor 8 that detects the temperature and outputs a temperature signal corresponding to the detected temperature of the flow path S, and has a half value indicated by the second difference data corrected by the temperature signal. Based on this, the flow velocity of the fluid flowing through the flow path S is measured.

  In order to achieve the above object, the flowmeter according to the present invention described in claim 6 is configured so that heat generated by energization of the heat source 5 disposed on the flow path S of the fluid to be measured is transferred to the fluid in the flow path S. Detected by upstream and downstream temperature sensors 7 and 9 arranged at equal intervals on the upstream and downstream sides in the flow direction of each of the upstream and downstream sides according to the detected heat temperature A detection signal is output from each of the upstream and downstream temperature sensors 7 and 9, and the upstream and downstream sides of the upstream and downstream temperature sensors 7 and 9 are obtained by the calculation means 25 subsequent to the upstream and downstream temperature sensors 7 and 9. A flowmeter for measuring a flow rate of a fluid flowing through the flow path S based on a difference between detection signals, comprising the anemometer according to claim 4 or 5, wherein the flow path S measured by the anemometer The flow rate of the flowing fluid and the known cross section of the flow path S With bets, and measuring the flow rate of the fluid flowing through the flow channel S.

  According to the flow velocity measuring method of the present invention described in claim 1, the upstream and downstream detection signals output from the upstream and downstream temperature sensors are caused by the upstream and downstream temperature sensors themselves. Temperature drift corresponding to the ambient temperature is included, and the first difference obtained by subtracting the downstream detection signal from the upstream detection signal or the upstream detection signal is subtracted from the downstream detection signal. The second difference includes a temperature drift according to the ambient temperature caused by the hardware for obtaining them.

  Among these, the temperature drift caused by the upstream and downstream temperature sensors themselves included in the upstream and downstream detection signals output from the upstream and downstream temperature sensors is the first difference. When the detection signal on the downstream side is subtracted from the detection signal on the upstream side in order to obtain the detection signal, or when the detection signal on the upstream side is subtracted from the detection signal on the downstream side in order to obtain the second difference.

  Further, the temperature drift caused by the hardware for obtaining them, which is included in each of the first difference and the second difference, obtains the difference between the first difference and the second difference in order to obtain the third difference. When they cancel each other.

  Therefore, the half value of the third difference does not include any temperature drift caused by the temperature sensor itself on the upstream side or the downstream side, nor temperature drift caused by the hardware for obtaining the first difference or the second difference. This is a pure difference between the detection signal of the upstream temperature sensor and the detection signal of the downstream temperature sensor.

  For this reason, the flow velocity of the fluid flowing through the flow path can be accurately measured using the half value of the third difference that does not include any temperature drift, which is the difference between the first difference and the second difference. .

  In addition, when the heat source changes heat generated by its resistance value, the resistance value of the heat source increases relatively if the temperature of the flow path is high, and relatively decreases if the temperature of the flow path is low. The amount of heat generated from the heat source increases as the temperature of the channel increases, and conversely decreases as the temperature of the channel decreases.

  Therefore, the higher the temperature of the flow path, the larger the amount of heat transferred from the heat source to the upstream and downstream temperature sensors via the fluid, and conversely, the lower the temperature of the flow path, The amount of heat transferred from the heat source to the upstream and downstream temperature sensors via the heat source becomes small.

  Therefore, when the heat source changes the heat generated by its resistance value, the proportional coefficient of the detection signal value of each upstream or downstream temperature sensor with respect to the flow velocity of the fluid to be measured flowing through the flow path is The height of the flow path is raised or lowered according to the height of the flow path.

In contrast, according to the flow rate measuring method of the present invention according to claim 2, at a flow rate measuring method of the present invention as set forth in claim 1, high and low proportionality factor due to the high and low temperature of the above-described flow path Measuring the flow velocity of the fluid flowing through the flow path based on the half value of the third difference obtained by correcting the fluctuation of the detection signal value of each temperature sensor by the temperature signal of the correction temperature sensor for detecting the temperature of the flow path. Therefore, even when the heat source changes the heat generated by the resistance value, the flow velocity of the fluid flowing through the flow path can be accurately measured.

  According to the flowmeter of the present invention as set forth in claim 4, the upstream and downstream detection signals output from the upstream and downstream temperature sensors 7 and 9 include the upstream and downstream temperature sensors. The temperature drifts according to the ambient temperature caused by 7 and 9 themselves are included.

  Further, the difference obtained by subtracting the downstream detection signal from the upstream detection signal indicated by the first difference data generated by the first subtraction means 21 in the first state of the switching signal, or in the second state of the switching signal The difference obtained by subtracting the upstream detection signal from the downstream detection signal indicated by the first difference data generated by the first subtraction unit 21 is attributed to the hardware configuring the first subtraction unit 21. Temperature drifts according to the ambient temperature are included.

  Of these, the temperature drifts caused by the upstream and downstream temperature sensors 7 and 9 themselves included in the upstream and downstream detection signals output from the upstream and downstream temperature sensors 7 and 9 are as follows. In order for the first subtracting means 21 to generate the first difference data, the difference obtained by subtracting the downstream detection signal from the upstream detection signal is obtained, or the upstream detection signal is obtained from the downstream detection signal. When obtaining the reduced difference, they are offset each other.

  In addition, the temperature subtraction caused by the hardware constituting the first subtraction unit 21 included in the difference indicated by the first difference data generated by the first subtraction unit 21 is the second subtraction unit A second. Are generated by the first subtracting means 21 in the first state of the switching signal and the first subtracting means 21 is generated in the second state of the switching signal. When the difference from the difference indicated by the first difference data is calculated, they are canceled out.

  Therefore, the half value of the difference indicated by the second difference data generated by the second subtracting means A obtains the temperature drift caused by the upstream and downstream temperature sensors themselves, the first difference, and the second difference. This is a pure difference between the detection signal of the upstream temperature sensor and the detection signal of the downstream temperature sensor that does not include any temperature drift component due to hardware.

  Therefore, the second subtracting means A, which is the difference between the first difference data generated by the first subtracting means 21 in the first state and the second state of the switching signal, respectively, and does not include any temperature drift component, Using the half value of the difference indicated by the generated second difference data, the flow velocity of the fluid flowing through the flow path can be accurately measured.

  When the heat source 5 changes the heat generated by its resistance value, the resistance value of the heat source 5 increases relatively when the temperature of the flow path S is high, and relative when the temperature of the flow path S is low. Therefore, the amount of heat generated from the heat source 5 increases as the temperature of the flow path S increases, and conversely decreases as the temperature of the flow path S decreases.

  Therefore, the higher the temperature of the flow path S, the greater the amount of heat transferred from the heat source 5 to the upstream and downstream temperature sensors 7 and 9 via the fluid. The lower the heat, the smaller the amount of heat transferred from the heat source 5 to the upstream and downstream temperature sensors 7, 9 via the fluid.

  Therefore, when the heat source 5 changes the heat generated by its resistance value, the detection signals of the temperature sensors 7 and 9 on the upstream side and the downstream side with respect to the flow velocity of the fluid to be measured flowing through the flow path S are detected. The proportional coefficient of the value increases or decreases according to the temperature of the flow path S.

In contrast, according to the velocity meter of the present invention as set forth in claim 5, at a flow rate meter of the present invention as set forth in claim 4, each by height proportionality factor due to the high and low temperature flow path S described above Based on the half value of the difference indicated by the second difference data obtained by correcting the fluctuation of the detection signal value of the temperature sensors 7 and 9 by the temperature signal of the correction temperature sensor 8 for detecting the temperature of the flow path S, Since the flow rate of the flowing fluid is measured, the flow rate of the fluid flowing through the flow path S can be accurately measured even when the heat source 5 changes the heat generated by the resistance value.

  According to the flow rate measuring method of the present invention described in claim 3, the flow rate measured by the flow rate measuring method of the present invention described in claim 1 or 2 is used, and the present invention described in claim 6 is also used. According to the flowmeter of the invention, the flow rate of the fluid flowing through the flow path can be accurately measured using the flow velocity measured by the flowmeter of the present invention according to claim 4 or 5.

  Hereinafter, a flowmeter that measures the flow rate of gas in the flow path by applying the flow rate measurement method according to the present invention is incorporated, and the flowmeter that measures the flow rate of gas in the flow path by applying the flow measurement method according to the present invention is implemented The form will be described with reference to the drawings.

  First, a schematic configuration of a flow sensor used in a flow meter according to an embodiment of the present invention will be described with reference to an explanatory diagram of FIG.

  A flow sensor denoted by reference numeral 1 in FIG. 2 is disposed on a flow path S of gas (corresponding to a fluid to be measured in the claims), and has a micro heater 5 (on a Si substrate 3). Corresponding to the heat source in the claims, upstream and downstream thermopiles 7, 9 (corresponding to the upstream and downstream temperature sensors in the claims), and the resistance 8 for temperature measurement (correction in the claims) Equivalent to a temperature sensor for use).

  The upstream thermopile 7 is upstream of the microheater 5 in the gas flow direction X in the flow path S, and the downstream thermopile 9 is downstream of the microheater 5 in the gas flow direction X in the flow path S. Are arranged at equal intervals from the microheater 5.

  Further, the temperature measuring resistor 8 is disposed at a position on the side of the microheater 5 that is relatively unaffected by the gas flow in the flow path S.

  In this flow sensor 1, the microheater 5 emits heat by energizing and driving the microheater 5 with a drive signal, and an electromotive force corresponding to the temperature of the heat transmitted from the microheater 5 is generated on each of the upstream side and the downstream side. The thermopile 7 and 9 is generated, and this electromotive force is configured to be output as a detection signal from the upstream and downstream thermopile 7 and 9.

  In addition, the flow sensor 1 is configured such that the resistance value of the temperature measuring resistor 8 changes depending on only the temperature of the flow path S.

  Next, a schematic configuration of the gas flowmeter according to the first embodiment of the present invention that measures the flow rate of the gas flowing through the flow path S using the flow sensor 1 described above will be described with reference to the circuit diagram of FIG. To do.

  A gas flow meter according to the first embodiment indicated by reference numeral 11 in FIG. 3 includes a flow sensor 1, a drive circuit 13 for energizing and driving the micro heater 5 and the temperature measuring resistor 8 of the flow sensor 1 with a DC voltage of a certain level. The first and second multiplexers 15 and 17 selectively output either the detection signal from the upstream thermopile 7 or the detection signal from the downstream thermopile 9 to the subsequent stage. .

  Further, in the gas flow meter 11 of the first embodiment, the difference between the detection signal output from the first multiplexer 15 being input in the positive phase and the detection signal output from the second multiplexer 17 being input in the reverse phase. The potential difference between the dynamic amplifier 21 (corresponding to the first subtracting means in the claims), the A / D converter 23 that converts the output of the differential amplifier 21 from analog to digital, and the temperature sensor resistor 8 of the flow sensor 1 ( An amplifier 22 that amplifies the voltage drop), an A / D converter 24 that converts the output of the amplifier 22 from analog to digital, and a flow rate of gas flowing through the flow path S from the analog-digital converted differential amplifier 21 and the output of the amplifier 22 Or a calculation device 25 for calculating the flow rate.

  The first multiplexer 15 (corresponding to the first signal selection means in the claims) is upstream on the high level of the switching signal from the arithmetic unit 25 (corresponding to the first state of the switching signal in the claims). The detection signal from the thermopile 7 is output to the subsequent stage, and at the low level of the switching signal (corresponding to the second state of the switching signal in the claims), the detection signal from the downstream thermopile 9 is output to the subsequent stage.

  On the other hand, the second multiplexer 17 (corresponding to the second signal selection means in the claims) receives the detection signal from the downstream thermopile 9 at the subsequent stage when the switching signal from the arithmetic unit 25 is at a high level. When the switching signal is at a low level, the detection signal from the upstream thermopile 7 is output to the subsequent stage.

  The computing device 25 (corresponding to computing means in the claims) has a microcomputer (hereinafter abbreviated as “microcomputer”) 27 and a nonvolatile memory 29, and the nonvolatile memory 29 includes: Stores data relating to a conversion formula or table for correcting a first average value and a second average value, which will be described later, calculated by the microcomputer 27 based on the output of the amplifier 22 analog-digital converted by the A / D converter 24. Yes.

  Further, in the nonvolatile memory 29, the microcomputer 27 calculates the first average value after correction and the second average value after correction by the output of the amplifier 22 that has been analog-digital converted by the A / D converter 24. Data for a conversion formula or table at a predetermined standard temperature for converting a corrected third average value to a flow velocity of the gas flowing through the flow path S, or the flow rate of the converted gas from the flow velocity of the converted gas. The data of the cross-sectional area of the flow path S and the like necessary for calculating the flow rate of the gas flowing through the channel S are stored.

  The microcomputer 27 converts the switching signal whose signal level periodically changes between a high level and a low level according to a program stored in an internal ROM (not shown) to the first and second multiplexers. 15 and 17 and the processing shown in the flowchart of FIG.

  When the program is started by connection to the power source, sampling of the output of the differential amplifier 21 (corresponding to the first difference in the claims) that is analog-digital converted by the A / D converter 23 during the high level of the switching signal, The sampling of the output (corresponding to the second difference in the claims) of the differential amplifier 21 analog-digital converted by the A / D converter 23 during the low level of the next switching signal is alternately performed a plurality of times. Repeatedly (step S1).

  Subsequently, a first average value that is an average value of a plurality of outputs of the differential amplifier 21 that are analog-to-digital converted during the high level of the switching signal, which is alternately sampled in step S1, is calculated (step S3). Similarly, a second average value, which is an average value of a plurality of outputs of the differential amplifier 21 that have been subjected to analog-digital conversion during the low level of the switching signal, which is alternately sampled in step S1, is calculated (step S1). Step S5).

  Then, the output of the amplifier 22 analog-digital converted by the A / D converter 24 is sampled (step S7), and the conversion formula or table stored in the nonvolatile memory 29 is referred to from the sampled output of the amplifier 22. Then, the correction value of the first average value calculated in step S3 is obtained, and the correction value of the second average value calculated in step S5 is calculated (step S9).

  Further, a value obtained by subtracting the first average value after correction from the second average value after correction calculated in step S9, that is, a third average value obtained by subtracting the first average value from the second average value. A half value of the corrected value (third average value after correction), that is, a half value is calculated (step S11), and stored in the nonvolatile memory 29 from the calculated half value of the corrected third average value. The flow rate of the gas flowing through the flow path S is calculated with reference to the conversion formula or table (step S13), and the flow rate of the flow path S stored in the nonvolatile memory 29 is calculated from the calculated flow speed of the gas. After referring to the cross-sectional area data and calculating the flow rate of the gas flowing through the flow path S (step S15), the process returns to step S1.

  As is apparent from the above description, in the gas flow meter 11 of the first embodiment, step S11 in the flowchart of FIG. 4 is processing corresponding to the second subtracting means in the claims. The half value of the corrected third average value calculated in S11 corresponds to the second difference data corrected by the temperature signal in the claims.

  Next, the operation (action) of the gas flow meter 11 of the first embodiment configured as described above will be described.

  When the microheater 5 of the flow sensor 1 is energized and driven by the drive circuit 13, heat is released from the microheater 5 to the gas in the flow path S, and a detection signal corresponding to the amount of heat transmitted through the gas is generated. Are output from the upstream and downstream thermopiles 7 and 9 to the first multiplexer 15 and the second multiplexer 17, respectively.

  The first multiplexer 15 outputs a detection signal from the upstream thermopile 7 during the high level of the switching signal, and outputs a detection signal from the downstream thermopile 9 during the low level of the switching signal. On the contrary, the second multiplexer 17 outputs a detection signal from the downstream thermopile 9 during the high level of the switching signal, and detects from the upstream thermopile 7 during the low level of the switching signal. A signal is output.

  Therefore, during the high level of the switching signal, the detection signal from the upstream thermopile 7 input to the positive phase of the differential amplifier 21 and the downstream thermopile 9 input to the reverse phase of the differential amplifier 21. A signal obtained by subtracting the detection signal is amplified by a predetermined gain and output from the differential amplifier 21.

  On the contrary, during the low level of the switching signal, the upstream thermopile 7 input to the reverse phase of the differential amplifier 21 from the detection signal from the downstream thermopile 9 input to the positive phase of the differential amplifier 21. A signal obtained by subtracting the detection signal from is amplified with a predetermined gain and output from the differential amplifier 21.

  Here, when the temperature of the flow path S (ambient temperature of the flow sensor 1) is shifted from a predetermined standard temperature, the temperatures detected by the upstream and downstream thermopiles 7 and 9 are also correspondingly increased. The electromotive force in the upstream and downstream thermopiles 7 and 9 fluctuates, and the upstream and downstream detection signals output from the upstream and downstream thermopiles 7 and 9 flow through the flow path S. A temperature drift corresponding to the shift amount of the temperature of the flow path S with respect to the standard temperature occurs in each offset value that is a value when the gas flow velocity is zero.

  For this reason, the upstream and downstream detection signals input from the upstream and downstream thermopiles 7 and 9 to the first and second multiplexers 15 and 17 respectively include the upstream and downstream thermopiles 7 and 9. The temperature drift due to 9 is included.

  However, since the temperature drift included in each detection signal cancels out when the difference between the upstream detection signal and the downstream detection signal is taken in the differential amplifier 21, the amplification output from the differential amplifier 21 The subsequent signal is a pure signal that does not include any temperature drift caused by the upstream and downstream thermopiles 7 and 9 themselves.

  That is, the temperature drift caused by the upstream and downstream thermopiles 7 and 9 themselves is substantially compensated by the differential amplification of the upstream detection signal and the downstream detection signal in the differential amplifier 21.

  In this way, the amplified signal from the differential amplifier 21 in which the temperature drift due to the upstream and downstream thermopiles 7 and 9 itself is substantially compensated is digitally converted by the A / D converter 23 and the microcomputer. The first average value, which is the average value, is obtained by the microcomputer 27 from a plurality of amplified signals output during the high level of the switching signal, and the low level of the switching signal. A second average value, which is an average value, is obtained by the microcomputer 27 from the plurality of amplified signals that are output.

  By the way, in the gas flow meter 11 of the first embodiment, the resistance value of the microheater 5 of the flow sensor 1 that the drive circuit 13 is energized and driven with a DC voltage of a certain level relatively increases if the temperature of the flow path S is high. If the temperature of the flow path S is low, the temperature is relatively lowered.

  For this reason, the amount of heat released from the microheater 5 to the gas flowing through the flow path S increases as the temperature of the flow path S increases, and conversely decreases as the temperature of the flow path S decreases. The amount of heat transferred from the microheater 5 to the upstream and downstream thermopiles 7 and 9 via the gas flowing through the flow path S increases as the temperature of the flow path S increases. The lower the temperature, the smaller.

  Therefore, the amount of change in the amount of heat transferred from the microheater 5 to the upstream and downstream thermopiles 7 and 9 with the change in the flow velocity of the gas flowing through the flow path S increases as the temperature of the flow path S increases. The higher the temperature, the smaller the temperature of the flow path S, and the lower the temperature, the smaller the proportional coefficient of the detection signal values of the upstream and downstream thermopiles 7 and 9 with respect to the gas flow velocity in the flow path S. It increases or decreases according to the temperature of the flow path S.

  Therefore, in the gas flow meter 11 of the first embodiment, the first average value and the second average value obtained by the microcomputer 27 from the amplified signal from the differential amplifier 21 digitally converted by the A / D converter 23. A change in the temperature of the flow path S from the standard temperature using a conversion formula or table for correction of the nonvolatile memory 29 corresponding to the output of the amplifier 22 that has been analog-digital converted by the A / D converter 24. The variation of the proportionality coefficient between the flow velocity and the detection signal value is corrected.

  When the fluctuation of the proportional coefficient of the flow velocity-detection signal value accompanying the fluctuation of the temperature of the flow path S from the standard temperature with respect to the first average value and the second average value is corrected, the microcomputer 27 further performs correction. A corrected third average value obtained by subtracting the corrected first average value from the second average value is obtained, and after the correction, using the conversion formula or table stored in the nonvolatile memory 29, The flow velocity of the gas flowing through the flow path S is calculated from the half value of the third average value, and further, from the calculated flow velocity of the gas using the cross-sectional area data of the flow path S stored in the nonvolatile memory 29. The flow rate of the gas flowing through the flow path S is calculated.

  At this time, if the temperature of the flow path S is shifted with respect to a predetermined standard temperature, the temperature drift caused by the differential amplifier 21 and the A / D converter 23 is amplified by the microcomputer 27 after being amplified. Occurs in digital signals.

  Therefore, if the temperature of the flow path S is shifted with respect to a predetermined standard temperature, the upstream thermopile 7 input to the positive phase of the differential amplifier 21 is sampled during the high level of the switching signal. The first average value obtained by the microcomputer 27 from the amplified digital signal of the signal obtained by subtracting the detection signal from the downstream thermopile 9 input to the opposite phase of the differential amplifier 21 from the detection signal from Temperature drifts caused by the differential amplifier 21 and the A / D converter 23 are included.

  Similarly, if the temperature of the flow path S is shifted with respect to a predetermined standard temperature, the downstream thermopile input to the positive phase of the differential amplifier 21 is sampled during the low level of the switching signal. 9 is obtained by subtracting the detection signal from the upstream thermopile 7 that is input to the opposite phase of the differential amplifier 21 from the detection signal from 9, and the second average value obtained by the microcomputer 27 from the amplified digital signal. Thus, temperature drifts caused by the differential amplifier 21 and the A / D converter 23 are included.

  However, the temperature drift caused by the differential amplifier 21 and the A / D converter 23 included in each of the first average value and the second average value is a flow velocity accompanying a change in the temperature of the flow path S from the standard temperature. -When the microcomputer 27 calculates the corrected third average value by subtracting the corrected first average value from the corrected second average value obtained by correcting the variation of the proportional coefficient of the detection signal value. Since they cancel each other out, the corrected third average value and the half value of the third average value obtained by the microcomputer 27 thereafter include any temperature drift caused by the differential amplifier 21 and the A / D converter 23. Not a pure value.

  That is, the temperature drift caused by the differential amplifier 21 and the A / D converter 23 is the third average after correction obtained by subtracting the first average value after correction from the second average value after correction in the microcomputer 27. By calculating the value, it is substantially compensated.

  The third average value after correction obtained by the microcomputer 27 is obtained by subtracting the first average value after correction from the second average value after correction. Of these, the first average value that is the basis of the corrected first average value is that of the pure upstream thermopile 7 that does not include temperature drift due to the upstream or downstream thermopile 7, 9 itself. This is the average value of the amplified digital signal of the signal obtained by subtracting the detection signal of the downstream thermopile 9 from the detection signal. The second average value that is the basis of the corrected second average value is the upstream side or The average of the amplified digital signal of the signal obtained by subtracting the detection signal of the upstream thermopile 7 from the detection signal of the downstream thermopile 9 that does not include temperature drift due to the downstream thermopile 7 and 9 itself Value.

  For this reason, the corrected third average value is substantially the temperature drift caused by the upstream and downstream thermopiles 7 and 9 itself, and the temperature drift caused by the differential amplifier 21 and the A / D converter 23. Is a value twice as large as the first average value that does not contain any of them.

  Therefore, the microcomputer 27 uses the half value to calculate the flow velocity or flow rate of the gas flowing through the flow path S, which means that the temperature drift caused by the upstream and downstream thermopiles 7 and 9 itself, the differential amplifier 21 and the like The microcomputer 27 calculates the flow rate or flow rate of the gas flowing through the flow path S using the first average value or the second average value that does not include any temperature drift due to the A / D converter 23.

  According to the gas flow meter 11 of the first embodiment described above, it is the average value of the amplified digital signal of the signal obtained by subtracting the detection signal of the downstream thermopile 9 from the detection signal of the upstream thermopile 7. By obtaining a first average value or a second average value that is an average value of the amplified digital signal of a signal obtained by subtracting the detection signal of the upstream thermopile 7 from the detection signal of the downstream thermopile 9, The temperature drift caused by the upstream and downstream thermopiles 7 and 9 themselves is canceled out, and the first average value and the second average value are converted into analog / digital converted by the A / D converter 24 according to the output of the amplifier 22. Then, the differential amplifier 21 and the A / D converter 23 are obtained by subtracting the corrected first average value from the corrected second average value to obtain the corrected third average value. Due to temperature drift offset it was all configured to calculate the flow velocity or flow rate of gas flowing through the flow channel S using the half of the third average value after the correction.

  For this reason, not only the temperature drift caused by the upstream and downstream thermopiles 7 and 9 itself, but also all the temperature drift caused by the differential amplifier 21 and the A / D converter 23 are compensated, and the gas flowing through the flow path S is compensated. It is possible to accurately measure the flow rate or flow rate.

  In the gas flow meter 11 of the first embodiment described above, the flow rate using the conversion formula or table for correction of the nonvolatile memory 29 corresponding to the output of the amplifier 22 that has been analog-digital converted by the A / D converter 24 is used. In the microcomputer 27, the correction of the fluctuation of the proportional coefficient of the flow velocity-detection signal value accompanying the fluctuation of the temperature of the path S from the standard temperature is performed on the first average value and the second average value. The third average value is obtained by subtracting the first average value from the second average value, and the flow rate-detection accompanying the fluctuation of the temperature of the flow path S from the standard temperature is obtained with respect to the third average value. Correction for the variation of the proportional coefficient of the signal value may be performed to obtain a half value of the corrected third average value corresponding to the second difference data corrected by the temperature signal in the claims.

  In that case, the non-volatile memory 29 corrects a first average value and a second average value, which will be described later, calculated by the microcomputer 27 based on the output of the amplifier 22 that has been analog-digital converted by the A / D converter 24. The A / D converter 24 converts the third average value calculated by the microcomputer 27 using the first average value and the second average value calculated by the microcomputer 27 as they are instead of the data relating to the conversion formula or the table, to the analog digital signal. Data relating to a conversion formula or table for correction based on the output of the converted amplifier 22 is stored.

  Next, the schematic configuration of the gas flowmeter according to the second embodiment of the present invention that measures the flow rate of the gas flowing through the flow path S using the flow sensor 1 described above will be described with reference to the circuit diagram of FIG. To do.

  In the gas flow meter of the second embodiment indicated by reference numeral 11A in FIG. 5, the temperature of the micro heater 5 of the flow sensor 1 is higher than the temperature of the flow path S by a constant temperature instead of the drive circuit 13 of the first embodiment. The flow rate or flow rate of the gas flowing through the flow path S is calculated from the point provided with the drive circuit 13A for energization driving so as to be, and the output of the differential amplifier 21 converted from analog to digital by the A / D converter 23. The microcomputer 27A in which the program stored in the internal ROM (not shown) is changed, and the nonvolatile memory 29A in which the contents of the data stored in accordance with the program of the microcomputer 27A are changed are the microcomputer 27 in the first embodiment. An arithmetic device 25A provided instead of the nonvolatile memory 29 is provided instead of the arithmetic device 25 of the first embodiment.

  The gas flow meter 11A of the second embodiment omits the amplifier 22 and the A / D converter 24 in the gas flow meter 11 of the first embodiment, and the other points are the gas flow meter of the first embodiment. 11 is configured in the same manner.

  FIG. 6 is a circuit diagram of the drive circuit 13 of FIG. 3. In this drive circuit, the series circuit of the microheater 5 and the fixed resistor Ra, the temperature measuring resistor 8, the fixed resistor Rb, and the variable resistor Rc described above. A series circuit is connected in parallel to form a bridge circuit. One end of each of the microheater 5 and the temperature measuring resistor 8 is grounded, and one end of each of the fixed resistor Ra and the variable resistor Rc is connected to a PNP transistor Q. Are connected to the power supply V for energization driving of the microheater 5 through the collector emitter.

  Then, the connection point a between the other end of the microheater 5 and the other end of the fixed resistor Ra, the other end of the fixed resistor Rb whose one end is connected to the other end of the temperature measuring resistor 8, and the other end of the variable resistor Rc Is amplified by an operational amplifier OP and connected to the base of the transistor Q via a bias resistor Rd.

  In the drive circuit 13 configured as described above, the fixed resistance is set such that the potential difference between the connection points a and b when there is no fixed resistance Rb is zero at the standard temperature determined by the resistance value of the variable resistance Rc. The resistance value of Ra is set, and by adding a fixed resistance Rb thereon, the temperature of the microheater 5 is always higher than the temperature of the flow path S measured by the resistance 8 for temperature measurement. The microheater 5 is configured to be energized and driven so that the temperature is increased by a certain temperature difference corresponding to the voltage drop determined by the resistance value of the fixed resistor Rb.

  For details of the drive circuit 13, refer to paragraphs 0032 to 0052 of Japanese Patent Laid-Open No. 2000-314645, description in FIG.

  In the nonvolatile memory 29A of the arithmetic unit 25A, the third average value calculated by the microcomputer 27 using the first average value and the second average value is converted into the flow velocity of the gas flowing through the flow path S. Data relating to a conversion formula or table at a predetermined standard temperature, data of a cross-sectional area of the flow path S necessary for calculating the flow rate of the gas flowing through the flow path S from the converted gas flow velocity, and the like are stored. Has been.

  Next, processing performed by the microcomputer 27A according to a program stored in an internal ROM (not shown) will be described with reference to a flowchart of FIG.

  When the program is started by connection to the power source, sampling of the output of the differential amplifier 21 (corresponding to the first difference in the claims) that is analog-digital converted by the A / D converter 23 during the high level of the switching signal, The sampling of the output (corresponding to the second difference in the claims) of the differential amplifier 21 analog-digital converted by the A / D converter 23 during the low level of the next switching signal is alternately performed a plurality of times. Repeatedly (step S21).

  Subsequently, a first average value that is an average value of a plurality of outputs of the differential amplifier 21 that are analog-to-digital converted during the high level of the switching signal, which is alternately sampled in step S21, is calculated (step S23). Similarly, a second average value, which is an average value of a plurality of outputs of the differential amplifier 21 that are analog-to-digital converted during the low level of the switching signal, which is alternately sampled in step S21, is calculated ( Step S25).

  Then, a half value of the third average value obtained by subtracting the first average value calculated in step S23 from the second average value calculated in step S25, that is, a half value is calculated (step S27). From the half value of the average value, the flow rate of the gas flowing through the flow path S is calculated with reference to the conversion formula or table stored in the nonvolatile memory 29A (step S29), and from the calculated gas flow rate, The flow rate of the gas flowing through the flow path S is calculated with reference to the cross-sectional area data of the flow path S stored in the nonvolatile memory 29A (step S31), and the process returns to step S21.

  As is apparent from the above description, in the gas flow meter 11A of the second embodiment, step S27 in the flowchart of FIG. 7 is processing corresponding to the second subtracting means in the claims. The half value of the third average value calculated in S27 corresponds to the second difference data generated by the second subtracting means in the claims.

  Next, the operation (action) of the gas flow meter 11A of the second embodiment configured as described above will be described.

  When the microheater 5 of the flow sensor 1 is energized and driven by the drive circuit 13A, heat is released from the microheater 5 to the gas in the flow path S, and a detection signal corresponding to the amount of heat transferred through the gas is generated. Are output from the upstream and downstream thermopiles 7 and 9 to the first multiplexer 15 and the second multiplexer 17, respectively.

  The first multiplexer 15 outputs a detection signal from the upstream thermopile 7 during the high level of the switching signal, and outputs a detection signal from the downstream thermopile 9 during the low level of the switching signal. On the contrary, the second multiplexer 17 outputs a detection signal from the downstream thermopile 9 during the high level of the switching signal, and detects from the upstream thermopile 7 during the low level of the switching signal. A signal is output.

  Therefore, during the high level of the switching signal, the detection signal from the upstream thermopile 7 input to the positive phase of the differential amplifier 21 and the downstream thermopile 9 input to the reverse phase of the differential amplifier 21. A signal obtained by subtracting the detection signal is amplified by a predetermined gain and output from the differential amplifier 21.

  On the contrary, during the low level of the switching signal, the upstream thermopile 7 input to the reverse phase of the differential amplifier 21 from the detection signal from the downstream thermopile 9 input to the positive phase of the differential amplifier 21. A signal obtained by subtracting the detection signal from is amplified with a predetermined gain and output from the differential amplifier 21.

  Here, the microheater 5 of the flow sensor 1 is energized and driven by the drive circuit 13A so that the temperature is always higher by a certain temperature difference than the temperature of the flow path S measured by the temperature measuring resistor 8. Therefore, the amount of heat released from the microheater 5 to the gas flowing through the flow path S is always constant regardless of the temperature of the flow path S.

  Therefore, the amount of change in the amount of heat transferred from the micro heater 5 to the upstream and downstream thermopiles 7 and 9 with the change in the flow velocity of the gas flowing through the flow path S is high or low in the temperature of the flow path S. Therefore, the proportional coefficient of the detection signal values of the upstream and downstream thermopiles 7 and 9 with respect to the gas flow velocity in the flow path S is always constant regardless of the temperature of the flow path S. ing.

  Therefore, the first average value or the second value obtained by the microcomputer 27 from the amplified signal from the differential amplifier 21 digitally converted by the A / D converter 23 performed by the gas flow meter 11 of the first embodiment. Of the temperature of the flow path S from the standard temperature using a conversion formula or table for correction of the nonvolatile memory 29 corresponding to the output of the amplifier 22 analog-digital converted by the A / D converter 24 with respect to the average value of The correction of the fluctuation of the proportionality coefficient of the flow velocity-detection signal value accompanying this is unnecessary in the gas flow meter 11A of the second embodiment.

  However, if the temperature of the flow path S (ambient temperature of the flow sensor 1) is shifted from a predetermined standard temperature, the temperatures detected by the upstream and downstream thermopiles 7 and 9 are also shifted by that amount. The upstream and downstream detection signals output from the upstream and downstream thermopiles 7 and 9 change in the electromotive force in the upstream and downstream thermopiles 7 and 9 and flow through the flow path S. A temperature drift corresponding to the amount of shift of the temperature of the flow path S with respect to the standard temperature occurs in the offset value, which is a value when the flow velocity of zero is zero.

  For this reason, the upstream and downstream detection signals input from the upstream and downstream thermopiles 7 and 9 to the first and second multiplexers 15 and 17 respectively include the upstream and downstream thermopiles 7 and 9. The temperature drift due to 9 is included.

  However, since the temperature drift included in each detection signal cancels out when the difference between the upstream detection signal and the downstream detection signal is taken in the differential amplifier 21, the amplification output from the differential amplifier 21 The subsequent signal is a pure signal that does not include any temperature drift caused by the upstream and downstream thermopiles 7 and 9 themselves.

  That is, the temperature drift caused by the upstream and downstream thermopiles 7 and 9 themselves is substantially compensated by the differential amplification of the upstream detection signal and the downstream detection signal in the differential amplifier 21.

  In this way, the amplified signal from the differential amplifier 21 in which the temperature drift due to the upstream and downstream thermopiles 7 and 9 itself is substantially compensated is digitally converted by the A / D converter 23 and the microcomputer. A first average value, which is an average value, is obtained by the microcomputer 27 from a plurality of amplified signals that are sampled by 27A and output during the high level of the switching signal, and also during the low level of the switching signal. The microcomputer 27A obtains a second average value that is an average value from the plurality of amplified signals that are output.

  Then, the microcomputer 27A further obtains a third average value obtained by subtracting the first average value from the second average value, and uses the conversion formula or table stored in the nonvolatile memory 29A to obtain the third average value. The flow velocity of the gas flowing through the flow path S is calculated from the half value of the average value, and the flow path S is calculated from the calculated flow velocity of the gas using the cross-sectional area data of the flow path S stored in the nonvolatile memory 29A. The flow rate of the gas flowing through is calculated.

  At this time, if the temperature of the flow path S is shifted with respect to a predetermined standard temperature, the temperature drift caused by the differential amplifier 21 and the A / D converter 23 is amplified after being sampled by the microcomputer 27A. Occurs in digital signals.

  Therefore, if the temperature of the flow path S is shifted with respect to a predetermined standard temperature, the upstream thermopile 7 input to the positive phase of the differential amplifier 21 is sampled during the high level of the switching signal. The first average value obtained by the microcomputer 27A from the amplified digital signal of the signal obtained by subtracting the detection signal from the downstream thermopile 9 input to the opposite phase of the differential amplifier 21 from the detection signal from Temperature drifts caused by the differential amplifier 21 and the A / D converter 23 are included.

  Similarly, if the temperature of the flow path S is shifted with respect to a predetermined standard temperature, the downstream thermopile input to the positive phase of the differential amplifier 21 is sampled during the low level of the switching signal. The second average value obtained by the microcomputer 27A from the amplified digital signal of the signal obtained by subtracting the detection signal from the upstream thermopile 7 input in the opposite phase of the differential amplifier 21 from the detection signal from Thus, temperature drifts caused by the differential amplifier 21 and the A / D converter 23 are included.

  However, the temperature drift caused by the differential amplifier 21 and the A / D converter 23 included in each of the first average value and the second average value is the first average value from the second average value to the microcomputer 27A. When the third average value obtained by subtracting is canceled out, the third average value and the half value of the third average value obtained thereafter by the microcomputer 27A are the differential amplifier 21 and the A / D converter 23. It is a pure value that does not include any temperature drift caused by.

  That is, the temperature drift caused by the differential amplifier 21 and the A / D converter 23 is substantially compensated by calculating the third average value obtained by subtracting the first average value from the second average value in the microcomputer 27A. Is done.

  The third average value obtained by the microcomputer 27A is obtained by subtracting the first average value from the second average value. As described above, the first average value is A digital signal after amplification of a signal obtained by subtracting the detection signal of the downstream thermopile 9 from the detection signal of the upstream thermopile 7 that does not include temperature drift caused by the upstream and downstream thermopiles 7 and 9 itself It is an average value of the signal, and the second average value is an upstream thermopile from a detection signal of a pure downstream thermopile 9 that does not include temperature drift caused by the upstream and downstream thermopiles 7 and 9 itself. 7 is an average value of the amplified digital signal of the signal obtained by subtracting the 7 detection signals.

  For this reason, the third average value substantially includes the temperature drift caused by the upstream and downstream thermopiles 7 and 9 itself and the temperature drift caused by the differential amplifier 21 and the A / D converter 23. That is, the value is twice the first average value that does not include any.

  Therefore, the microcomputer 27A uses the half value to calculate the flow velocity or flow rate of the gas flowing through the flow path S, which means that the temperature drift caused by the upstream and downstream thermopiles 7 and 9 itself, the differential amplifier 21 and the like The microcomputer 27 calculates the flow velocity or flow rate of the gas flowing through the flow path S using the first average value that does not include any temperature drift caused by the A / D converter 23.

  According to the gas flow meter 11 of the second embodiment described above, it is an average value of the amplified digital signal of the signal obtained by subtracting the detection signal of the downstream thermopile 9 from the detection signal of the upstream thermopile 7. By obtaining a first average value or a second average value that is an average value of the amplified digital signal of a signal obtained by subtracting the detection signal of the upstream thermopile 7 from the detection signal of the downstream thermopile 9, By canceling the temperature drift caused by the upstream and downstream thermopiles 7 and 9 themselves and subtracting the first average value from the second average value to obtain the third average value, the differential amplifier 21 and A The temperature drift caused by the / D converter 23 is all canceled out, and the flow rate or flow rate of the gas flowing through the flow path S is calculated using the half value of the third average value.

  For this reason, not only the temperature drift caused by the upstream and downstream thermopiles 7 and 9 itself, but also all the temperature drift caused by the differential amplifier 21 and the A / D converter 23 are compensated, and the gas flowing through the flow path S is compensated. It is possible to accurately measure the flow rate or flow rate.

  In each of the above-described embodiments, the case where the microheater 5 is used as a heat source has been described. However, the release and absorption of heat are switched depending on the energization direction, and the amount of heat released or absorbed varies depending on the energization amount. The present invention is also applicable when a Peltier element is used as a heat source.

  Similarly, in each of the above-described embodiments, the case where the thermopile 7 or 9 is used as the temperature sensor has been described. However, the thermoelectromotive force such as Pt, Pt film, Pn junction semiconductor, permalloy, or doped Si is used in the temperature sensor. The present invention is widely applicable not only to what occurs but also to a sensor whose resistance value varies with temperature as a temperature sensor.

  Further, in each of the above-described embodiments, the flowmeter has been described as an example. However, the present invention can be applied even to a flowmeter that obtains a flow velocity at a stage before the flow rate is obtained using the cross-sectional area of the flow path S. In addition, the present invention can be applied not only to gas flowmeters and current meters such as gas meters and leak alarms, but also to other fluid flowmeters and current meters such as water meters, for example. Needless to say.

It is a basic lineblock diagram of the current meter and flow meter concerning the present invention. It is explanatory drawing which shows schematic structure of the flow sensor used in the flowmeter of embodiment of this invention. It is a circuit diagram showing a schematic structure of a gas flow meter concerning a 1st embodiment of the present invention. It is a flowchart of the process which the microcomputer of the arithmetic unit of FIG. 3 performs according to the control program stored in internal ROM. It is a circuit diagram showing a schematic structure of a gas flow meter concerning a 1st embodiment of the present invention. FIG. 6 is a circuit diagram showing a specific configuration of the drive circuit of FIG. 5. It is a flowchart of the process which the microcomputer of the arithmetic unit of FIG. 5 performs according to the control program stored in internal ROM.

Explanation of symbols

5 Heat Source 7 Upstream Temperature Sensor 8 Correction Temperature Sensor 9 Downstream Temperature Sensor 15 First Signal Selection Unit 17 Second Signal Selection Unit 21 First Subtraction Unit 25 Arithmetic Unit A Second Subtraction Unit S Flow Road

Claims (6)

The heat generated by energization of the heat source disposed on the flow path of the fluid to be measured is distributed upstream and downstream in the flow direction of the fluid in the flow path at equal intervals, respectively. The upstream and downstream detection signals detected by the temperature sensor and output according to the detected heat temperature are output from the upstream and downstream temperature sensors, respectively, and the upstream and downstream detection signals are output. In measuring the flow velocity of the fluid flowing through the flow path based on the difference of
A third difference is a first difference obtained by subtracting the downstream detection signal from the upstream detection signal and a second difference obtained by subtracting the upstream detection signal from the downstream detection signal. The half value of the difference is the difference between the detection signals on the upstream side and the downstream side, and based on the half value of the third difference, the flow velocity of the fluid flowing through the flow path is measured.
A flow rate measuring method characterized by the above.   The flow rate of the fluid flowing through the flow path is corrected by a temperature signal output in accordance with the temperature of the position from a correction temperature sensor disposed at a position deviated from the fluid flow in the flow path. The flow velocity measuring method according to claim 1, wherein the measurement is based on the difference. The heat generated by energization of the heat source disposed on the flow path of the fluid to be measured is distributed upstream and downstream in the flow direction of the fluid in the flow path at equal intervals, respectively. The upstream and downstream detection signals detected by the temperature sensor and output according to the detected heat temperature are output from the upstream and downstream temperature sensors, respectively, and the upstream and downstream detection signals are output. In measuring the flow rate of the fluid flowing through the flow path based on the difference of
The flow rate of the fluid flowing through the flow channel is measured using the flow velocity of the fluid flowing through the flow channel measured by the flow velocity measuring method according to claim 1 or 2, and the known cross-sectional area of the flow channel.
A flow rate measuring method characterized by the above. The heat generated by energization of the heat source disposed on the flow path of the fluid to be measured is distributed upstream and downstream in the flow direction of the fluid in the flow path at equal intervals, respectively. The upstream and downstream detection signals detected by the temperature sensor and output according to the detected heat temperature are output from the upstream and downstream temperature sensors, respectively, and the upstream and downstream temperature sensors are output. A flowmeter that measures the flow velocity of the fluid flowing through the flow path based on the difference between the detection signals on the upstream side and the downstream side obtained by the calculation means in the subsequent stage;
The computing means is
Among the upstream detection signal and the downstream detection signal, the upstream detection signal is selectively output in the first state of the switching signal, and the downstream detection signal is selected in the second state of the switching signal. First signal selecting means for selectively outputting;
Of the upstream detection signal and the downstream detection signal, the downstream detection signal is selectively output in the first state of the switching signal, and the upstream side in the second state of the switching signal. Second signal selection means for selectively outputting a detection signal;
First subtracting means for receiving first output signals of the first and second signal selecting means and generating first difference data indicating a difference between the two output signals;
The difference indicated by the first difference data generated by the first subtraction means in the first state of the switching signal and the first subtraction means generated by the first subtraction means in the second state of the switching signal. Second subtracting means for generating second difference data indicating a difference from the difference indicated by the difference data,
The half value of the difference indicated by the second difference data generated by the second subtracting means is set as a difference between the detection signals on the upstream side and the downstream side, and the flow is calculated based on the half value of the second difference signal. Measure the flow velocity of the fluid flowing through the path,
An anemometer characterized by that. It further includes a correction temperature sensor that is arranged at a location deviating from the fluid flow in the flow path, detects the temperature of the flow path, and outputs a temperature signal corresponding to the detected temperature of the flow path, It said temperature signal based on the half-value indicated by the corrected second difference data is, the flow rate meter according to claim 4, wherein measuring the flow rate of the fluid flowing through the flow channel. The heat generated by energization of the heat source disposed on the flow path of the fluid to be measured is distributed upstream and downstream in the flow direction of the fluid in the flow path at equal intervals, respectively. The upstream and downstream detection signals detected by the temperature sensor and output according to the detected heat temperature are output from the upstream and downstream temperature sensors, respectively, and the upstream and downstream temperature sensors are output. A flowmeter that measures the flow rate of the fluid flowing through the flow path based on the difference between the detection signals on the upstream side and the downstream side obtained by the calculation means in the subsequent stage,
The anemometer according to claim 4 or 5 ,
Using the flow velocity of the fluid flowing through the flow path measured by the anemometer and the known cross-sectional area of the flow path, the flow rate of the fluid flowing through the flow path is measured.
A flow meter characterized by that.

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