JP2004347352A - Flow sensor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flow sensor capable of making a user easily recognize a large flow value without having to increase the number of figures. <P>SOLUTION: A main body part 200 of the flow sensor comprises an indicating part 230. The indicating part 230 is provided with two indicators 231 and 232; output indicating lamps 233 and 234; a mode button 235; an anomaly alarm indicating lamp 238; and manual adjusting buttons 239 and 240. The indicator 231 indicates an integrated value, and the indicator 232 indicates a unit of integration of the integrated value indicated in the indicator 231. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a flow sensor for detecting a flow rate of a fluid.
[0002]
[Prior art]
Conventionally, various flow sensors have been used to detect the flow rate of a fluid (see Patent Document 1). For example, an ultrasonic vortex flow sensor detects a Karman vortex regularly generated downstream of a vortex generating column arranged in a flow by ultrasonic waves in a non-contact manner. The ultrasonic vortex flow sensor can detect a flow rate with high accuracy in a wide flow rate range by detecting a change in the Karman vortex using ultrasonic waves.
[0003]
[Patent Document 1]
JP-A-8-304142
[0004]
[Problems to be solved by the invention]
In a conventional flow sensor, when the integrated value of the flow rate is displayed, the displayed integrated value increases with time. In order to display a large integrated value, it is necessary to increase the number of digits on the display unit. However, when the number of digits of the display unit is increased, the size of the display unit becomes large, and the flow sensor becomes large.
[0005]
Therefore, when the integrated value of a large number of digits is displayed on the display unit with a small number, it becomes difficult for the user to read the integrated value. In addition, only the upper digit of the integrated value is displayed in a predetermined integration unit. However, in this case, it is difficult for the user to understand the integration unit of the currently displayed integrated value. Therefore, it is difficult to easily recognize the true integrated value.
[0006]
An object of the present invention is to provide a flow sensor that allows a user to easily recognize a large flow value without increasing the number of display digits.
[0007]
Means for Solving the Problems and Effects of the Invention
A flow sensor according to the present invention is a flow sensor that detects a flow rate of a fluid, a flow rate detection unit that detects a flow rate of the fluid, a first display unit that displays a flow value detected by the flow rate detection unit, And a second display unit for displaying information related to the flow value.
[0008]
In the flow rate sensor according to the present invention, the flow rate of the fluid is detected by the flow rate detecting section, the detected flow rate value is displayed on the first display section, and information related to the flow rate value is displayed on the second display section. You.
[0009]
As described above, by displaying information related to the flow rate value on the second display unit, a large flow rate value can be determined based on the information without increasing the number of digits of the flow rate value displayed on the first display unit. Can be easily recognized by the user. Thereby, the size and cost of the flow sensor can be reduced, and the usability of the flow sensor is improved.
[0010]
The second display unit may display a unit of the flow value displayed on the first display unit as information.
[0011]
In this case, the second display unit displays the unit of the flow value displayed on the first display unit, thereby increasing the flow rate without increasing the number of digits of the flow value displayed on the first display unit. It is possible for the user to easily recognize the unit of the value. Thereby, the size and cost of the flow sensor can be reduced, and the usability of the flow sensor is improved.
[0012]
The first display unit may display an integrated flow value as a flow value, and the second display unit may display a unit of the integrated flow value displayed on the first display unit as information. Here, the integrated flow value refers to a flow value integrated from a predetermined point in time.
[0013]
In this case, the first display unit displays the integrated flow value, and the second display unit displays the unit of the integrated flow value displayed on the first display unit, thereby displaying the integrated flow value on the first display unit. The user can easily recognize a unit of a large integrated flow value without increasing the number of digits of the integrated flow value. Thereby, the size and cost of the flow sensor can be reduced, and the usability of the flow sensor is improved.
[0014]
The apparatus may further include a setting unit for setting a unit of the flow rate value displayed on the first display unit.
[0015]
In this case, the unit of the flow rate value displayed on the first display unit can be set by the setting unit. Therefore, the flow rate value can be displayed on the first display unit in an arbitrary unit.
[0016]
The first display unit may switchably display the instantaneous flow value and the integrated flow value as the flow value. Here, the instantaneous flow rate value refers to a flow rate value per unit time.
[0017]
In this case, since the instantaneous flow value and the integrated flow value are switchably displayed on the first display unit, the instantaneous flow value and the integrated flow value are selectively displayed without increasing the size of the first display unit. be able to. Thereby, the size and cost of the flow sensor can be reduced, and the usability of the flow sensor is improved.
[0018]
Display switching means for switching between the instantaneous flow value and the integrated flow value displayed on the first display unit may be further provided.
[0019]
In this case, the display of the instantaneous flow value and the integrated flow value is switched by the display switching means. Thereby, the user can arbitrarily display the instantaneous flow rate value and the integrated flow rate value.
[0020]
The first display unit may display a peak flow value and a bottom flow value as flow values so as to be further switchable.
[0021]
In this case, since the peak flow value and the bottom flow value are switchably displayed on the first display unit in addition to the instantaneous flow value and the integrated flow value, the instantaneous flow value, The integrated flow value, the peak flow value, and the bottom flow value can be selectively displayed. Thus, the flow sensor can be reduced in size and cost, and the usability of the flow sensor is further improved.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a schematic diagram showing a configuration of a flow sensor according to one embodiment of the present invention.
[0023]
In FIG. 1, the flow sensor includes a detection unit (sensor head) 100 and a main unit (sensor main unit) 200. The detection unit 100 is connected to the main unit 200 by a cable. The main body 200 has a display unit 230.
[0024]
FIG. 2 is a plan view of the display unit 230 of the main body 200 of the flow sensor. The display unit 230 includes two indicators 231 and 232, output indicators 233 and 234, a mode button 235, set value indicators 236 and 237, an abnormality alert indicator 238, and manual adjustment buttons 239 and 240.
[0025]
The display 231 displays the current value of the flow rate, the integrated value, the integrated current value, the instantaneous flow rate, and the like. The display 232 displays a set value, an integration unit, and the like. Here, the current value and the instantaneous flow rate are the flow rate values detected at the present time per unit time, and the integrated value and the integrated current value are the integrated flow rate values from the measurement start time to the present.
[0026]
For example, the integrated value of the flow rate is displayed on the display 231, and the integrated unit is displayed on the display 232. Thus, the large integrated value is displayed in a small number of digits, and the user can easily recognize the integrated unit of the displayed integrated value.
[0027]
In the example of FIG. 2, the integrated value of the flow rate is displayed as “120” in three digits on the display 231, and the integrated unit is displayed as “100” on the display 232. This indicates that the least significant digit of the integrated value is “100”, and the integrated value is “12000”.
[0028]
The flow sensor according to the present embodiment has first and second outputs corresponding to the first and second channels. Also, two set values P1 and P2 can be set corresponding to the first and second channels, and further two set values (bank set values) B1 and B2 can be set. Here, the set values P1 and P2 are an instantaneous flow value or an integrated flow value serving as a reference for turning on and off the first or second output. The relationship between the set values P1 and P2 and the first and second outputs will be described later.
[0029]
The output indicators 233 and 234 indicate ON and OFF of the first and second outputs, respectively. For example, the output indicator 233 lights up when the first output is on, and the output indicator 233 goes off when the first output is off. When the second output is on, the output indicator 234 is turned on, and when the second output is off, the output indicator 234 is turned off.
[0030]
The mode button 235 is used for changing a display mode, switching between a display mode and a parameter change mode, and the like. The set value indicator 236 lights up when the set value of the first channel is displayed, and the set value indicator 237 lights up when the set value of the second channel is displayed. The abnormality warning indicator 238 lights up when an abnormality occurs. The manual adjustment buttons 239 and 240 are used for adjusting set values and the like.
[0031]
FIG. 3 is a block diagram showing the configuration of the flow sensor. As shown in FIG. 3, the flow sensor includes a detection unit 100 and a main unit 200.
[0032]
The detection unit 100 includes a transmitter 111, a receiver 112, a high-frequency signal oscillator 120, a high-frequency signal amplifier 130, a phase comparator 140, a low-frequency amplifier 150, a comparator 160, a frequency divider 170, a decoder 180, a signal level determination device 190, It has a flow indicator LU. The flow indicator LU includes light emitting units 81 to 84. The light emitting section 81 includes a red LED (light emitting diode) 81R and a green LED 81G. The light emitting units 82 to 84 each include a green LED. The transmitter 111 and the receiver 112 are composed of, for example, an ultrasonic element such as a piezoelectric element.
[0033]
The main unit 200 includes a frequency measuring device 210, a computing device 220, a display unit 230, a control output unit 250, and an analog output unit 260. The frequency measuring device 210 and the computing device 220 are constituted by, for example, a CPU (Central Processing Unit).
[0034]
The high-frequency signal oscillator 120 generates a high-frequency signal and supplies it to the transmitter 111. Thereby, the transmitter 111 transmits the ultrasonic wave. The receiver 112 receives the ultrasonic wave from the transmitter 111. In this case, the frequency of the Karman vortex generated in the fluid changes depending on the flow rate of the fluid. The propagation time of the ultrasonic wave changes in proportion to the frequency of the Karman vortex. Therefore, the flow rate can be detected by detecting a change in time during which the ultrasonic wave propagates from the transmitter 111 to the receiver 112.
[0035]
The high-frequency signal amplifier 130 amplifies the output signal of the receiver 112. The phase comparator 140 compares the phase of the high-frequency signal generated by the high-frequency signal oscillator 120 with the output signal of the high-frequency signal amplifier 130, and outputs a voltage corresponding to the phase difference. The low-frequency amplifier 150 amplifies the output voltage of the phase comparator 140.
[0036]
Comparator 160 compares the output signal of low-frequency amplifier 150 with a reference voltage, and outputs a pulse indicating the comparison result. The frequency divider 170 divides the pulse output from the comparator 160. The decoder 180 includes a shift register, and sequentially turns on the light emitting units 81 to 84 of the flow indicator LU in green by decoding the output signal of the frequency divider 170. In this case, the sequential lighting speed of the light emitting units 81 to 84 of the flow indicator LU changes according to the flow rate.
[0037]
The signal level determination device 190 determines whether the level of the output signal of the high-frequency signal amplifier 130 has dropped below a predetermined value, and turns off the red LED 81R of the light emitting unit 81 when the level of the output signal falls below the predetermined value. At the same time, the lighting of the light emitting units 81 to 84 is prohibited by the decoder 180, and an alarm signal is given to the arithmetic unit 220. As a result, the computing unit 220 can recognize that the reception level has dropped.
[0038]
If the water flowing conduit through which the fluid flows is not filled with the fluid or if there are bubbles in the fluid, the reception level of the receiver 112 decreases, and an accurate flow rate value cannot be detected. In this case, the signal level determination device 190 outputs an alarm signal.
[0039]
Here, when an alarm signal is provided from the signal level determination device 190 to the arithmetic unit 220, the arithmetic unit 220 controls the display unit 230, the control output unit 240, and the analog output unit 260 based on the provided alarm signal. I do.
[0040]
When the given alarm signal is on (for example, at a high level), the arithmetic unit 220 causes the display unit 230 to display an alarm and performs processing using a digital filter. For example, when the alarm signal is on, the arithmetic unit 220 displays the flow value before the alarm signal is turned on on the display unit 230 for a predetermined number of times, or performs a moving average of the flow number for a predetermined number of times. Is calculated and displayed on the display unit 230. Further, when the alarm signal is on, the control output unit 240 turns the first and second outputs on or off using a flow value before the alarm signal is turned on for a preset number of times, or The first and second outputs are turned on or off based on a moving average of the flow number of the set number of times. Further, the analog output section 260 outputs an analog alarm signal.
[0041]
As described above, when the alarm signal is on, the arithmetic unit 220 performs a process based on a flow value close to an accurate flow value by performing a process different from that when the alarm signal is off (for example, low level). Thus, it is possible to prevent a process based on an erroneous flow rate value from being performed when the alarm signal is on, without reducing the response speed when the alarm signal is off (normal).
[0042]
The frequency measuring device 210 measures the frequency of the pulse output from the comparator 160. The calculator 220 converts the frequency measured by the frequency measuring device 210 into a flow rate, and controls the display section 230, the control output section 250, and the analog output section 260 based on the flow rate value. The operation of the display unit 230 will be described later.
[0043]
The control output unit 250 turns on and off the first and second outputs based on the flow value. Analog output section 260 outputs an analog signal indicating a flow value.
[0044]
The flow sensor according to the present embodiment has four detection modes, ie, F-1 mode (upper / lower limit mode), F-2 (window mode), F-3 (integration detection mode), and F-4 (bank setting mode). Having. The detection mode will be described later.
[0045]
Next, transition of the display state of the displays 231 and 232 will be described. 4 to 12 show the transition of the display state of the indicators 231 and 232 in FIG. Each detection mode has a display mode and a parameter change mode. In the display mode, a current value, a set value, and the like are displayed. In the parameter change mode, the setting of the function is changed.
[0046]
4 to 12, an arrow marked “MODE” indicates a transition by the mode button 235 in FIG. 2, an arrow marked with time indicates a transition due to the passage of time, and two triangle marks and an arrow indicate , Manual transition buttons 239, 240. An ellipse indicates blinking of the display.
[0047]
FIG. 4 is a diagram showing display state transitions in the display modes of the F-1 mode and the F-2 mode. FIGS. 5 and 6 are diagrams showing display state transitions in the parameter change mode of the F-1 mode and the F-2 mode.
[0048]
As shown in FIG. 4, in the display mode of the F-1 mode or the F-2 mode, every time the mode button 235 is pressed, the display of the current value and the set value, the display of the peak hold value and the bottom hold value, and the integration value are performed. The display is switched in the order of display of the integration unit and the display of the current value and the set value. By pressing the mode button 235 and the manual adjustment buttons 239 and 240 in displaying the current value and the set value, the display of the current value and the set value P1 and the display of the current value and the set value P2 can be switched.
[0049]
In the display of the current value and the set value, the set value can be adjusted by operating the manual adjustment buttons 239 and 240. The display of the hold "HOLD" and the display of the peak hold value and the bottom hold value are automatically switched. In this case, the display time is 0.3 seconds and 1 second, and the switching time is 0.1 seconds. The display is switched to the display of the current value and the set value by operating the manual adjustment buttons 239 and 240. In the display of the peak hold value and the bottom hold value, the peak hold value and the bottom hold value can be reset by long-pressing the manual adjustment buttons 239 and 240. In the display of the integrated value and the integrated unit, the integrated value can be reset by long-pressing the manual adjustment buttons 239 and 240.
[0050]
Further, the key can be locked by pressing the mode button 235 and the manual adjustment buttons 239 and 240 for 3 seconds.
[0051]
Next, as shown in FIG. 5, by pressing the mode button 235 for 3 seconds, the mode shifts to the parameter change mode detection mode. In the detection mode, the F-1 mode, the F-2 mode, the F-3 mode, and the F-4 mode can be switched by operating the manual adjustment buttons 239 and 240.
[0052]
By pressing the mode button 235 in the detection mode, the mode shifts to the output mode. In the output mode, the output mode can be switched to “noo”, “noC”, “nCo” and “nCC” by operating the manual adjustment buttons 239 and 240. In “noo”, the first output is normally open and the second output is normally open. In "noC", the first output is normally open and the second output is normally closed. In “nCo”, the first output is normally closed, and the second output is normally open. In “nCC”, the first output is normally closed, and the second output is normally closed.
[0053]
Here, normally open means that the output is turned on when the current value is higher than the set value, and normally closed means that the output is turned on when the current value is lower than the set value.
[0054]
When the mode button 235 is pressed in the output mode, the mode is shifted to the integration unit setting, and the integration unit can be set by operating the manual adjustment buttons 239 and 240.
[0055]
By pressing the mode button 235 in the integration unit setting, the mode shifts to the analog scale upper / lower limit setting, and the analog scale upper / lower limit setting can be turned on or off by operating the manual adjustment buttons 239 and 240. When the analog scale upper / lower limit setting is turned on, the upper / lower limit setting of the analog signal indicating the flow value output from the analog output unit 260 is enabled. When the analog scale upper / lower limit setting is turned off, the analog output section 260 outputs an analog signal indicating a flow value at full scale. When the analog scale upper / lower limit setting is on, the mode button 235 is pressed to shift to the analog scale lower limit setting. By further pressing the mode button 235, it is possible to shift to the analog scale upper limit setting. By setting the upper and lower limit values of the analog scale, it is possible to set the upper and lower flow rate values of the analog signal in units of 10% of the full scale.
[0056]
As shown in FIG. 6, by pressing the mode button 235 in the analog scale upper / lower limit setting or the analog scale lower limit setting, the mode shifts to the response speed (chattering prevention) setting, and the response time is set by operating the manual adjustment buttons 239 and 240. can do.
[0057]
By pressing the mode button 235 in response speed (chattering prevention) setting, the mode shifts to hysteresis setting, and the hysteresis can be set by operating the manual adjustment buttons 239 and 240.
[0058]
By pressing the mode button 235 in the hysteresis setting, the mode shifts to the eco mode, and the on / off of the eco mode (power saving mode) can be set by operating the manual adjustment buttons 239 and 240. In the eco mode, the indicators 231 and 232 only blink. That is, the indicators 231 and 232 only indicate that the flow sensor is operating.
[0059]
When the mode button 235 is pressed in the eco mode, the mode shifts to the abnormality alarm output, and the operation of the manual adjustment buttons 239 and 240 can be set to turn on or off the abnormality alarm output. When the abnormality alarm output is on, the control output unit 250 outputs an alarm signal from the external output line when the fluid to be measured is exhausted or when the fluid contains bubbles.
[0060]
FIG. 7 is a diagram showing a display state transition in the display mode of the F-3 mode. FIGS. 8 and 9 are diagrams showing the display state transition in the parameter change mode of the F-3 mode.
[0061]
As shown in FIG. 7, in the display mode of the F-3 mode, every time the mode button 235 is pressed, the display switches between the display of the integrated current value and the set value, the instantaneous flow rate display, and the display of the integrated value and the integration unit. The display returns to the current value and set value display. By pressing the mode button 235 and the manual adjustment buttons 239 and 240 in the display of the integrated current value and the set value, the display of the integrated current value and the set value P1 and the display of the integrated current value and the set value P2 can be switched.
[0062]
In the display of the integrated current value and the set value, the set value can be adjusted by operating the manual adjustment buttons 239 and 240. In the display of the integrated value and the integrated unit, the integrated value can be reset by long-pressing the manual adjustment buttons 239 and 240.
[0063]
Next, as shown in FIG. 8, by pressing the mode button 235 for 3 seconds, the mode shifts to the detection mode of the parameter change mode. The detection mode, output style, and integration unit setting in FIG. 8 are the same as the detection mode, output style, and integration unit setting shown in FIG. The response speed setting, the eco mode, and the abnormality alarm output in FIG. 9 are the same as the response speed setting, the eco mode, and the abnormality alarm output shown in FIG.
[0064]
FIG. 10 is a diagram showing a display state transition in the display mode of the F-4 mode. FIGS. 11 and 12 are diagrams showing display state transitions in the parameter change mode of the F-4 mode.
[0065]
As shown in FIG. 10, in the display mode of the F-4 mode, every time the mode button 235 is pressed, the present value and the set value are displayed, the peak hold value and the bottom hold value are displayed, and the integrated value and the integrated unit are displayed. And the display returns to the display of the current value and the set value. By pressing the mode button 235 and the manual adjustment buttons 239 and 240 in displaying the current value and the set value, the display of the current value and the set value P1 and the display of the current value and the set value P2 can be switched. Further, when the mode button 235 and the manual adjustment buttons 239 and 240 are pressed, the set value indicators 236 and 237 blink, indicating that the respective bank set values are displayed.
[0066]
The display of the peak hold value and the bottom hold value and the display of the integrated value and the integration unit in FIG. 10 are the same as the display of the peak hold value and the bottom hold value and the display of the integrated value and the integration unit in FIG.
[0067]
Next, as shown in FIG. 11, when the mode button 235 is pressed for 3 seconds, the mode shifts to the parameter change mode detection mode. The detection mode, output mode, and integration unit setting in FIG. 11 are the same as the detection mode, output mode, and integration unit setting illustrated in FIG. The response speed setting, hysteresis setting and eco mode in FIG. 12 are the same as the response speed setting, hysteresis setting and eco mode shown in FIG.
[0068]
Next, the states of the first and second outputs in the detection mode will be described.
FIG. 13 is a diagram showing the state of the first and second outputs in the F-1 mode. As shown in FIG. 13, the first output is turned on when the current value reaches a value higher by the hysteresis HyS than the set value P1, and is turned off when the current value falls to the set value P1. The second output is turned on when the current value reaches the set value P2, and is turned off when the current value falls to a value lower by hysteresis HyS than the set value P2.
[0069]
FIG. 14 is a diagram showing the state of the first and second outputs in the F-2 mode. As shown in FIG. 14, the first output is turned on when the current value reaches a value higher by the hysteresis HyS than the set value P1, turned off when the flow rate value reaches the set value P2, and turned off when the current value becomes the set value P2. When the current value reaches a set value P1, it turns on when the current value reaches a set value P1. The second output generates one pulse for each integrated flow rate unit. That is, the second output is inverted every 0.5 integrated flow units.
[0070]
FIG. 15 is a diagram showing states of the first and second outputs in the F-3 mode. As shown in FIG. 15, the first output is turned on when the integrated value reaches the set value P1, and turned off by the pulse of the external input signal. The second output is turned on when the integrated value reaches the set value P2, and turned off by a pulse of an external input signal.
[0071]
FIG. 16 is a diagram showing the state of the first and second outputs in the F-4 mode. As shown in FIG. 16A, when the external input signal is off, the first output is turned on when the current value reaches a value higher by the hysteresis HyS than the set value P1, and the first value is changed to the set value P1. It turns off when it drops to. The second output is turned on when the current value reaches the set value P2, and is turned off when the current value falls to a value lower by hysteresis HyS than the set value P2.
[0072]
As shown in FIG. 16B, when the external input signal is on, the first output is turned on when the current value reaches a value that is higher than the bank set value B1 by the hysteresis HyS, and the first value is turned on. When it drops to B1, it turns off. The second output is turned on when the current value reaches the set value B2, and is turned off when the current value falls to a value lower by hysteresis HyS than the set value B2.
[0073]
In the flow rate sensor according to the present embodiment, the display 231 displays the integrated value of the flow rate, and the display 232 displays the integration unit of the integrated value displayed on the display 231. Therefore, the number of display digits is increased. Without displaying a large integrated value, the user can easily recognize the unit of integration of the displayed integrated value. As a result, it is possible to provide a flow sensor that can be reduced in size and has good visibility at low cost.
[0074]
By operating the mode button 235 and the manual adjustment buttons 239 and 240, the integration unit can be set arbitrarily and easily. Therefore, the usability of the user is improved.
[0075]
In the above embodiment, the integration unit is set by the mode button 235 and the manual adjustment buttons 239 and 240. However, the integration unit may be set by an external signal.
[0076]
In the present embodiment, the detection unit 100 corresponds to a flow rate detection unit, the display 231 corresponds to a first display, and the display 232 corresponds to a second display. The mode button 235 and the manual adjustment buttons 239 and 240 correspond to a setting unit and a display switching unit.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing a configuration of a flow sensor according to an embodiment of the present invention.
FIG. 2 is a plan view of a display unit of a main body of the flow sensor.
FIG. 3 is a block diagram showing a configuration of a flow sensor.
FIG. 4 is a diagram showing display state transitions in display modes of F-1 mode and F-2 mode.
FIG. 5 is a diagram showing a display state transition in a parameter change mode of F-1 mode and F-2 mode.
FIG. 6 is a diagram showing a display state transition in a parameter change mode of F-1 mode and F-2 mode.
FIG. 7 is a diagram showing a display state transition in a display mode of an F-3 mode.
FIG. 8 is a diagram showing a display state transition in a parameter change mode of the F-3 mode.
FIG. 9 is a diagram showing a display state transition in a parameter change mode of the F-3 mode.
FIG. 10 is a diagram showing a display state transition in the display mode of the F-4 mode.
FIG. 11 is a diagram showing a display state transition in a parameter change mode of the F-4 mode.
FIG. 12 is a diagram showing a display state transition in a parameter change mode of an F-4 mode.
FIG. 13 is a diagram showing a state of first and second outputs in the F-1 mode.
FIG. 14 is a diagram showing a state of first and second outputs in the F-2 mode.
FIG. 15 is a diagram showing states of first and second outputs in an F-3 mode.
FIG. 16 is a diagram showing states of first and second outputs in the F-4 mode.
[Explanation of symbols]
100 detector
111 sender
112 receiver
120 high frequency signal transmitter
130 High frequency signal amplifier
140 phase comparator
150 Low frequency amplifier
160 comparator
170 divider
180 decoder
190 Signal level judgment device
LU flow indicator
200 main body
210 frequency measuring instrument
220 arithmetic unit
230 Display
250 control output section
260 Analog output section
231 and 232 display
233,234 Output indicator
235 mode button
236,237 Set value indicator
238 Abnormal alarm indicator
239,240 Manual adjustment button

Claims (7)

A flow sensor for detecting a flow rate of a fluid,
A flow rate detector for detecting a flow rate of the fluid,
A first display unit that displays a flow value detected by the flow detection unit;
A second display unit for displaying information relating to the flow value. The flow sensor according to claim 1, wherein the second display unit displays a unit of the flow value displayed on the first display unit as the information. The first display unit displays an integrated flow value as the flow value,
The flow sensor according to claim 2, wherein the second display unit displays a unit of the integrated flow value displayed on the first display unit as the information. The flow sensor according to claim 2, further comprising a setting unit configured to set a unit of a flow value displayed on the first display unit. The flow sensor according to any one of claims 2 to 4, wherein the first display unit switchesably displays an instantaneous flow value and an integrated flow value as the flow value. 6. The flow sensor according to claim 5, further comprising display switching means for switching between an instantaneous flow value and an integrated flow value displayed on the first display unit. 7. The flow sensor according to claim 5, wherein the first display unit further displays a peak flow value and a bottom flow value as the flow value so as to be switchable.

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