JP2010085302A - Flow meter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flow meter collecting trend data, having relatively low cost and a simple constitution. <P>SOLUTION: A flow meter includes a flow detecting means (flow sensor 12) for detecting a flow of a fluid to be measured flowing through a predetermined pathway, and a time-measuring means (timer 37) for measuring the time elapsed from a reference time. The flow meter, further, includes an information collecting means (CPU31, EEPROM33) for correlating and storing the information regarding the flow detected by the flow detecting means with the information regarding the elapsed time measured by the time-measuring means. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a flow meter.

  Conventionally, flow meters that detect the flow rate of a fluid to be measured (gas, liquid, etc.) have been put into practical use. For example, gas flow meters that detect the flow rate of industrial gases such as hydrogen, methane gas, and propane gas, and medical gases such as oxygen, synthetic air, and laughing gas have been proposed and put into practical use. Such a gas flow meter is equipped with a small control unit such as a microprocessor, and by accumulating the instantaneous flow rate measured using a flow sensor by the control unit, the amount of gas used (charge flow rate) to be charged. (Integrated value) is calculated (for example, refer to Patent Document 1).

By the way, even when calculating the integrated value of the flow rate using a gas flow meter, information on the instantaneous flow rate (hereinafter sometimes referred to as “trend data”) at a predetermined time is collected in order to grasp the state of gas use. It may be required to do. The conventional technology for collecting such trend data is to detect the fluid usage of multiple devices together with the date and time of use using a flow meter, and analyze the information on the detected fluid usage using a personal computer. A data processing system has been proposed (see, for example, Patent Document 2).
JP-A-6-88742 JP 2005-147721 A

  However, since the data processing system described in Patent Document 2 has a complicated device configuration, there is a problem that high cost is required to construct such a system.

  On the other hand, a method is also conceivable in which a timepiece is mounted on a flow meter as described in Patent Document 1 and time information measured by this timepiece is stored in association with an instantaneous flow rate measured by a flow rate sensor. However, since the watch is prone to failure and error (clocking error) with long-term use, and the power consumption is relatively large and relatively expensive, the watch is simply connected to the flow meter for trend data collection. Even if it is installed, there is a high possibility that problems to be improved still remain in terms of measurement accuracy and cost.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a flow meter capable of collecting trend data while having a relatively inexpensive and simple configuration.

  In order to achieve the above object, a flow meter according to the present invention includes a flow rate detection means (sensor) for detecting a flow rate of a fluid to be measured flowing through a predetermined flow path, and a time measurement means for measuring an elapsed time from an arbitrary reference time. An information collecting means (memory, processor) for storing information relating to the flow rate detected by the flow rate detecting means and information relating to the elapsed time measured by the time measuring means in association with each other. Is further provided.

  When such a configuration is adopted, information relating to the flow rate and information relating to the elapsed time can be stored in association with each other (flow rate-time information is collected). Therefore, for example, when the information collection start time (the time when information collection is started by the information collection unit) and the information collection end time (the time when information collection is completed by the information collection unit) are clear, this information collection start (end) Based on the time and the information on the stored elapsed time, the information on the time corresponding to the detected flow rate can be calculated. That is, it is possible to obtain trend data by effectively using information related to the elapsed time. As a result, since it is not necessary to mount a clock on the flow meter, there is no need to worry about a clock failure or a clock error (error), and data can be collected relatively accurately. In addition, since a timepiece is not employed, it is possible to reduce the processing load and power consumption in the control circuit of the flow meter, and further it is possible to reduce the cost of the flow meter.

  In the flow meter, an information collection start setting means for starting information collection in the information collection means, a time input means for inputting an information collection start time in the information collection means, and an information collection start time input by the time input means Based on this, it is possible to provide time setting means for converting information related to the elapsed time stored in the information collecting means into information related to the time corresponding to the flow rate and storing the information in the information collecting means. In addition, the time input means for inputting the information collection end time in the information collection means, and the information related to the elapsed time stored in the information collection means based on the information collection end time input in the time input means, the time corresponding to the flow rate Time setting means for converting the information into information and storing the information in the information collecting means.

  When such a configuration is adopted, when the information collection start (end) time is received, the information related to the elapsed time stored in the information collection means is associated with the flow rate based on the information collection start (end) time. It can convert into the information which concerns on time. As a result, the information relating to the detected flow rate and the information relating to the time can be stored in correspondence (that is, as flow rate-time information).

  In addition, the flow meter may include display means for displaying information stored by the information collecting means.

  When such a configuration is adopted, information stored in the information collecting means (information relating to the detected flow rate and information relating to the elapsed time or time corresponding thereto) can be displayed on the display means to notify the user.

  Further, in the flow meter, when displaying the information stored by the information collecting means on the display means, prior to displaying the information relating to the flow rate, the information relating to the elapsed time or the time corresponding to the information relating to the flow rate is displayed. It can also be configured to.

  If such a configuration is adopted, the correspondence between the elapsed time (or time) and the flow rate can be easily notified to the user.

  In the flow meter, a display setting unit for setting a display mode of information on the display unit may be provided. Each time the user performs a predetermined operation on the display setting unit, the information stored in the information collecting unit can be displayed on the display unit in the order of measurement of elapsed time or in the order of time.

  When such a configuration is adopted, the collected information can be displayed in order of measurement of elapsed time or time order by the user's operation.

  Further, the flow meter may be configured to automatically display the information stored in the information collecting unit on the display unit at a predetermined time interval in the order of measurement of elapsed time or the order of time.

  By adopting such a configuration, it is possible to automatically display the collected information at predetermined time intervals in the order of measuring elapsed time or in time order without any user operation.

  The flow meter may further include a communication unit that transfers information stored in the information collection unit to a device outside the flow meter.

  When such a configuration is adopted, information stored in the information collecting means (information relating to the detected flow rate and information relating to the elapsed time or time corresponding thereto) can be transferred to an external device for effective use.

  Further, an information collecting means having a non-volatile storage means for storing information collected by being detachably attached to the flow meter may be employed. In such a case, the information stored in the nonvolatile storage means can be read into an external device.

  When such a configuration is adopted, information stored in the non-volatile storage means removed from the flowmeter (information relating to the detected flow rate and information relating to the elapsed time or time corresponding thereto) is read by an external device for effective use. can do.

  In the flow meter, a flow rate detecting means for detecting an instantaneous flow rate of the fluid to be measured can be employed. In such a case, the information collecting means stores the information related to the instantaneous flow rate detected by the flow rate detection means over the predetermined detection period and the information related to the elapsed time (or time) corresponding thereto, and the instantaneous flow rate in each detection period. Additional flow rate information including at least one of a maximum value, a minimum value, an average value, and an integrated value can also be stored.

  When such a configuration is adopted, the information collecting means, in addition to the information related to the detected instantaneous flow rate and the information related to the elapsed time (or time) corresponding thereto, the maximum value, minimum value, and average of the instantaneous flow rate in each detection period Additional flow rate information such as values and integrated values can be stored together.

  In the flow meter, an information collecting unit that simultaneously stores a predetermined determination result for the additional flow rate information may be employed.

  When such a configuration is adopted, a predetermined determination (for example, whether or not the maximum value of the instantaneous flow rate exceeds a predetermined threshold value or whether the minimum value of the instantaneous flow rate is less than the predetermined threshold value) is added to the additional flow rate information. When such a determination is made, the determination result (for example, the maximum instantaneous flow rate exceeds a predetermined threshold) can be stored simultaneously.

  Moreover, in the said flow meter, when the predetermined determination result with respect to additional flow information satisfy | fills specific conditions, the information collection means which memorize | stores only the additional flow information in that case can also be employ | adopted.

  When such a configuration is adopted, when a predetermined determination result for the additional flow rate information satisfies a specific condition (for example, when the maximum value of the instantaneous flow rate exceeds the upper limit value and reaches a level to be notified to the user), in that case Only additional flow rate information (maximum instantaneous flow rate) can be stored. Therefore, the amount of information stored in the information collecting unit can be reduced, which is effective when the storage capacity of the information collecting unit is limited.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the flowmeter which can collect trend data, having a comparatively cheap and simple structure.

  Hereinafter, a flow meter according to an embodiment of the present invention will be described with reference to the drawings. The flow meter according to the present embodiment is an integrated flow meter that detects the instantaneous flow rate of a gas (measuring fluid) and calculates the amount of gas used by integrating the detected instantaneous flow rate.

  As shown in FIGS. 1 to 4, the flow meter 1 according to the present embodiment includes a flow meter body 2 that is attached to a part of a pipe P through which a gas flows to form a flow path, a flow sensor 12, and a control. The measuring unit 3 having the unit 30 and the like and connected to the flow meter body unit 2 is provided as a main configuration.

  The flow meter body portion 2 is a housing having a substantially rectangular parallelepiped shape as shown in FIGS. 2 to 4, a pipe 7 having a circular cross section through which gas flows, a throttle mechanism 8 formed in the middle of the pipe 7, Branch channels 9, 10, etc. that are formed on the upper side (the side to which the measurement unit 3 is connected) of the pipe line 7 and are located upstream and downstream with the throttle mechanism 8 interposed therebetween, and communicate the pipe line 7 with the outside. have. A pipe P is screwed and connected to the upstream side and the downstream side of the pipe line 7. The throttle mechanism 8 has an inner diameter smaller than the inner diameter of the pipe line 7 and functions to throttle the flow rate of the gas flowing from the upstream pipe P to the downstream pipe P.

  As shown in FIGS. 2 and 4, a concave portion 2 a having a substantially circular shape in plan view and having a predetermined depth is formed on the upper surface of the flow meter body portion 2. The concave portion 2 a has a bypass flow of the measuring portion 3. A path forming portion 3b (described later) is fitted. The branch flow path 9 arranged on the upstream side of the throttle mechanism 8 includes a small-diameter portion on the inner side of the body and a large-diameter portion on the outer side of the body, and bypasses the bypass flow path forming portion 3b of the measurement unit 3. The channel 3c (described later) is connected in communication. Similarly, the branch flow path 10 disposed on the downstream side of the throttle mechanism 8 includes a small-diameter portion on the inner side of the body and a large-diameter portion on the outer side of the body, and is connected to the bypass flow path 3c.

  As shown in FIGS. 1 to 4, the measuring unit 3 has a housing having a substantially rectangular parallelepiped shape, and a display unit 4 a and an operation unit are provided on the upper side of the housing (the side opposite to the flow meter body unit 2). A display operation panel 4 having a portion 4b is provided. As shown in FIG. 7, the display unit 4 a includes a 7-segment display 41 that displays various types of information in a maximum of 5 digits or letters, and a mode indicator (instantaneous flow rate mode) that indicates the mode set by the operation of the operation unit 4 b. Indicator lamp 42 and integrated flow mode indicator lamp 43). The 7-segment display 41 displays the instantaneous flow rate of the detected gas and the integrated value of the instantaneous flow rate in real time, as well as various information (information related to the elapsed time and time corresponding to the instantaneous flow rate) stored in the EEPROM 33 described later. It functions as display means in the present invention. The operation unit 4b has various keys (ENTER key 51, MODE key 52, UP key 53, DOWN key 54) for setting various information display modes (display contents and display format), and display setting means. Function as.

  A cable connecting portion 5 for connecting a power supply cable C and a signal transmission / reception cable C is provided on a side surface of the housing constituting the measurement unit 3. In addition, a plate-like portion 3a is fixed to the lower side of the casing constituting the measuring unit 3 (the side to which the flow meter body unit 2 is connected). As shown in FIGS. 2 and 4, the screw 6 is screwed into the plate-like part 3 a of the measuring part 3 and the screw holes formed in the flow meter body part 2 and overlapped with each other, whereby the measuring part 3 is fixed to the flow meter body 2.

  As shown in FIG. 4, a bypass flow path forming portion 3 b is disposed between the plate-like portion 3 a of the measuring portion 3 and the flow meter body portion 2. The bypass flow path forming portion 3b is a thin member having a substantially circular shape in a plan view so as to be fitted into the concave portion 2a of the flow meter body portion 2. On the lower surface thereof, the bypass flow passages 9, 10 are provided. A bypass flow path 3c is formed in communication with each other. A part of the gas flowing through the pipe line 7 on the upstream side of the flow meter body part 2 flows into the bypass flow path 3c of the measurement part 3 via the upstream branch flow path 9, and then the flow meter body. It is bypassed to the downstream pipe line 7 via the branch flow path 10 on the downstream side of the section 2. A packing 11 as shown in FIGS. 2 and 4 is fitted in the recess 2a of the flow meter body 2 and around the bypass flow path forming portion 3b. The airtightness of the space formed by the shape portion 3a and the concave portion 2a of the flow meter body portion 2 is ensured.

  A flow sensor 12 is provided at the center of the plate-like part 3 a fixed to the bottom surface of the measuring part 3. The flow sensor 12 detects the flow velocity or flow rate (instantaneous flow rate) of the gas flowing through the bypass flow path 3c, and corresponds to the flow rate detection means in the present invention. Various configurations can be adopted as the flow sensor 12, and in the present embodiment, a thermal flow sensor having a semiconductor diaphragm is adopted.

  That is, as shown in FIGS. 5 and 6, the flow sensor 12 is provided on the substrate 20 provided with the cavity 26, the insulating film 25 disposed on the substrate 20 so as to cover the cavity 26, and the insulating film 25. The heater 21, the upstream resistance temperature sensor 22 provided on the upstream side of the heater 21, the downstream resistance temperature sensor 23 provided on the downstream side of the heater 21, and the upstream side of the upstream resistance temperature sensor 22. And an ambient temperature sensor 24 and the like.

  The portion of the insulating film 25 covering the cavity 26 constitutes a heat insulating diaphragm. The ambient temperature sensor 24 measures the temperature of the fluid flowing into the bypass flow path 3c. The heater 21 is disposed at the center of the insulating film 25 covering the cavity 26, and the fluid flowing through the bypass flow path 3c is set to a certain temperature (for example, 10 ° C.) higher than the temperature measured by the ambient temperature sensor 24. Heat. The upstream resistance temperature sensor 22 is used to detect the temperature upstream of the heater 21, and the downstream temperature resistance element 23 is used to detect the temperature downstream of the heater 21.

  Here, when the fluid in the bypass passage 3c is stationary, the heat applied by the heater 21 is diffused symmetrically in the upstream direction and the downstream direction. Accordingly, the temperatures of the upstream resistance temperature element 22 and the downstream resistance temperature element 23 are equal, and the electrical resistances of the upstream resistance temperature element 22 and the downstream resistance temperature element 23 are equal. On the other hand, when the fluid in the bypass channel 3c flows from the upstream to the downstream, the heat applied by the heater 21 is carried in the downstream direction. Therefore, the temperature of the downstream temperature measuring resistance element 23 becomes higher than the temperature of the upstream temperature measuring resistance element 22. Therefore, a difference is generated between the electrical resistance of the upstream resistance temperature sensor 22 and the electrical resistance of the downstream resistance temperature sensor 23. The difference between the electrical resistance of the downstream resistance temperature sensor 23 and the electrical resistance of the upstream resistance temperature sensor 22 has a correlation with the speed and flow rate of the fluid in the bypass passage 3c. Therefore, the speed and flow rate of the fluid flowing through the bypass flow path 3c are calculated from the difference between the electrical resistance of the downstream temperature measurement resistance element 23 and the electrical resistance of the upstream temperature measurement resistance element 22.

As a material of the substrate 20 shown in FIGS. 5 and 6, silicon (Si) or the like can be used. As a material of the insulating film 25, silicon oxide (SiO ₂ ) or the like can be used. The cavity 26 is formed by anisotropic etching or the like. Further, platinum (Pt) or the like can be used for each material of the heater 21, the upstream resistance temperature sensor 22, the downstream resistance temperature sensor 23, and the ambient temperature sensor 24, and can be formed by lithography or the like.

  Moreover, the measurement part 3 has the control part 30 which performs integrated control of various electronic devices, as shown in FIG. The control unit 30 includes a central processing unit (hereinafter referred to as “CPU”) 31, a ROM 32 in which various control programs are written in addition to algorithms for setting operations and arithmetic processing, an EEPROM 33 as nonvolatile storage means, a measurement RAM 34 for temporarily storing the flow rate data etc., input / output interface 35 for inputting / outputting control signals etc. to / from the outside of the flow meter 1, and communication for transmitting / receiving information to / from the outside of the flow meter 1 The unit 36 has a timer 37 as time measuring means for measuring the elapsed time from an arbitrary reference time. The EEPROM 33 is detachably attached to the flow meter 1, and stores information related to the instantaneous flow rate detected by the flow sensor 12 and information related to the elapsed time measured by the timer 37. Information stored in the EEPROM 33 is read by an external device.

The CPU 31 reads various control programs in the ROM 32 and performs various information processing and device control. Specifically, in response to the operation of the operation unit 4b by the user, the CPU 31 starts collecting information on the instantaneous gas flow rate and information on the elapsed time (hereinafter referred to as “flow rate-time information”). For example, when the user presses the ENTER key 51 in a state where the flow meter 1 is activated and information is not collected, the CPU 31 activates the timer 37 and the time when the user inputs an operation (any reference time) The measurement of the elapsed time from the start is started, and the detection of the instantaneous gas flow rate by the flow sensor 12 is started. Then, as shown in FIGS. 8 and 9, the CPU 31 detects the instantaneous gas flow rate (Q ₁ , Q ₂ ,..., Q _N−1 , Q _N ) detected by the flow sensor 12 and a timer at each detection. The elapsed time (T ₁ , T ₂ ,..., T _N−1 , T _N ) measured in 37 is stored in the EEPROM 33 in a one-to-one correspondence. That is, the CPU 31 functions as information collection start setting means in the present invention. The CPU 31 and the EEPROM 33 constitute information collecting means in the present invention and function as a processor and a memory in the present invention, respectively.

  The instantaneous flow rate detection interval (sampling cycle) and the number of detections in the flow sensor 12 and the measurement time cycle in the timer 37 can be set as appropriate according to the specifications of the flow meter 1, usage conditions, and the like. For example, the timer 37 has a measurement cycle of 800 minutes (13 hours and 20 minutes), and the timer 37 measures the instantaneous flow rate at intervals of 10 minutes while the timer 37 measures the time of 800 minutes from the time when the user inputs an operation. It can be set to detect 80 times at (sampling period: 10 minutes). The CPU 31 converts the detected value (the instantaneous flow rate of the gas flowing through the bypass flow path 3c) in the flow sensor 12 into the instantaneous flow rate of the gas flowing through the pipe P using a predetermined conversion formula. Is stored in the EEPROM 33.

Further, the CPU 31 receives the operation of the operation unit 4b by the user, inputs the collection start time of the flow rate-time information, and based on the input information collection start time, the information related to the elapsed time stored in the EEPROM 33 is Convert to information related to time. That is, the CPU 31 also functions as time input means and time setting means in the present invention. For example, as shown in FIG. 9, the instantaneous flow rate (Q ₁ , Q ₂ ,..., Q ₇₉ , Q ₈₀ ) of gas detected 80 times at 10 minute intervals in the flow sensor 12 and the timer 37 at each detection. The measured elapsed time (T ₁ (10 minutes), T ₂ (20 minutes),..., T ₇₉ (790 minutes), T ₈₀ (800 minutes)) is stored in a one-to-one correspondence. Assume a case. In this case, if the collection start time of the flow rate-time information (time when the operation of the timer 37 is started) is “8:00”, the CPU 31 determines that each elapsed time (T ₁ , T ₂ ,..., T ₇₉ , T ₈₀ ) are converted into times (8:10, 8:20,..., 21:10, 21:20) and stored in the EEPROM 33. Thereby, “flow rate-time information” is converted to “flow rate-time information”.

  When the instantaneous flow rate mode is set by operating the MODE key 52, the CPU 31 turns on the instantaneous flow rate mode indicator lamp 42 of the display unit 4a as shown in FIG. A value obtained by converting the detected value in the flow sensor 12 into an instantaneous flow rate of the gas flowing through the pipe P) is displayed on the 7-segment display 41 in real time. On the other hand, when the integrated flow mode is set by operating the MODE key 52, the CPU 31 turns on the integrated flow mode indicator lamp 43 of the display unit 4a as shown in FIG. The integrated value of the flow rate is displayed on the 7-segment display 41. When the integrated value of the instantaneous flow rate is 6 digits or more, the CPU 31 divides an upper digit of 6 digits or more and a lower digit of 5 digits or less and alternately displays them on the 7-segment display 41 every predetermined time. Like that.

  In addition, when a specific operation (for example, a 2-second long press operation of the ENTER key 51 and the MODE key 52) is performed on the operation unit 4b, the CPU 31 stores information on the instantaneous flow rate stored in the EEPROM 33 and the instantaneous flow rate. Both the information related to the elapsed time corresponding to the flow rate (flow rate-time information) are alternately displayed on the 7-segment display 41 every predetermined time. At this time, prior to the display of the information related to the instantaneous flow rate, the CPU 31 displays the information related to the elapsed time corresponding to the information related to the instantaneous flow rate. For example, when the instantaneous flow rate at the time when 10 minutes have elapsed from the start of measurement by the timer 37 is 200 L / min, the CPU 31 first displays information (00.10h) relating to the elapsed time as shown in FIG. Next, after a predetermined time has elapsed, information (200) relating to the instantaneous flow rate is displayed. In the present embodiment, XX hours ΔΔ minutes are displayed as “XX.ΔΔh”.

  Further, the CPU 31 changes the flow rate-time information displayed on the 7-segment display 41 when the UP key 53 or the DOWN key 54 of the operation unit 4b is operated. Specifically, when the UP key 53 is pressed once in a state where the initial elapsed time (00.10h) and the information related to the instantaneous flow rate corresponding to the initial elapsed time (00.10h) are displayed as shown in FIG. Displays the elapsed time (20.20h) measured next (stored) and information related to the instantaneous flow rate corresponding thereto. FIG. 12 shows an instantaneous flow rate (10 L / min) at the time point when 2 hours and 30 minutes have elapsed from the start of measurement by the timer 37 (02.30 h) as a result of the UP key 53 being pressed a plurality of times from the state shown in FIG. Is displayed. When the DOWN key 54 is pressed once in the state shown in FIG. 12, the CPU 31 displays the elapsed time (02.20h) measured (stored) immediately before and information related to the instantaneous flow rate corresponding thereto. To do.

  In addition, when a specific operation of the operation unit 4b (for example, a 4-second long press operation of the ENTER key 51 and the MODE key 52) is performed, the CPU 31 stores information on the instantaneous flow rate stored in the EEPROM 33 and the instantaneous flow rate. Both the information related to the time corresponding to the flow rate (flow rate-time information) are alternately displayed on the 7-segment display 41 every predetermined time. At this time, the CPU 31 displays information related to the time corresponding to the instantaneous flow before displaying the information related to the instantaneous flow. For example, when the instantaneous flow rate at the time of 8:10 (at the time when 10 minutes have elapsed from the start of the timer 37) is 200 L / min, the CPU 31 first displays information (8: 10), and then information (200) on the instantaneous flow rate is displayed after a predetermined time has elapsed.

  Further, the CPU 31 changes the flow rate-time information displayed on the 7-segment display 41 when the UP key 53 or the DOWN key 54 of the operation unit 4b is operated. Specifically, as shown in FIG. 13, when the UP key 53 is pressed once in the state where the initial time (8:10) and the information related to the instantaneous flow rate are displayed, the CPU 31 Next, the stored time (8:20) and the information related to the instantaneous flow rate corresponding thereto are displayed. FIG. 14 shows a state where the instantaneous flow rate (10 L / min) at the time 10:30 (10:30) is displayed as a result of pressing the UP key 53 a plurality of times from the state shown in FIG. . When the DOWN key 54 is pressed once in the state shown in FIG. 14, the CPU 31 displays the time (10:20) stored immediately before and information related to the instantaneous flow rate corresponding thereto.

Further, the CPU 31 causes the EEPROM 33 to store additional flow rate information in each detection period of the instantaneous flow rate (measurement cycle of the timer 37) in addition to the information related to the detected instantaneous flow rate and the information related to the elapsed time or time corresponding thereto. The additional flow rate information can be displayed on the display unit 4a. For example, as shown in FIG. 8, the CPU 31 stores information on the maximum value Q _MAX , the minimum value Q _MIN, and the average value Q _AVE in each detection period (0 to T _N ) of the instantaneous flow rate in the EEPROM 33 as additional flow rate information. The additional flow rate information can be stored and displayed on the 7-segment display 41. At this time, the CPU 31 determines whether the maximum value Q _MAX of the instantaneous flow rate exceeds a predetermined threshold value (upper limit value), or whether the minimum value Q _MIN of the instantaneous flow rate is less than a predetermined threshold value (lower limit value). , And the determination result (for example, the maximum value Q _MAX of the instantaneous flow rate exceeds the upper limit value) can be stored in the EEPROM 33 at the same time. Further, the CPU 31 causes the EEPROM 33 to store, as additional flow information, information related to the integrated value of the instantaneous flow rate in each detection period (0 to T _N ) and the integrated value of the instantaneous flow rate in each sampling period (for example, T _{1 to} T ₂ ). The additional flow rate information can also be displayed on the 7-segment display 41.

  In addition, the CPU 31 stores various information (information related to the instantaneous flow rate and information related to the elapsed time and time corresponding to the instantaneous flow rate) stored in the EEPROM 33 via the communication unit 36 and a wireless communication method or a wired communication method. Thus, it can be transferred to a device external to the flow meter 1 (for example, a portable terminal device for performing setting of various functions for the flow meter 1 and automatic meter reading of the integrated flow value). That is, the CPU 31 and the communication unit 36 constitute communication means in the present invention.

  In the flow meter 1 according to the embodiment described above, information related to the instantaneous flow rate and information related to the elapsed time can be stored in association with each other (flow rate-time information is collected). Therefore, it is possible to calculate information related to the time at which the instantaneous flow rate is detected based on the information collection start time and the stored elapsed time. That is, it is possible to obtain trend data by effectively using information related to the elapsed time. As a result, since it is not necessary to mount a clock on the flow meter, there is no need to worry about a clock failure or a clock error (error), and data can be collected relatively accurately. In addition, since a timepiece is not employed, it is possible to reduce the processing load and power consumption in the control circuit, and further, it is possible to reduce the cost of the flow meter.

  In the flow meter 1 according to the embodiment described above, when the information collection start time is input, the information related to the elapsed time stored in the EEPROM 33 is related to the time based on the information collection start time. It can be converted into information, and the information related to the instantaneous flow rate and the information related to the time can be stored in correspondence with each other (that is, as flow rate-time information).

  In the flow meter 1 according to the embodiment described above, the information stored in the EEPROM 33 (information related to the detected instantaneous flow rate and information related to the elapsed time or time corresponding thereto) is displayed on the 7-segment display 41. Can be notified to the user. At this time, prior to the display of the information related to the instantaneous flow rate, it is possible to display the information related to the elapsed time or time corresponding to the information related to the instantaneous flow rate, so the correspondence between the elapsed time (or time) and the instantaneous flow rate The relationship can be notified to the user in an easily understandable manner.

  Further, in the flow meter 1 according to the embodiment described above, the information stored in the EEPROM 33 is updated every time the user performs a predetermined operation (pressing operation of the UP key 53 or the DOWN key 54) in the operation unit 4b. It can be displayed on the 7-segment display 41 in the order of time measurement (storage) or time.

  Further, in the flow meter 1 according to the embodiment described above, information stored in the EEPROM 33 (information on the detected instantaneous flow rate and information on the elapsed time or time corresponding thereto) is transferred to an external device. Can be used effectively.

  Further, in the flow meter 1 according to the embodiment described above, the EEPROM 33 can be removed, and information stored in the EEPROM 33 can be read by an external device and effectively used.

In addition, in the flow meter 1 according to the embodiment described above, in addition to the information related to the detected instantaneous flow rate and the information related to the elapsed time or time corresponding thereto, additional flow rate information (the maximum of the instantaneous flow rate in each detection period) Information such as the value Q _MAX , the minimum value Q _MIN , the average value Q _AVE , and the integrated value) can be stored together, and a predetermined determination result for the additional flow rate information (for example, the maximum value Q _{MAX of the} instantaneous flow rate is That a predetermined threshold value has been exceeded) can be stored simultaneously.

  In the present embodiment, an example is shown in which the CPU 31 starts collecting the flow rate-time information in response to the operation of the operation unit 4b by the user. However, the trigger for starting the collection of the flow rate-time information is limited to this. It is not something. For example, the CPU 31 can be configured to automatically start collecting the flow rate-time information simultaneously with the activation of the flow meter 1.

  Further, in the present embodiment, an example is shown in which information related to the elapsed time stored in the EEPROM 33 is converted into information related to time based on the collection “start” time of the flow rate-time information. Based on the time, the information related to the elapsed time can be converted into the information related to the time.

For example, as shown in FIG. 9, the instantaneous flow rate (Q ₁ , Q ₂ ,..., Q ₇₉ , Q ₈₀ ) of gas detected 80 times every 10 minutes by the flow sensor 12 and the timer 37 at each detection. The measured elapsed time (T ₁ (10 minutes), T ₂ (20 minutes),..., T ₇₉ (790 minutes), T ₈₀ (800 minutes)) is stored in a one-to-one correspondence. Assume a case. In such a case, assuming that the collection end time of the flow rate-time information (time when the operation of the timer 37 is stopped) is “21:20”, the CPU 31 determines each of the information based on the information collection end time (21:20). The elapsed time (T ₈₀ , T ₇₉ ,..., T ₂ , T ₁ ) can be converted into time (21:20, 21:10,..., 8:20, 8:10). At this time, the CPU 31 calculates the information collection start time (8:00) based on the information collection end time (21:20) and the total measurement time (800 minutes) of the timer 37, and based on the information collection start time. Each elapsed time (T ₁ , T ₂ ,..., T ₇₉ , T ₈₀ ) can be converted into a time (8:10, 8:20,..., 21:10, 21:20).

  Moreover, in this embodiment, although the CPU31 showed the example which received the collection start time of flow volume-time information in response to operation of the operation part 4b by a user, the input method of information collection start time is limited to this. It is not something. For example, when an information collection start signal transmitted from a remote location is received via the communication unit 36, the CPU 31 can input the reception time as the information collection start time. As for the information collection end time input method, various methods (for example, by an operation input by a user or by receiving an information collection end signal transmitted from a remote location) are used in the same manner as the information collection start time input method. Can be adopted.

  In the present embodiment, the CPU 31 changes the display of the flow rate-time information and the flow rate-time information in response to the operation of the operation unit 4b by the user (every time the user performs a predetermined operation on the operation unit 4b. Although the example in which the information stored in the EEPROM 33 is displayed in the order of measurement of elapsed time or the order of time is shown, the CPU 31 automatically changes the display of the flow rate-time information and the flow rate-time information at a predetermined time interval (stored). The displayed information is automatically displayed at a predetermined time interval in order of measurement of elapsed time or time.

Moreover, in this embodiment, although CPU31 showed the example which memorize | stored additional flow rate information and the determination result with respect to this additional flow rate information simultaneously in EEPROM33, when the said determination result satisfy | fills specific conditions (for example, When the maximum value Q _MAX of the instantaneous flow rate exceeds the upper limit value and reaches a level to be notified to the user, only the additional flow rate information (maximum value Q _{MAX of the} instantaneous flow rate) in that case can be stored in the EEPROM 33. . In this way, the amount of information to be stored can be reduced, which is effective when a storage unit such as the EEPROM 33 having a limited storage capacity is employed.

  In the present embodiment, the flow sensor 12 that detects the instantaneous gas flow rate is used as the flow rate detection unit. However, the flow rate detection unit that detects the integrated gas flow rate is used, and the flow rate detection unit. It is also possible to adopt a configuration in which the integrated gas flow rate detected in step 1 and the elapsed time measured at each detection are stored in the memory in a one-to-one correspondence. Even when such a configuration is adopted, the flow rate-time information (the information related to the integrated flow rate and the information related to the elapsed time corresponding thereto) is changed to the flow rate-time information (the information related to the integrated flow rate and the time corresponding thereto). Information) and can be displayed on the display unit.

  Further, in this embodiment, an example in which a thermal flow sensor is employed as the flow detection means has been shown, but instead of such a thermal flow sensor, another type (ultrasonic or electromagnetic) flow sensor is used as a flow rate. It can also be employed as detection means. Moreover, in this embodiment, although the example which applied this invention to the gas flowmeter was shown, this invention can also be applied to the flowmeter which detects the flow volume of a liquid. In addition, the present invention can be variously modified and implemented without departing from the scope of the invention. Note that the terms “upper” and “lower” used in the above description are expedient expressions, and do not necessarily represent the limitation of the direction with respect to the direction of gravity.

It is a perspective view of a flow meter concerning an embodiment of the present invention. It is a perspective view which shows the state which isolate | separated the measurement part of the flowmeter of FIG. 1 from the flowmeter body part. (A) is a front view of the flow meter of FIG. 1, (B) is a side view of the flow meter of FIG. 1 (a view seen from the direction of arrow B in (A)), and (C) is a view of FIG. It is a top view (figure seen from arrow C direction of (A)) of a flow meter. It is sectional drawing in the IV-IV part of the flowmeter of FIG. 3 (B). It is a perspective view which shows the flow sensor provided in the measurement part of the flowmeter of FIG. FIG. 6 is an end view when the flow sensor of FIG. 5 is viewed from the VI-VI direction. It is a block diagram which shows the functional structure of the control part provided in the measurement part of the flowmeter of FIG. It is a map which shows the flow-time information collected by the flow meter of FIG. 2 is a data table showing flow rate-time information and flow rate-time information collected by the flow meter of FIG. 1. 1A and 1B show a display unit of the flow meter of FIG. 1 and information displayed on the display unit, in which FIG. 1A shows an instantaneous flow rate, and FIG. 2B shows an integrated value of the instantaneous flow rate. It is a figure which shows an example of the flow volume-time information displayed on the display part of FIG. It is a figure which shows the other example of the flow volume-time information displayed on the display part of FIG. It is a figure which shows an example of the flow volume-time information displayed on the display part of FIG. It is a figure which shows the other example of the flow volume-time information displayed on the display part of FIG.

Explanation of symbols

1 ... Flow meter 3c ... Bypass channel (predetermined channel)
4b ... operation unit (display setting means)
12 ... Flow sensor (flow rate detection means)
31 ... CPU (information collecting means, time input means, time setting means, information collection start setting means, communication means, processor)
33 ... EEPROM (nonvolatile storage means, memory)
36. Communication unit (communication means)
37. Timer (time measuring means)
41 ... 7 segment display (display means)

Claims (13)

A flowmeter comprising a flow rate detection means for detecting a flow rate of a fluid to be measured flowing through a predetermined flow path, and a time measurement means for measuring an elapsed time from an arbitrary reference time,
Information collecting means for storing information relating to the flow rate detected by the flow rate detecting means and information relating to the elapsed time measured by the time measuring means in association with each other;
Flowmeter. Time input means for inputting an information collection end time in the information collection means;
Based on the information collection end time input by the time input means, the time setting for converting the information related to the elapsed time stored in the information collection means into the information related to the time corresponding to the flow rate and storing the information in the information collection means Means,
The flow meter according to claim 1. Information collection start setting means for starting information collection in the information collection means;
Time input means for inputting an information collection start time in the information collection means;
Based on the information collection start time input by the time input unit, the time setting for converting the information related to the elapsed time stored in the information collection unit into the information related to the time corresponding to the flow rate and storing the information in the information collection unit Means,
The flow meter according to claim 1 or 2. Display means for displaying the information stored in the information collecting means;
The flow meter according to any one of claims 1 to 3. When the information stored in the information collecting unit is displayed on the display unit, prior to displaying the information on the flow rate, information on the elapsed time or time corresponding to the flow rate is displayed.
The flow meter according to claim 4. Comprising display setting means for setting a display mode of information in the display means;
Each time a user performs a predetermined operation in the display setting means, the information stored in the information collecting means is displayed on the display means in the order of measurement of elapsed time or in time order.
The flow meter according to claim 5. The information stored in the information collecting means is automatically displayed on the display means at predetermined time intervals in order of measurement of elapsed time or time.
The flow meter according to claim 5. Comprising communication means for transferring the information stored in the information collecting means to an external device of the flow meter,
The flow meter according to any one of claims 1 to 7. The information collecting means includes nonvolatile storage means for storing information collected by being detachably attached to the flowmeter,
Information stored in the non-volatile storage means is read into an external device,
The flow meter according to any one of claims 1 to 7. The flow rate detecting means detects an instantaneous flow rate of the fluid to be measured.
The information collecting unit stores information on the instantaneous flow rate detected by the flow rate detection unit over a predetermined detection period and information on an elapsed time or time corresponding to the information, and a maximum value of the instantaneous flow rate in each detection period, The additional flow rate information including at least one of the minimum value, the average value, and the integrated value is stored.
The flow meter according to any one of claims 1 to 9. The information collecting unit is configured to simultaneously store a predetermined determination result for the additional flow rate information.
The flow meter according to claim 10. When the determination result for the additional flow rate information satisfies a specific condition, the information collection unit stores only the additional flow rate information in that case.
The flow meter according to claim 11. A sensor for detecting the flow rate of the fluid to be measured flowing through the predetermined flow path;
A timer that measures the elapsed time from any reference time;
A processor that stores information related to the flow rate detected by the sensor and information related to the elapsed time measured by the timer in a memory, and
Flowmeter.

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