JP2017090268A - Ultrasonic flow meter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress a decrease in measurement accuracy by suppressing the intrusion of moisture or the like into the inside of a tubular measurement flow path portion with respect to an ultrasonic flow meter for measuring the flow rate of a fluid to be measured by using ultrasonic waves. Provide an ultrasonic flow meter. An ultrasonic flow meter 1 has an inlet buffer portion 27 and an outlet buffer portion 29 of a meter case 3 connected by a measurement flow path portion 15 of a flow rate measuring unit 11, and flows from an inflow port 5. The flow rate of the fuel gas is measured by propagating ultrasonic waves from a pair of ultrasonic vibrators to the fuel gas flowing inside the measurement flow path portion 15 toward the outlet 6. The fuel gas that has flowed in from the inflow port 5 flows into the inside of the inlet buffer portion 27 through the opening 32, and flows into the inside of the measurement flow path portion 15 from the inlet portion 15A of the measurement flow path portion 15. Inside the inlet buffer portion 27, the inlet portion 15A of the measurement flow path portion 15 is arranged so as to be above the opening portion 32 formed in the inlet buffer portion 27. [Selection diagram] Fig. 4

Description

  The present invention relates to an ultrasonic flowmeter that measures the flow rate of a fluid to be measured using ultrasonic waves.

  Conventionally, an ultrasonic flowmeter is configured by disposing a tubular measurement channel (conduction channel) inside a substantially box-shaped meter case. Sound waves are propagated, and the flow rate of the measurement fluid is measured by utilizing the fact that the propagation time or propagation speed of the ultrasonic waves changes depending on the flow velocity of the measurement fluid (for example, gas).

  Here, the gas as the fluid to be measured inevitably contains moisture and impurities (for example, dust mixed during gas production, oil-based impurities generated in the petroleum refining process, etc.). For this reason, in order to measure the flow rate of the fluid to be measured with an ultrasonic flow meter, if the fluid to be measured flows into the meter case, moisture and impurities (hereinafter, moisture etc.) are condensed inside the meter case. Or stick.

  As described above, the measurement flow path portion is disposed inside the meter case of the ultrasonic flow meter, and is a portion where the fluid to be measured that has flowed into the meter case flows down. In some cases, moisture or the like enters the inside of the measurement channel. The moisture or the like affects the propagation time and propagation speed of the ultrasonic wave inside the measurement channel part, or causes a malfunction of a pair of ultrasonic vibrators disposed on the measurement channel part. Therefore, the measurement accuracy of the flow rate by the ultrasonic flowmeter may be lowered.

  As an invention relating to an ultrasonic flowmeter made in this regard, the invention described in Patent Document 1 is known. The gas meter described in Patent Document 1 is formed in an airtight structure, and is divided into a first case and a second chamber by a partition, and a cylindrical gas conduction path (measurement flow) arranged to penetrate the partition. And a pair of ultrasonic transducers arranged opposite to each other with a predetermined length in a direction parallel to the gas flow passing through the gas conduction path. In the gas meter described in Patent Document 1, the gas flowing into the first chamber from the upstream gas pipe is sent from the first chamber to the downstream gas pipe through the gas conduction path and the second chamber. The flow rate of the gas flowing down the gas conduction path toward the second chamber is measured by a pair of ultrasonic transducers, and the gas flow rate is calculated based on the value of the flow rate.

  In the gas meter described in Patent Document 1, the gas conduction path is inclined with respect to the horizontal direction so that the end portion on the first chamber side is located above and the end portion on the second chamber side is located below. Are arranged as follows. In other words, the gas meter is arranged so that the gas conduction path is inclined with respect to the horizontal direction, so that moisture and oil-based impurities that have entered the gas conduction path are hardened and deposited before being hardened and deposited. Moisture, oil-based impurities, and the like are positively dropped along the inclination of the gas conduction path by gravity acting on the inner surface of the gas conduction path. That is, the gas meter described in Patent Document 1 prevents a decrease in measurement accuracy due to moisture or the like existing inside the gas conduction path by causing moisture or the like that has entered the gas conduction path to flow out to the outside at an early stage. ing.

Japanese Patent Application Laid-Open No. 11-051723

  However, in the invention described in Patent Document 1, when moisture or the like enters the gas conduction path, the period during which the moisture or the like remains in the gas conduction path is shortened. No measures have been taken with respect to the entry of moisture. That is, the invention described in Patent Document 1 has succeeded in shortening the period during which the measurement accuracy decreases due to the presence of moisture and the like in the gas conduction path, but moisture and the like enter the gas conduction path. The decrease in measurement accuracy itself could not be suppressed.

  Further, in the gas meter described in Patent Document 1, the upstream gas pipe is connected to the upper surface of the first chamber in the meter case, and is configured to allow gas to flow downward from the upper surface of the first chamber. Has been. And in the said 1st chamber, the gas conduction path is inclined and arrange | positioned so that the edge part may be located upwards. That is, the gas meter is arranged such that moisture contained in the gas flowing in from the upstream gas pipe disposed on the upper surface of the first chamber can easily enter the inside of the gas conduction path. It has become the structure which the fall of the measurement accuracy resulting from the water | moisture content etc. in the inside of a channel | path easily occurs.

  The present disclosure has been made in view of the above-described problems, and relates to an ultrasonic flowmeter that measures the flow rate of a fluid to be measured using ultrasonic waves, such as moisture in the tubular measurement channel section. An ultrasonic flowmeter capable of suppressing a decrease in measurement accuracy by suppressing entry is provided.

  In order to achieve the above object, an ultrasonic flowmeter according to one aspect of the present invention is provided in a meter case having an inlet for a fluid to be measured and an outlet for the fluid to be measured, and disposed inside the meter case. A flow rate measurement unit for measuring a flow rate of the fluid to be measured that passes through the meter case through the inlet and the outlet, and the flow rate measurement unit extends from the inlet to the outlet. And a pair of ultrasonic transducers disposed respectively on the upstream side and the downstream side of the flow of the fluid to be measured in the measurement channel portion. The meter case has an opening which is an end portion of an inflow path extending from the inflow port in an inner wall portion, and the fluid to be measured which has flowed through the inflow port and the opening is the measurement flow path unit. Flow against the inlet In addition, the fluid to be measured that flows out from the outlet portion of the measurement flow path portion is communicated with the inlet buffer portion partitioned in a substantially box shape and the outlet port, and the meter case passes through the outlet port. An outlet buffer section partitioned into a substantially box shape so as to flow out to the outside, and the inlet section of the measurement flow path section is located above the opening section in the inlet buffer section. It is characterized by.

  The ultrasonic flowmeter has an inlet buffer portion and an outlet buffer portion inside the meter case so as to be connected by a measurement flow path portion of the flow rate measurement unit, and is directed from the inlet to the outlet. Thus, the flow rate of the fluid to be measured can be measured by propagating ultrasonic waves from a pair of ultrasonic transducers with respect to the fluid to be measured flowing inside the measurement flow path section. Here, since an opening which is an end portion of the inflow passage extending from the inflow port is formed in the inner wall portion of the inlet buffer portion, when the fluid to be measured flows into the inflow passage from the inflow port, It flows down and flows into the inlet buffer section through the opening. When the fluid to be measured flows from the opening into the inlet buffer, the fluid to be measured flows into the measurement channel from the inlet in the measurement channel of the flow rate measurement unit, and the outlet in the measurement channel. Then, it flows out of the meter case through the outlet buffer section and the outlet.

  And in the said ultrasonic flowmeter, since the said inlet part of the said measurement flow-path part is located above the said opening part in the inside of the said inlet buffer part, it is the inside of an inlet buffer part via an opening part. The fluid to be measured flows upward against gravity and flows into the inlet of the measurement channel. In other words, according to the ultrasonic flowmeter, even when moisture, dust, oil-based impurities, etc. (that is, moisture, etc.) are contained in the fluid to be measured, the fluid to be measured flows from the opening to the inlet portion. Gravity can be applied to moisture and the like in the process of reaching the depth, so that entry of moisture and the like into the inside of the measurement channel can be suppressed. And according to the ultrasonic flowmeter, by suppressing the entry of moisture and the like into the inside of the measurement flow path portion, occurrence of a decrease in measurement accuracy due to the moisture and the like is prevented, and the flow rate of the fluid to be measured is reduced. Such measurement accuracy can be maintained.

  An ultrasonic flowmeter according to another aspect of the present invention is the ultrasonic flowmeter according to claim 1, wherein the inlet portion of the measurement flow path portion is more than the center of the opening portion of the inlet buffer portion. It is located above.

  In the ultrasonic flowmeter, the inlet portion of the measurement flow path portion is located above the center of the opening portion of the inlet buffer portion. That is, even when moisture or the like is contained in the fluid to be measured, the moisture or the like does not flow against the gravity up to a position above the inlet portion of the measurement flow path portion. It cannot enter the inside of the inlet portion in the flow path portion. As a result, according to the ultrasonic flow meter, it is possible to more reliably suppress the entry of moisture and the like into the inside of the measurement flow path portion, thereby preventing the occurrence of a decrease in measurement accuracy due to the moisture and the like. In addition, the measurement accuracy related to the flow rate of the fluid to be measured can be maintained.

  An ultrasonic flow meter according to another aspect of the present invention is the ultrasonic flow meter according to claim 1 or 2, wherein a lower end edge of the measurement flow path portion at the inlet portion is formed by the inlet buffer portion. It is located above the upper end edge in the said opening part, It is characterized by the above-mentioned.

  In the ultrasonic flowmeter, a lower end edge of the measurement channel portion at the inlet portion is located above an upper end edge of the opening portion of the inlet buffer portion. That is, even when moisture or the like is contained in the fluid to be measured, the moisture or the like exceeds the upper end edge of the opening portion of the inlet buffer portion and further above the inlet portion of the measurement flow path portion. If it does not flow against gravity up to a position above the lower end edge, it cannot enter the inside of the inlet portion in the measurement flow path portion. As a result, according to the ultrasonic flowmeter, a sufficient distance can be secured against gravity, so that moisture and the like can be more reliably suppressed from entering the measurement channel. Therefore, it is possible to prevent the occurrence of a decrease in measurement accuracy due to the moisture or the like. That is, according to the ultrasonic flowmeter, the measurement accuracy related to the flow rate of the fluid to be measured can be maintained in a desired state at the time of design, for example.

It is a disassembled perspective view which shows schematic structure of the ultrasonic flowmeter which concerns on 1st Embodiment. It is a front view which shows the ultrasonic flowmeter of the state which removed the cover of the meter case. It is principal part sectional drawing which shows the internal structure of a flow measurement unit. It is sectional drawing which shows the positional relationship of the inlet part of the flow measurement unit in 1st Embodiment, and the opening part of an inlet buffer part. It is sectional drawing which shows the positional relationship of the inlet part of the flow measurement unit in 2nd Embodiment, and the opening part of an inlet buffer part.

  Hereinafter, an embodiment (first embodiment) in which an ultrasonic flowmeter according to the present invention is embodied in an ultrasonic flowmeter 1 will be described in detail with reference to the drawings.

(Schematic configuration of ultrasonic flowmeter)
First, a schematic configuration of the ultrasonic flowmeter 1 according to the first embodiment will be described with reference to FIGS. The ultrasonic flowmeter 1 according to the first embodiment is a fuel gas meter that measures the flow rate of a fuel gas (for example, city gas or LP gas) that is an example of a fluid to be measured. A flow rate measurement unit 11 is arranged inside the connected meter case 3.

  As shown in FIGS. 1 and 2, the meter case 3 includes a meter housing 3A formed in a substantially rectangular parallelepiped shape with one surface open, and a substantially box-shaped cover having a recess recessed at a predetermined depth on the inner surface. 3B, and is configured to hold the inside of the meter case 3 in an airtight manner by screwing the cover 3B to one side of the meter housing 3A.

  An inflow port 5 and an outflow port 6 are formed to protrude at both ends in the longitudinal direction on the upper surface of the meter housing 3A. The fuel gas pipe 2 is airtight with respect to the inflow port 5 and the outflow port 6, respectively. Connected to. The inflow port 5 and the outflow port 6 communicate with a space (an inlet buffer unit 27 and an outlet buffer unit 29 described later) formed in the meter case 3. Accordingly, in the ultrasonic flow meter 1, the fuel gas is supplied to the inside of the meter case 3 through the inlet 5 to which the pipe 2 is connected, and the meter from the inside of the meter case 3 through the outlet 6. It is discharged to the pipe 2 extending to the outside of the case 3.

  The flow rate measuring unit 11 is disposed inside the meter case 3 that is kept airtight, and the inside of the meter case 3 using a pair of ultrasonic transducers 12A and 12B (see FIG. 3). Measure the flow rate of fuel gas passing through. As shown in FIGS. 1 and 2, the flow rate measurement unit 11 is inserted into the meter case 3 from one surface side of the meter housing 3 </ b> A, and the measurement flow path unit 15 of the flow rate measurement unit 11 extends in the longitudinal direction of the meter case 3. It arrange | positions so that it may extend along a direction.

(Schematic configuration of flow measurement unit)
Here, the schematic configuration of the flow rate measurement unit 11 will be described in detail with reference to the drawings. As shown in FIGS. 1 to 4, the flow rate measurement unit 11 includes a measurement flow path unit 15 functioning as a fuel gas flow path inside the meter case 3, and an upper side of the central portion in the longitudinal direction of the measurement flow path unit 15. The circuit case 16 is formed. The measurement flow path portion 15 is formed in a cylindrical shape in which the flow path cross section has a rectangular shape that is long in the vertical direction.

  As shown in FIG. 3, an ultrasonic transducer 12A and an ultrasonic transducer 12B are provided on one surface side of the measurement flow channel portion 15 (see FIG. 3). 3 is arranged on the upper surface side of the measurement flow path section 15. The ultrasonic transducer 12A is disposed on the upstream side in the direction of fuel gas flow (hereinafter referred to as gas flow downward direction F) on one surface of the measurement flow path section 15, and the ultrasonic transducer 12B is disposed on the measurement flow path section 15. It is arrange | positioned in the downstream of the gas flow downward direction F in one surface.

  Then, the ultrasonic wave output from one of the ultrasonic vibrator 12A and the ultrasonic vibrator 12B is reflected by the facing surface (lower surface) in the measurement flow path section 15, and the ultrasonic vibrator 12A and the ultrasonic vibration are reflected. Reach the other child 12B. Accordingly, an ultrasonic wave propagation path 17 is formed inside the measurement flow path unit 15 in the flow rate measurement unit 11, and the propagation path 17 is ultrasonic waves via an opposing surface (lower surface) in the measurement flow path unit 15. V-shaped connecting the transducer 12A and the ultrasonic transducer 12B.

  A circuit board 18 is disposed above the ultrasonic transducers 12A and 12B inside the circuit case 16, and each ultrasonic transducer 12A, ultrasonic wave is disposed on the circuit board 18. A measurement circuit 18A to which the vibrator 12B is electrically connected is formed. That is, the circuit board 18 is configured to be able to calculate and output a flow rate measurement value of a fluid to be measured such as fuel gas using the measurement circuit 18A.

  As shown in FIGS. 1 and 2, an inlet portion 15 </ b> A is formed on one end side of the measurement channel portion 15, and an outlet portion 15 </ b> B is formed on the other end side of the measurement channel portion 15. . The inlet portion 15A and the outlet portion 15B of the measurement flow path portion 15 are formed in curved surfaces whose inner peripheral surfaces smoothly spread outward.

  As shown in FIG. 3, a plurality of (for example, five) flow dividing plates 19 are arranged below the ultrasonic transducers 12 </ b> A and 12 </ b> B inside the measurement flow path unit 15. ing. The plurality of flow dividing plates 19 are parallel to the long side of the flow channel cross section of the measurement flow channel portion 15 in a state of being substantially equally spaced in the short side direction of the flow channel cross section of the measurement flow channel portion 15 (that is, It is arrange | positioned so that it may extend in the left-right direction. That is, each flow dividing plate 19 is provided inside the measurement flow path unit 15 so as to be parallel to a plane including the ultrasonic wave propagation path 17 between the ultrasonic vibrator 12A and the ultrasonic vibrator 12B. It extends so as to be parallel to the flow-down direction F. Thereby, it becomes possible to stabilize the flow of the fuel gas inside the measurement flow path portion 15 by the respective flow dividing plates 19.

  In addition, two rows of ribs 25 are erected over the entire circumference of the outer circumference of the measurement flow path section 15 in the flow rate measurement unit 11. The rib 25 is used when attaching a so-called O-ring formed of elastic rubber or the like in order to maintain airtightness on the outer peripheral portion of the measurement flow path portion 15.

(Schematic configuration of meter case)
Next, a schematic configuration of the meter case 3 will be described in detail with reference to the drawings. As shown in FIGS. 1, 2, and 4, the meter case 3 includes an inlet buffer portion 27, a central space portion 28, and an outlet buffer portion 29, from the one end side in the longitudinal direction of the meter case 3 to the other end portion. It forms so that it may line up in order toward the side. The inlet buffer portion 27, the central space portion 28, and the outlet buffer portion 29 are arranged on one side of the meter housing 3A in a state in which the flow rate measuring unit 11 having an O-ring attached between the ribs 25 is disposed inside the meter case 3. By screwing the cover 3B to the side, each is kept airtight.

  The inlet buffer portion 27 is a space partitioned in a substantially box shape by the partition wall 21A of the meter housing 3A and the partition wall 22A of the cover 3B inside the meter case 3, and through an opening 32 described later, It communicates with the inflow port 5. As shown in FIG. 1 and the like, the partition wall 21A stands up from the rear side wall surface portion to the front end portion inside the meter housing 3A over the entire height at a predetermined distance from one longitudinal end portion of the meter housing 3A. It is installed. As shown in FIG. 4, the partition wall 22A is erected from the back side wall surface portion to the front end portion in the cover 3B over the entire height at a position facing the partition wall 21A in the meter housing 3A. .

  And the recessed part 23A is formed in the predetermined position in the up-down direction in the partition wall 21A, and the said recessed part 23A hold | maintains the measurement flow-path part 15 of the flow volume measurement unit 11 (refer FIG. 2, FIG. 4). ). Specifically, the recess 23A is slightly larger than the outer shape of the measurement flow path unit 15 of the flow rate measurement unit 11 from the front end portion of the partition wall 21A to the rear side direction (for example, the outer shape of the measurement flow path unit 15 is larger than the outer shape). It is formed so as to be recessed in a rectangle (about 1 mm to about 3 mm larger outward). Therefore, in the recess 23A, an O-ring is attached between the ribs 25 of the measurement flow path unit 15 in the flow rate measurement unit 11, and a portion where the O-ring of the measurement flow path unit 15 is attached is one side of the meter housing 3A. The O-ring can enhance the airtightness between the outer peripheral surface of the measurement flow path portion 15 and the recess 23A.

  Further, the distance from one end in the longitudinal direction inside the meter housing 3A to the partition wall 21A is a predetermined distance (for example, approximately about a distance from each rib 25 of the measurement flow path portion 15 of the flow rate measurement unit 11 to the inlet portion 15A. 10 mm). Therefore, inside the inlet buffer 27, the inlet 15A of the measurement flow path 15 is disposed so as to protrude from the partition wall 21A to the inside of the inlet buffer 27 (see FIGS. 2 and 4).

  As shown in FIGS. 1 and 2, the central space portion 28 is formed in a substantially box-like shape between the inlet buffer portion 27 and the outlet buffer portion 29 in the longitudinal direction. It is located between the wall 22A and the partition wall 21B. The width of the central space 28 in the longitudinal direction (that is, the distance between the partition wall 21A and the partition wall 21B) is slightly longer than the length of the circuit case 16 in the longitudinal direction of the flow rate measurement unit 11 (for example, The distance is set to about 6 mm longer.

  The height in the vertical direction in the central space portion 28 (the height in the vertical direction between the partition wall 21A and the partition wall 21B of the meter housing 3A) is between the ribs 25 of the measurement flow path unit 15 of the flow rate measurement unit 11. When the O-ring is attached to the measurement flow passage portion 15 and the portion where the O-ring is attached to the recess 23A or the like from the front side of the meter housing 3A, the circuit case 16 can be inserted into a height. Is formed. When the flow rate measuring unit 11 is disposed inside the meter case 3, the central space 28 is provided with a central portion sandwiched between the circuit case 16 and the ribs 25 of the measurement flow path portion 15 in the flow rate measuring unit 11. Is done.

  An external terminal (not shown) is airtightly attached to the back side wall surface portion in the central space portion 28 and is electrically connected to the circuit board 18 accommodated in the circuit case 16. . The external terminal is configured to be able to output the fuel gas flow rate measurement value output from the measurement circuit 18A of the circuit board 18 to the outside.

The outlet buffer unit 29 is a space partitioned in a substantially box shape by the partition wall 21B of the meter housing 3A and the partition wall of the cover 3B inside the meter case 3, and the meter case 3 via the outlet 6. Communicates with the outside. As shown in FIG. 1 and the like, the partition wall 21B extends from the rear side wall surface portion to the front end portion inside the meter housing 3A over the entire height at a predetermined distance from the other longitudinal end of the meter housing 3A. It is erected.
Note that the cover 3B has a partition wall formed at a position facing the partition wall 21B in the meter housing 3A. The partition wall, like the partition wall 22A, covers the entire inside of the cover 3B. Is provided upright from the rear side wall surface portion to the front end portion.

  And the recessed part 23B is formed in the partition wall 21B in the predetermined position in an up-down direction, and the said recessed part 23B hold | maintains the measurement flow-path part 15 of the flow volume measurement unit 11 (refer FIG. 2). Specifically, the concave portion 23B is slightly larger than the outer shape of the measurement flow path unit 15 of the flow rate measurement unit 11 from the front end portion of the partition wall 21B to the back side direction (for example, larger than the outer shape of the measurement flow channel unit 15). It is formed so as to be recessed in a rectangle (about 1 mm to about 3 mm larger outward). Therefore, in the recess 23B, an O-ring is attached between the ribs 25 of the measurement flow path portion 15 in the flow rate measurement unit 11, and a portion where the O-ring of the measurement flow path portion 15 is attached is connected to one side of the meter housing 3A. The O-ring can improve the airtightness between the outer peripheral surface of the measurement flow path portion 15 and the concave portion 23B.

  Further, the distance from the other end in the longitudinal direction inside the meter housing 3A to the partition wall 21B is a predetermined distance (for example, a distance from each rib 25 of the measurement flow path portion 15 of the flow rate measurement unit 11 to the outlet portion 15B). It is formed to be longer by about 10 mm). Therefore, the outlet portion 15B of the measurement flow path portion 15 is disposed inside the outlet buffer portion 29 so as to protrude from the partition wall 21B to the inside of the outlet buffer portion 29 (see FIG. 2).

  As shown in FIGS. 2 to 4, the inlet portion 15 </ b> A of the measurement channel portion 15 is located inside the inlet buffer portion 27, and the outlet of the measurement channel portion 15 is located inside the outlet buffer portion 29. Since the part 15B is located, the inlet buffer part 27 and the outlet buffer part 29 are communicated with each other by the substantially rectangular measurement channel part 15 whose section is long in the vertical direction.

  In the meter housing 3A, an inflow passage 5A is formed extending from the inlet 5 in the vertical direction of the meter housing 3A. The inflow passage 5 </ b> A is formed along the back side wall surface portion of the inlet buffer portion 27, and a substantially rectangular parallelepiped inflow chamber 31 is adjacent to the rear side of the inlet buffer portion 27 at the lower end portion of the inflow passage 5 </ b> A. Are formed together.

  As shown in FIGS. 1, 2, and 4, an opening 32 having a circular cross section is formed in the inner wall surface of the inlet buffer 27, and the inlet buffer 27 and the end of the inflow passage 5A are formed. The inflow chamber 31 which comprises a part is connected. The opening 32 is formed so that the center C of the opening is orthogonal to the axis of the measurement flow path 15 disposed so as to protrude into the inlet buffer 27. The relationship between the position where the opening 32 is formed inside the inlet buffer 27 and the position where the inlet 15A of the flow rate measurement unit 11 is disposed will be described in detail later with reference to the drawings.

  As shown in FIG. 4, a shutoff valve 33 is disposed inside the inflow chamber 31 at a position facing the opening 32 opened in the back side wall surface portion of the inlet buffer portion 27. It is configured to be occluded. The shut-off valve 33 is electrically connected to a control board (not shown) constituting the ultrasonic flow meter 1 so as to close the opening 32 when an abnormality occurs in the supply gas flow rate or the like. Be controlled. Thereby, the ultrasonic flow meter 1 can forcibly block the flow of the fuel gas between the inflow chamber 31 and the inlet buffer portion 27 when an abnormality occurs in the supply gas flow rate or the like. The supply of gas can be stopped.

  The ultrasonic flow meter 1 is provided with the above-described control board (not shown), and the control board has a control unit including a microcomputer. The control unit is electrically connected to an external terminal electrically connected to the measurement circuit 18A of the flow rate measurement unit 11, the shut-off valve 33, and the like. The control unit detects an abnormality such as a supply gas flow rate based on the measured value of the flow rate of the fuel gas output from the measurement circuit 18A. If the abnormality is a predetermined gas cutoff target, the cutoff valve 33 is detected. , The opening 32 is closed and the supply of fuel gas is stopped. Further, the control unit is configured to be able to output the fuel gas flow rate measurement value output from the measurement circuit 18A to an external personal computer (not shown) or the like.

(Flow of fuel gas in ultrasonic flowmeter)
The flow of the fuel gas in the ultrasonic flowmeter 1 configured as described above will be described in detail with reference to the drawings. As shown in FIGS. 1, 2, and 4, the fuel gas is supplied to the ultrasonic flowmeter 1 through a pipe 2 connected to the inflow port 5. The fuel gas that has flowed into the inflow port 5 flows into the inflow chamber 31 that forms the lower end of the inflow passage 5A through the inflow passage 5A that extends along the vertical direction of the meter housing 3A. Then, in the inflow chamber 31, the fuel gas flows so as to be bent substantially at right angles to the gas flow downward direction F in the inflow passage 5 </ b> A, and flows into the inlet buffer portion 27 through the opening 32.

  When the fuel gas flows into the inlet buffer 27 through the opening 32, the fuel gas flows along the inner surface of the inlet buffer 27 constituted by the meter housing 3A and the cover 3B. Flows into the inlet portion 15A of the measurement flow path portion 15 located inside (see FIGS. 2 and 4).

  As shown in FIGS. 2 and 3, when the fuel gas flows from the inlet portion 15 </ b> A into the measurement flow path portion 15, the fuel gas flows along the inner wall surface of the measurement flow path portion 15 to the outlet buffer portion 29. Flow to exit 6. The ultrasonic flowmeter 1 propagates ultrasonic waves to the inside of the measurement flow path portion 15 in which the fuel gas flows from the inlet portion 15A to the outlet portion 15B using the ultrasonic vibrator 12A and the ultrasonic vibrator 12B. By measuring the propagation time and the like, the flow rate of the fuel gas in the measurement flow path unit 15 can be measured.

  Thereafter, the fuel gas is discharged from the outlet portion 15B of the measurement flow path portion 15 into the outlet buffer portion 29. As shown in FIG. 2, since the outlet buffer unit 29 is connected to the pipe 2 via the outlet 6, the fuel gas is discharged from the outlet unit 15 </ b> B of the measurement channel unit 15 to the outlet buffer unit 29. Then, it flows to the outside of the ultrasonic flowmeter 1 through the outlet 6 and the pipe 2.

(Movement of fuel gas and moisture inside the inlet buffer)
Next, in the ultrasonic flowmeter 1 configured as described above, the movement of the fuel gas and the like inside the inlet buffer unit 27 will be described in detail with reference to the drawings. As described above, fuel gas inevitably contains impurities such as moisture, dust mixed during gas production, and oil-based impurities generated in the petroleum refining process. Therefore, the fuel gas supplied through the pipe 2 and the inflow port 5 flows into the inlet buffer unit 27 through the opening 32 while containing moisture and the like.

  In the ultrasonic flow meter 1, the flow rate measurement unit 11 has a relative relationship in the ultrasonic flow meter 1 by fitting the measurement flow path portion 15 into the concave portion 23 </ b> A and the concave portion 23 </ b> B formed in the meter housing 3 </ b> A. Is positioned properly. As shown in FIGS. 2 and 4, the inlet portion 15 </ b> A of the measurement flow path portion 15 in the flow rate measurement unit 11 is inside the inlet buffer portion 27 from an opening portion 32 formed in the back side wall surface portion of the inlet buffer portion 27. Is also arranged to be on the upper side.

  More specifically, on the basis of the lower surface of the meter case 3, the center position of the inlet portion 15A in the measurement flow path section 15 (hereinafter referred to as the inlet center position LB) is the position of the opening center C in the opening 32 (hereinafter referred to as the following). It is located above the opening center position LA). Note that the center of the inlet 15A in the measurement channel 15 is located on the central axis of the measurement channel 15 formed in a square cylinder (see FIGS. 2 and 4).

  As described above, in the inlet buffer unit 27, the fuel gas flows into the inlet buffer unit 27 from the opening 32 and passes through the inlet unit 15 </ b> A of the measurement flow channel unit 15. Flows outside. Therefore, in the inside of the inlet buffer part 27 of the ultrasonic flowmeter 1 according to the first embodiment, the fuel gas flows through the opening part 32 and then is positioned above the opening part 32. It flows to the outside through 15 inlet portions 15A.

  At this time, in the process of flowing from the opening part 32 of the inlet buffer part 27 to the inlet part 15A of the measurement flow path part 15 located above the gravity part, gravity acts on the moisture contained in the fuel gas. . Due to the action of the gravity, moisture and the like contained in the fuel gas are stored in the lower portion of the inlet buffer portion 27 without reaching the inlet portion 15A of the measurement flow path portion 15, and only the fuel gas is stored. Then, it flows into the inside of the inlet portion 15A in the measurement flow path portion 15.

  As a result, according to the ultrasonic flow meter 1, the inlet 15 </ b> A of the measurement channel 15 is positioned above the opening 32 inside the inlet buffer 27, so that moisture and the like can be converted into the fuel gas. Even if it is included, gravity can act on moisture or the like in the process of the fuel gas from the opening 32 to the inlet 15A of the measurement channel 15 so that the measurement flow Ingress of moisture and the like into the interior of the road portion 15 can be suppressed. And according to the said ultrasonic flowmeter 1, generation | occurrence | production of the fall of the measurement precision resulting from the said water | moisture content etc. is prevented by suppressing the approach of the water | moisture content etc. with respect to the inside of the measurement flow-path part 15, and the flow volume of fuel gas The measurement accuracy according to can be maintained.

  As described above, the ultrasonic flowmeter 1 according to the first embodiment connects the inlet buffer unit 27 and the outlet buffer unit 29 inside the meter case 3 by the measurement flow path unit 15 of the flow rate measurement unit 11. A pair of ultrasonic transducers 12A and 12B is applied to the fuel gas flowing in the measurement flow path section 15 from the inlet 5 toward the outlet 6. The flow rate of the fuel gas can be measured by propagating ultrasonic waves. Here, since the opening 32 which is the end of the inflow path 5A extending from the inflow port 5 is formed in the back side wall surface portion of the inlet buffer unit 27, when the fuel gas flows in from the inflow port 5, the opening 32 is formed. It flows down inside the inflow passage 5A and flows into the inlet buffer 27 through the opening 32 (see FIG. 4). Then, when the fuel gas flows into the inlet buffer unit 27 from the opening 32, the fuel gas flows into the measurement channel unit 15 from the inlet unit 15 </ b> A in the measurement channel unit 15 of the flow rate measurement unit 11. It flows out of the meter case 3 through the outlet 15B, the outlet buffer 29, and the outlet 6 in the section 15.

  As shown in FIGS. 2 and 4, in the ultrasonic flowmeter 1 according to the first embodiment, the inlet portion 15 </ b> A of the measurement flow path portion 15 is formed in the inlet buffer portion 27 inside the inlet buffer portion 27. It arrange | positions so that it may become above the opening part 32. FIG. For this reason, when flowing into the inlet buffer 27 through the opening 32, the fuel gas flows upward against gravity and flows into the inlet 15 </ b> A of the measurement flow path 15.

  That is, according to the ultrasonic flowmeter 1, even when moisture or the like is contained in the fuel gas, the fuel gas is in the process from the opening portion 32 to the inlet portion 15 </ b> A of the measurement flow path portion 15. Gravity can be applied to moisture and the like, and therefore, moisture and the like can be prevented from entering the inside of the measurement channel section 15. Then, according to the ultrasonic flow meter 1, by suppressing the entry of moisture and the like into the measurement flow path section 15, it is possible to prevent the occurrence of a decrease in measurement accuracy related to the flow rate of the fuel gas caused by the moisture and the like. The measurement accuracy related to the flow rate of the fuel gas can be maintained.

  In the ultrasonic flowmeter 1 according to the first embodiment, the inlet portion 15A of the measurement flow path portion 15 is above the center (that is, the opening portion center C) in the opening portion 32 formed in the inlet buffer portion 27. (Refer to FIG. 2 and FIG. 4). That is, even when the fuel gas contains moisture or the like, the moisture or the like does not flow against the gravity up to a position above the inlet portion 15A of the measurement flow path portion 15; It cannot enter the inside of the inlet portion 15A in the measurement flow path portion 15. As a result, according to the ultrasonic flowmeter 1, it is possible to more reliably suppress the entry of moisture and the like into the measurement flow path portion 15, and thus, relates to the flow rate of the fuel gas caused by the moisture and the like. The occurrence of a decrease in measurement accuracy can be prevented, and the measurement accuracy relating to the flow rate of the fuel gas can be maintained.

(Second Embodiment)
Next, a schematic configuration of the ultrasonic flowmeter 1 according to an embodiment (second embodiment) different from the first embodiment described above will be described in detail with reference to FIG. The ultrasonic flowmeter 1 according to the second embodiment is the same as that of the first embodiment described above except for the positional relationship between the opening 32 inside the inlet buffer 27 and the inlet 15A of the measurement channel 15. The ultrasonic flowmeter 1 has the same configuration. Therefore, in the following description, the description of the same configuration as that of the first embodiment is omitted, and a different configuration will be described in detail.

(Movement of fuel gas, moisture, etc. inside the inlet buffer section in the second embodiment)
The movement of the fuel gas and the like inside the inlet buffer unit 27 according to the ultrasonic flow meter 1 according to the second embodiment will be described in detail with reference to FIG. As described in the first embodiment, the fuel gas inevitably contains impurities such as moisture, dust mixed during gas production, and oil-based impurities generated in the petroleum refining process. The fuel gas supplied through the inlet 5 flows into the inlet buffer 27 through the opening 32 while containing moisture and the like.

As shown in FIG. 5, in the inlet buffer unit 27 of the ultrasonic flowmeter 1 according to the second embodiment, the inlet unit 15 </ b> A of the measurement flow path unit 15 in the flow rate measurement unit 11 is the back side wall of the inlet buffer unit 27. It arrange | positions so that it may become above the opening part 32 formed in the surface part.
More specifically, the lower end edge of the inlet portion 15 </ b> A in the measurement flow path portion 15 is located above the upper opening edge of the opening portion 32 formed in the inlet buffer portion 27. In other words, in the ultrasonic flowmeter 1 according to the second embodiment, the lower edge height HB of the inlet portion (that is, the height of the lower end edge of the inlet portion 15A of the measurement flow path portion 15 when the lower surface of the meter case 3 is used as a reference). ) Is set larger than the opening upper edge height HA (that is, the height of the upper opening edge of the opening 32 when the lower surface of the meter case 3 is used as a reference) (see FIG. 5). In this case, the inlet center position LB is located above the opening center position LA.

  Therefore, according to the ultrasonic flowmeter 1 according to the second embodiment, in the process of flowing from the opening portion 32 of the inlet buffer portion 27 to the inlet portion 15A of the measurement flow path portion 15 positioned above the fuel gas, Gravity acts on the contained moisture and the like. Due to the action of the gravity, moisture and the like contained in the fuel gas are stored in the lower portion of the inlet buffer portion 27 without reaching the inlet portion 15A of the measurement flow path portion 15, and only the fuel gas is stored. Then, it flows into the inlet portion 15A of the measurement flow path portion 15.

  Furthermore, as shown in FIG. 5, by configuring the inlet lower edge height HB to be larger than the opening upper edge height HA, the measurement flow is increased above the opening 32 inside the inlet buffer part 27. The inlet portion 15A of the passage portion 15 is positioned, and the distance between the opening portion 32 in the vertical direction and the inlet portion 15A of the measurement flow path portion 15 can be made sufficiently large. Thereby, according to the ultrasonic flowmeter 1, even when moisture or the like is contained in the fuel gas, the process of the fuel gas from the opening 32 to the inlet 15A of the measurement channel 15 Thus, gravity can be applied to moisture and the like for a sufficient period of time, so that entry of moisture and the like into the measurement channel portion 15 can be reliably suppressed. Then, according to the ultrasonic flow meter 1, by suppressing the entry of moisture and the like into the measurement flow path portion 15, the occurrence of a decrease in measurement accuracy due to the moisture and the like is reliably prevented, and the fuel gas It is possible to maintain the measurement accuracy related to the flow rate.

  As described above, the ultrasonic flow meter 1 according to the second embodiment is similar to the ultrasonic flow meter 1 according to the first embodiment in that the inlet buffer unit 27 and the outlet buffer unit 29 inside the meter case 3 To the fuel gas flowing in the measurement flow path portion 15 from the inflow port 5 toward the outflow port 6. Thus, the flow rate of the fuel gas can be measured by propagating ultrasonic waves from the pair of ultrasonic transducers 12A and 12B.

  As shown in FIG. 5, in the ultrasonic flowmeter 1 according to the second embodiment, the inlet portion 15 </ b> A of the measurement flow path portion 15 is provided inside the inlet buffer portion 27, as in the first embodiment. It arrange | positions so that it may become above the opening part 32 formed in the buffer part 27. FIG. For this reason, when flowing into the inlet buffer 27 through the opening 32, the fuel gas flows upward against gravity and flows into the inlet 15 </ b> A of the measurement flow path 15.

  That is, according to the ultrasonic flowmeter 1, even when moisture or the like is contained in the fuel gas, the fuel gas is in the process from the opening portion 32 to the inlet portion 15 </ b> A of the measurement flow path portion 15. Gravity can be applied to moisture and the like, and therefore, moisture and the like can be prevented from entering the inside of the measurement channel section 15. Then, according to the ultrasonic flow meter 1, by suppressing the entry of moisture and the like into the measurement flow path section 15, it is possible to prevent the occurrence of a decrease in measurement accuracy related to the flow rate of the fuel gas caused by the moisture and the like. The measurement accuracy related to the flow rate of the fuel gas can be maintained.

  In the ultrasonic flowmeter 1 according to the second embodiment, the inlet portion 15A of the measurement flow path portion 15 is above the center (that is, the opening portion center C) in the opening portion 32 formed in the inlet buffer portion 27. (Refer to FIG. 5). That is, even when the fuel gas contains moisture or the like, the moisture or the like does not flow against the gravity up to a position above the inlet portion 15A of the measurement flow path portion 15; It cannot enter the inside of the inlet portion 15 </ b> A of the measurement flow path portion 15. As a result, according to the ultrasonic flowmeter 1, it is possible to more reliably suppress the entry of moisture and the like into the measurement flow path portion 15, and thus, relates to the flow rate of the fuel gas caused by the moisture and the like. The occurrence of a decrease in measurement accuracy can be prevented, and the measurement accuracy relating to the flow rate of the fuel gas can be maintained.

  Further, in the second embodiment, the inlet lower edge height HB is set to be larger than the opening upper edge height HA, and the lower end edge of the inlet 15A of the measurement channel 15 is the inlet buffer 27. It is located above the upper end edge of the opening 32. That is, even when the fuel gas contains moisture or the like, the moisture or the like passes through the upper end edge of the opening 32 in the inlet buffer portion 27 and further enters the inlet portion in the measurement flow path portion 15 above. If it does not flow against the gravity up to a position above the lower end edge of 15A, it cannot enter the inside of the inlet portion 15A of the measurement flow path portion 15. As a result, according to the ultrasonic flowmeter 1, it is possible to secure a sufficient distance to flow against gravity, and thus more reliably suppress the entry of moisture and the like into the measurement flow path unit 15. Therefore, it is possible to prevent the measurement accuracy of the fuel gas flow rate from being reduced due to the moisture or the like. That is, according to the ultrasonic flow meter 1, the measurement accuracy relating to the flow rate of the fuel gas can be maintained in a desired state at the time of design, for example.

  In the above-described embodiment, the ultrasonic flow meter 1 is an example of the ultrasonic flow meter in the present invention, and the meter case 3 is an example of the meter case in the present invention. And the inflow port 5 is an example of the inflow port in this invention, and the outflow port 6 is an example of the outflow port in this invention. The flow rate measurement unit 11 is an example of the flow rate measurement unit in the present invention, and the measurement flow path unit 15 is an example of the measurement flow path unit in the present invention. The ultrasonic transducer 12A and the ultrasonic transducer 12B are examples of the ultrasonic transducer in the present invention. The inlet buffer unit 27 is an example of an inlet buffer unit in the present invention, and the outlet buffer unit 29 is an example of an outlet buffer unit in the present invention. And the opening part 32 is an example of the opening part in this invention, and the inlet part 15A is an example of the inlet part in this invention.

  Although the present invention has been described based on the embodiments, the present invention is not limited to the above-described embodiments, and various improvements and modifications can be made without departing from the spirit of the present invention. For example, in the present invention, with respect to the vertical direction inside the inlet buffer portion, the inlet portion of the measurement flow path portion only needs to be positioned above the opening, and the direction perpendicular to the vertical direction (for example, the horizontal direction) And the front-rear direction), the positions of the inlet and the opening can be changed as appropriate. When determining the position of the inlet and the opening in the direction perpendicular to the vertical direction (for example, the left and right direction and the front and rear direction), the fluid to be measured heading from the opening of the inlet buffer to the inlet of the measurement channel It is desirable to determine that the flow path is as long as possible. By determining in this way, gravity can be sufficiently applied to moisture or the like contained in the fluid to be measured going from the opening of the inlet buffer portion to the inlet portion of the measurement channel portion. Intrusion of moisture or the like into the interior of the passage can be more reliably suppressed.

  In the embodiment described above, the inlet buffer 27, the central space 28, and the outlet buffer 29 are formed inside the meter case 3. However, the present invention is not limited to this mode. . It is sufficient that the inlet buffer portion and the outlet buffer portion in the present invention are formed inside the meter case, and the central space portion 28 may be omitted.

  Further, in the flow rate measurement unit 11 in the above-described embodiment, the ultrasonic vibrator 12A is disposed on the upstream side of the gas flow direction F on the upper surface side of the measurement flow path section 15, and the ultrasonic vibration is provided on the downstream side of the gas flow direction F. Although the configuration is such that the child 12B is disposed, the configuration is not limited to this configuration. Various configurations can be adopted as long as the ultrasonic transducer 12 </ b> A and the ultrasonic transducer 12 </ b> B can transmit and receive ultrasonic waves and can measure the propagation time of the ultrasonic waves.

DESCRIPTION OF SYMBOLS 1 Ultrasonic flow meter 3 Meter case 5 Inflow port 5A Inflow path 6 Outlet 11 Flow rate measurement unit 12A Ultrasonic vibrator 12B Ultrasonic vibrator 15 Measurement flow path part 15A Inlet part 15B Outlet part 27 Inlet buffer part 29 Outlet buffer part 32 Opening LA Opening center position LB Inlet center position HA Opening upper edge height HB Inlet lower edge height

Claims (3)

A meter case having an inlet for the fluid to be measured and an outlet for the fluid to be measured;
A flow rate measuring unit that is disposed inside the meter case and measures a flow rate of the fluid to be measured that passes through the meter case through the inlet and the outlet, and
The flow rate measuring unit is
A measurement flow path section through which the fluid to be measured flows from the inlet to the outlet;
A pair of ultrasonic transducers respectively disposed on the upstream side and the downstream side of the flow of the fluid to be measured in the measurement flow path unit,
The meter case is
The inner wall portion has an opening that is an end portion of an inflow path extending from the inlet, and the fluid to be measured that has flowed through the inlet and the opening flows into the inlet of the measurement channel portion. An inlet buffer section partitioned into a substantially box-like shape,
An outlet buffer that communicates with the outlet and is partitioned in a substantially box shape so that the fluid to be measured that has flowed out from the outlet of the measurement flow path portion flows out of the meter case through the outlet. And
The inlet part of the measurement channel part is
The ultrasonic flowmeter is located above the opening in the inlet buffer. The inlet part of the measurement channel part is
The ultrasonic flowmeter according to claim 1, wherein the ultrasonic flowmeter is located above a center of the opening of the inlet buffer. The lower end edge at the inlet portion of the measurement channel portion is
The ultrasonic flowmeter according to claim 1, wherein the ultrasonic flowmeter is located above an upper end edge of the opening portion of the inlet buffer portion.

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