JPH11325994A - Ultrasonic flow-meter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ultrasonic flow-meter which has a large flow passage sectional area, is capable of a high accuracy measurement and can be made compact. SOLUTION: A tubular center cone 16 is concentrically disposed in a tubular case 1 open at both ends, a tubular partition 12 is disposed between the case 1 and center cone 16 to form a plurality of flow passages in a multiple condition, sensor case rings 4, 5 are fitted and set in both end openings of the case 1 and have a set of ultrasonic wave transmitter/receiver sensors 26A, 26B, 27A, 27B opposed on extension lines of the flow passages 15, 17, and ring-like cover flanges 6, 7 are fitted and mounted on the outsides of both sensor case rings 4, 5.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to an ultrasonic flowmeter.

[0002]

2. Description of the Related Art Conventionally, as shown in FIG.
One flow path 1 having an annular cross section formed by 1, 102
03, the fluid to be measured is caused to flow along the direction of the tube axis, and one of a pair (a pair) of ultrasonic emission / reception sensors 104 is connected to the inner tube 10.
1 and the other 105 is placed on the outer tube 102 and launches the ultrasonic waves 106 obliquely across the flow,
An ultrasonic flowmeter is known which calculates and calculates a flow rate from a linear average flow velocity connecting between the transmitting and receiving sensors.

[0003]

In the above-described ultrasonic flowmeter, since the flow rate is calculated from the linear average flow velocity as described above, the fluid flowing in the flow path needs to be in a rectified state. is there.

The flow path formed between the wall surfaces of the pipe as described above has a high rectifying effect. To rectify the flow, the flow path width (length between the wall surfaces) is determined by the flow path length (tube axis). (Length in direction) L needs to be about 1/10.

Further, in order to make a flow meter of a large capacity, it is necessary to increase the cross-sectional area of the flow passage.
Therefore, in the above conventional flow meter, in order to increase the capacity, the flow path must have a narrow flow path width H and a large-diameter circular cross section, and the flow meter becomes large in the radial direction. On the other hand, when the flow path width H is increased, the flow path length L is also increased, and there is a problem that the flow path becomes larger in the tube axis direction.

[0006] Further, in the conventional arrangement in which the transmission / reception sensor is disposed in the inner and outer tubes, an opening for assembling these internal devices is formed in the middle of the outer tube 102, and a cover is placed on the opening. It is necessary to attach the case or divide the case, and there is also a problem that the flowmeter becomes large.

Therefore, the present invention aims at reducing the size of the flow meter,
It is an object of the present invention to provide an ultrasonic flowmeter particularly suitable for a large-capacity flowmeter.

[0008]

According to a first aspect of the present invention, a cylindrical central cone is disposed in a cylindrical case having both ends opened, and the case and the case are connected to each other. A cylindrical partition plate is arranged between the central cones, a plurality of flow paths are formed in an overlapping state between these, a sensor case ring is fitted and attached to both ends of the case, and both sensor case rings are fitted. And a pair of ultrasonic transmission / reception sensors which are located on an extension of at least one of the flow paths and are opposed to each other.

In the present invention, a plurality of flow paths are formed to have a narrow width so that a rectifying effect can be obtained for each of the flow paths, and the flow paths are superimposed, so that a high-accuracy flow rate measurement can be performed by the ultrasonic transmission / reception sensor. In addition, a large flow path cross-sectional area can be ensured by the plurality of flow paths. Therefore, it is possible to achieve a large capacity and downsizing in the radial direction.

The fact that the width of the flow path can be reduced as described above can also shorten the length of the flow path. for that reason,
A large capacity and downsizing in the tube axis direction can be achieved. Therefore, a large-capacity, high-accuracy, and more compact flowmeter can be formed.

According to a second aspect of the present invention, a cylindrical central cone is arranged in a cylindrical case having both ends opened, and a cylindrical partition plate is arranged between the case and the central cone. A plurality of flow paths are formed in a superimposed state by these gaps, and a sensor case ring is fitted and attached to both ends of the case, and at least one of the flow paths is extended to both of the sensor case rings. A pair of ultrasonic transmission / reception sensors are provided facing each other on the line, and furthermore, ring-shaped lid flanges are fitted and mounted on the outside of the two sensor case rings at both open ends of the case. It is assumed that.

According to the present invention, the same action as described above can be exhibited, and the center cone, the partition plate and the sensor case ring can be inserted and fitted from both ends of the case and internally assembled. In this way, an assembly opening is provided in the center of the case and a lid is provided on it, or the flow meter is more compact than one that divides the case, and the structure of the case is simpler and the processing is easier. It will be easier.

Further, according to the above structure, since the inflow side and the outflow side can be formed in the same structure, the restriction on the connection direction of the case to the pipe can be eliminated, and the installation of the case can be improved. Can be.

Further, by attaching the ring-shaped lid flange, the flow path is narrowed at the lid flange portion, so that the piping displacement and the protrusion of the packing at the piping flange portion formed on the outer periphery of the lid flange are performed. Also, the disturbance of the flow of the fluid is reduced, and the accuracy of the flow rate measurement can be improved.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described based on an embodiment shown in FIGS. 1 and 2 show a first embodiment.

The case 1 constituting the ultrasonic flowmeter is formed in a cylindrical shape having both ends opened, and flanges 2 and 3 are integrally formed on the outer periphery of both ends. Sensor case rings 4 and 5 are fitted and mounted on the inner peripheral surfaces of both ends of the case 1. Ring-shaped lid flanges 6 and 7 formed separately from the flanges 2 and 3 are fitted to the outer sides of the two sensor case rings 4 and 5 in the tube axis direction. Has been blocked. The lid flanges 6 and 7 and the flanges 2 and 3 are axially positioned by steps 8 and 9 and are sealed by O-rings 10 and 11.

The flow openings 6 in the lid flanges 6 and 7
The inner peripheral surfaces 6b, 7b forming the a, 7a are formed to have the same diameter as the inner surfaces of the sensor case rings 4, 5, and
The outer peripheral surface is formed on the tapered surfaces 6c, 7c that expand outward. That is, both the distribution ports 6a and 7a are narrowed inward. The aperture diameter is, for example, φ8
Squeeze from 0 to φ70.

Inside the case 1, a partition plate 12 formed in a cylindrical shape having a smaller diameter than the inner diameter of the case 1 is arranged concentrically with the case 1. The axial length of the partition plate 12 is set such that flow portions 13 and 14 are formed on the end surface of the partition plate 12 and the inner end surfaces of the sensor case rings 4 and 5. Further, the partition plate 12 is formed of a thin plate, the diameter of its outer peripheral surface and the first passage 15 of the narrow channel width H ₁ as rectifier effect is obtained between the inner peripheral surface of the case 1 is formed It is set to be.

Inside the cylindrical partition plate 12, a cylindrical central cone 16 is arranged concentrically with the case 1 and the partition plate 12, and its outer diameter is equal to the outer peripheral surface thereof and the partition plate 12. the second flow path 17 of the narrow channel width H ₂ as rectifier effect is obtained is set to be formed in the inner circumferential surface 12.

For example, the inner diameter of the case 1 is set to φ110, the thickness of the partition plate 12 is set to 2 mm, the outer diameter is set to φ94, the inner diameter is set to φ92, and the outer diameter of the central cone 16 is set to φ76. It is set to form a channel width H ₁ of the first channel 15 a channel width of H ₂ second flow path 17, respectively 8 mm.

[0021] With the above configuration, the channel width H ₁ is narrow donut-shaped first flow path 15 of the (annular) second flow path 17 of the channel width H ₂ is small donut-shaped (annular) polymerization Thus, a double circular pipe flow path is formed.

At both ends of the central cone 16, the outer surfaces in the axial cross section are formed as guide surfaces 16a, 16b of concave arc surfaces.
Cone portions 16c and 16d are formed, and flow portions 18 and 19 are formed between the guide surfaces 16a and 16b and the sensor case rings 4 and 5, respectively.

The flow parts 13, 18, and 14, 19 have three rectifying plates 20, 21, 22 arranged in the axial direction, respectively.
And 23 (24, 25) are provided at equal intervals in the circumferential direction.
2 and the central cone 16 are held in place.

A pair of ultrasonic transmission / reception sensors 26A and 26B are housed in the two sensor case rings 4 and 5 and located opposite to each other and extended on both ends of the first flow path 15,
The pair of ultrasonic sensors 26A and 26B calculate the flow rate of the fluid flowing through the first flow path 15 from the flow rate as is well known.

Further, another pair of ultrasonic emission / reception sensors 27A and 27B located on the extension of both ends of the second flow path 17 are provided.
Are housed in the sensor case rings 4 and 5 and face each other.
By B, the flow rate of the fluid flowing in the second flow path 17 is calculated from the flow rate as is well known.

The sensor case rings 4 and 5 are provided with holes 4a and 5a for passing ultrasonic waves. Each of the above-mentioned sets of transmission / reception sensors 26A, 26B and 27A, 27B
Is set at an arbitrary position in the circumferential direction.

The flanges 2 and 3 have bolt holes 28 and 2 respectively.
9 are formed. In FIG. 1, reference numerals 30 and 31 denote packings. With the above structure, one of the cases 1 is set to the inflow side and the other is set to the outflow side. The shapes of the one flange 2, the cover flange 6 and the sensor case ring 4, and the other flange 3 and the cover flange 7 are provided. The shape of the sensor case ring 5 is formed symmetrically in the axial direction (the left-right direction in FIG. 1), and can be connected to the pipe regardless of which side is the inflow side.

With the above structure, when assembling, the one sensor case ring 4 containing the one transmission / reception sensor 26A, 27A is fitted into the case 1 through one opening of the case 1. At the same time, one lid flange 6 is fitted and mounted on the case 1. Also, the other sensor case ring 5 containing the other transmitting / receiving sensors 26B and 27B is fitted and mounted in the case 1 through the other opening of the case 1 and the other lid flange 7 is fitted and mounted in the case 1. To assemble.

The flange 2 is connected to the upstream piping (not shown) with a packing 30 and a bolt through a bolt hole 28, and the reference B is connected to the upstream piping (not shown). The case 1 is installed by connecting the flange 3 as an outflow side to a downstream pipe (not shown) with a packing 31 interposed therebetween and a bolt through a bolt hole 29. By this connection, the case 1 and the piping are connected to the packing 3
Sealed by 0, 31 and lid flanges 6, 7 are more firmly assembled.

When the case 1 is installed, it is desirable to install the display unit 32 in a direction that makes it easy to see. In the present embodiment, the flanges 2 and 3 of the entrance and exit are formed in a symmetrical shape as described above so that any one of them can be connected to the pipe as an inlet or an outlet. 1 can be connected to the piping. In this case, at the time of initial installation, a function is provided in which the flow meter automatically determines the inflow direction and operates normally in the flow direction.

By doing so, there is no restriction on the installation direction of the case 1, and the installation work can be performed easily and without errors. That is, in a case where the installation direction (direction of the entrance side) is restricted, there is a possibility that the installation direction may be erroneous, and the display unit must be mechanically rotated and turned. There is a problem that it is necessary to ensure its rotation mechanism, waterproofness, etc. According to the present embodiment, such a problem can be solved.

When the fluid to be measured flows, the fluid flows into the tapered surface 6 c at the inlet 6 a of the lid flange 6.
It is squeezed and flows in. The reason for forming the aperture in this way is that
Since the measurement area of the transmission / reception sensors 26A and 26B and 27A and 27B is a part of the narrow donut-shaped flow paths 15 and 17, the drift will adversely affect the measurement accuracy. In this way, the deviation due to the displacement of the pipe or the protrusion of the packing is reduced, and the measurement accuracy is improved.

The fluid that has flowed in as described above
After the flow is divided into the first flow path 15 and the second flow path 17 through the flow paths 8 and 13, the flow paths 14 and 1 flow through the flow paths 15 and 17.
9 flows out of the outlet 7a of the lid flange 7 to the downstream pipe.

In the above-mentioned fluid flow state, ultrasonic waves are transmitted and received from one set of the light emitting and receiving sensors 26A and 26B, and the linear average flow velocity between the light emitting and receiving sensors in the first flow path 15 is known. And the flow rate of the first flow path 15 is calculated and obtained. Further, the other set of the transmission / reception sensors 27A, 2A
7B, the second flow path 1 is transmitted and received as is well known.
From the line average flow velocity between the transmitting and receiving sensors in
The flow rate in the flow path 17 is calculated and obtained. Then, the total flow rate is obtained by summing the flow rates in the two flow paths 15 and 17.

At this time, the fluid flowing through the _two flow paths 15 and 17 has a narrow flow path width H ₁ and H ₂ , so that the flow becomes a rectified uniform flow in each flow path, and a highly accurate flow rate is obtained. You can ask.

When both the first flow path 15 and the second flow path 17 generate a uniform flow at the same flow rate, only one set of transmission / reception sensors is installed on only one of the flow paths. Alternatively, the overall flow rate may be determined from the flow rate of one of the flow paths.

Further, even when the transmitting / receiving sensor is provided for each flow path, a plurality of sets may be provided for each flow path. The chain lines 26c and 27c in FIG. 1 show the installation state in this case. FIG. 3 shows a second embodiment.

In the second embodiment, the partition plate 12 in the first embodiment is a cylindrical partition plate 40 having a large thickness, and a first flow passage similar to that described above is provided between the partition plate 40 and the case 1. 15, a second flow path 17 similar to that described above is formed between the partition plate 40 and the central cone 41, and tapered surfaces 40a, 41
a, a sensor case ring 42 is disposed between the tapered surfaces 40a and 41a and on an extension of the second flow path 17, and the transmission / reception sensor 27A of the first embodiment is mounted on the sensor case ring 42. It is stored. As shown in FIG. 3, the tip of the central cone 41 has a tapered tip surface 41 b that guides the flow of the fluid to the inside of the sensor case ring 42.
The intermediate tapered surface 41c and the small diameter portion 41d are continuously formed.

In the drawing, only the right side of the case 1 is shown, and the left side of the case 1 is also formed symmetrically. The receiving sensor 27B (not shown) is facing.

Since other structures are the same as those of the first embodiment, the same portions are denoted by the same reference numerals and description thereof will be omitted. In the second embodiment, the same operation and effect as those of the first embodiment can be exhibited.

In each of the above embodiments, one cylindrical partition plate 17 and 40 is used. However, a plurality of such cylindrical partition plates are provided at appropriate intervals (flow path widths). Provided in
Two or more flow paths may be provided in a multiplex manner.

[0042]

As described above, according to the first aspect of the present invention, the flow path cross-sectional area is large, high-precision measurement can be performed, and the flowmeter can be made more compact. Therefore, it is particularly effective for a large-capacity ultrasonic flowmeter.

According to the second aspect of the present invention, it is possible to further reduce the size of the flowmeter, facilitate the installation of the case, improve the accuracy of the flow measurement, and facilitate the manufacture of the case.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing a first embodiment of the present invention.

FIG. 2 is a sectional view taken along line CC in FIG.

FIG. 3 is a partial longitudinal sectional view showing a second embodiment of the present invention.

FIG. 4 is a schematic perspective view showing a conventional structure.

[Explanation of symbols]

1 ... Case 4,5,42 ... sensor case rings 6,7 ... Lid flange 12, 40 ... partition plate 15 ... first flow channel 16,41 ... central cone 17 ... second flow path H _1, H ₂ ... passage Width 26A, 26B, 27A, 27B ... Ultrasonic transmission / reception sensor

Claims (2)

[Claims] 1. A cylindrical central cone is disposed in a cylindrical case having both ends opened, a cylindrical partition plate is disposed between the case and the central cone, and a plurality of flow paths are formed between these. It is formed in a superimposed state, and a sensor case ring is fitted and attached to both ends of the case, and a pair of super-positions are provided on both sensor case rings on an extension of at least one of the flow paths. An ultrasonic flowmeter comprising an ultrasonic wave emitting / receiving sensor opposed thereto. 2. A cylindrical central cone is disposed in a cylindrical case having both ends opened, and a cylindrical partition plate is disposed between the case and the central cone. It is formed in a superimposed state, and a sensor case ring is fitted and attached to both ends of the case, and a pair of super-positions are provided on both sensor case rings on an extension of at least one of the flow paths. An ultrasonic flowmeter comprising a pair of sound wave emitting and receiving sensors facing each other, and a ring-shaped lid flange fitted to and mounted on both sensor case rings at both open ends of the case.