UA69589A - Demountable pipeline section with an ultrasonic flow rate meter - Google Patents

Abstract

The proposed demountable pipeline section with an ultrasonic flow rate meter, which is designed for measuring liquid flow rate by the difference of the propagation times of ultrasonic vibrations transmitted in opposite directions relative to the liquid flow, contains two trough openings that are made in the pipeline section wall and arranged in the same plane. In the said openings, transmit-receive ultrasonic transducers are installed. The detecting pad of each transducer is arranged at an angle to the longitudinal axis of the transducer. The center points of the detecting pads of the transducers are arranged at the level of the inside surface of the pipeline section. The detecting pads of the transducers are arranges so that acoustic coupling between the transducers is provided.

Description

Description of the invention

The invention relates to the field of measuring technology and can be used in various branches of the national 2 economy when measuring the flow rate, instantaneous or integral (volumetric) flow rates of liquid in fully filled (pressure) pipes.

There are known ultrasonic so-called (teigapvy flowmeters), which allow to estimate the flow rate M of a liquid in a pipe based on measurements of the propagation time of ultrasonic vibrations along the flow of the liquid and against the flow (see, for example, the book by A.Sh. Kiyasbeyla, A.M. Izmailov, V. M. Gurevich. Frequency-time ultrasonic 70 flowmeters and counters. Moscow, "Mashinostroenie", 1984.) Fluid consumption C (m/h) is calculated by multiplying the estimated fluid flow rate M (m/s) by the constant 360075, where 5 - the area of the internal cross-section of the pipe, and 3600 - the number of seconds in an hour. The advantages of flowmeters of this type are a significant service life due to the absence of moving parts, as well as an acceptable measurement error in a wide range of flow rates. t In the composition of the mentioned flowmeter, a recessed section is used, which represents it is equipped with flanges of a pipe segment with an internal diameter of OO. A pair of sensors is rigidly fixed in the cut-in section during manufacture in factory conditions. ikov should be oriented oppositely, at some angle f to the longitudinal axis of the pipe. 20 There are known recessed sections in which the sensors are located on the same or diametrically opposite sides of the pipe at some distance from each other along its longitudinal axis (see pages 44-46, fig. 23 of the book

A.Sh. Kiyasbeyly, A.M. Izmailov, V.M. Gurevich. Frequency-time ultrasonic flowmeters and counters.

Moscow, "Mashinostroenie", 1984). In these recessed sections, the ultrasonic signal on the way from the transmitting sensor to the receiving sensor crosses the fluid flow in the diametrical plane one or more times (with reflections from the inner surface of the pipe). 25 This device is analogous to the claimed one, as it also represents a mortise section. "

Common essential features are: ""- two receiving and transmitting sensors; n pipe segment; Ф n holes in the pipe wall; 30 n" sensors are installed in the holes.

The disadvantage of cut-in sections of this type is the relatively low accuracy of measuring the average flow speed, which is due to the fact that the averaging is not performed along a two-dimensional field of velocities (over the entire cross-sectional area of the pipe), but only along a line lying in the diametrical plane. Therefore, the measurements are accompanied by (o) hydrodynamic error, the value of which varies depending on the Reynolds number for the flow, which in turn depends on the flow speed, the roughness of the inner walls of the pipe, etc.

It is shown (see US patent Mo4.103.551) that for axisymmetric fluid flows, the hydrodynamic error can be almost completely eliminated if the ultrasound flow probe is performed along a chord crossing the pipe at a distance of half the inner radius from the longitudinal axis of the pipe. If there is no certainty about the axisymmetric nature of the flow, it is recommended to probe the liquid flow along several chords that do not lie in the same plane. c Such probing (along several chords) when using only one pair of receiving and transmitting sensors can be ensured if several metal reflectors (mirrors) are used to reradiate the ultrasonic signal in the pipe (see fig. 24, 25 on page 47 of the book mentioned above) authors A. Sh. Kiyasbeyli and others).

The mortise section is known according to the US patent Mo4.103.551, M. cl BO1E1/66, priority from 1.08.1978. (see also

Fu fig. 26 of the above-mentioned book by A.Sh. Kiyasbeyli et al.), in which sounding is performed along three chords lying in three planes, rotated relative to each other by an angle of 10 degrees. The section consists of two receiving and transmitting (se) sensors, four mirrors and a section of pipe, in both walls of which at a distance of Х! two through parallel holes are made relative to each other along the axial line, in which the first and second sensors are mounted on one side of the pipe, and the first and second mirrors are mounted on the other side, the third and fourth mirrors are mounted in the walls (o) at a distance along the axial line from the first mirror HER and 2x! respectively, so that the projections of the installation locations

The mirrors on the cross-section of the pipe are the vertices of an equilateral triangle. In the cut section, sensors are used in which the emitting plane is oriented normal (perpendicular) to the longitudinal axis of the sensor. All mirrors are appropriately oriented to ensure acoustic communication between the sensors.

Projections of the ultrasonic beam on the cross section of the pipe create an equilateral triangle, and the distance » of its sides from the center of the pipe reaches 0.25ХО, which helps to increase the accuracy of measuring the average flow speed due to the elimination of hydrodynamic error.

The advantages of the section according to the US patent Mo4.103.551 are high accuracy of measurements. The disadvantages of the section are: 60 a) the complexity of the design: all four mirrors must be oriented relative to each other with an error of 0.02-0.Tgrad.; b) each reflection of the acoustic signal from the mirror is accompanied by energy losses, which worsens the signal/noise ratio in the measuring path; c) a large number of reflections of the acoustic signal leads to the impoverishment of high-frequency components in b5 of its spectrum, which makes it difficult to fix the signal's course on the time axis; d) the presence of two "passive" shades on the path of propagation of the acoustic signal (from the corresponding sensor to the nearest mirror on the opposite wall of the pipe). These traces are oriented normal to the flow velocity vector, so the flow velocity has no effect on the acoustic signal propagation speed. For measurements, these shades are useless, but they contribute to the attenuation of the signal.

This device is analogous to the claimed one, as it also represents a cut-in section.

Common essential features are: "two receiving and transmitting sensors; n pipe segment, which is used as the main structural element of the section; n - two holes on one side of the pipe; 70 n" - sensors installed in holes; n" acoustic communication between the sensors is performed along three chords.

The closest to the claimed section is the cut-in section according to the Ukrainian patent Mo36757 A, IPC 6 СО1Е1/66, priority from 02.3.2000, which consists of two receiving-transmitting sensors, the radiating plane of which is oriented normal to the longitudinal axis, two mirrors and a pipe segment with an internal diameter O, in both walls of which along the axis line at a distance of Х! two through holes are made from each other, in which sensors are mounted on one side of the pipe, and mirrors are mounted on the other side, which are appropriately oriented to ensure acoustic communication between the sensors along three chords, while the holes are made so that their geometric axes intersect in the center of the pipe at an angle y, and the centers of the mirrors protrude to a height D above the inner surface of the pipe.

This section provides high measurement accuracy and is more reliable compared to the US patent section

Mo4.103.551, because the mirrors are raised to a height A above the inner surface of the pipe and are therefore more resistant to contamination.

The disadvantages of the section are: a) the complexity of the design due to the presence of two mirrors, which must be oriented in a certain way relative to each other; b) each of the four reflections of the acoustic signal (from the mirrors and from the inner surface of the pipe) is accompanied by energy losses, which worsens the signal/noise ratio in the measuring path; c) a large number of reflections of an acoustic signal leads to the impoverishment of high-frequency components in its spectrum, which makes it difficult to fix the signal path on the time axis; (o) d) the presence of two "passive" shades on the path of propagation of the acoustic signal (from the sensor to the nearest mirror on the opposite side of the pipe). These traces are oriented normal to the flow velocity vector, so the flow velocity has no effect on the acoustic signal propagation speed. For yuyu measurements, these shades are useless, but they make their contribution to the attenuation of the signal.

This section is a prototype in relation to the claimed device. Common essential features are: Ф n pipe segment, which is used as the main supporting element of the section; (Se) "two receiving and transmitting sensors; n« two holes in one pipe wall; n" holes are made normal to the longitudinal axis of the pipe; "n" - sensors installed in holes; n" acoustic communication between the sensors is performed along three chords. - c The task of the invention is to simplify the design of the cut-in section while simultaneously improving the signal-to-noise ratio in the measurement signal. "» 1. The recessed section, which consists of two receiving-transmitting sensors and a pipe segment with an internal diameter of 0, in one wall of which, at a distance of Ж! from each other along the axial line, two through holes are made normal to the axial line, in which are installed sensors, (22) which differs in that the axes of the holes lie in the same plane, the radiating plane of each sensor is oriented at an angle o to its longitudinal axis, the sensors are installed so that the centers of their radiating planes are at the same level as the inner surface of the pipe and oriented relative to each other in the appropriate 1 way to ensure acoustic communication. o 20 2. The recessed section according to item 1, which differs in that the distance between the centers of the holes is chosen according to the ratio: с Хх1 - 3 х (бу 4)х х тво

C. The recessed section according to paragraphs 1 and 2, which differs in that, to ensure acoustic communication, the sensors are installed so that the projection on the horizontal plane of the normal to the radiating plane of the sensor forms an angle D with respect to the longitudinal axis of the pipe:

Р» in - agssov y - 1 LZ x 92907 -- oo) 4. The recessed section according to item 1, C, which differs in that the angle of inclination of the radiating plane of the sensor in relation to its longitudinal axis lies in the range from 30" to 60". 60 Figs. 1 and 2 show the drawings of the claimed cut-in section. A sketch of the sensor is shown in Fig. 3a (general view) and Fig. 3b (cross section). Figure 4 shows the relative location of the sensors in the recessed section (top view).

According to Fig. 1, the cut-in section consists of a pipe segment 1 and two receiving and transmitting sensors 2 and 3. For installation in the pipeline, the section is equipped with two flanges (on the edges of the pipe segment). Sensors 2 and C are mounted in the pipe section so that the centers of their radiating planes are at the same level as the inner surface of the pipe. To prevent mechanical damage to the sensors, they are protected by nozzles 4 and 5, which are rigidly attached to the pipe (for example, by electric welding). In Figures 1 and 4, the numbers 6 and 7 indicate the areas on the inner surface of the pipe section where the signal is reflected.

The principle of operation of the mortise section is as follows. The propagation path of the acoustic signal is shown in fig. 1 and 4. When measuring the propagation time of the ultrasonic signal in the first direction (for example, along the flow of liquid), the ultrasonic signal created by sensor 2 spreads through the liquid to area 6, is reflected from the metal and is directed to area 7. from area 7, the signal is received by sensor 3. 70 When measuring the propagation time of an ultrasonic signal in another direction, the radiation and reflection of the signal is performed in the reverse order.

The propagation path of the acoustic signal in relation to the longitudinal axis of symmetry of the recessed section is the angle ф: 1 pa

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The value Ф is necessary for calculating the conversion factor of the flow meter.

Figure 2 shows a projection on the cross-section of the pipe of the ultrasonic signal propagation path between the first 2 and the second Z sensors. The projection is an equilateral triangle. Probing of the liquid flow is performed along three chords.

Figure 2 shows the relative orientation of the sensors. Sensors 2 and C should be installed in the pipe so that the maxima of their directional diagrams are directed towards each other at an angle of 9 to the longitudinal axis of symmetry of the pipe.

The advantages of the mortise section, which is claimed, are as follows. 1. Since the sensing of the liquid in the pipe is performed along three chords, a small level of hydrodynamic errors is ensured. « 2. The length of the ultrasonic signal propagation path between the sensors is less than in the prototype, as there are no "passive" shades. This guarantees a more favorable measurement signal energy.

Q. The design of the section is simplified compared to the prototype, as there are no mirrors. Adjustment of the Fo section is ensured by turning sensors 2 and 3.

At this time, the installation batch of cut-in sections for UVR-O11, 00 flow meters-counters has been released from production and has successfully passed the approval. yu

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Claims (2)

29 Formula of the invention " 1. The recessed section, which consists of two receiving-transmitting sensors and a section of pipe with an internal diameter О, in one wall of which, at a distance Ж x Ж from each other along the axial line, two through holes normal to the axial line are made, in which installed sensors, which differs in that the axes of the holes lie in the same plane, the radiating plane of each sensor is oriented at an angle A to its longitudinal d) axis, the sensors are installed so that the centers of their radiating planes are at the same level with the inner surface of the pipe and are oriented relative to each other in an appropriate manner to ensure acoustic communication. 2. Mortise section according to claim 1, which differs in that the distance between the centers of the holes is chosen according to the /Ф) ratio: щ Ге) Хх - заз х (Ол 4)х ХХ ДИ VOO ДЯ Z. The recessed section according to claims 1 and 2, which differs in that, to ensure acoustic communication, the sensors are installed so that the projection on the horizontal plane of the normal to the radiating plane of the sensor forms an angle of 4 with respect to the longitudinal axis of the pipe: th с В - agssoye 4-13 x 19 90 -с "» 4. Cut-out section according to claims 1-3, which differs in that the angle A of the inclination of the radiating plane of the sensor in relation to its longitudinal axis lies in the range from 30" to 60 ". Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated (22) microcircuits", 2004, M 9, 15.09.2004. State Department of Intellectual Property of the Ministry of Education and Social Science of Ukraine. 1 (ee) iChe) 60 b5