RU58128U1 - COMPLEX OF MEASUREMENT OF COMPONENT EXPENDITURE OF GAS-FLUID FLOW - Google Patents

Abstract

The utility model can be used in the oil industry to control the flow rate of oil wells. The proposed complex contains three coaxially mounted high-frequency resonators, each of which is equipped with two mutually orthogonal I / O, short-circuited limiting and short-circuited limiting-separation coils, a temperature sensor, a computational-control unit, a controlled high-frequency generator, a controlled switch, a mode controller, input amplifiers as well as six transceiver paths, each containing two isolation capacitors, an input amplifier, an amplitude detector analog-to-digital converter. The utility model makes it possible to measure the relative content of its components in two mutually orthogonal directions based on the method of radio-frequency RF sounding of a controlled flow in two mutually orthogonal directions, and also, using the method of autocorrelation velocity measurement, determine the flow velocity and calculate the component-wise volumetric flow rate of a gas-liquid medium using these measurements. The analysis of the gas-liquid medium flow regime performed in the mode controller makes it possible to reliably determine the component-wise flow rate even with a substantially unsteady flow, and the mutually orthogonal sounding method of the controlled medium used in the complex provides the possibility of measurements even in a fully steady flow of a homogeneous medium when there are no local inhomogeneities in the controlled flow component composition. If necessary, the complex can, using information from a temperature sensor, calculate and transmit information to an external system about the component-by-mass flow rate of a gas-liquid medium.

Description

The proposed utility model relates to measuring technique and can be used in the oil industry to control the flow rate of oil wells.

A known system for measuring the component flow rate of a multiphase flow of oil wells containing oil, gas and water (see RF patent No. 2270981, IPC G 01 F 15/08, G 01 F 1/74, G 01 F 1/84, E 21 B 47 /10).

This system contains a separator that separates the gas and liquid components of the controlled stream, as well as a microwave moisture meter that determines the water content in the liquid component by radio wave sensing.

The disadvantage of this system is the impossibility of determining the component composition of a multiphase flow without prior separation: mechanical separation into gas and liquid fractions.

Free from this drawback are systems for measuring the component flow rate of a three-component gas-liquid flow, containing a radio wave sensor of component composition of the stream, a microwave generator, and a computing and control unit (see RF patent No. 2063615, IPC G 01 F 1/56, RF patent No. 43068, IPC G 01 F 1/74 and RF patent No. 2275604, IPC G 01 F 1/74). These systems do not require separation of the gas-liquid stream, however, they have another drawback: the impossibility of reliable radio-wave sounding of the controlled stream in the presence of salt water in it. This disadvantage is due to the attenuation of microwave radio waves of a microwave generator of known systems in substantially conductive salt water. Since the content of salts dissolved in borehole water is tens of grams per liter, borehole water has high electrical conductivity, which makes it virtually non-transparent for microwave radiation and does not allow reliable radio monitoring of water content at ultrahigh frequencies.

Closest to the proposed utility model by technical nature

and the achieved result is a well-known complex of measuring the component flow rate of a multicomponent gas-liquid flow, which includes a radio wave sensor containing high-frequency resonators, each of which is a zigzag conductor in the form of a winding from a copper wire, and an electronic computer-control device containing a computer-control unit and a controlled high-frequency generator, which is used as a controlled frequency synthesizer (see the application for etenie RF №2002100228 / 28, IPC G 01 F 1/00, G 01 F 5/00). This complex is taken as the closest analogue (prototype) of the proposed utility model.

The well-known complex is based on two measurement methods. To measure the component composition of the flow, the method of high-frequency radio wave sounding of a controlled medium using a high-frequency resonator was chosen; In this method, as informative parameters of the signal about the component-wise composition of the controlled medium, the parameters of the resonant absorption of the high-frequency electromagnetic field by this medium at several resonant frequencies, for example, at two resonant frequencies F _res1 , F _res2 lying in the high-frequency range, are used.

To measure the speed of a controlled flow in a known complex, an autocorrelation method of measuring speed was selected based on measuring the transit time of a certain base length of a radio wave sensor by local heterogeneity of the component composition of the stream; the indicated time is determined either by the maximum of the mutual correlation function (VKF) of the temporal realizations of two radio wave RF signals characterizing this heterogeneity, or by the minimum of the discriminatory characteristic, which is the first derivative of the temporal realization of one of these signals and the temporal realization of the other of these signals.

The composition of the radio wave sensor of this complex includes sequentially installed first and second open radio wave cylindrical high-frequency resonators, each of which is equipped with a separate input and a separate output, and the electronic computing and controlling device of this complex includes a computing and controlling unit,

a controlled high-frequency generator, an input amplifier, as well as two transmission paths, each of which is a series-connected input amplifier, an amplitude detector, and an analog-to-digital converter.

The output of the first and the output of the second open radio wave cylindrical resonators of the known complex are each connected to one of the corresponding inputs of the computing and control unit through one of the respective transmission paths, and the input of the first and input of the second resonators are connected to the output of the controlled high-frequency generator through the input amplifier, the input and output each of the aforementioned resonators are each connected to one of two different diametrically opposite points of the zigzag a short-circuited conductor of the corresponding resonator. Each of the two open radio-wave cylindrical high-frequency resonators of the known complex is a winding of copper wire, zigzag mounted on the outer cylindrical surface of the dielectric tube of this high-frequency resonator, which is coaxially mounted inside the tubular metal casing of this high-frequency resonator.

Due to the fact that the known complex uses a high-frequency electromagnetic field as a probing radio wave signal, it makes it possible to probe a gas-liquid flow at a relatively low frequency compared to microwave radiation and thereby makes it possible to reliably control the parameters of a gas-liquid flow even if it contains salt water.

However, the disadvantage of this complex is the high measurement error of the component-wise flow rate that occurs in each of the two extreme flow regimes of the controlled flow: in an unsteady flow and, conversely, in a steady flow.

With a substantially unsteady flow of a gas-liquid medium, typical of most domestic oil wells, the component composition and flow rate quickly and chaotically change over time, resulting in an error caused by fast and chaotic changes

flow regime, can reach significant values.

As for the wells operating in a fully steady flow mode, in which the component composition and flow rate remain almost unchanged, and the controlled medium is an almost uniform finely divided mixture of individual components, the use of the well-known complex in such wells is difficult, since it is the basis of its work autocorrelation radio wave method for measuring flow velocity using unidirectional radio wave sensing iruemoy environment is valid only if the controlled flow pronounced local inhomogeneities component composition, which are not under steady flow.

The objective of the proposed utility model is to increase the reliability and accuracy of measuring the component flow rate for unsteady and steady flow of a controlled environment.

To solve this problem, a complex for measuring the component flow rate of a gas-liquid flow, which includes coaxially arranged first and second resonators, each of which is a short-circuited zigzag conductor having the shape of a rectangular meander, placed on the outer cylindrical surface of the dielectric pipe mounted inside the tubular metal casing coaxially him, a controlled high-frequency generator, an input amplifier, a control unit, two in front channels, a temperature sensor installed in the housing, the output of each of which is connected to the input of the control unit, each of which is connected through one of the transmitting paths to one of the inputs of the control unit, the output of which is connected to the input of the controlled high-frequency generator, and each of the transmission paths is a series-connected output amplifier, amplitude detector and analog-to-digital converter.

New in relation to the prototype is that the complex additionally introduced a third resonator mounted coaxially with the first and second

resonators on a dielectric tube inside the housing, each of the three resonators is equipped with a first input-output and a second input-output orthogonal to it, the first input-output and the second input-output of each resonator lying in diametrical mutually perpendicular planes. In addition, four transmitting paths identical to the two first transmitting paths, a mode controller, an input amplifier and a controlled switch connected to the output of the controlled high-frequency generator, equipped with two outputs, each of which is connected to the input of one of the input amplifiers, are additionally connected and connected its control input to the computing control unit. Each of the six transmission paths of the complex is additionally equipped with an input and two dividing capacitors interconnected at a common point, one of which is connected to the input of the output amplifier, and the other to the input of this transmission path, each of the transmission paths together with those introduced into it Separating capacitors are separately shielded and form a transmit-receive path. Each input-output of each resonator of the complex is connected to only one of the transceiver paths - to the common point of its isolation capacitors, while the output of each transceiver path is the output of an analog-to-digital converter connected to one of the inputs of the computer-control unit. Each of the transceiver paths connected to the first input-output of one of the resonators is connected by its input to one of the input amplifiers, and each of the other transceiver paths is connected to another input amplifier, while the output of each of the transceiver paths of the third the resonator is additionally connected to one of the inputs of the mode controller, the output of which is connected to the computing and control unit. For a clear fixation of the spatial boundaries of the electromagnetic field excited in each of the resonators, a limit coil is installed at the end sections of the dielectric tube, and a boundary-separation coil is installed between the resonators, while the cross-section of the restriction coil, restrictive separation coil, and zigzag conductor of each resonator is has a rectangular shape.

The work of the proposed complex is illustrated by Figures 1, 2, 3, 4 and 5.

Figure 1 presents a functional diagram of the proposed complex, Figure 2 is a scan of the resonators, Figure 3 is a cross section of a zigzag resonator conductor, Figure 4 is a cross section of a resonator, and Figure 5 is a structural diagram of a transceiver path.

In Figures 1, 2, 3, 4, and 5, the following notation is introduced: 1 — housing, 2 — first resonator, 3 — second resonator, 4 — third resonator, 5 — first resonator input-output, 6 — resonator second input-output, 7 - a dielectric pipe, 8 - a centering lock, 9 - an external sealing ring, 10 - an internal sealing ring, 11 - a restrictive coil, 12 - a restrictive and dividing coil, 13 - a dielectric sleeve, 14 - a dielectric substrate, 15 - a computing and control unit , 16 - computer, 17 - control unit, 18 - controlled high-frequency generator p, 19 - managed switch, 20 - mode controller, 21 - input amplifier, 22 - input isolation capacitor, 23 - output isolation capacitor, 24 - output amplifier, 25 - amplitude detector, 26 - analog-to-digital converter, 27 - first transceiver the path of the first resonator, 28 - the first transceiver path of the second resonator, 29 - the first transceiver path of the third resonator, 30 - the second transceiver path of the first resonator, 31 - the second transceiver path of the second resonator, 32 - the second transceiver t third resonator 33 - shield box 34 - the overall shield housing 35 - Temperature sensor 36 - the external system.

The complex includes a housing 1, which is a piece of metal pipe with flanges at its ends, designed to connect the housing 1 to an external pipeline, and three in series, one after the other, open inside the housing 1 of the open radio-wave cylindrical high-frequency resonator: the first resonator 2, the second resonator 3 and the third resonator 4 (see Figure 1). Each of the resonators 2, 3, 4 is a short-circuited zigzag conductor having the shape of a rectangular meander placed on a cylindrical surface (see Figures 2 and 4).

The first input-output 5 is connected to one of the points of the zigzag conductor of each of the resonators 2, 3, 4, and the second input-output 6 is connected to the other point of the aforementioned conductor of each of the resonators 2, 3, 4, and the points of attachment of each first input-output 5 of each of the resonators 2, 3, 4 and the attachment points of each second input-output of each of these resonators lie in mutually orthogonal planes with an angle of 0.5π between them (see Figure 4). Moreover, the indicated points of attachment of the first input-output 5 and the second input-output 6 to the zigzag conductor can either be located at opposite ends of each of the resonators 2, 3, 4, as shown in Figures 1 and 2, or both can be on the same the same end of the corresponding resonator 2, 3, 4.

Resonators 2, 3, 4 are sequentially, one after the other, coaxially located on the outer cylindrical surface of the dielectric tube 7, axisymmetrically mounted inside the housing 1 using two metal centering clips 8, each of which is equipped with two o-rings: an outer o-ring 9 and an inner o-ring ring 10.

In addition to the resonators 2, 3, 4, two pairs of short-circuited metal coils are also installed on the outer surface of the dielectric tube 7: two restrictive coils 11 and two restrictive-separation coils 12, one of the restrictive coils 11 installed at the outer end of the first resonator 2, the other at the outer end of the third resonator 4, one of the restrictive-separation coils 12 is between the first and second resonators 2 and 3, respectively, and the other is between the second and third resonators 3 and 4, respectively.

Each of the first I / O 5 and the second I / O 6 of each of the resonators 2, 3, 4 passes through its corresponding hole in the wall of the housing 1 and is isolated from the housing 1 by means of a dielectric sleeve 13. Dielectric bushings 13 and O-rings 9, 10 ensure the tightness of the internal gas-filled cavity of the radio wave sensor of the component flow rate limited by the housing 1, the dielectric tube 7 and the centering clips 8.

The cross section of each of the short-circuited zigzag conductors of each of the resonators 2, 3, 4 is a rectangle, and the scan of this conductor has the shape of a rectangular meander (see Figures 2, 3); Electrotechnical copper may be selected as the material of the zigzag conductor.

The choice of a rectangular cross-section for a zigzag short-circuited conductor makes it possible to significantly reduce the electrical capacitive connections between adjacent parallel sections of this conductor in comparison with the inter-turn electrical capacitive connections of the resonator winding of the known complex made of a copper wire and thereby significantly increase the quality factor of the resonator.

Restrictive and restrictive-separation coils 11, 12, respectively, are used in the proposed complex with the aim of clearly fixing the spatial boundaries of the electromagnetic field at the end ends of each of the resonators 2, 3, 4 and the independence of the position of these boundaries from the influence of nearby metal structural elements of the radio wave sensor.

All of the mentioned working elements and turns are made by a method that ensures their mutual identity, for example, by photo-printing a scan pattern of a zigzag conductor of each of the resonators 2, 3, 4 and each of the turns 11, 12 on the metal surface of a metal-foiled flexible dielectric substrate 14 of width 2πR (see. Figure 2). After the electrochemical treatment of the indicated metal surface, the dielectric substrate 14 with the scans of the meander-like conductors of the resonators 2, 3, 4 and turns 11, 12 formed on it is installed with the dielectric layer inward on the outer cylindrical surface of the dielectric tube 7 and fixed to it, and mutually corresponding end points n _i of each of the meander-like conductors of each resonator 2, 3, 4 and mutually corresponding endpoints m _{i of} each of the turns 11, 12 are galvanically connected between themselves so that each of the connection points n _i corresponds to the connection point m _i , where i = 1, 2, ... 7 is the serial number of the connection point.

The axial distances L ₀ and L between the geometric centers of the first and second resonators 2, 3 and the second and third resonators 3, 4 are used in constant flow calculation algorithms.

It should be noted that the replacement of a separate input and a separate output of a known complex resonator with a single resonator input-output proposed in the claimed complex makes it possible to galvanically connect each of the first input-output 5 and each of the second input-output 6 to the corresponding resonator 2, 3, 4 only at one point of its zigzag conductor, which ensures complete mutual identity of the input and output impedances of each of the aforementioned input-output terminals, while in the known complex the indicated impedance s differ from each other because each input and each output of each of the resonators of this complex are electrically connected to a corresponding zigzag conductor in its two different inevitably differ from each other, the points.

The proposed complex also includes a computing and control unit 15, in which, for convenience, the operation of the proposed complex in Figure 1, a calculator 16 and a control unit 17, a controlled high-frequency generator 18, a controlled switch 19, a mode controller 20, two input amplifiers 21, six input isolation capacitors 22, six output isolation capacitors 23, as well as six transmission paths, each of which includes a series-connected output amplifier 24, amplitudes detector 25 and A / D converter 26.

To exclude mutual influence, each of the six above transmission paths together with its input and output isolation capacitors 22 and 23 are shielded and form a transceiver path, namely: the first transceiver path of the first resonator, the first transceiver path of the second resonator, the first transceiver -the transmitting path of the third resonator, as well as the second transmitting and transmitting path of the first resonator, the second transmitting and transmitting path of the second resonator and the second transmitting and transmitting path of the third cut onator.

Input isolation capacitors 22 and output isolation capacitors 23 are used to simultaneously connect each of the first I / O 5 and second I / O 6 to two different electrical circuits: through the input isolation capacitor 22 to the excitation circuit of the resonators 2, 3, 4, containing one of the input amplifiers 21, the controlled switch 19 and the controlled high-frequency generator 18, and through the output isolation capacitor 23 to the measuring and computing circuit containing the transmitting path of one of the receivers o-transmission paths 27, 28, 29, 30, 31, 32 and computationally-control unit 15.

Each of the first transceiver paths 27, 28, 29 and the second transceiver paths 30, 31, 32 contains an input, output and a common point, moreover, each of these transceiver paths 27, 28, 29, 30, 31 , 32 includes input and output isolation capacitors 22 and 23, respectively, an output amplifier 24, an amplitude detector 25, and an analog-to-digital converter 26 installed inside one of the shielding shrouds 33, galvanically connected to a common shielding shroud 34, which in turn is grounded to building 1.

The common point of each of the first transceiver paths 27, 28 and 29 and the common point of each of the second transceiver paths 30, 31 and 32 through its corresponding output isolation capacitor 23, output amplifier 24, amplitude detector 25 and analog-to-digital converter 26 is connected to the output of this path, and through the corresponding input isolation capacitor 22, said common point is connected to the input of this path.

Each of the first input-output 5 of each of the resonators 2, 3 and 4 is connected to a common point of the corresponding first transceiver path 27, 28 and 29: the first input-output 5 of the first resonator 2 - with a common point of the first transceiver path 27 , the first input-output 5 of the second resonator 3 with a common point of the first transceiver path 28 and the first input-output 5 of the third resonator 4 with a common point of the first transceiver path 29, and each of the second input-output 6 of the resonator 2, 3 and 4 in a similar way

connected to a common point, respectively, of the second transceiver path 30, the second transceiver path 31 and the second transceiver path 32.

Each of the outputs of each of the aforementioned transceiver paths 27, 28, 29 and 30, 31, 32 is connected through a corresponding input of the computing and control unit 15 to one of the inputs of the transmitter 16, and the output of the first transceiver path 29 and the output of the second transceiver -transmission path 32, in addition, each is connected, respectively, to the first and second input of the mode controller 20.

The output of the mode controller 20 is connected to one of the inputs of the computing and control unit 15, connected to the corresponding input of the calculator 16. One of the outputs of the control unit 17 through the corresponding output of the computing and control unit 15 is connected to the control input of the managed switch 19, and the other output of the control unit 17 through the corresponding output of the computing and control unit 15 is connected to the input of a controlled high-frequency generator 18.

The managed switch 19 contains two outputs: the first and second, and said first output through one of the input amplifiers 21 is connected to the inputs of the first transceiver paths 27, 28, 29, and said second output through another input amplifier 21 is connected to the inputs of the second receivers transmission paths 30, 31, 32.

The control unit 17 is connected by two-way information communication with the transmitter 16.

The complex also contains a temperature sensor 35 installed in the housing 1, the output of the sensor is connected to one of the inputs of the calculator 16 through the corresponding input of the computing and control unit 15, which, if there are external systems 36, is connected to these systems using the information exchange line.

The proposed complex measurement of the component flow rate of a gas-liquid flow is as follows.

If there is a controlled gas-liquid medium in the dielectric tube 7 moving at a speed W, a command is sent to the input of the calculator 16

the launch coming to the calculator 16, for example from external systems 36, via the information exchange line.

By two-way information communication, this command is transmitted from the calculator 16 to the control unit 17, and from one of the outputs of this unit, through the corresponding output of the computing and control unit 15, is fed to the input of a controlled high-frequency generator 18.

In accordance with the accepted command, said generator generates a high-frequency signal with a frequency that gradually changes in time, increasing from the value of F _min to the value of F _max . The specified signal is necessary to excite a high-frequency electromagnetic field in each of the three resonators 2, 3, 4 of the proposed system.

During the operation of the proposed complex, the third resonator 4 serves to obtain information on the relative volume fractions V ₁ , V ₂ , V _{3 of} each of the three components of the controlled flow, and the first and second resonators 2 and 3, respectively, to obtain information on the value of the speed W of the controlled flow.

From the output of the controlled high-frequency generator 18, the excitation signal is fed to the input of the managed switch 19 and, if there is a last command “first output” at the control input, generated in the control unit 17 and received from one of the outputs of this block through the corresponding output of the computing and control unit 15 is transmitted from the first output of the managed switch 19 through the corresponding input amplifier 21 to the inputs of the first transceiver paths 27, 28 and 29 and further through the input isolation capacitor 22 and o The common point of each of these paths goes, respectively, to each of the first I / O 5 of the first, second, and third resonators (positions 2, 3, and 4, respectively), exciting in each of them a high-frequency electromagnetic field varying from F _min to F _max frequency.

Since in the dielectric tube 7 there is a three-component gas-liquid medium, each of the three components of which is characterized by certain values of the complex dielectric constant ε _j ^* and complex conductivity σ _j ^* , where j = 1, 2, 3 is the number of the medium component, then

upon excitation of a high-frequency electromagnetic field in each of the resonators 2, 3, 4, the resonant absorption of the excited field energy by a medium at several resonant frequencies F _{res of} absorption will occur, where

F _min ≤F _rez ≤F _max ,

for example, at the first, second and third resonant frequencies F _res1 , F _res2 , F _res3 , respectively.

Since the informative parameters of signals characterizing resonant absorption, such as, for example,

- the amplitudes of the output signals at the first, second and third resonant frequencies I _res1 , I _res2 , I _res3 , respectively,

- the transmission coefficients of the signals at the first, second and third resonant frequencies D _res1 , D _res2 , D _res3 , respectively,

- resonant frequencies F _res1 , F _res2 , F _res3 ,

as well as other informative parameters, significantly depend on the complex characteristics of the controlled medium ε ₁ ^* , ε ₂ ^* , ε ₃ ^* and σ ₁ ^* , σ ₂ ^* , σ ₃ ^* , each of the output signals of the first, second and third resonators (position 2 , 3 and 4, respectively), contains information on the component composition of the gas-liquid flow.

Each of these signals is fed through one of the inputs of the computing and control unit 15 to the corresponding input of the calculator 16 through the following circuits: the signal from the first input-output 5 of the first resonator 2 is supplied through a series-connected output isolation capacitor 23, output amplifier 24, amplitude detector 25 and analog-to-digital Converter 26 of the first transceiver path 27, the signal from the first input-output 5 of the second resonator 3 enters through similar elements 23, 24, 25, 26 of the first transceiver tr kta 28 and the signal from the first input-output 5 of the third resonator 4 enters through the elements 23, 24, 25, 26 of the first transceiver path 29. In addition, the specified signal from the output of the first transceiver path 29 enters the first input of the mode controller 20 in which a preliminary classification analysis of informative parameters of the received signal is carried out.

The purpose of the preliminary classification analysis is to roughly classify the flow patterns of the controlled flow as one of the “steady state” and “non-steady state” modes, with the subsequent refinement of the choice of the sub-mode of the steady state mode, for example, one of the sub-modes: “steady-state - oil”, “steady-state — water”, “ steady-state - gas "," steady-state - oil-water "," steady-state - oil-gas "," steady-state - gas-water "," steady-state - oil-water-gas ", or" transient - oil-water "," transient - oil-gas "and t .d. The code signal corresponding to the selected submode is supplied from the output of the mode controller 20 to one of the inputs of the computing and control unit 15 to the corresponding input of the calculator 16, in which the algorithm corresponding to the received submode code is selected from the group of control algorithms for the component composition.

In accordance with the selected algorithm, the calculator 16 analyzes the informative signal received from the first input-output 5 of the third resonator 4 through the first transceiver path 29 and instantaneous values of the relative volume fractions V ₁ , V ₂ and V _{3 of} each of the three are calculated controlled flow components.

After the described procedure is completed, a “second output” command is generated in the control unit 17, which arrives from one of the outputs of this unit through the corresponding output of the computing and control unit 15 to the control input of the managed switch 19, as a result of which the high-frequency signal generated by the controlled high-frequency generator 18 and transmitted from its output to the input of the managed switch 19, switches to the second output of the given switch, from where it goes to each of the inputs of the second transceiver paths 30, 31 and 32.

From each of the common points of each of these transceiver paths, a high-frequency signal is transmitted through the corresponding input amplifier 21 to the second input-output 6 of each of the resonators 2, 3, 4.

When switching a high-frequency signal from the first I / O 5 of the resonators 2, 3, 4 to their second I / O 6, the directivity of the electromagnetic field inside each of these resonators orthogonally changes, which makes it possible to produce a precise electromagnetic

sounding of the controlled medium in the direction orthogonal to the initial sounding direction, and obtain additional information in relation to the initial information on the component-wise composition of the non-axisymmetric gas-liquid flow.

Signals that carry additional clarifying information are removed from each of the second inputs and outputs of 6 resonators 2, 3, 4; each of these signals arrives at the common point of the corresponding second transceiver path (positions 30, 31, 32) and from the output of each of them is transmitted to the input of the transmitter 16 through one of the inputs of the computing and control unit 15 corresponding to each of them.

In addition, from the output of the second transceiver path 32, the specified signal is fed to the second input of the mode controller 20, in which, based on an analysis of the informative parameters of the incoming signal, the previously established sub-mode of the monitored stream is specified and the code signal corresponding to the specified sub-mode is transmitted through one of the inputs computing and control unit 15 to the corresponding input of the calculator 16, where based on the analysis of the signal received by the calculator 16 with additional input-output 6 of the third resonator 4 through a second transceiver transmission path 32, if necessary, update is performed earlier selected correction algorithm and the previously calculated instantaneous values of the relative volume fractions of V _1, V ₂ and V ₃ each of the three components of the controlled flow.

To determine the speed W in the proposed complex, the autocorrelation method was chosen. In this case, depending on the mode of the controlled flow, information on the motion of the natural flow label, or information on the motion of the local inhomogeneity of the flow, or information on the motion of the local flow feature, is used.

In the first case, when the mode controller 20 is set to a mode of essentially unsteady movement of the controlled flow, received at the input of the calculator 16 from the first I / O 5 and second I / O 6 of the first and second resonators 2 and 3, respectively, as previously described

informative signals are continuously recorded in the memory of the calculator 16 in the form of temporary implementations of each of these signals.

As temporary implementations of informative signals of resonators 2 and 3, for example, the dependences of signal amplitudes on time t can be used: _Irezl (t), _Irez2 (t), _Ires3 (t) near the previously mentioned first, second and third resonant frequencies F _res1 , F _res2 , F _res3 , respectively.

Taking into account the submode of the essentially unsteady movement defined by the mode controller 20, in the calculator 16 from the group of algorithms “Speed calculation” an algorithm is selected that corresponds to the code of this submode and, in accordance with the selected algorithm, the above-mentioned temporary realizations of informative signals generated by each of the resonators are processed 2 and 3.

After processing these realizations, their mutual correlation function is determined and one of the realizations is shifted relative to the other in time t, until the maximum of the mutual correlation function is obtained.

When the maximum of the mutual correlation function is obtained during the bias of the implementations, the bias time is determined in the calculator 16, and since this time is equal to the time interval Δτ running by the natural mark of the flow — its stable fluctuation — some fixed length of the radio wave sensor, taken as the base length L _o , the speed is calculated W controlled flow in accordance with the expression

W = L _o / Δτ,

where L _o is the base length equal to the axial distance between the geometric centers of the first and second resonators 2 and 3, respectively.

The obtained velocity value W is used in the calculator 16 to calculate the instantaneous values of the component-wise volumetric flows Q ₁ , Q ₂ , Q _{3 of} each of the three components of the gas-liquid flow.

In the second case, when the mode controller 20 determines the steady-state movement of an almost uniform controlled flow, in which there are no local, pronounced fluctuations in the composition of the controlled medium, the velocity W can be determined from the above

the method may not be valid. In this case, as a reliably controlled flow feature in the proposed complex, not a local fluctuation of the component composition of the flow is used, but a local flow feature, characterized by a significantly different ratio of the informative signals of the resonators 2 and 3 obtained by mutually orthogonal radio wave sounding of the controlled medium.

The mutually orthogonal sounding method allows fixing such local features of an almost uniform steady flow, as, for example, local axial flow asymmetry, local helical flow swirling, concentrated helicoidal swirling of the flow, local turbulence and other local features that are not detected in principle with unidirectional sounding.

In the case when the mode controller 20 has established an almost uniform flow of the monitored stream and the corresponding submode has been refined, a code corresponding to the refined submode is transmitted to the calculator 16, and in this calculator, the algorithm corresponding to the obtained code is selected from the group of algorithms “Speed calculation”.

In accordance with the selected algorithm, the time realizations of the relations of each of the signals generated on the first input-output 5 of the first resonator 2 and on the first input-output 5 of the second resonator 3 are processed, respectively, to the signal generated on the second input-output 6 of the first resonator 2 and to the signal generated at the second input-output 6 of the second resonator 3.

After processing the indicated, significantly different from the average signal ratios, in the calculator 16 it is determined, as in the previous case, the mutual correlation function of their time realizations and the shift time of the realizations is found, at which this function experiences a maximum. As with a substantially unsteady flow, this time is equal to the time interval Δτ running by the natural mark of the flow - its local feature, characterized by a significantly different ratio of the signals received during mutually orthogonal sounding of the controlled medium, the base length L _o .

The speed of the controlled flow in this case, as before, is

W = L _o / Δτ.

The found values of the velocity W and the relative volume fractions V ₁ , V ₂ and V _{3 of the} components of the controlled flow allow us to calculate the component-by-volume flow rate Q ₁ , Q ₂ , Q _{3 of} each of the three components of the gas-liquid medium:

Q ₁ = S · W · V ₁ , Q ₂ = S · W · V ₂ , Q ₃ = S · W · V ₃ , where

S = πR ² is the area of the passage section of the dielectric pipe 7.

If it is necessary to determine the component-wise mass flow rate Q _m1 , Q _m2 , Q _{m3 of} each of the three components of the gas-liquid medium in the calculator 16, in addition to the described procedure, the signals about the instantaneous temperature values of the controlled medium supplied to the corresponding input of the calculator 16 from the output of the temperature sensor 35 are taken into account and also stored in the memory of the calculator 16 data on the nominal densities ρ ₁ , ρ ₂ , ρ _{3 of} each of the three specified components.

Information about the component-wise volumetric flow rate and, if necessary, about the component-wise mass flow rate of the controlled flow can be transmitted from the calculator 16 via the information exchange line to external systems 36.

Thus, the problem solved by the proposed utility model, which consists in increasing the reliability and accuracy of measuring the component flow rate at two extreme flow conditions of a controlled environment: a substantially unsteady and fully steady flow, is solved by using the following new technical solutions in the proposed complex: firstly, - through the use of preliminary analysis of the flow regime in the mode controller 20 using the resonator 3, and secondly, through the use of two different directions of radio-wave sounding using two mutually orthogonal I / O 5 and 6 and a controlled switch 19 and, thirdly, due to the identity and mutual symmetry of the resonators 2, 3, 4 and their working elements, such as restrictive and restrictive-dividing turns 11 and 12.

Claims (1)

A complex for measuring the component flow rate of a gas-liquid stream, which includes coaxially arranged first and second resonators, each of which is a short-circuited zigzag conductor having the shape of a rectangular meander, mounted on the outer cylindrical surface of the dielectric pipe mounted inside the tubular metal body coaxially with it, controlled by a high-frequency generator, input amplifier, computer control unit, two transmission paths, each of which It contains a series-connected output amplifier, an amplitude detector and an analog-to-digital converter, the complex also contains a temperature sensor installed in the housing, the output of which is connected to the corresponding input of the computer-control unit, and each of the two resonators is connected through one of its transmitting paths to one of the inputs of the computing and control unit, the output of which is connected to the input of a controlled high-frequency generator, characterized in that a third resonator is introduced into it placed coaxially with the first and second resonators, all three resonators are placed on a dielectric tube inside the housing, each resonator is equipped with a first input-output and the second input-output orthogonal to it, and the first input-output and second input-output of each resonator are mutually diametrical perpendicular to the planes, the complex additionally contains an input amplifier, as well as connected to the output of a controlled high-frequency generator, a controlled switch equipped with two outputs, each of which s is connected to one of the input amplifiers, and also equipped with a control input connected to the computer-control unit, in addition, the complex further comprises a mode controller, as well as four transmission paths identical to the first two, each of the mentioned transmission paths is additionally equipped with an input and two dividing capacitors interconnected at a common point, one of which is connected to the input of the output amplifier, and the other to the input of this transmission path, each of the transmitting paths together with the introduced isolation capacitors, it is shielded and forms a transceiver path, and the first or second input-output of each resonator is connected to only one of the transceiver paths - to the common point of its separation capacitors, the output of each transceiver path is the analog output a digital converter, which is connected to one of the inputs of the computing and control unit, each of the transceiver paths connected to the first input-output of one of the resonators is connected to an input with one of the input amplifiers, and each of the other transceiver paths is connected by its input to another input amplifier, while the output of each of the transceiver paths of the third resonator is additionally connected to one of the inputs of the mode controller, the output of which is connected to one of the inputs of the computing and control unit, at the end sections of the dielectric pipe is installed along the restrictive coil, and between the resonators - along the restrictive-separation coil, restrictive turns, restrictive zdelitelnye and zigzag windings each resonator conductors have a rectangular cross section.