RU2663418C1 - Multiphase flowmeter - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: use for measuring the flow parameters of a multiphase fluid. Summary of the invention is that the flowmeter includes an X-ray tube, an X-ray transparent pipeline section for studying multiphase fluid, a matrix X-ray detector, an analysis tool for processing data coming from the detector, an anti-scattering X-ray mask to reduce the effect of scattered radiation on the image. X-ray filter is installed in front of the detector, which is made of two kinds of filter materials having different radiation absorption coefficient and arranged in staggered order. After the X-ray transparent section, a spectrometer is installed parallel to the matrix X-ray detector, which serves to measure the intensity of X-ray radiation, taking into account its photon energy distribution.

EFFECT: simplification of the design of a multiphase X-ray flowmeter with simultaneous increase in reliability and accuracy of measurement during operation.

1 cl, 5 dwg

Description

The invention relates to the field of measuring the parameters of a multiphase fluid flow, and in particular, to a device for measuring the flow rate and / or composition of a multiphase fluid without preliminary separation of the multiphase fluid, and can be used in information-measuring systems of the oil and oil refining industries.

To determine the phase composition of the mixture, the most commonly used method is x-ray or gamma densitometry. The principle of operation is based on the difference in the absorption coefficients of photons of the X-ray spectrum of radiation of various energies by the substances that make up the mixture under study. This effect is described by the Bouguer-Lambert-Beer law. For the oil and gas industry, the determination of the composition of the fluid consisting of water, oil (liquid hydrocarbons) and natural gas is of greatest interest. In this case, it is convenient to use radiation with two energy ranges for densitometry: low-energy radiation (20–40 keV) and high-energy (50–80 keV). At low energies, the difference in the absorption coefficients of radiation between water and liquid hydrocarbons is maximum, which makes it possible to distinguish between these two fractions. At high energies, the difference between the absorption coefficients of the radiation of water and liquid hydrocarbons becomes insignificant, and between liquid components and natural gas, on the contrary, it increases. It is worth noting that the energy range above 20 keV is considered, because below this energy all radiation is strongly absorbed in the surrounding air and does not carry useful information.

A multiphase X-ray flow meter is known for measuring the flow rate and composition of a multiphase fluid, comprising a radiation means adapted to generate a photon beam to irradiate the multiphase fluid spatially along a portion of the multiphase fluid stream, a detection means spatially configured to receive photons emanating from said portion of the multiphase fluid stream, at different time intervals to form an image of the spatial distribution of the received photons for each about the mentioned time interval, and analysis tool adapted to determine the fluid velocity of one or more phases of the multiphase fluid based on the time sequence of images of the spatial distributions of the received photons, wherein said detection means includes a two-dimensional array of detector elements, and said radiation means, adapted, to generate photons at the first energy level and the second energy level, and for the first energy level the coefficient The absorption coefficients of photons for two different phases contained in a multiphase liquid are essentially equal; for the second energy level, the absorption coefficients of photons for the two phases of a multiphase liquid differ [Patent RU No. 2533758, cl. G01F 1/704, publ. 11/20/2014].

A feature of this device is the ability to filter the photon flux from x-ray sources. It is assumed either the presence of two pulsed X-ray sources with different potentials on the X-ray tubes operating alternately, or one X-ray tube operating in a pulsed mode and providing a variation of the potential of the X-ray tube from pulse to pulse. The pulse repetition rate is in direct direct proportion to the flow velocity of the investigated multiphase fluid flow. At flow rates (water, oil, gas) of the mixture from 1 to 10 m / s, typical for the intended applications of this multiphase flow meter, and the size of a single element of the matrix detector of the order of 1 mm, the x-ray pulse repetition rate should be of the order of 100 Hz and higher. A pulsed x-ray source, providing a pulse repetition rate of 100 Hz and higher, is technically complex and, therefore, an expensive device, and, as a rule, the service life of such devices is quite small.

Closest to the claimed object is a device for measuring the flow rate and / or composition of a multiphase fluid containing radiation means configured to generate a pulsed photon beam for irradiating a multiphase fluid spatially along a portion of the multiphase fluid flow, configured to apply voltage to the radiation means, detection means spatially configured to receive photons emanating from a portion of a multiphase fluid stream to form images the spatial distribution of photons received for each of the points in time and analyzing means arranged to determine the flow rates of one or more phases of the multiphase fluid and / or its composition based on the temporal sequence of images of the spatial distribution of photons received. The voltage applied to the radiation means is a predetermined, time-dependent voltage, having any course of change between the initial voltage and the final voltage during one pulse of photons, and the photons emanating from the portion of the multiphase fluid flow are received at different times during one pulse photons. To reduce the effect of scattered radiation on the image in such flowmeters, as a rule, after the portion of the multiphase fluid flow, an anti-scattering x-ray mask is installed [Patent RU No. 2565346, cl. G01F 1/708, publ. 10/20/2015].

A feature of this device is the use of a pulsed x-ray source, which allows you to vary the potential supplied to the x-ray tube during the pulse, and thereby provide the necessary spectral composition of the photons incident on the matrix x-ray detector. As in the solution according to the above patent RU No. 2533758, this design of a multiphase X-ray flow meter implies the use of a pulsed X-ray source providing a pulse repetition rate of 100 Hz and above, with all the technical disadvantages mentioned above: a technically complex and expensive design, low life of operation of such a flow meter , reducing its reliability.

In addition, when performing the calibration procedure using this flowmeter, the distribution of the X-ray absorption coefficients of the components in a multiphase liquid (oil, gas, water) depending on the X-ray energy is not taken into account, which leads to low measurement accuracy.

The invention is aimed at simplifying the design of a multiphase X-ray flow meter while reducing its cost, increasing the reliability and accuracy of measurement during operation.

This is achieved by the fact that in the multiphase X-ray flow meter for measuring the flow rate and / or composition of the multiphase liquid containing the radiation means, an X-ray transparent section of the pipe for examining the multiphase liquid, after which the anti-scattering X-ray mask is located to reduce the effect of radiation on the image, the matrix X-ray detector as a means detection, analysis tool, configured to determine the flow rate of one or more phases of the liquid and / or its composition, according to and To the invention, an X-ray filter is installed in front of the X-ray matrix detector, which is made of two types of filter materials having different absorption coefficients and arranged in a checkerboard pattern so that each filter cell is located above its own pixel in the matrix detector, while after the X-ray transparent section, parallel to the matrix X-ray detector is installed spectrometer used to measure the intensity of x-ray radiation, taking into account its distribution of photon energies.

An advantage of the proposed design is the organization of X-ray filtering using a filter with two different types of filter elements arranged in a checkerboard pattern placed in front of the matrix X-ray detector. This ensures the simultaneous obtaining of the spatial distribution of photons of "high" and "low" energies in each frame recorded by the matrix detector. Thus, the proposed design will make it possible to abandon the use of pulsed x-ray sources with a pulse repetition rate of 100 Hz and higher and will make it possible to use x-ray sources of "continuous" mode of operation (pulse duration 0.1 s and longer), which will greatly simplify and reduce the cost of a multiphase flow meter, and also increase its reliability in operation.

The presence of a spectrometer in the design of a multiphase flow meter during the calibration procedure will make it possible to take into account the distribution of the x-ray absorption coefficients of the components of a multiphase liquid (oil, gas, water) depending on the x-ray energy, which will significantly increase the accuracy of the flow meter.

In FIG. 1 schematically shows the inventive x-ray multiphase flow meter; in FIG. 2 - x-ray filter; in FIG. Figure 3 shows the dependence of the absorption coefficients of copper as a material with a low atomic number and tin with a high atomic number on the radiation energy; in FIG. Figure 4 shows a typical spectrum of x-ray radiation from an x-ray tube with a voltage of 80 kV after passing through an x-ray filter made of staggered two types of filter materials: copper and tin; in FIG. 5 - shows a histogram depicting the distribution of the intensity of the x-ray signal depending on the energy of x-ray photons.

A multiphase X-ray flow meter will include an X-ray source — an X-ray tube 1, a test section — an X-ray transparent portion 2 of a pipe for examining a multiphase liquid, a detection means — an X-ray matrix detector 3 and an analysis tool (not shown) for processing data from the detector 3, and determining the flow rate of one or more phases of the liquid and / or its composition. After the X-ray transparent section 2 of the pipeline, an anti-scattering X-ray mask 4 is located to reduce the effect of scattered radiation on the image, while an X-ray filter 5 is installed in front of the detector 3, which serves to selectively transmit X-ray radiation and is made of two types of filter materials 6 and 7 having different absorption coefficients radiation and staggered so that each cell of the filter materials of the X-ray filter 5 is above its own pi Xel 8 matrix detector. After the X-ray transparent section 2, a spectrometer 9 is installed parallel to the matrix X-ray detector 3, which serves to measure the intensity of X-ray radiation taking into account its distribution by photon energies.

The x-ray filter is illustrated clearly in FIG. 2. The filter is made of staggered two types of filter materials 6 and 7 having different absorption coefficients: with a high and low atomic number and installed in front of the matrix X-ray detector, where 8 are the pixels of the detector. In particular, the filter may be made of copper as a material with a low atomic number and tin as a material with a high atomic number. The filter may be made of other pairs of filter materials 6 and 7 having different radiation absorption coefficients. It is empirically revealed that when using such an X-ray filter, the absorption coefficient of a material with a high atomic number has a “dip” in the low-energy region, which is not observed for light materials. In particular, for tin, this “dip” is located in the region of 10-30 keV (Fig. 3), which makes it possible to obtain a prominent peak from the intensity of x-ray radiation in this energy range after passing through the tin radiation. In particular, in FIG. Figure 4 shows a typical x-ray spectrum from an 80 kV x-ray tube after passing an x-ray filter of copper with a thickness of 150 μm and tin with a thickness of 350 μm. The thicknesses of the materials are selected in such a way as to maximize the accuracy of determining the phase composition of the mixture through the solution of the Bouguer-Lambert-Behr system of equations (1):

где

Where

I ₁ , - integrated signal from a low-energy X-ray;

I ₂ - integrated signal from a high-energy x-ray;

δ ₁ and δ ₂ are the thicknesses of the respective filters;

σ _1i and σ _2i are the absorption coefficients of the corresponding filters, taking into account their dependence on the energy of x-ray photons;

σ _wi , σ _gi , σ _oi , are the X-ray absorption coefficients for water, gas, and oil, respectively;

x _w , x _g , x _o - the effective thickness of the layers of water, gas and oil in the mixture, along the path of radiation;

d is the internal size of the pipeline along the radiation path;

Κ ₁ , K ₂ - calibration factors.

The proposed multiphase X-ray flow meter is implemented as follows.

An X-ray tube 1 with a voltage of 80-100 kV generates a photon flux 10, which is passed through an X-ray transparent section 2 of the pipeline in which the studied multiphase liquid 11 flows, after which the radiation passes through an anti-scattering X-ray mask 4, which reduces the effect of radiation scattered on the fluid (multiphase liquid) and the pipeline section, on the image. After radiation passes through one of the two filter materials 6 or 7 of the X-ray filter 5, two images are formed on the X-ray matrix detector 3. Images are taken from the detector with a frequency of up to ten kHz. Then the images are processed by the analysis tool, and then, using mathematical algorithms, the phase composition and velocity of the fluid flow (and, accordingly, the flow rate) of each phase of the multiphase fluid are determined using the above system of equations (1).

To calibrate the flowmeter, a spectrometer 9 is connected, which splits the part of the X-ray spectrum of interest to us into a number of sections and gives the intensity of the X-ray signal for each of these sections, as shown in the histogram (see Fig. 5). Next, the calibration procedure occurs during the transmission of the photon flux through:

- empty pipe (background);

- a pipe filled with oil under operating conditions (temperature, pressure, etc.);

- a pipe filled with natural gas under operating conditions;

- a pipe filled with water under operating conditions.

и

, параллельно через спектрометр получаем сигнал вида

, где i - номер спектрального участка.1. Background. A picture is taken of an empty test section. We get two intensity values

and

, in parallel through a spectrometer we obtain a signal of the form

where i is the number of the spectral section.

и

, параллельно через спектрометр получаем сигнал вида

Предполагаем, что

и соответственно определяем распределение коэффициентов затухания рентгеновского излучения для нефти.2. Oil. A shot of the test section is filled with oil. We get two intensity values

and

, in parallel through a spectrometer we obtain a signal of the form

We assume that

and, accordingly, we determine the distribution of the x-ray attenuation coefficients for oil.

и

соответственно, параллельно через спектрометр получаем сигнал вида

. Предполагаем, что

и соответственно определяем распределение коэффициентов затухания рентгеновского излучения для газа.3. Gas. A shot of the test section is filled with gas. We get two intensity values

and

accordingly, in parallel through a spectrometer we obtain a signal of the form

. We assume that

and accordingly, we determine the distribution of the x-ray attenuation coefficients for the gas.

и

соответственно, параллельно через спектрометр получаем сигнал вида

Предполагаем, что

и соответственно определяем распределение коэффициентов затухания рентгеновского излучения для воды.4. Water. A shot of the test section is filled with water. We get two intensity values

and

accordingly, in parallel through a spectrometer we obtain a signal of the form

We assume that

and accordingly, we determine the distribution of the x-ray attenuation coefficients for water.

5. Next, it is necessary to determine the calibration coefficients, for this we substitute the values measured at the previous stages of calibration into equation 1. We get:

From this system, the calibration coefficients Κ ₁ and K ₂ can be obtained.

Thus, all the coefficients of equation (1) necessary for determining the arbitrary composition of a multiphase liquid (oil, water, gas) were found.

In further measurements of the signal intensity at the matrix X-ray detector, the composition of the multiphase liquid is determined by the formula (1).

The use of the proposed multiphase X-ray flow meter will eliminate the need to use an expensive matrix X-ray detector with spectral resolution for the energies of the recorded photons or additional X-ray sources and detectors for different X-ray energy with a pulse repetition rate of 100 Hz and higher and will make it possible to use an X-ray tube with a broadband radiation spectrum ( with a pulse duration of 0.1 s or longer) for "continuous" mode operation and simultaneous acquisition of two independent images of the investigated multiphase mixture with different radiation energies.

This will allow, in comparison with the closest analogue according to patent RU No. 2565346, to significantly simplify and reduce the cost of the flowmeter design, as well as to increase its reliability in operation.

In addition, the proposed design of the flow meter will make it possible to take into account the distribution of the absorption coefficients of x-ray radiation of the components of a multiphase liquid (oil, gas, water) depending on the energy of the x-ray radiation, and this, in comparison with the closest analogue, will significantly increase the accuracy of the flow meter.

Claims (1)

A multiphase flow meter for measuring the flow rate and / or composition of a multiphase fluid containing radiation means, an X-ray transparent section of the pipeline for examining multiphase liquids, after which an anti-scatter x-ray mask is located to reduce the effect of radiation on the image, an X-ray matrix detector as a detection means, analysis means made with the ability to determine the flow rate of one or more phases of the liquid and / or its composition, characterized in that before the matrix X-ray an X-ray filter is installed in the detector, which is made of two types of filtering materials with different absorption coefficients and arranged in a checkerboard pattern so that each filter cell is located above its own pixel in the matrix detector, and after the X-ray transparent section, a spectrometer is installed parallel to the X-ray matrix detector, which serves to measuring the intensity of x-ray radiation taking into account its distribution over the photon energies.

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