RU2292040C1 - Method of calibrating aid for measuring volume fraction of free gas - Google Patents

Abstract

FIELD: measuring technique; calibration devices.

SUBSTANCE: mixtures of known volume fraction of free gas are formed in measuring vessel made of same material as working part of pipeline; geometric sizes in cross-section of vessel are also the same as those one for pipeline. Value of direct ionizing radiation r passed through the vessel is measured at measuring vessel for any gas-liquid mixture with known value of volume fraction φi, which direct radiation was registered after mixture was radiated by narrow beam of ionizing radiation. After that values of φpassedi are calculated, which values correspond to known values φi. The relation is received which ties value of volume fraction φ of free gas in gas-liquid mixture with value of volume fraction of free gas φpassed, which contains in that part of volume of gas-liquid mixture, which was radiated by narrow beam of ionizing radiation. Then within working part of pipeline the value of dissipated radiation r _dirdisj is measured for a number of gas-liquid mixtures with unknown volume fraction φ_j of free gas. Value of direct radiation r_dirpassedj is measured additionally. Then values of volume fractions φ_dirj of free gas are measured, which free gas contains in that part of volume of gas-liquid mixtures with unknown values of φj, which is irradiated by narrow beam of ionizing radiation. Then while using dependence received for measuring vessel before, which dependence ties value φ and value φ_dir, numerical values of φj are found which values correspond to calculated values φ_dirj. Calibration dependence to be found is determined on the base of measured values r _{dir passed}j and φj.

EFFECT: simplified method of calibration of aid for measuring volume fraction of free gas.

2 dwg

Description

The invention relates to measuring equipment and can be used in various industries, in particular in the oil industry, to determine the gas content in a gas-liquid mixture using radioisotope measuring instruments.

At present, non-contact radioisotope means for measuring the parameters of a gas-liquid mixture transported through a pipeline are very promising, the operation of which is based on measuring the ionizing radiation transmitted through a gas-liquid mixture. These means require a preliminary calibration, during which calibration dependencies are determined that link the readings of these means with the measured parameter.

So, in particular, a known method for calibrating a radioisotope means for measuring the fraction of free gas is described in the description of the patent for utility model RU 35008.

This calibration method is carried out on the working section of the pipeline of the measuring line of the oil metering unit and includes the operation of taking readings of the graduated measuring means when filling the working section of the pipeline with gas-liquid mixtures with a known fraction of free gas.

A known method of calibrating a radioisotope means for measuring the fraction of free gas is described in the description of the patent for invention RU 2141640, which is chosen by the authors as the closest analogue.

The specified calibration method is based on measuring the value of the ionizing scattered radiation r _{tr races} transmitted through the gas-liquid mixture during the irradiation of the gas-liquid mixture by a wide beam of ionizing radiation. In this case, measurements are carried out for a number of mixtures with a known fraction of free gas, the formation of which is carried out directly in the working section of the pipeline. Then, using the obtained data, a calibration dependence is determined that relates the value of the volume fraction of free gas φ in the gas-liquid mixture with the value of r _{tr rac} .

However, the calibration method under consideration (as well as the method described in RU 35008) is difficult to implement on the working sections of pipelines that are part of the plants for monitoring parameters and transporting oil and gas flows, since it is difficult to organize the process of forming gas-liquid mixtures with precisely known gas volumes in these sections.

The objective of the proposed method for calibrating means for measuring the volume fraction of free gas is to simplify its implementation in relation to the working section of the pipeline, which is part of the installation for monitoring parameters and transportation of oil and gas flow.

The essence of the claimed invention lies in the fact that in the method of calibration of the means for measuring the volume fraction of free gas in the gas-liquid mixture transported through the pipeline, based on the measurement of ionizing radiation transmitted through the gas-liquid mixture, including measuring the amount of scattered radiation r _{tr races} recorded at the working section of the pipeline irradiation of a gas-liquid mixture with a wide beam of ionizing radiation and the determination of the calibration the dependence connecting the value of the volume fraction of free gas φ in the gas-liquid mixture with the value of r _{Tr races} , while to obtain the indicated calibration dependence using mixtures with a known volume fraction of free gas, according to the invention, mixtures with a known volume fraction of free gas are formed in a measuring vessel made of of the same material and having the same geometric dimensions in the plane of the cross section as the working section of the pipeline, while on the measuring tank for each of the gas-liquid mixtures with a known value of φ _i measure the value of direct ionizing radiation r _{pr i} passed through it, which was recorded when the mixture was irradiated with a narrow beam of ionizing radiation, including measuring the value of radiation r _{pr 0} recorded when the mixture was irradiated, which was a gas-free liquid, and radiation r _{CR 1} recorded during the irradiation of the mixture, which is a gas, after which a dependence is obtained that relates the volume fraction of free gas φ in the gas-liquid mixture to the volume fraction of free gas φ _pr contained in that part of the volume of the specified gas-liquid mixture that is irradiated with a narrow beam of ionizing radiation, calculating the values of φ _{pr i} corresponding to the known values of φ _i by substituting the measured r _{pr i} , r _{pr 0} , r _{pr 1} into the equation obtained on the basis of the Lambert-Baire law:

and then at the working section of the pipeline for a number of gas-liquid mixtures with an unknown volume fraction of free gas φ _j measure the amount of scattered radiation r _{Tr diss j} and additionally measure the direct radiation r _{Tr CR j} , while measure the direct radiation r _{Tr CR 0} , filling the working the pipeline section with gas-free liquid, and the radiation value r _{tr CR 1} , filling the working section of the pipeline with gas, after which the values of volume fractions of free gas φ _{CR j} contained in that part of the gas-liquid volume are calculated mixtures with unknown values of φ _j , which is irradiated with a narrow beam of ionizing radiation, by substituting the measured values of r _{Tr CR j} , r _{Tr CR 0} , r _{Tr CR 1} in the above equation, and then on the relationship obtained earlier for the measuring capacitance, connecting the value with the value of φ φ _etc., are calculated corresponding values φ _{ave j} φ _j numerical values, and then on the basis of the measurements values r _{tr Dist j} and φ _j values found by determining the required calibration relationship that relates the magnitude vol oh φ percentage of free gas in the gas-liquid mixture with the value r _{tr races.}

A fundamentally important difference between the proposed calibration method is that the formation of mixtures with a known volume fraction of free gas φ is carried out not on the working section of the pipeline, but in a measuring vessel made of the same material and having the same geometric dimensions in the plane of the cross section as the working a section of the pipeline, so that the conditions for the passage of ionizing radiation through the gas-liquid mixture placed in the indicated container are similar to the conditions for the passage of radiation through gas-liquid mixture in the working area of the pipeline.

This allows you to carry out on the measuring tank, and not on the working section of the pipeline, the exact job and / or measuring the volume or mass of the components of the gas-liquid mixture of components, carried out during the formation of a number of gas-liquid mixtures with known gas content.

In this case, on a measuring vessel filled with a mixture with a known gas content, it is not the amount of scattered radiation obtained by irradiating the mixture in the vessel with a wide beam of ionizing radiation, but the value of the direct radiation obtained by irradiating the mixture with a narrow beam of ionizing radiation, since the recorded direct radiation signal is less than sensitive to possible differences in the geometric parameters of the measuring capacity and the working section of the pipeline.

Based on the measured direct radiation for a gas-liquid mixture with a gas content φ known in its entire volume φ, calculated in accordance with the equation obtained on the basis of the Lambert-Baire law, the volume fraction of free gas φ _pr contained in that part of the volume of the gas-liquid mixture that is irradiated a narrow beam of ionizing radiation. Thus, a relationship is obtained that relates the gas content in the entire volume of the gas-liquid mixture φ to the gas content φ _pr in the part of its volume through which a narrow beam of radiation passes.

Further, both scattered and direct ionizing radiation are measured at a working section of the pipeline for a number of gas-liquid mixtures with some unknown gas content. At the same time, the measured values of direct radiation make it possible for each mixture to calculate the gas content φ _pr in the part of the mixture volume through which a narrow beam of radiation passes through the above equation, and to determine for each mixture from the dependence obtained previously on the measuring tank that relates φ and φ _pr previously unknown value φ.

The measured values of the scattered radiation when correlating them with the corresponding known values of φ allow us to obtain the desired calibration dependence.

Thus, due to the implementation of a complex and time-consuming procedure for the formation of gas-liquid mixtures with a known gas content in a special measuring tank and adapting the dependences obtained for the measuring tank to the results of measurements and calculations performed on the working section of the pipeline, the implementation of the method on the working sections of the pipeline as part of the installation for monitoring parameters and transportation of oil and gas flow.

Figure 1 presents a General view of a graduated measuring means and measuring capacity; figure 2 presents a section aa in figure 1.

The method is as follows.

A graduation of a radioisotope means placed on a horizontally oriented working section of the pipeline is performed to determine the volume fraction of free gas in the gas-liquid mixture passing through the indicated section of the pipeline. The considered measuring means comprises an ionizing radiation source placed outside the pipeline, including a radiation unit 1, irradiating the gas-liquid mixture with a narrow beam of direct ionizing radiation, and blocks 2 and 3, irradiating the mixture with two beams of wide ionizing radiation, covering the entire cross section of the pipeline, as well as volumetric determination unit 4 the fraction of free gas in the gas-liquid mixture φ, which includes a unit for detecting direct radiation transmitted through the gas-liquid mixture, as well as radiation eyannogo said mixture and the walls of the pipeline, and a calculating unit, wherein the processing on the basis of the registered signals calculated value of φ.

Place the calibrated means on the measuring vessel 5, which is made in the form of a horizontally oriented cylinder, made of the same material and has the same geometric dimensions in the plane of the cross section as the working section of the pipeline, while the length of the vessel 5 is usually less than the length of the working section of the pipeline.

The tank 5 is equipped with a valve 6 for filling it with liquid, a valve 7 for draining the liquid, as well as through holes 8 for monitoring the completeness of filling the container 5 with liquid and the horizontal position.

A series of media with a known volumetric gas content of φ _{i is} formed in the indicated container 5 and the magnitude of the direct ionizing radiation r _{pr i} passed through it is measured for each medium.

At the same time, the signal r _{pr 1} is first measured for a medium with φ = 1 on a tank 5 completely filled with atmospheric air.

Then, through the valve 6, the container 5 is completely filled with liquid (for example, gas-free oil), controlling the completeness of the filling of the container 5 and the horizontal level of the liquid in it using the holes 8, and the signal r _{pr 0 is} measured for a medium with φ = 0.

The formation of gas-liquid mixtures with a known gas content φ _{i is} carried out by pouring a fixed amount of liquid through the valve 7, while the volume of the molten liquid corresponds to the volume of gas supplied from the atmosphere to the tank 5, and the signal r _{pr i is} measured.

For each of the mixtures, knowing the value of direct ionizing radiation passing through it, r _{pr i} , calculate the volume fraction of free gas φ _{pr i} in the part of the volume of the mixture irradiated by a narrow beam of direct radiation (volume V _pr in figure 2), according to equation (1 ) obtained on the basis of the Lambert-Baire law of attenuation of a narrow beam of direct ionizing radiation transmitted through a gas-liquid mixture.

Knowing the calculated values of φ _{pr i} and the corresponding values of the volumetric gas content φ _i known for each of the mixtures formed, a graphical dependence is constructed that relates these values.

Place the graduated means on the working section of the pipeline.

Measure the signal r _{TP CR 1} for a medium in which φ = 1, completely filling the working section of the pipeline with atmospheric air.

Then fill the indicated area with liquid (for example, gas-free oil) and measure the signal r _{Tr CR 0} for a medium in which φ = 0.

A series of media with a certain unknown volumetric gas content of φ _{j is} formed on the working section of the pipeline, and for each medium, the value of direct ionizing radiation passing through it r _{tr CR j} and the amount of scattered ionizing radiation passing through it r _{tr cr j} are measured.

For each of the mixtures, knowing the magnitude of the direct ionizing radiation passing through it r _{tr CR j} , calculate the value of the volume fraction of free gas φ _{CR j} in the part of the volume of the mixture irradiated by a narrow beam of direct radiation.

The values φ _j corresponding to the calculated values φ _{pr j} obtained from the graphic dependence obtained for the measuring capacitance 5 are determined.

Knowing the measured values of r _{tr races j} and the corresponding values of φ _j determined from the graphical dependence, they build the desired calibration dependence in graphical form.

Claims (1)

A method for calibrating a means for measuring the volume fraction of free gas in a gas-liquid mixture transported through a pipeline, based on the measurement of ionizing radiation transmitted through a gas-liquid mixture, comprising measuring the amount of scattered radiation r _tr.races recorded during irradiation of the gas-liquid mixture with a wide beam of ionizing radiation and determination, based on the measurements, of a calibration dependence relating the volume fraction of free g aza φ in a gas-liquid mixture with a value of r _tr.sup. , in order to obtain the indicated calibration dependence, mixtures with a known volume fraction of free gas are used, characterized in that mixtures with a known volume fraction of free gas are formed in a measuring vessel made of the same material and having the same geometrical dimensions in the cross-sectional plane as the working section of the pipeline, with the measuring capacitance for each of the gas-liquid mixtures with a known value φ _i measured value etc. was walking therethrough direct ionizing radiation r _pr.i recorded by irradiation of a narrow beam of ionizing radiation, including measurement of r _pr.0 radiation recorded by irradiating the mixture, which is a liquid-free gas, and the values r _app.1 radiation registered by irradiating the mixture is a gas, whereupon a relationship relating the volume fraction φ of free gas in the gas-liquid mixture with a quantity of free gas volume fraction φ, _etc., contained in the t per part of the volume of the indicated gas-liquid mixture, which is irradiated with a narrow beam of ionizing radiation, calculating the values of φ _ai , corresponding to the known values of φ _i , by substituting the measured r _ai , r _{ave 0} , r _{ave 1} in the equation obtained on the basis of Lambert-Baire Law

and then at the working section of the pipe for a number of gas-liquid mixtures with unknown free gas volume fraction φ _j scattered radiation measured value r _tr.rass.j and further measured value r _tr.pr.j direct radiation, the direct radiation measured value _{Tr r. pr.0} , filling the working section of the pipeline with gas-free liquid, and the radiation value r _tr.sub.1 , filling the working section of the pipeline with gas, then calculate the values of volume fractions of free gas φ _pr.j contained in that part of the gas-liquid volume mixtures with unknown values of φ _j , which is irradiated with a narrow beam of ionizing radiation, by substituting the measured values of r _tr.sub.j , r _tr.sub.0 , t _tr.sub.1 in the above equation, and then, according to previously obtained for measuring capacitance depending linking φ value with the value of φ, _etc., are the respective values computed numerical values _pr.j φ φ _j, a then produced based on the measurement values of r _tr.rass.j and found values φ _j define the required calibration relationship associating volumetric of the free gas fraction φ in the gas-liquid mixture with a value of r _tr.rass .

Images