RU2640341C2 - Method of selecting liquid samples from pipeline and device for its implementation - Google Patents

Abstract

FIELD: measuring equipment.SUBSTANCE: device includes a sampling device installed in the main pipeline, a bypass line from the main pipeline, a sampling element for automatic sampling, a dispersant, a sampling element for manual sampling, a sampler. The bypass line is connected in series with the sampling device. In this case, the dispersant and a sampling element for manual sampling are installed behind the sampling element for automatic sampling along the flow path of the bypass line from the main pipeline from the condition of increasing the differential head on the sampling element for automatic sampling. When the sampling device is simultaneously a sampling pipe for automatic sampling, the dispersant at the sampling site is set from the condition of increasing the differential head on the sampling device. The dispersant is used as an element to increase the differential head on the sampling element for automatic sampling. The dispersant is carried out with a variable cross-sectional configuration along the flow path, provided that in the horizontal part of the pipeline the average width of the pipeline internal cross-section in the horizontal plane is less than the average height of the pipeline internal cross-section in the vertical plane, and in the vertical part of the pipeline, so that the cross-section area of the passage decreases along the flow direction. The sampling device with the main pipeline is strapped by means of a bypass line from the main pipeline. The part of the flow of the main pipeline is pumped under the influence of excess pressure through the sampling device and a bypass line connected in series with the main pipeline. The bypass line from the main pipeline is connected with an automatic sampler channel and a sampling element. A dispersant and a sampling element are installed for manual sampling for the sampling element for automatic sampling along the flow path of the bypass line from the main pipeline. The strapping of the elements is performed from the condition of increasing the differential head in the channel connecting the bypass line from the main pipeline with the automatic sampler, in comparison with the differential head created due to the velocity head of the flow of the bypass line from the main pipeline or due to the velocity head of the main pipeline flow. Sampling is carried out by an automatic sampler from this channel. Manual sampling is carried out from the flow of the bypass line from the main pipeline. The strapping of the elements is performed with the formed transformation of the cross-section of the flow or its part at the sampling site.EFFECT: high accuracy with quantitative and qualitative accounting of fluid pumped through the pipeline, conducted on a set of parameters.2 cl, 4 dwg

Description

The invention relates to technology and techniques for sampling liquid from a pipeline and can find application in oil and other industries where high accuracy is required for determining the parameters of the fluid pumped through the pipelines.

A known method of sampling fluid from a pipeline, in which, with an inhomogeneous fluid flow of the main pipeline, a slot-type sampling device or a sampling device in the form of sampling tubes with bent ends are placed in the main pipeline, and a sampling device in the form of one tube with a uniform fluid flow is placed in the main pipeline with a bent end, regardless of the diameter of the pipeline, while on a horizontal section of the main pipeline the outlet of the sampling device placed on top; bind the sampling device to the main pipeline using a bypass from the main pipeline (equivalent terms: bypass pipe, bypass pipe) with the possibility of ensuring a constant movement of a portion of the pumped liquid through the sampling device along the bypass line from the main pipeline and returning the pumped part of the liquid back to the main pipeline, the bypass line may include transitions, one or more dispersants with a dis the oblique section of the sampling tube actuators, which constantly pump part of the main pipeline flow through the sampling device under the influence of excess pressure and the bypass line connected to it from the main pipeline at a fluid velocity at the inlet of the sampling device equal to the average linear fluid velocity in the main pipeline or differing from it by no more than two times, with the use of a pumping pump installed in the bypass line; connect the bypass line from the main pipeline to the automatic sampler channel using the sampling and connecting tubes, while they can form a bypass line from the bypass line from the main pipeline with the possible replacement of some of it (bypass line from the bypass line from the main pipeline) part of the channel in the case of automatic sampler sampling performed autosampler from this channel by selecting a sampling point, the volume of which is set from 1 to 10 cm ^3, and Lib them probosbornik to a volume of not less than 3000 cm ³ without stopping the movement in the flow line from the main pipe, manual selection is performed from the sample stream flow loop from the primary pipeline to GOST 2517-85. Change No. 1. Amendment, paragraph 2.13, damn. 18a, damn 18b, p. 1.5.4.5, [1].

Note 1. To hell. 18a), 18b), [1], the tap for manual sampling and the locking device of the automatic sampler are connected to the bypass line from the main pipeline (in terms of clauses 2.13.2.2 and 2.13.2.3 [1]) have a connection without a sampling tube.

A device for implementing this method is known, including a sampling device installed in the main pipeline, which is a slot-type device or a device in the form of sampling tubes with bent ends with an inhomogeneous fluid flow of the main pipeline or which is a device in the form of a single tube with a bent end, regardless of the diameter of the pipeline with a uniform fluid flow of the main pipeline, while on the horizontal section of the main pipeline the sampling outlet is Wow devices are placed on top; a bypass line from the main pipeline, connected in series with a sampling device, a sampling element for manual sampling, mounted on a bypass from the main pipeline, a disperser, and / or sampling tube, and / or a tap for manual sampling, a sampling element for automatic sampling, a dispersant and / or sampling tube, an automatic sampler with connecting tubes, while the sampling tube and connecting tubes may form a bypass line from the bypass the second line from the main pipe with possible replacement of some of its (the bypass line by a bypass line from the main duct) part of the channel in the housing autosampler, pump, mounted on a bypass of the main pipe, probosbornik, one or two, GOST 2517-85. Change No. 1. Amendment, paragraph 2.13, damn. 18a, 18b, [2].

A disadvantage of the known sampling technique [1-2] is the deterioration in the representativeness of sampling at the stage of automatic sampling. The time interval between the selection of the next point sample is calculated in minutes, for example 5 or 10 minutes. During this time, the fluid in the connecting tubes under the influence of gravity exfoliates and the composition of the fluid changes due to the communication of the connecting tubes with a bypass line. As a result, the spot sample does not correspond in composition to the flow of the bypass line.

A known method of sampling fluid from a pipeline, in which, with an inhomogeneous fluid flow of the main pipeline, a slot-type sampling device or a sampling device in the form of sampling tubes with bent ends are placed in the main pipeline, and a sampling device in the form of one tube with a uniform fluid flow is placed in the main pipeline bent end, regardless of the diameter of the pipeline or sampling device, which is a tube with an oblique cut on the pipeline with a conditional diameter with a meter of 50 mm, while on the horizontal section of the main pipeline, the outlet node of the slot-type sampling device or in the form of tubes with bent ends is placed at the top, and the sampling device exit node in the form of a tube with an oblique cut is placed at the bottom; the sampling device is strapped to the main pipeline using a bypass line from the main pipeline with the constituent elements of the bypass line, in particular a disperser for connecting an automatic sampler to it, while the strapping is carried out with the possibility of directing part of the bypass line flow from the main pipeline through the automatic sampler body with return it into the flow of the bypass line from the main pipeline, for which they connect the bypass line from the main pipeline to the automatic Attic sampler channel, - the connection is made using two connecting tubes installed on the sampler body, communicating with each other through a cavity in the sampler body, from which the automatic sampler performs the selection of point samples, while the free ends of the tubes are connected; one end is connected through a tee to a sampling tube with an oblique slice mounted below in the disperser body to connect an automatic sampler to it, the other end is connected to an opening in the disperser case for connecting an automatic sampler located behind the sampling tube with an oblique cut along the bypass flow lines from the main pipeline; in this connection, the sampling and connecting tubes form a bypass line from the bypass line from the main pipeline, in which part of it is replaced by a channel in the body of the automatic sampler; the strapping of the elements is carried out from the condition of increasing the pressure drop in the channel connecting the bypass line from the main pipeline to the automatic sampler, compared with the pressure drop created due to the high-pressure head of the bypass line flow from the main pipeline or due to the high-pressure head of the main pipeline flow, at which the cross section of the bypass flow from the main pipeline or the main pipeline and thereby increase the pressure drop in the channel connecting m bypass line from the main pipeline with an automatic sampler; transformation of the flow section is carried out by placing in a removable part of the bypass line from the main pipeline or the main pipeline, namely in the disperser housing for connecting an automatic sampler, an additional dispersant in the form of a transition, which is a truncated cone, with a smaller base facing the flow, with an additional dispersant between a sampling tube with an oblique cut and a hole made in the dispersant housing for connecting automatically th sampler for sample probe tube with an oblique cut; sampling by an automatic sampler from this channel is carried out, when part of the main pipeline flow through the sampling device / sampling tube with an oblique cut and the bypass line connected from it from the main pipeline with its return to the main pipeline is constantly pumped under the influence of excessive pressure; sampling by an automatic sampler is carried out by sampling point samples, the volume of which is set from 1 cm ³ to 10 cm ³ , and draining them into a sample collector for an automatic sampling method to a volume of at least 3000 cm ³ , manual sampling is carried out from the bypass stream from the main pipeline through a tap for manual sampling, installed on the bypass line from the main pipeline / tee connected to the sampling tube with an oblique cut. The method of sampling fluid from the pipeline / Passport 03.004.001 PS, combined with a technical description and operating instructions. Sampler automatic "Selection-A-Rsliv" [3] (prototype method).

Note 2. During the operation of the automatic Sampling-A-Rsliv sampler [5] in accordance with its purpose [5], it can be operated in accordance with GOST 2517-85 [6, 7], in particular according to [1]. Therefore, the list of operations [3] includes operations of the analogue method [1] listed above.

A device for implementing this method is known, including a sampling device installed in the main pipeline, which is a slot-type device or a device in the form of sampling tubes with bent ends with an inhomogeneous fluid flow of the main pipeline or which is a device in the form of a single tube with a bent end, regardless of the diameter of the pipeline with a uniform fluid flow of the main pipeline, or the sampling device is a tube with an oblique cut to the pipeline with the condition with a distinct diameter of 50 mm, while on a horizontal section of the main pipeline, the slot-out sampling device outlet unit or in the form of tubes with bent ends are placed at the top, and the sampling device outlet assembly in the form of a tube with an oblique cut is placed at the bottom; a sampling device can be installed on a removable / non-removable section of the main pipeline; a bypass line connected in series with a sampling device from the main pipeline with a nominal diameter of 50 mm, the removable part of which includes a disperser for mounting an automatic sampler, in the housing of which are installed:

a constricting device, a dispersant in the form of a truncated cone, with a smaller base facing the flow, used as an element to increase the pressure drop in the connecting pipes of the automatic sampler, connecting the bypass line from the main pipe to the automatic sampler,

and a sampling element for automatic sampling in the form of a sampling tube with an oblique cut, which is installed from the bottom;

a connecting pipe is connected to the latter through a tee, connecting the cavity in the body of the automatic sampler, from which the point-and-point sample is taken by the automatic sampler; the cavity in the case of the automatic sampler through the second connecting tube is connected to the hole made in the disperser body for connecting the automatic sampler behind the sampling tube with an oblique cut along the flow of the bypass line from the main pipeline; in this connection, the sampling and connecting tubes form a bypass line — a channel — from the bypass line from the main pipeline, in which part of it is replaced by a channel in the body of the automatic sampler, and an additional disperser is installed behind the sampling element for automatic sampling along the bypass stream from the main pipeline from the condition of increasing the pressure drop across the sampling element for automatic sampling or when the sampling device is simultaneously a booster element for automatic sampling, the dispersant in the sampling section is installed from the condition of increasing the differential pressure on the sampling device;

sampling element for manual sampling - a valve for manual sampling, installed on the bypass line from the main pipeline from the condition of increasing the pressure drop on the sampling element for automatic sampling, behind the sampling element for automatic sampling along the flow of the bypass line from the main pipeline (note , the bypass stream consists of two parts: one is routed through the body of the autosampler, and the other is routed through the disperser to be connected I autosampler), namely, the tap for manual sampling is mounted on a bypass of the main line pipe or tee mounted on the probe member for automatic selection of the sample; a sampler (note, the equivalent term for a sampler is a sampler), consisting of two cylinders, a program control unit, an automatic sampler installation kit, which can also include any of the listed features of the device, in addition to the automatic sampler for using the automatic sampler for its intended purpose (implementation sampling in full accordance with the method of sampling fluid from pipelines [1]). A device for sampling liquid from a pipeline / Passport 03.004.001 PS, combined with a technical description and operating instructions. Sampler automatic "Selection-A-Rsliv" [3] (prototype device).

Note 3. Sampler automatic “Selection-A-Rsliv” [5], when operated in accordance with GOST 2517-85, [6-7], in particular in accordance with [1], can only work as part of a device [2] , without it, the automatic Sampling-A-Rsliv sampler [5] cannot be operated in accordance with GOST 2517-85 [1], [6-7]. Therefore, since the case of the automatic Sampling-A-Rsliv sampler [5] is considered in accordance with GOST 2517 [1], it includes the attributes of the GOST 2517-85 device [2].

The disadvantages of the known technology and sampling techniques [3-4].

To analyze the known technique [3-4], we use the hydraulic circuit of the prototype device [4], shown in FIG. 1, in which the elements included in it have the following designation: a removable section 1 of the bypass line 2 from the main pipeline 3; the removable section 1 is a coil in the form of a Venturi tube with a variable cross-section (a disperser for connecting an automatic sampler to it), a sampling device 4 installed in the main pipeline 3, a bypass line 2 from the main pipeline 3, connected in series with the sampling device 4; a sampling element for automatic sampling in the form of a sampling tube 5, which is installed below in the removable part 1 of the bypass line 2 from the main pipe 3; a connecting tube 6, which interconnects the automatic sampler 7 and the sampling tube 5; a connecting pipe 8, which with a connecting pipe 6 and one of the branches of the branched channel 9 in the case of the automatic sampler 7 form a bypass line 10 from the bypass line 2 from the main pipe 3; dispersant 11 (optional), used as an element to increase the differential pressure on the sampling tube 5 and in the connecting tubes 6 and 8 of the automatic sampler 7, the dispersant 11 is installed in the removable part 1 of the bypass line 2 between the sampling tube 5 and the end of the connecting tube 8, located on a removable section 1 of the bypass line 2 behind the sampling tube 5 along the flow of the bypass line 2 from the main pipe 3, the sampling element for manual sampling - a valve 12 for manual sampling, installed taken along the flow of the bypass line 10 on the tee 13 of the connecting tube 6 after the sampling element for automatic sampling, that is, after the sampling tube 5; samplers 14 and 15, a pump 16 installed on the bypass line 2 from the main pipeline 3. In order to increase the pressure drop across the sampling element, a known device [3-4] uses a device (narrowing device) —dispersant 11 (narrowing the section leads to dispersion, that is, the narrowing device is a special case of the execution of the dispersant), which narrows the passage section of the pipeline (bypass line from the main pipeline); dispersant 11 is located in the housing of the removable part 1 (dispersant for mounting an automatic sampler). The configuration of the dispersant 11 is a truncated cone (transition), with a smaller base facing the flow. This leads to the fact that a pocket appears around the cone, where there is an increase in the concentration of impurities (water droplets, solids, other inclusions), which leads to a change in the composition of the flow in the fluid withdrawal zone, which contradicts clause 1.5.4.5 of the normative document ) [one]. As a result, the representativeness of the sample taken according to known solutions is deteriorating [3-4].

The technical result of this invention is to increase the representativeness of the sample.

To achieve a technical result in a method for sampling liquid from a pipeline, in which a sampling device is placed in the main pipeline,

carry out the binding of the sampling device with the main pipeline using a bypass line from the main pipeline,

pumped under the influence of excess pressure, part of the flow of the main pipeline through the sampling device and a bypass line connected to it from the main pipeline in series

connect the bypass line from the main pipeline to the automatic sampler channel,

the strapping of the elements is carried out from the condition of increasing the pressure drop in the channel connecting the bypass line from the main pipeline to the automatic sampler, compared with the pressure drop created due to the high-pressure head of the bypass line from the main pipeline or due to the high-pressure head of the main pipeline flow,

sampling by an automatic sampler from this channel,

carry out manual sampling from the bypass flow from the main pipeline, according to the invention, the elements are strapped from the condition of increasing the pressure drop in the channel connecting the bypass from the main pipeline to the automatic sampler, so that the transformation of the cross section of the flow or part thereof the sampling area occurred under the condition that, with the horizontal direction of fluid flow, their average width was less than the average height, and with vertical The direction of fluid travel to their cross-sectional area decreases along the flow of fluid motion.

In the claimed method, the distinguishing feature is the sign: the strapping of the elements from the condition of increasing the pressure drop in the channel connecting the bypass from the main pipeline to the automatic sampler is performed so that the transformation of the cross section of the flow or part of it formed at the sampling site is formed - the main a pipeline with a sampling circuit (sampling device with a bypass line from the main pipeline with elements placed on it; the sampling circuit may it was placed on a removable section of the main pipeline), provided that, with the horizontal direction of the fluid (flow), their average width was less than their average height, and with the vertical direction of the fluid (flow), the cross-sectional area decreased along the fluid (flow), in particular, the transformation of the flow section is carried out by placing an element in the pipeline, which provides the corresponding transformation of the flow section from the condition of increasing the pressure drop in the channel, calling a bypass line from the main pipeline with an automatic sampler. This provides an excess pressure drop and an increase in pressure drop in the channel connecting the bypass line from the main pipeline to the automatic sampler, but with this transformation of the flow section there is no change in the composition of the stream, and therefore, into the channel connecting the bypass line from the main pipe to the automatic sampler, an identical part of the bypass line flow from the main pipeline will flow (note, the bypass from the main pipeline is for pumping and part of the flow of the main pipeline, respectively, the bypass line from the bypass line from the main pipeline is designed to pump part of the flow of the bypass line from the main pipeline). This distinguishes the claimed solution from the prototype [3] - this eliminates the pocket in the area of the element to create an excess pressure drop in the bypass line. As a result of the implementation of the set of operations that make up the common and distinctive features when implementing the proposed method, the representativeness of the sample increases, which ensures its higher quality than when implementing the prototype method [3].

Thus, the implementation of the operations of the common features of the proposed method together with the operations of the distinguishing features will allow, in comparison with the prototype method [3], to increase the representativeness of the sample.

The application of the proposed method will allow for a representative sampling, reduce fluid loss during accounting operations.

To achieve a technical result in the implementation of the proposed method using a device that includes:

a sampling device installed in the main pipeline;

a bypass line from the main pipeline, connected in series with the sampling device;

dispersant,

sampling element for manual sampling;

sampling element for automatic sampling;

sampler

wherein the dispersant and the sampling element for manual sampling are installed behind the sampling element for automatic sampling along the flow of the bypass line from the main pipeline from the condition of increasing the pressure drop across the sampling element for automatic sampling or when the sampling device is simultaneously a sampling element for automatic sampling , the dispersant in the sampling area is installed from the condition of increasing the pressure drop on the sampling device,

according to the invention, the dispersant used as an element to increase the pressure drop across the sampling element for automatic sampling is performed with a variable cross-sectional configuration along the stream, in which it is made from conditions so that on the horizontal section of the pipeline the average width of the pipe cross-section in the horizontal plane is less than the average height of the pipe cross section in the vertical plane, and in the vertical section of the pipeline so that the cross sectional area and in the direction of flow decreased.

In the inventive device, the distinguishing feature is the dispersant, used as an element to increase the pressure drop across the sampling element for automatic sampling, performed with a variable cross-sectional configuration along the stream, in which it is made from conditions so that the average width of the pipeline cross section on a horizontal section of the pipeline in the horizontal plane was less than the average height of the pipeline cross section in the vertical plane, and on the vertical section of the pipeline th In general, the cross-sectional area of the passage in the direction of flow decreased.

Due to this distinguishing feature, when sampling using the inventive device, in contrast to the prototype [4], there is no change in the composition of the bypass line flow from the main pipeline in the sampling zone, in particular when the bypass line flow rate decreases from the main pipeline.

As a result, the use of the claimed device provides the selection of a more representative sample than the sample obtained by the prototype device [4].

Thus, the claimed device due to its distinctive features will allow for the selection of a more representative sample (in contrast to the prototype device [4]).

The inventive method of sampling liquid from a pipeline and a device for its implementation can be specifically applied, for example, in oil fields - at commercial oil metering stations.

The inventive method of sampling fluid from a pipeline is as follows.

In the main pipeline through which fluid is transported,

place a sampling device;

carry out the binding of the sampling device with the main pipeline using a bypass line from the main pipeline,

pumped under the influence of excess pressure, part of the flow of the main pipeline through the sampling device and a bypass line connected to it from the main pipeline in series

connect the bypass line from the main pipeline to the automatic sampler channel,

the strapping of the elements from the condition of increasing the pressure drop in the channel connecting the bypass line from the main pipeline to the automatic sampler is performed so that the transformation of the cross section of the flow or part of it formed in the sampling area is formed under the condition that, with the horizontal direction of fluid flow, their width was less than the average height, and in the vertical direction of the fluid flow so that the cross-sectional area of the flow decreased along the fluid tee

sampling by an automatic sampler from this drip,

carry out manual sampling from the bypass stream from the main pipeline. The sample taken in the sampler is sent for analysis - determination of the relative content of ballast in the sample.

The invention is illustrated in the drawing.

In FIG. 2 presents one of the variants of the inventive device for sampling liquid from a pipeline, FIG. 3 is a view of a dispersant used as an element to increase the pressure drop in the connecting tubes of the automatic sampler from the side of the incoming flow, when the removable section 1 of the bypass line is horizontal, 4 is a view of the dispersant used as an element to increase the pressure drop in the connecting pipes of the automatic the sampler from the side of the flow on it when the removable section 1 of the bypass line is vertical. In FIG. 3 and 4, the inner surface of the dispersant 11 is tinted.

The device of FIG. 2 includes, see also FIG. 3:

removable section 1 of the bypass line 2 from the main pipeline 3; the removable section 1 is a coil in the form of a venturi with a variable cross-section; a sampling device 4 installed in the main pipe 3; a bypass line 2 from the main pipe 3, connected in series with the sampling device 4; a sampling element for automatic sampling in the form of a sampling tube 5, which is installed below in the removable part 1 of the bypass line 2 from the main pipe 3; a connecting tube 6, which interconnects the automatic sampler 7 and the sampling tube 5; a connecting pipe 8, which with a connecting pipe 6 and one of the branches of the branched channel 9 in the case of the automatic sampler 7 form a bypass line 10 from the bypass line 2 from the main pipe 3;

dispersant 11 (see Fig. 2-3), used as an element to increase the differential pressure on the sampling tube 5 and in the connecting tubes 6 and 8 of the automatic sampler 7, the dispersant 11 is installed in the removable part 1 of the bypass line 2 between the sampling tube 5 and the end of the connecting tube 8, located on the removable section 1 of the bypass line 2 behind the sampling tube 5 along the flow of the bypass line 2 from the main pipe 3, the sampling element for manual sampling, - valve 12 for manual sampling, install the first downstream flow loop 10 at a tee 13 connecting tube 6, after the sample probe element for automatically sampling, i.e. after the sample probe tube 5; samplers 14 and 15.

The device is also equipped with a pump 16 installed on the bypass line 2 from the main pipeline 3.

The inventive device for sampling fluid from a pipeline, FIG. 2, is intended for sampling liquid from the flow of the main pipeline 2 using an automatic sampler 7 installed on a removable section 1 of the bypass line 2 from the main pipeline 3 using sampling 5 and connecting tubes 6 and 8; the removable section 1 of the bypass line 2 from the main pipe 3 also serves to mix the fluid flow passing through it. Serially connected sampling device 4 and the bypass line 2 from the main pipe 3 are designed for constant pumping through them part of the flow of the main pipe 2. Sampling pipe 5, connecting pipes 6, 8, and one of the branches of the branched channel 9 in the case of the automatic sampler 7, which connects tubes 6 and 8 form a bypass line 10 from a bypass line 2 from the main pipe 3 for constant flow of part of the flow through the sampling tube 5 and the bypass line 10. Another part of the branched channel Ala 9 connects the automatic sampler 7 with the bypass line 10, from which the automatic sampler 7 takes the point samples sent to the sampler 15. The disperser 11 is designed to increase the pressure drop in the channel formed by the bypass line 10, that is, on the sampling tube 5, in the connecting tubes 6 and 8, channel 9. The valve 12 is designed for manual sampling. Sampler 14 serves as a container (sampler) into which a sample is taken through a valve 12 for manual sampling, sampler 15 - as a tank for sampling automatically using an automatic sampler 7. Pump 16 is designed to continuously transfer part of the flow of the main pipe 3 through sampling device 3 bypass line 2 from the main pipeline 3.

The device for sampling fluid from the pipeline of FIG. 2 works as follows.

Part of the fluid flow from the main pipeline 2 under the influence of the excess pressure created by the pump 16 is constantly pumped through the sampling device 4 and the bypass line 2 connected in series with it from the main pipeline 3. On the removable section 1 of the bypass line 2 from the main pipeline 3, the flow is mixed due to variable section of section 1 and its implementation in the form of a venturi. When this happens, the flow section is transformed when dispersant 11 passes through it. As a result of the transformation of the flow cross section of the bypass line 2 from the main pipeline 3 in the channel formed by the bypass line 10, the pressure drop increases, while the pressure drop between the inlet on the sampling tube 5 and the outlet of the connecting pipe increases tube 8, which provides a constant movement of fluid along the bypass line 10. Moreover, due to the fact that the dispersant 11 (see Fig. 2-3), used as an element to increase the differential the pressure in the sampling tubes 5 and connecting 6, 8, is performed with a variable cross-sectional configuration along the stream, in which the dispersant 11 is made on a horizontal section of the pipeline so that the average width of the pipe cross section in the horizontal plane is less than the average pipe cross section height in the vertical the plane, in the vertical section of the pipeline dispersant 11 is made from the condition that the cross-sectional area of the passage in the direction of flow decreases, eliminates the cost pockets collision of a location area 11 and therefore the dispersant composition of the flow tube in the sample probe location area 5 is not subject to change. As a result, the fluid flows in the bypass line 10 and the bypass line 2 from the main pipe 3 on the removable section 1 are adequate in composition of the part of the bypass line 2 stream from the main pipe 3. As a result, the sample taken in the samplers 14 and 15 manually or automatically using the device of FIG. 2, characterized by high quality.

For testing, a device for sampling fluid from the pipeline of FIG. 2 with the design parameters given below.

The inner diameter of the pipelines, the main 3 and the bypass line 2, 49 mm. The liquid transported through pipeline 3 is engine oil with a water content of 3% vol. The output of the dispersant 11 (upstream) was elliptical with the horizontal location of the removable section 1 of the bypass line 2 and in the shape of a circle with the horizontal location of the removable section 1 of the bypass line 2. The horizontal diameter of the dispersant 11 from the output side (upstream) was 10 times smaller than the vertical diameter with the horizontal location of the removable section 1 of the bypass line 2, FIG. 3. With the vertical location of the removable section 1 of the bypass line 2, the flow was upward, and the outlet diameter of the dispersant 11 was 4 times smaller than the inlet diameter, FIG. 4. The flow rate in the main pipeline was 0.5 m ³ / h.

Comparative tests of the inventive method and device for sampling liquid from the pipeline were carried out using the sampling method [3] and the sampling device [4], FIG. 1. In this case, the removable section 1 of the device [4] was installed on the horizontal section of the bypass line 2 from the main pipeline 3.

Comparative tests showed that the water content in the sample taken using the method and device [3-4] exceeded the actual one by 15-21%, and the water content in the sample taken using the claimed solutions did not exceed 3% regardless of the location of the removable section 1, FIG. 2 and changes in this configuration of dispersant 11, FIG. 3-4. These experimental data confirm the conclusions of a previous analysis of the known technique [3-4] that the dispersant 11 used in it as a transition with a smaller base facing the flow in the bypass line 2 from the main pipeline 3 prevents the flow from flowing freely, changes the diagram of the velocity distribution in the cross section flow, forms stagnant zones near the sampling zone, where water droplets accumulate. This has a negative effect on the representativeness of the sample using known sampling techniques [3-4]. On the contrary, the use of dispersant 11 in full accordance with the distinguishing features of the claimed sampling technique eliminates the change in the composition of the flow in the sampling zone and thereby ensures a higher representativeness of the sample. Moreover, if we confine ourselves to a section of the selection scheme, FIG. 2, namely for the main pipeline to take the bypass line 2, and for the bypass line 10 - the sampling device 4, and the main pipe 3 to exclude from the diagram, the test results will mean the case when the dispersant 11 is installed in the main pipeline. The conclusions in this case, quite obviously, will remain the same.

Thus, the data of comparative tests confirm that when sampling from the pipeline flow according to the claimed method and device, it will be characterized by a higher quality than the sample taken using known techniques [3-4].

The inventive sampling method and device for its implementation are industrially applicable, they do not require radical reconstruction of existing metering units for liquids pumped through pipelines, and the changes necessary to implement the inventive technique can be carried out by the manufacturers who service these systems.

Literature

1. The method of sampling fluid from the pipeline / GOST 2517-85. Change No. 1. Amendment, paragraph 2.13, damn. 18a, damn 18b, p. 1.5.4.5, [1].

2. A device for sampling liquid from a pipeline / GOST 2517-85. Change No. 1. Amendment, paragraph 2.13, damn. 18a, damn 18b, p. 1.5.4.5. [one].

3. The method of sampling fluid from the pipeline / Passport IKB 03.004.001PS, combined with the technical description and operating instructions. Sampler automatic "Selection-A-Rsliv".

4. A device for sampling liquid from a pipeline / Passport IKB 03.004.001PS, combined with the technical description and operating instructions. Sampler automatic "Selection-A-Rsliv".

Claims (2)

1. A method of sampling liquid from a pipeline in which a sampling device is placed in the main pipeline, the sampling device is connected to the main pipeline by a bypass line from the main pipeline, a part of the main pipeline flow is pumped through the sampling device under the influence of excessive pressure and connected in series with it a bypass line from the main pipeline, connect the bypass line from the main pipeline to the automatic sampler channel and a sampling element, install a disperser and a sampling element for manual sampling behind the sampling element for automatic sampling along the flow of the bypass line from the main pipeline, the piping of the elements is performed from the condition of increasing the pressure drop in the channel connecting the bypass from the main pipeline to the automatic sampler, compared with the pressure drop created due to the high-pressure head of the bypass line flow from the main pipeline or due to the high-pressure head of the main pipeline flow, sampling by an automatic sampler from this channel is carried out, manual sampling is performed from the bypass flow from the main pipeline, characterized in that the elements are strapped with the transforming the cross section of the flow or its part in the sampling section, provided that, with horizontal the direction of the fluid flow, the average width of the pipeline cross section in the horizontal plane was less than the average height of the pipeline cross section in the vertical plane, and in the vertical direction of the fluid flow, the cross-sectional area of the flow passage or part thereof decreased along the fluid path. 2. A device for sampling liquid from a pipeline, which includes: a sampling device installed in the main pipeline; a bypass line from the main pipeline, connected in series with the sampling device; sampling element for automatic sampling; dispersant, sampling element for manual sampling; sampler; wherein the disperser and the sampling element for manual sampling are installed behind the sampling element for automatic sampling along the bypass flow from the main pipeline from the condition of increasing the pressure drop across the sampling element for automatic sampling or when the sampling device is simultaneously a sampling tube for automatic sampling samples, the dispersant at the sampling site is set from the condition of increasing the pressure drop on the sampling device, distinguishing the fact that the dispersant used as an element to increase the pressure drop across the sampling element for automatic sampling is performed with a variable cross-sectional configuration along the stream, provided that on the horizontal section of the pipeline the average width of the pipe cross-section in the horizontal plane is less than the average height the cross-section of the pipeline in the vertical plane, and in the vertical section of the pipeline, so that the cross-sectional area of the passage in the direction of flow decreases.

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