RU85232U1 - SAMPLING DEVICE - Google Patents

Abstract

1. A device for sampling a liquid containing a housing; a piston mounted in the housing with the ability to move, dividing the internal cavity of the housing into two chambers, the first of which is made with the possibility of hydraulic communication with the circuit of the first fluid through the first inlet pipe, and the second is made with the possibility of hydraulic communication with the circuit of the second fluid through the second inlet pipe ; a sampler installed in the circuit of the second fluid, adapted for sampling from the second chamber; wherein the first inlet pipe has a portion located on the side of the first fluid circuit, made in the form of a bypass adapted for continuous passage of a portion of the first fluid circuit flow therein during sampling; despite the fact that a valve is installed on the first inlet pipe to ensure that a single sample of the first fluid passes from the bypass line into the first chamber during the sampling of the second fluid from the second chamber, and a shut-off element; moreover, the housing is mounted with the possibility of disconnecting it from at least a part of the first inlet pipe and from at least a part of the second inlet pipe, characterized in that the total volume of the first and second chambers is selected from a range from about 500 cm3 to about 10000 cm3 . ! 2. The device according to claim 1, characterized in that the possibility of disconnecting the housing from the first inlet pipe is provided by performing a portion of the first inlet pipe on which the shut-off element is placed, in the form of a high pressure sleeve with a quick-detachable

Description

The utility model relates to measuring equipment, in particular, to devices for sampling liquid from a pipeline, and can be used in oil and other industries where accuracy is required for determining the parameters of the fluid pumped through the pipelines.

Known from patent RU No. 2305770 (publ. 2007.09.10), a storage sampler containing a pipeline, a housing in the form of a pipe with a hollow stem and valve. The hollow rod is rigidly and hermetically connected to the pipeline and is made in the form of a pipe with a beveled end and radial holes placed against the fluid flow from the opposite cut of the beveled end of the side of the rod. The pipeline behind the stem is equipped with a restriction. The second end of the pipe is hermetically connected to the pipeline for its narrowing in the zone of low pressure. The pipe between the valve and the second end is equipped with a cylindrical casing with a piston, made with the possibility of axial movement relative to the casing, on the side of the valve provided with a drain pipe. The piston is equipped with a valve that allows fluid to pass through from the valve side. The valve is made in the form of a cylinder with an electromagnet and a rod inserted tightly into the cylinder with the possibility of axial movement using an electromagnet. The cylinder is equipped with an exhaust pipe and is in communication with a drain pipe. Branch pipes are blocked by a rod. The stem is equipped with two annular grooves. The first groove is made with the possibility of communication of the pipe with the cylinder and tight shutoff of the pipe when moving the rod in the cylinder, and the second with the possibility of communication of the drain and exhaust pipes when moving the rod in the cylinder.

Known from patent RU No.RU 2213948 (publ. 2003.10.10) a method of sampling liquid from a pipeline and a device for its implementation. In the method, the pumping of the fluid duct is carried out under the influence of excess pressure through the pipeline and point samples are taken by an automatic sampler. Between the time periods during which the automatic sampler performs the selection of spot samples, mixing along the pipeline fluid flow to align and distribute the ingredients in the stream. The device has a channel connecting the pipeline to the automatic sampler. A mixer is installed on the pipeline in front of the channel to mix the liquid stream along the pipeline to equalize and distribute the ingredients in the stream between time periods during which point sampling is performed by the automatic sampler.

A disadvantage of the known methods and devices is not high enough representativeness and reliability of sampling.

There are also many types of continuous float densitometers that differ in the design and shape of the float, the type (mechanical, electrical, pneumatic, optical) and the principle (inductive, potentiometric) of the float displacement transducer.

Known float devices for measuring the density of a liquid (Kivilis S.S. Density meters. - M .: Energy, 1980, pp. 25-34). To measure density using a hydrometer, the relationship between the density of the fluid being monitored and the depth of immersion at which the hydrometer comes into equilibrium is used. The disadvantage of the hydrometer is the occurrence of large errors due to the evaporation of light fractions from oil.

A well-known pressure pyknometer of the English company Stanhope Set Limited (Belyakov V.L. Automatic control of the parameters of oil emulsions. - M .: Nedra, 1992, pp. 187-189), which is a calibrated metal vessel made in the form of a cylinder with by cranes. An oil sample is taken from the pipeline into this vessel, and then the vessel is weighed on a precision balance. By dividing the mass of oil by volume, the density of oil is obtained. The pressure pycnometer is very difficult to manufacture and expensive.

It is known from patent No. 78942 (publ. 10.12.2008) selected for the prototype device for sampling from the pipeline, which includes a housing; a piston mounted in the housing with the ability to move, dividing the internal cavity of the housing into two chambers, the first of which is hydraulically connected to the circuit of the first fluid, and the second is hydraulically connected to the circuit of the second fluid; a sampler located in the second fluid circuit, adapted to take a given number of samples from a second chamber in a given time; wherein the first chamber is connected to the circuit of the first fluid via an inlet line having a portion arranged on the side of the circuit of the first fluid in the form of a bypass line that is adapted to continuously pass part of the flow path of the first fluid circuit during sampling of a given number of samples; despite the fact that a shut-off element and a valve are installed on the input line; providing the transmission of a single sample of the first fluid from the bypass line into the first chamber during the sampling of a single sample of the second fluid. In an embodiment, the device body is configured to disconnect from the second fluid circuit. A disadvantage of the known device is that the permissible working volumes of the chambers are not characterized.

The utility model is based on the task of creating a device for sampling from a pipeline, providing high quality sampling and improving the accuracy of measuring the parameters of the controlled fluid by increasing the representativeness and reliability of the selected sample by ensuring that it is kept under pressure and the selection of the necessary design parameters.

The problem is solved in that a device for sampling a liquid containing a housing; a piston mounted in the housing with the ability to move, dividing the internal cavity of the housing into two chambers, the first of which is made with the possibility of hydraulic communication with the circuit of the first fluid through the first inlet pipe, and the second is made with the possibility of hydraulic communication with the circuit of the second fluid through the second inlet pipe ; a sampler installed in the circuit of the second fluid, adapted for sampling from the second chamber; wherein the first inlet pipe has a portion located on the side of the first fluid circuit, made in the form of a bypass adapted for continuous passage of a portion of the first fluid circuit flow therein during sampling; despite the fact that a valve is installed on the first inlet pipe to ensure that a single sample of the first fluid passes from the bypass line into the first chamber during the sampling of the second fluid from the second chamber, and a shut-off element; moreover, the housing is mounted with the possibility of disconnecting it from at least part of the first inlet pipe and from at least part of the second inlet pipe, characterized by the following main and secondary distinguishing features.

It is advisable that the total volume of the first and second chambers is selected from a range of from about 500 cm ³ to about 10,000 cm ³ .

Preferably, the ability to disconnect the housing from the first inlet pipe is provided by performing a portion of the first inlet pipe on which the shut-off element is placed, in the form of a high pressure sleeve with a quick-detachable connection.

Preferably, the ability to disconnect the housing from the second inlet pipe is provided by performing a portion of the second inlet pipe from the side of the body in the form of a high pressure sleeve with a quick-detachable connection.

It is desirable that the device is configured to measure the temperature of the first fluid in the first chamber.

It is preferable that the total volume of the first and second chambers is selected from a range from 1000 cm ³ to 5000 cm ³ .

It is possible that a shut-off element is installed on the second inlet pipe from the housing side.

It is advisable that the sampler is an automatic sampler.

It is desirable that a discharge means adapted to supply the second fluid under pressure to the second chamber be arranged in the second fluid circuit.

It is possible that the second fluid is a viscous liquid, for example oil.

It is advisable that the circuit of the second fluid is closed and that a reservoir for storing the second fluid is connected thereto, communicated by its inlet with the outlet of the sampler and the outlet with the second chamber.

It is desirable that the housing was made in the form of a sealed cylinder.

In addition, the device may be configured to drain the first fluid from the first chamber.

It is possible that the device was equipped with a means for venting air pressure from the sampler and / or the first inlet pipe before sampling.

It is desirable that the circuit of the first fluid is the main pressure pipe, for example an oil pipeline.

Preferably, the valve is installed on the bypass line from the side of the outlet of the flow into the circuit with the first fluid.

It is advisable that the housing was mounted essentially vertically, and the first inlet pipe is designed so that the shut-off element mounted on it is located above the lower end wall of the housing.

It is possible that at least one end wall of the housing is made in the form of a removable cover.

It is advisable that the device is used to determine the density of the first fluid.

Other objectives and advantages will be clear from the following description with reference to the accompanying drawing, which shows:

Figure 1 - is a diagram of a device for sampling in one of the variants of its execution.

Figure 2 - is a diagram of a device for sampling in another embodiment.

Figure 3 is a graph of comparative measurements of the density of the liquid, on which the solid line represents the data obtained during the measurement by the inventive device, and the dashed line represents the data obtained during the measurement by the working densitometer.

In the drawings, similar or similar structural elements are denoted by the same positions, and the direction of flows is shown by arrows.

The device shown in Fig. 1 contains a vertically mounted cylindrical body 1, in which a piston 2 is placed that separates the internal cavity of the body 1 into two chambers isolated from each other - the first chamber 3, hydraulically connected through the first inlet pipe 4 to the circuit of the first fluid ( not shown), and a second chamber 5, hydraulically connected by means of the second inlet pipe 6 to the circuit of the second fluid 7.

At the first inlet pipe 4, a locking element 8 and a valve 9 are installed.

The first inlet pipe 4 from the side of the first fluid circuit has a first section, made in the form of a bypass line 10, through which a part of the flow path of the first fluid passes through it through the inlet 11 of the bypass line 10, which is adapted to connect the device to the first fluid circuit, and leaving through the output 12 of the bypass line 10 adapted for connecting the device to the circuit of the first fluid medium.

The valve 9 is installed on the bypass line 10 from the outlet 12 side and connects the first section (bypass line 10) of the first inlet pipe 4 with its second section 13, through which the first fluid enters from the bypass line 10 into the first chamber 3. The shut-off element 8 is mounted on the second section 13 of the first inlet pipe 4.

The locking element 8 is placed on the second section 13 of the first inlet pipe 4 from the side of the housing 1 so that it is at the same level with the lower end wall 14 of the housing 1 or slightly higher.

In the second section 13 of the first inlet pipe 4, in the direction of the flow of the first fluid in front of the shut-off element 8, a detachable connection 15 is made, which disconnects the lower chamber 3 with a part of the first inlet pipe 4 from the circuit of the first fluid. The section of the first inlet pipe 4 between the detachable connection 15 and the entrance to the first chamber 3 can be made in the form of a high pressure pipe with a quick connection.

The second chamber 5 of the housing 1 through the second inlet pipe 6 with a locking element 16 mounted on it through a tee 17 is connected to the circuit of the second fluid 7.

On the second inlet pipe 6 behind the shut-off element 16, a detachable connection 18 is installed, which allows you to disconnect the second chamber 5 of the housing 1 with a part of the second inlet pipe 6 from the circuit of the second fluid.

It is possible to perform a portion of the second inlet pipe 6 between the plug-in connection 18 and the tee 17 in the form of a high-pressure pipe with a quick-connect.

In the circuit of the second fluid 7, a sampler 19 is installed, the input of which along the line 20 through the tee 17 and the locking element 16 is connected with the second chamber 5 of the housing 1.

The output of the sampler 19 through line 21 is connected to the reservoir 22, intended for the second fluid.

The output of the reservoir 22 through the pump 23 along line 24 with a locking element 25 installed on it through a tee 17 connecting line 24 to the second inlet pipe 6 is connected to the second chamber 5 of the housing 1.

On line 24 between the pump 23 and the locking element 25 posted by a pressure gauge 26.

The valve 9 is designed so that when the shut-off element 8 is open, the flow of the first fluid from the bypass line 10 is provided through the second section 13 of the first inlet pipe 4 to the first chamber 3 at the time of taking a single sample of the second fluid by the sampler 19 from the second chamber 5 and the passage is stopped through the valve 9 of the fluid flow in the pause between the sampling of single samples, which prevents the ingress of impurities from the flow of the first fluid into the first chamber 3.

As valve 9, any suitable valve can be used to ensure flow in only one direction when exposed to a valve with a given pressure, for example, a spring valve or a controlled electronic valve.

The valve 9 can be made in the form of a ball placed with the possibility of its movement relative to the valve seat

The piston 2 is movable within the internal cavity of the housing for selectively changing the volume of the first or second chamber.

The total volume of the first chamber 3 and the second chamber 5 is selected depending on the required volume of the combined sample, consisting of a predetermined number of single samples and selected from the range from 500 cm ³ to 10,000 cm ³ , preferably from the range from 1000 cm ³ to 5000 cm ³ .

The discharge of the sample from the first chamber 3 in this embodiment is carried out through a detachable connection 15.

In embodiments, the locking element 8 may be rigidly connected to the lower end wall 14 of the housing 1, and the locking element 16 may be rigidly connected to the upper end wall 27 of the housing 1, i.e. in this case, the locking elements are part of the housing 1 (not shown).

Sampler 17 can be performed in any design, including can be automatic or non-automatic. The most appropriate use of the automatic sampler "Pulsar-AGI", made in accordance with patent No. 39707.

The pump 23 can be performed in any design, including with an electric drive.

The upper end wall 27 and / or the lower end wall 14 of the housing 1 can be made in the form of removable covers.

As the second fluid, any liquid may be used, including a viscous liquid, for example oil.

Ball valves (in the versions of the device with increased electrical safety) or controlled electrovalves (in the versions with the automatic control of the device) can be used as locking elements.

The circuit of the second fluid shown in FIG. 1 is closed. Variants are possible in which the circuit of the second fluid may be open, i.e. the outlet of the sampler 19 may be open (run for drain) or may be connected to another reservoir (not shown).

In the embodiment shown in FIG. 2, the device is additionally equipped with a drain line 29 connected to the first chamber 3 through a tee 28 with a locking element 30 installed on it.

The sampler 19 may be equipped with a means for venting air pressure 31, connected to it through a locking element 32.

The first inlet pipe 4 may also be equipped with a means for venting the air 33, connected to it through the locking element 34 and the tee 35. The venting is carried out in preparation for operation.

Part of the second section 13 of the first inlet pipe 4 between the tee 35 and the detachable connection 15 can be made in the form of a high pressure sleeve with a quick connection.

The device is configured to measure the temperature of the first fluid in the first chamber. To this end, the lower end wall 14 may be provided with a plugged hole 36, which in the open position is adapted to hermetically accommodate means for measuring the temperature of the first fluid in the first chamber 3.

The device is initialized by injection of a second fluid (for example, oil) from the tank 22 into the second chamber 5 using the pump 23. In this case, the locking element 8 is closed and the locking elements 16, 25 and 30 are open. The end of the filling is determined by the increase in pressure recorded by the pressure gauge 26. The full filling of the volume of the chamber 5 with the second fluid can be determined in any other suitable way, for example, by the volume of the second fluid that has left the tank 22. After filling the second chamber 5 and moving the piston 2 to its lowest position at the wall 14, the locking elements 25 and 30 are closed (Figure 2).

To collect the combined sample from the first fluid circuit, the shut-off element 8 is opened and the sampler 19 is put into operation.

At the time of sampling each single sample by the sampler 19, a fixed amount of the second fluid (for example, oil) is displaced through the sampler 19 from the second chamber 5 into the container 22, and the same amount of the first fluid from the bypass line 10, passing under the influence of pressure drop through the valve 9 , fills the first chamber 3. The volume of the product in one sampling is equal to the volume of a single sample installed on the sampler 19.

The selection is completed after the required volume of the combined sample of the first fluid is set, which is set in the settings of the sampler 19. In the first chamber 3, the collected combined sample is maintained under the pressure equal to the working pressure in the first fluid circuit until the sample is operated for 19.

To drain the selected sample, close the shut-off element 8, open the shut-off elements 25 and 30, and with the help of the pump 23, the second chamber 5 is filled with the second fluid from the tank 22. In this case, the liquid from the first chamber 3 is displaced by the piston 2 along the drain line 29 into the tank for the combined sample (not shown). The end of the drain is determined by the increase in pressure recorded by the pressure gauge 26. After the drain, the locking elements 25 and 30 are closed.

Further, the operation of the device is carried out cyclically. The proposed device can be used to determine the density of the sample taken. To determine the density used version of the device with a removable housing.

To determine the density with closed shut-off elements 8 and 16, the housing 1 was disconnected and weighed on an electronic balance along with the selected sample.

Density was calculated by the formula:

where MBR is the mass of the cylinder with the combined sample, g

Must is the known mass of the empty cylinder; g

Vpr - the volume of the combined sample, ml, determined by the formula:

V _ol = V _mouth · K _p , ml

where Vust - known cylinder capacity, ml

Cp is the coefficient of correction of the cylinder volume, calculated from the experimentally determined dependence of the cylinder capacity on pressure.

A series of the same type measurements was carried out for the same sampling time, at different pressures and densities of oil in the pipe, and the results were compared with the readings of a working density measuring device (Solartron type electronic flow densitometer).

The results of comparative measurements are reduced to normal conditions (15 ° C, 0 MPa) in graphical form are presented in Figure 3.

The tests showed high accuracy in measuring fluid density.

The proposed device for sampling from the pipeline provides high quality sampling under pressure and high accuracy of measurement of the parameters of the controlled fluid.

Claims (18)

1. A device for sampling a liquid containing a housing; a piston mounted in the housing with the ability to move, dividing the internal cavity of the housing into two chambers, the first of which is made with the possibility of hydraulic communication with the circuit of the first fluid through the first inlet pipe, and the second is made with the possibility of hydraulic communication with the circuit of the second fluid through the second inlet pipe ; a sampler installed in the circuit of the second fluid, adapted for sampling from the second chamber; wherein the first inlet pipe has a portion located on the side of the first fluid circuit, made in the form of a bypass adapted for continuous passage of a portion of the first fluid circuit flow therein during sampling; despite the fact that a valve is installed on the first inlet pipe to allow a single sample of the first fluid to pass from the bypass line to the first chamber during the sampling of the second fluid from the second chamber, and a shut-off element; moreover, the housing is mounted with the possibility of disconnecting it from at least part of the first inlet pipe and from at least part of the second inlet pipe, characterized in that the total volume of the first and second chambers is selected from a range from about 500 cm ³ to about 10000 cm ³ . 2. The device according to claim 1, characterized in that the possibility of disconnecting the housing from the first inlet pipe is provided by performing a portion of the first inlet pipe on which the shut-off element is placed, in the form of a high pressure sleeve with a quick-detachable connection. 3. The device according to claim 1 or 2, characterized in that the possibility of disconnecting the housing from the second inlet pipe is provided by performing a portion of the second inlet pipe from the side of the body in the form of a high pressure sleeve with a quick-detachable connection. 4. The device according to claim 1, characterized in that it is configured to measure the temperature in the first chamber of the first fluid. 5. The device according to claim 1, characterized in that the total volume of the first and second cameras is selected from the range from 1000 to 5000 cm ³ . 6. The device according to claim 1, characterized in that a shut-off element is installed on the second inlet pipe from the housing side. 7. The device according to claim 1, characterized in that the sampler is an automatic sampler. 8. The device of claim 1, characterized in that it contains a discharge means arranged in the second fluid circuit, adapted to supply the second fluid under pressure to the second chamber. 9. The device of claim 1, wherein the second fluid is a viscous liquid, such as oil. 10. The device for according to claim 1, characterized in that the circuit of the second fluid is closed, while the reservoir for storing the second fluid is connected to said circuit, communicated by its inlet with the outlet of the sampler, and the outlet with a second chamber. 11. The device according to claim 1, characterized in that the housing is made in the form of a sealed cylinder. 12. The device according to claim 1, characterized in that it is configured to drain the first fluid from the first chamber. 13. The device according to claim 1, characterized in that it is equipped with a means for bleeding the air pressure from the sampler and / or the first inlet pipe before sampling. 14. The device according to claim 1, characterized in that the first fluid circuit is the main pressure pipe, for example an oil pipeline. 15. The device according to claim 1, characterized in that the valve is installed on the bypass line from the side of the outlet of the flow into the circuit with the first fluid. 16. The device according to claim 1, characterized in that the housing is installed essentially vertically, and the first inlet pipe is made so that the shut-off element mounted on it is located above the lower end wall of the housing. 17. The device according to claim 1, characterized in that at least one end wall of the housing is made in the form of a removable cover. 18. The device according to claim 1, characterized in that it is used to determine the density of the first fluid.