RU39707U1 - AUTOMATIC SAMPLING SYSTEM - Google Patents

Abstract

1. An automatic sampling system containing an electronic control unit for the redistribution of fluid flows in a system of hydraulic lines formed by pipelines connecting a dosing device with at least one storage tank for collecting single samples of a given volume and with a controlled main pipe line, two solenoid valves, electrically associated with said block, a piston disposed within the dispensing means with the possibility of reciprocating movement and forming in the dosing means two chambers isolated from each other, the first of which is hydraulically connected to the said container and to the controlled line of the main pressure pipe, and the second is hydraulically connected to the mentioned line, while during the progressive movement of the piston the first chamber is filled with the said sample and during the return movement of the piston, said sample is displaced from this chamber into said container under the action of pressure created in the second chamber characterized in that the second chamber of the dispensing means is hydraulically connected to the said container, and at least two solenoid valves are additionally placed in the hydraulic line system, while during the return movement of the piston the second chamber is filled with said sample, which is displaced during the translational movement of the piston into said container under the action of pressure generated in the first chamber. 2. The automatic sampling system according to claim 1, characterized in that

Description

The utility model relates to fluid sampling devices and may find application in industries where fluid sampling is required from pipelines operating under pressure, in particular in the oil industry.

Widely used are systems for sampling fluid from a pipeline, based on taking individual doses of fluid flowing through the pipeline with a constant movement of a portion of the pumped fluid through the sampling device along the bypass line of the main pipeline at regular intervals and collecting them in a special container. From individual doses, a total average sample of the liquid is compiled.

A device is known for sampling fluid from a pipeline, including a fluid flow control unit through a sampling device, in the housing of which a sleeve, a spring, a spool, an electromagnet, the anchor of which is connected to the spool, are placed. A metering chamber is located on the side surface of the housing, in the housing of which there is a differential piston. The volume of the sample taken in one cycle is regulated by setting the stroke pitch of the piston. The supra-piston part of the body of the metering chamber is connected through the nozzle to the bypass line of the pipeline to create retaining pressure on the piston, and an opening is made in the sub-piston part of the body to connect the chamber to the bypass pipe and the sampling tank. In the initial position, the armature with the spool under the spring force is in the upper position. When a control action is applied to the electromagnet, the armature retracts, overcoming the spring resistance, and the spool goes to the lower position, while the product enters the working cavity of the metering chamber, overcoming the pressure in the chamber cavity and moving the differential piston. Liquid filling the metering chamber is carried out by displacing the slide valve relative to the windows in the surface on which it slides. When removing the control action on the electromagnet, the spring returns the anchor with the spool to its original position.

The piston moves under the influence of fluid pressure in the supra-piston cavity and the product is discharged into a container for collecting samples (Passport for a sampler of type АПЭ-М АИУ 2.840.008, factory number 054 BUP No. 068 of October 5, 2001).

The disadvantage of this device is the presence of complex structural units (spool system redistribution of fluid flows) that do not ensure reliable operation of the device in operation and increase the dimensions of the device.

The closest technical solution by design features to the claimed utility model is a device for sampling fluid from a pipeline disclosed in a utility model according to patent document RU No. 31533 (publ. 08/20/2003, bull. No. 23). The known sampling system comprises a metering chamber with an adjustable sample volume, a control unit for the redistribution of fluid flows and means for creating a section of the intake manifold adjacent to the section of the outlet manifold combined with the section of the exhaust manifold, while the metering chamber is made in the form of a housing with the possibility of a predetermined axial displacement by the piston and has a hole in the nadporshnevoy part to provide retaining pressure on the piston, and in the piston part of the hole for communication of the above EASURES through an inlet line to the pipeline conduit and through an outlet line with a container for collecting samples, wherein the intake and outlet solenoid valves installed highways, electrically connected to said control unit for controlling the process fluid intake dose and discharge of this dose into the container.

The disadvantage is that for sampling it is necessary to provide a pressure difference in the supra-piston and sub-piston cavities, which leads to an increase in the length of the pipelines of the hydraulic lines of the sampling system. Sampling is carried out in two piston strokes, which reduces the operational life of the device without replacing worn parts.

The basis of this utility model is the task of creating a simple small-sized device design providing high

the degree of reliability, convenience and durability in operation, provided that the device performs the liquid sampling function in a high-quality manner.

The problem is solved in that in an automatic sampling system containing an electronic control unit for redistributing fluid flows in a system of hydraulic lines formed by pipelines connecting a dosing device with at least one storage tank for collecting single samples of a given volume and with a controlled main line pressure pipe, two solenoid valves electrically connected to the control unit, a piston located inside the dosing means with the possibility of reciprocating movement, in which two chambers are isolated from each other, each of which is made with at least one opening, in the dosing means, the first chamber being hydraulically connected to the storage tank and to the main line of the main pressure pipe, and the second chamber hydraulically connected to the controlled line of the main pressure pipe, and during the progressive movement of the piston the first working chamber of the aforementioned is filled breakdown, and during the return movement of the piston, the said sample is displaced from this chamber into the container for collecting samples under the pressure created in the second working chamber, it is new that at least two electromagnetic valves are additionally placed in the hydraulic line system, the second chamber is hydraulically connected to the storage tank.

The second chamber, like the first one in this embodiment of the device, is the working chamber, since during the return movement of the piston, its predetermined single sample is filled, which during the translational movement of the piston is displaced into the said container under the action of pressure created in the first chamber.

It is advisable to dispense the automatic sampling system in the form of a cylindrical body, the cavity of the first chamber

hydraulically coupled to said tank along a first exhaust manifold with a first solenoid valve installed thereon and to said main pressure manifold manifold along a first intake manifold with a second electromagnetic valve mounted thereon, wherein the cavity of the second chamber is hydraulically connected to said main manifold manifold along the line of the second inlet line, and with the mentioned capacity along the line of the second drain line, moreover, on the second inlet and second outlet On the expressways install the third and fourth solenoid valves, respectively.

The volume of the inner cavity of the cylindrical body determines the specified volume of the sample taken. It is preferable to leave the cylinder diameter constant and select the piston length for a specific predetermined dose volume. Another embodiment of the device is possible, in which to change the value of a given sample volume, the dispensing means is provided with means for restricting the stroke of the piston, placing it inside the cylindrical body from the end surface side.

It is advisable to limit the piston stroke with the possibility of regulation and fixation of its position. It is possible to implement the device with two piston stroke limiters, installing them on each end side.

The cylindrical body can be made with one removable cover having an opening, and the second hole can be made in the bottom of the cylindrical body. A cylindrical housing can be made and other modifications - with two removable covers, each of which has an opening to provide hydraulic connection.

It is advisable to pre-execute part of the pipelines of the hydraulic line system in one piece with the cover, for example, by making through the cover through radial channels communicated through the axial channel to the camera.

In an automatic sampling system, it is preferable to partially align the pipelines of the first inlet and second intake manifolds in the area between the third and second valves from the side of the pressure pipe. It is advisable to provide an automatic sampling system

two storage tanks, each of which is hydraulically connected to one of the two mentioned chambers.

The advantages and features of the utility model will become more apparent from the detailed description in conjunction with the accompanying drawing, which shows:

Figure 1 presents a diagram of the proposed sampling system, where the solid lines show the pipelines for the formation of hydraulic lines, and the dotted lines show the electrical connections of the control unit with actuators (valve actuators). The controlled highway is depicted as a pipe segment with an arrow - P slave. The direction of the fluid in the lines is shown by solid and dashed arrows.

The device includes a metering means in the form of a vertically oriented sealed cylindrical body 1 with a piston 2 located inside the body 1, dividing the cavity of the metering means into the first chamber 3 and the second chamber 4.

On the front side of the housing 1, a hole 5 is made for connecting the camera with 3 with the hydraulic line system. The chamber 3 is hydraulically connected to the controlled line 6 through the hole 5 and the valve 7 mounted on the inlet line 8. The camera 3 is also hydraulically connected to the storage tank 9 through the hole 5 and the valve 10 mounted on the outlet line 11.

On the opposite end side of the housing 1, a hole 12 is made for connecting the camera with 4 with the hydraulic line system. The chamber 4 is hydraulically connected to the pipeline 6 of the monitored line through an opening 12 and a valve 13 installed on the inlet line 14, and with a storage tank 9 through the opening 12 and a valve 15 installed on the outlet line 16.

Part of the exhaust pipe 11 from the valve 10 from the side of the tank 9 and part of the exhaust pipe 16 from the valve 15 from the side of the tank 9 are made combined to form a common entrance to the tank 9.

Part of the intake manifold 8 from the valve 7 from the side of the monitored pipeline 6 and part of the intake manifold 14 from the valve 13 from the monitored pipe 6 are combined.

In the chamber 4 is mounted a means of restricting the stroke of the piston 17, made with the possibility of its movement and fixation in a given position. The tool 17 is intended to regulate the volume of a single sample.

The actuators of the valve 7, valve 10, valve 13 and valve 15 are connected to the control unit 18.

The control unit 18 serves to generate and supply the necessary control signals to the valve actuators and allows flexible control of the sampling process.

In the initial state, all valves are closed.

To fill the metering chamber, the control unit 18 generates a signal to open a predetermined valve.

When sampling after a predetermined time, which is determined experimentally for minimum operating pressures, control signals to close or open predetermined valves are given by a signal from block 18.

If, when taking a portion of the liquid, valves 7 and 15 are open, and valves 13 and 10 are closed, then under the influence of the pressure of the liquid the piston translates and moves from the lower position to the upper one, forces the liquid out of the chamber 4 into the container 9 (see the intermittent arrow). After a time determined practically (empirically) for different values of P slave, valves 7 and 15 are closed.

At the next selection of a portion of the liquid, the valves 13 and 10 are open, and the valves 7 and 15 are closed. At the same time, under the influence of liquid pressure, the piston, making a return motion, moves from the upper position to the lower one, forcing the liquid out of the chamber 3 into the container 9 (see the solid arrow). After a time determined practically (empirically) for different values of P slave, the valves 13 and 10 are closed.

The above procedures are repeated a specified number of times.

Thus, sampling takes place for each stroke of the piston 2, since the filling of the liquid dosing agent. (V samples) with simultaneous sampling is carried out both with translational and with reciprocal movements of the piston 2.

In the example of a specific implementation of the sampling system undergoing pilot testing, the solenoid valves PVXG 262C013 24V from ASKO / JOUCOMATIC were used. A controller is used as a control unit, which converts information commands from a computer into analog electrical signals for actuators of electromagnetic valves.

The advantages of the proposed sampling device are that it is compact, has high reliability, has a relatively simple sampling scheme, which does not require large expenditures of time and labor for assembling the system and its operation.

Claims (5)

1. An automatic sampling system containing an electronic control unit for the redistribution of fluid flows in a system of hydraulic lines formed by pipelines connecting a dosing device with at least one storage tank for collecting single samples of a given volume and with a controlled main pipe line, two solenoid valves, electrically associated with said block, a piston disposed within the dispensing means with the possibility of reciprocating movement and forming in the dosing means two chambers isolated from each other, the first of which is hydraulically connected to the said container and to the controlled line of the main pressure pipe, and the second is hydraulically connected to the mentioned line, while during the progressive movement of the piston the first chamber is filled with the said sample and during the return movement of the piston, said sample is displaced from this chamber into said container under the action of pressure created in the second chamber characterized in that the second chamber of the dosing means is hydraulically connected to the said container, and at least two solenoid valves are additionally placed in the hydraulic line system, while during the return movement of the piston the second chamber is filled with the said sample, which is displaced during the translational movement of the piston into said container under the action of pressure created in the first chamber. 2. The automatic sampling system according to claim 1, characterized in that the dispensing means is made in the form of a cylindrical body with at least one lid, the cavity of the first chamber is hydraulically connected to the said container along the line of the first exhaust line and to the controlled main line of the main pressure pipe through the line of the first inlet line, and the cavity of the second chamber is hydraulically connected to the controlled line of the main pressure pipe along the line of the second inlet line and with the mentioned capacity the second exhaust manifold, with the first and second solenoid valves installed respectively on the first exhaust and first inlet ducts, and the third and fourth solenoid valves installed in the second inlet and second exhaust manifolds, respectively. 3. The automatic sampling system according to claim 1, characterized in that the dispensing means is made in the form of a cylindrical body with at least one lid, the cavity of the first chamber is hydraulically connected to the said container along the line of the first exhaust line and to the controlled main line of the main pressure pipe through the line of the first inlet line, and the cavity of the second chamber is hydraulically connected to the controlled line of the main pressure pipe along the line of the second inlet line and with the mentioned capacity a second exhaust manifold, with the first and second solenoid valves installed respectively on the first exhaust and first intake manifolds, and the third and fourth solenoid valves installed respectively on the second inlet and second exhaust manifolds, and a portion of the pipelines of said hydraulic manifold system is preliminarily made in one piece with said lid. 4. The automatic sampling system according to claim 1, characterized in that it contains two storage tanks, each of which is hydraulically connected to one chamber of the said dosing means. 5. The automatic sampling system according to claim 1, characterized in that it further comprises at least one means of restricting the stroke of the piston located inside the dispensing means and configured to control the volume of a single sample.