RU2032885C1 - Plant for sampling measuring of productive capacity of oil source - Google Patents

Abstract

FIELD: oil industry. SUBSTANCE: multi-path switch 1 is coupled with electric drive 2. When gas is fed to the space of electric drive 2 from measuring separator 3, next oil source is connected. Fluid counter 4 is set in operation only if flow rate controller 5 comes into action. The controller is adjusted for a given pressure drop. EFFECT: enhanced reliability . 3 cl, 7 dwg

Description

 The invention relates to means of accounting for oil coming from a group of sources, in particular when accounting for oil from devices for its collection in case of leaks of pipelines located at sea, for example, on floating islands.

 A known installation for selective measurement of the performance of an oil source in group accounting, containing a multi-way switch, separator, liquid meter.

 The disadvantage of this installation is its high energy intensity.

 Known installation of a similar purpose, containing a multi-way switch of sources, a separator, counter, control unit.

 The disadvantage of this installation is also its high energy intensity, since all switching is carried out by electromechanical units powered by a power network.

 Closest to the proposed one is a device containing a multi-way switch with inlet pipes for communication with each of the oil sources, the output pipe of which is connected to the hydrocyclone head of the metering separator, while the drain pipe of the latter is connected to the hydraulic line for communication with the common pipeline, the control panel, through the control and display unit, in communication with the control input of the electric actuator, and the output the latter is in communication with the rodless cavity of the power cylinder of a multi-way hydraulic switch.

 The disadvantage of this technical solution is its lack of reliability, since the electrohydraulic actuator is made on the basis of a mor-compressor, and the flow regulator is connected by control lines to the cavities of the metering separator, in addition, the gas damper experiences significant mechanical stresses from the float mechanism located in the separator, which often leads to damage to the rods.

 The aim of the invention is to reduce energy consumption and increase the reliability of the installation.

 This goal is achieved by the fact that the electrohydraulic actuator is made in the form of an electro-pneumatic valve and two cylinders of different diameters located on the same axis and connected to each other, in each of which pistons are connected, connected by a rod, and the rodless cavity of a cylinder of a smaller diameter is filled with a working fluid and communicated with a rodless the cavity of the power cylinder of the multi-way switch, and the rodless cavity of the cylinder of a larger diameter is connected via the electro-pneumatic valve to the gas line of the measuring sep Ator, in addition, between the piston of larger diameter and the corresponding end part of the cylinder of smaller diameter, a return spring is installed, as well as by the fact that the check valve of the flow regulator is made in the form of a slide valve, spring-loaded relative to the shoulder of the inlet part of the check valve body, while the inner diameter of the case in the inlet part exceeds the diameter of the corresponding part of the spool, and in the middle part of the spool an inlet is made, and on the outer surface of this part there are made fixing grooves and for interacting with the clamp rod, as well as the fact that the gas damper is made in the form of a check valve installed in the inlet pipe of the gas line and a float mechanism located in the lower part of the metering separator, the latter being kinematically connected with the eccentric shaft, which is able to interact with check valve when the float is located in the lower part of the tank of the measuring separator.

 A search conducted in the scientific and patent literature showed that the proposed set of features is unknown, i.e. the proposed technical solution meets the criterion of "novelty." Since the tools and individual components that make up this installation are standard or made of standard elements, the proposed installation meets the criterion of "industrial applicability". The analysis of the properties, features included in the proposed technical solution, showed that higher quality properties are due to the new design of the electromechanical drive, flow controller and gas damper, i.e. there is a new, higher effect, expressed in increasing the reliability of the installation and increasing its efficiency, i.e. the proposed technical solution meets the criterion of "inventive step".

 In FIG. 1 is a block diagram of an installation; in FIG. 2 sectional flow regulator; in FIG. 3 the same, in the open state; in FIG. 4 block diagram of an electromechanical drive; in FIG. 5 gas damper in the open position; in FIG. 6 the same, in the closed position.

 The installation comprises a multi-way switch 1, an electrohydraulic actuator 2, a metering separator 3, a liquid meter 4, a flow regulator 5, a control and indication unit 6, a fan 7, valves 8, inlet pipes for communication with each of the oil sources 9, on which the ball valves are located, pipelines (hydraulic lines) 10, control panel 11.

 The flow regulator has a housing 12, a spool 13 with a shoulder 14 on the inlet part, which has a seal, a return spring 15, adjusting nuts 16, 17, an OR-OR 18 valve, a latch 19, a release button 20.

 The electrohydraulic actuator 2 has a spring 21 located between the pistons 22, 23 of different diameters communicated by the rod 24, and the piston 22 forms a cavity 26 with the walls of the cylinder 25, which communicates hydraulically with the rodless cavity of the power hydraulic cylinder 27. The electro-pneumatic valve 28 connects the rodless cavity 29 with the gas line 30 separator 3 and with outlet pipe 31 (exit to the "candle").

 In the separator 3 there is a gas damper in the form of a check valve 32 located in the nozzle 33 of the gas line and connected to the float mechanism 34 kinematically connected with the cam shaft 35.

 In this case, the switch 1 is in communication with the hydrocyclone head of the separator 3, from which oil flows through the counter 4 and the regulator 5 into the common pipeline 10. The electrohydraulic actuator 2 is connected to the power cylinder of the switch 1, and the control and indication unit 6 is connected to the control elements of the operation of the switch 1, for example , as is the case in the Sputnik installation, an indication of the recorded values is also carried out, all the oil lines of this installation are left unchanged.

 The proposed installation works as follows. Oil from the source through one of the pipes 9 enters the switch 1 and then into the separator 3. The lower part of the separator 3 is filled, the float mechanism 34 ceases to act with the eccentric 35 on the check valve 32, which closes. The pressure in the separator 3 increases and when a certain set value is reached, the flow regulator 5 opens, i.e. the spool 13 is pressed out and the oil passes into the common pipeline 10. The flow value is recorded by the liquid counter 4. On block 6, the registered and set parameters are displayed, such as the source number, flow rate, etc. (as in the "Satellite" installation).

 If it is necessary to switch the switch 1 to another source on block 6, this number is set, and block 6 begins to control the operation of the electro-pneumatic valve 28, which operates a predetermined number of times. At the same time, gas from the separator 3 through the line 30 enters the cavity 29 shockly, as a result of which the pressure pulse is transmitted with amplification to the working fluid located in the cavity 26. This pressure is transmitted through a hydraulic line to the rodless cavity of the power cylinder 27 of switch 1 and causes the cylinder rod to move 27 and switching to one position of switch 1, when the valve 28 is re-activated, it switches one position further until the necessary source is connected to the separator 3. At the same time, for prison used energy gas flow that is always present as in the case of receipt of oil tanks as a result of its preliminary collection of leakages or when entering directly from the well.

 At the same time, during operation, the check valve 32 opens only at the moments when the float of the float mechanism 34 rises, acting on the eccentric 35, which avoids mechanical impact on the damper when it is jammed, i.e. avoid damage to the lever system of the float mechanism 34.

 The proposed technical solution makes it possible to efficiently use the energy of the gas flow when switching sources to measurement, to eliminate the possibility of breakdown of the gas damper and to use a simpler design of the flow regulator, eliminating the pneumatic connections of the regulator with the separator, which leads to a general increase in reliability while reducing the cost of the design.

Claims (3)

 1. INSTALLATION FOR SELECTIVE MEASUREMENT OF OIL SOURCE PERFORMANCE IN GROUP ACCOUNTING, comprising a multi-way switch with inlet pipes for communication with each of the oil sources, the outlet pipe of which is in communication with the hydrocyclone head of the metering separator, and the drain pipe of the latter by means of a liquid meter and flow valve connected to the hydraulic line for communication with the common pipeline, the control panel, through the control unit and display communicated with the input unit an electrohydrodrive, the latter being connected to the rodless cavity of the multi-way switch power cylinder, characterized in that the electrohydrodrive is made in the form of an electro-pneumatic valve and two cylinders of different diameters located on the same axis and connected to each other, in each of which pistons are connected by a rod, moreover, the rodless cavity of a cylinder of a smaller diameter is filled with a working fluid and is in communication with the rodless cavity of the power cylinder of a multi-way switch, and without larger diameter rod side of the cylinder through the electropneumatic valve communicates with the gas line test separator, moreover, between the piston and the corresponding larger diameter end portion of the smaller diameter cylinder installed return spring.  2. The installation according to claim 1, characterized in that the flow valve of the flow regulator is made in the form of a valve, spring-loaded relative to the shoulder of the inlet part of the valve body, while the inner diameter of the body in the zone of the inlet exceeds the diameter of the corresponding part of the valve, and in the middle part of the valve a through hole is made, and on the outer surface of this part, fixing grooves are made for interacting with the lock rod.  3. Installation according to claim 1, characterized in that the gas damper is made in the form of a check valve installed in the inlet pipe of the gas line and a float mechanism located in the lower part of the metering separator, the latter being kinematically connected with the shaft of the eccentric, which is arranged to interact with a check valve when the float is located in the lower part of the tank of the measuring separator.

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