RU2386160C1 - Dosed liquid supply control device - Google Patents

Abstract

FIELD: mechanics.

SUBSTANCE: invention can be used as flow stabiliser at automatic dosed introduction of inhibitor of hydrating and corrosion to gas flow (to gas wells or their tail areas). Device includes pressure control in the form of spring-loaded piston 5, command point in the form of the main and additional crane switches and discharge chamber with differential piston 11, throttle point having a sleeve with the hole controlled through the section by moving in it the piston with controlled stop on the end, system of channels in the form of two common outlet lines, which connect the points of the device. The main and additional crane switches are made in the form of sleeves 8, 8' correspondingly with slide valves 9, 14 located in them.

EFFECT: invention provides reliable and accurate dosing within wide range of the specified working liquid flow owing to elimination of effect of division vibrations at inlet and outlet and changes of liquid viscosity.

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Description

The invention relates to hydraulic devices and can be used as a flow stabilizer when setting the desired fluid flow rate, in particular, as a dispenser for automatically introducing an inhibitor of hydrate formation and corrosion into a gas stream, for example, into gas wells or their plumes.

At the gas industry enterprises, devices that simultaneously regulate the flow of the working fluid operating on the principle of continuous supply of the inhibitor while maintaining a constant predetermined flow rate regardless of the pressure of the dosed medium at the device inlet are used to supply hydrate formation and corrosion inhibitors to the gas stream, i.e. compensating inlet pressure fluctuations.

So, it is known a device for controlling the flow of fluid used in the input systems of hydrate inhibitors, comprising a housing with input and output channels, a differential pressure regulator installed in it, which consists of a spring-loaded membrane and a plunger connected to it, forming a discharge and submembrane cavity, and a three-way a solenoid valve connected by an inlet with a submembrane cavity, and by exits - with an inlet channel and a discharge cavity [1].

The disadvantages of the known device are a narrow range of flow control, due to the assigned characteristics of the spring and the flow area of the throttle, and insufficient metering accuracy, which necessitates the use of additional devices for measuring the actual flow rate.

A device for regulating the flow of fluid is known, used in systems for automatically introducing a hydrate inhibitor into a gas stream, comprising a housing with channels for supplying liquid, a constant differential pressure controller installed in the housing, consisting of a plunger rigidly connected to a membrane, balanced by a spring and forming a supra-membrane and a submembrane cavity communicating with the channel through a variable choke [2].

A disadvantage of the known device is the low accuracy of dosing the fluid supply, since the required flow rate is determined indirectly by the dial, which determines the position of the elements of the adjustable throttle. In addition, the disadvantage is the narrow range of installed costs, due to the assigned characteristic of the spring.

A known hydrate inhibitor flow regulator comprising a housing with an input and output chambers connected by a channel through a constant choke, a sensing element located in the output chamber, and a spring-loaded regulating element located in the inlet chamber and rigidly connected to the sensitive element, a regulating unit located on the external the surface of the body and rigidly connected by a rod with a sensitive element [3]. The throttle is placed in the channel, forming a shutter having sharp edges at the junction of the channel with the output chamber.

The disadvantages of the known device are the restriction on the ratio of varying pressures at the input and output of the device and a narrow range of flow control, which is due to the assigned characteristics of the spring and the area of the orifice of the throttle, as well as the insufficient accuracy of dosing of the inhibitor supply, which necessitates the use of additional devices for measuring the actual flow. When operating in a continuous mode of maintaining the set flow rate, the direct-acting differential pressure regulators used have very strict requirements for the purity of the working fluid, because the presence of foreign particles in the working fluid leads to deterioration of the shutoff edges of the gates, and in some cases, overlapping by foreign particles during operation of the shutter slit leads to an imbalance of the "sensitive element-gate" system, which in turn causes the emergence of unfavorable self-oscillation modes in the line, which exclude maintenance fixed costs.

A device for regulating a dosed fluid supply, comprising a housing with an automatic constant pressure differential controller located in it, consisting of a spring-loaded sensing element forming an input and output cavity, interconnected by a constant-pressure inductor, a shutter installed in the channel in the housing, connected to the sensitive an element of the constant differential pressure regulator, the discharge chamber of the shutter is connected by the discharge channel to the inlet cavity, and the overflow meter yes pressure with fluid supply channels [4]. The device automatically maintains the flow rate determined by the size of the orifice of the throttle by maintaining a constant pressure drop across the throttle.

A disadvantage of the known device is the low accuracy of automatically maintaining a constant predetermined fluid flow rate, since a change in the viscosity of the fluid causes a change in pressure drop and creates false prerequisites for additional adjustment of the device to adjust the flow rate. Establishing the actual flow rate of the working fluid during operation of the device is possible only with the use of additional flow meters. Another disadvantage of the device is the restriction on the ratio of varying pressures at the input and output of the device and a narrow range of flow control, which is due to the assigned characteristics of the spring and the flow area of the throttle. In addition, the device places high demands on the purity of the working fluid, which is almost impossible to provide in the conditions of gas production enterprises, as a result of which the device is not reliable enough.

Closest to the claimed combination of essential features is a device for regulating the dosed fluid supply, used to automatically enter a hydrate inhibitor in gas wells and their plumes. A device for controlling a dosed fluid supply contains a housing with fluid inlet and outlet nozzles and a differential pressure regulator located in it in the form of a spring-loaded piston forming inlet and outlet cavities interconnected via a throttle assembly, a command assembly with a crane switch in the form of a sleeve with holes and installed in it with the possibility of blocking the spool holes, connected through the rod to the piston of the differential pressure controller, a channel system. [5]

A disadvantage of the known device is the lack of accuracy in automatically maintaining a constant predetermined fluid flow rate, since the existing narrow annular gap in the throttle leads to the deposition of inhibitor components in it, which leads to a change in fluid flow. The use of a throttle with an annular gap makes it extremely difficult to configure, because the cross-sectional area of the gap varies in quadratic function, and not in linear.

Mechanical fixation of the spool leads to rapid wear of the elements of the locking mechanism due to large cyclic loads, as a result of which the extreme points of the location of the spool change, which leads to a change in fluid flow.

The absence of a rigid constant connection between the piston and the spool causes them to contact at the time of the highest speeds of the piston and the associated shock loads on the spool, which leads to premature failure of the device. Also a disadvantage of the known device is the low accuracy of maintaining a given flow rate, which necessitates frequent periodic monitoring and configuration of the device.

In addition, the use of the device places high demands on the purity of the working fluid, which is practically impossible in the conditions of gas producing enterprises.

The technical result of the claimed invention is to increase reliability and increase the accuracy of dosing, simplifying settings for a given flow rate, ensuring a stable cyclic fluid supply of a given flow rate.

The technical result is achieved by the fact that in the device for regulating the dosed fluid supply, comprising a housing with nozzles for supplying and dispensing fluid with a pressure regulator located in it in the form of a spring-loaded piston forming the inlet and outlet cavities interconnected via a throttle assembly, a command assembly with the main a crane switch in the form of a sleeve with holes and a spool installed in it with the possibility of blocking the holes, connected through the rod to the piston of the pressure regulator, a channel system , according to the invention, the command unit is additionally equipped with an ejection chamber with a differential piston installed therein, dividing the chamber into inlet and outlet cavities, and an additional crane switch made in the form of a sleeve with holes and with a spool located in it with the possibility of overlapping holes connected to the differential piston , the throttle assembly is made in the form of a sleeve with an adjustable cross-section of the hole and with a spring-loaded piston placed in it with the possibility of overlapping the hole, having an adjustable the emphasis, while the channel system in two single output lines connects: crane switches with each other and through the supply pipe to the input cavity of the discharge chamber, and crane switches, the sleeve of the throttle assembly and the output cavity of the pressure regulator, respectively, and the additional crane switch is separately connected with the sleeve of the throttle assembly and with the input cavity of the pressure regulator, and the main crane switch is connected to the output cavity of the ejection chamber, while the piston rod of the pressure regulator is rigid the spool connected to the main switch of the crane.

The use of a sectional command unit, a throttle unit with an adjustable hole, a rigid kinematic connection of the piston rod of the differential pressure regulator with the spool of the main crane switch and a two-line channel system ensures the device operates in two cyclic modes - in the first mode, the output cavity and the liquid discharge chamber are filled, in the second the mode is the release of fluid into the output line, and the duration of the device in the second mode is adjustable in a value that depends on the area of the orifice of the throttle, changed by manually rotating the stop at the time of adjustment, during operation.

The use of a switching valve in the control valve switch, rigidly connected to the differential piston, which is blocked by the command device by switching the channel command device by the valve, allows maintaining a constant flow of fluid regardless of the pressure drop at the inlet and outlet, as well as when changing the viscosity of the fluid.

When the input pressure is removed, the device stops, when the pressure is applied, the device starts automatically, providing a previously configured flow rate.

In addition, the constant rigid connection of the piston with the spool leads to a significant reduction and almost complete absence of shock loads on the spool, which in turn leads to an increase in the reliability of the device as a whole.

This mode of operation is more reliable, because does not respond to environmental pollution, provides a wider range of set flow rate and more accurate dosage of the working fluid, as eliminates the influence of fission fluctuations at the inlet and outlet and changes in the viscosity of the liquid.

The invention is illustrated by drawings, where in Fig.1 shows a General view of a device for regulating a dosed fluid supply in section, in Fig.2 - node 1A of Fig.1.

A device for controlling a dosed fluid supply comprises a housing 1 with an input 2 and an output 3 channels and with a pressure regulator coaxially placed therein, a command unit, a throttle unit and a channel system.

The pressure regulator, made in the form of a piston 5 spring-loaded with a spring 4, forming inlet 6 and outlet 7 cavities in the housing.

The command node has a primary and secondary crane switches and a discharge chamber.

The main switch is made in the form of a sleeve 8 with holes and a spool 9 installed in it with the possibility of overlapping holes, kinematically rigidly connected through the rod 10 with the piston 5 of the pressure regulator, and an additional one in the form of a sleeve 8 'with holes and placed in it with the possibility of overlapping holes the spool 14. The ejection chamber is made in the form of a cylinder with a differential piston 11 installed therein, dividing the chamber into the inlet 12 and outlet 13 of the cavity, while the inlet channel 2 enters the inlet cavity 12. Differential rshen 11 kinematically rigidly connected to the spindle 14.

The throttle assembly consists of a sleeve 15 with an adjustable hole 16 and a piston 18 having an adjustable stop 19, which is threaded by a threaded portion screwed into the sleeve 15, which is mounted with the possibility of a variable overlap over the cross section of the hole, which is spring-loaded and rotates the stop 19 by tightening the lock nut 20 .

The channel system in the form of two single output lines connects the crane switches to each other and through the channel with the input cavity of the discharge chamber and the crane switches, the sleeve of the throttle assembly and the output cavity of the pressure regulator, respectively, the additional crane switch being separately connected to the sleeve of the throttle assembly and to the input cavity a pressure regulator, and the main crane switch is connected to the outlet cavity of the ejection chamber.

The device operates as follows.

The operation of the device for controlling the dosed fluid supply is cyclic, includes two modes.

First mode:

Under the influence of the spring 4, the spool 9 of the main switch of the command unit is in the extreme right position, connecting the channel 21 through the sleeve 8 with the cavities 7 and 13 through the channels 22 and 23.

When the input pressure is supplied through the inlet channel 2, high pressure enters the cavity 12, forcing the differential piston 11 to move along with the spool 14 to the right, while the spool 14 of the additional switch connects the channel 24 to the channel 25, through which liquid enters the inlet cavity 6, forcing the piston 5, the rod 10 and the spool 9 of the main switch move to the left to the position at which the spool 9 connects the channel 24 (inlet pressure) with the channel 21 and the cavity 13. Due to the movement of the piston 5 of the pressure regulator to the left, enshenie volume of the outlet cavity 7, the compression spring 4. The liquid from the cavity 7 in volume V (I) through the outlet channel 3 is granted to the consumer. Due to the spool 9 connecting the main switch of the channel 24 to the channel 21, the liquid enters the cavity 13, the differential piston 11, the spool 14 of the additional switch move quickly to the left until the channels 26 and 25 are connected, while the movement of the piston 5 of the pressure regulator to the left stops, it stops.

Second mode:

Due to the force created by the spring 4, there is a movement

piston 5 pressure regulator to the right. The liquid from the cavity 6 through the channel 25, 26 enters the sleeve of the throttle assembly, where through the hole 16 it enters the channel 23. When the stop 19, which is screwed into the sleeve 15, is rotated, it moves linearly, and the piston 18 pressed by a spring 17 to the end face of the stop 19. A hole 16 is made in the sleeve 15. The stroke of the piston 18 is such that it allows either to completely close the hole 16, or to open part of it, or to open it completely, that is, the passage area of the hole 16 is smooth (linear) regulated in pr affairs from 0 to its fully open position.

The time of fluid flow from the cavity 6 through the throttle varies depending on the size of the orifice of the throttle, which is regulated by the position of the stop 19.

The movement of the piston 5 of the pressure regulator under the action of the spring to the right will stop at the moment when the spool 9 of the main switch in the right position connects the channel 21 through the sleeve 8 with the cavities 7 and 13 through the channels 22, 23. In this case, the differential piston 11 will move to the right, moving behind itself the spool 14 of the additional switch until the channels 24 and 25 are connected through the sleeve 15. The liquid from the cavity 13 through the channel 21, the sleeve 8, the channel 22 enters the channel 23. That is, a liquid is discharged with a volume of V (2) from the cavity 13 (discharge chamber) to the consumer . The volume of liquid dispensed to the consumer in one cycle is the sum of the volumes V (I) + V (2).

The device is ready for the next cycle. A stable amount of fluid displaced for each cycle, and the determination of the number of operation cycles per unit time, changed by an adjustable throttle, allow you to determine or set the actual actual flow rate of the fluid passing through the device. The fixed position is set by rotation of the stop 19 with the tightening of the lock nut 20, which sets a certain value of the area of the passage section of the hole 16.

The magnitude of the area of the orifice of the hole 16 determines the flow rate of the fluid passing through the hole, which in turn sets a certain speed for the differential piston 11 of the ejection chamber, the spool 14 of the additional switch, which determines the amount of time the fluid flows from the cavity 6.

The rate of fluid outflow from the cavity 6 determines the flow rate and the dosed fluid supply from the cavity 13 into the cavity 7 to a consumer of volume V (2) per device operation cycle. The expiration rate of the fluid volume V (2) is an adjustable component of the expiration time of the volume of the displaced fluid to the consumer in the cycle of the device and determines the number of cycles of work for a certain period of time, i.e. fluid supply. The prototypes of the proposed device for regulating the dosed liquid supply, installed on the technological equipment of the Orenburg gas production department "Orenburggazprom", showed the following results:

- due to the exact amount of injections of a fixed amount of inhibitor (methanol) injected into the well plume per unit time, the device provided an adequate dosed supply of the inhibitor, despite changes in the pressure at the inlet of the device and fluid viscosity during testing, due to changes in ambient temperature conditions;

- the dosing accuracy was not affected by the contamination of the working medium (methanol) by mechanical impurities, moreover, as a result of switching the methanol supply system unit due to switching the command unit (shutter) of the device to the extreme positions, layering of the inner surface of the pipes was cleared, which also did not affect the operation devices.

Compared with all known analogues and prototype, this device is more reliable, because does not respond to environmental pollution, provides a wider range of set flow rate and more precise regulation of the dosage of the working fluid, as eliminates the influence of fission fluctuations at the inlet and outlet and changes in the viscosity of the liquid.

Thus, the technical result of the use of this invention is to increase the reliability of operation and increase the accuracy of dosing regulation in a wide range of set flow rate by providing a cyclic supply of discrete constant doses of the working fluid.

Sources of information that contain information about analogues of the invention

1. SU N 544950A, G05D 7/00, 1977.

2. SU N 330435A, G05D 7/01, 1970.

3. SU N 634242A, G05D 7/00, 1978.

4. SU N 675403A, G05D 7/01, 1979.

5. RU N 2129728 C1, G05D 7/01, 04/27/1999.

Claims (1)

A device for regulating the dosed fluid supply, comprising a housing with fluid supply and discharge nozzles with a pressure regulator located in it in the form of a spring-loaded piston forming the inlet and outlet cavities interconnected via a throttle assembly, a command assembly with a main crane switch in the form of a sleeve with holes and installed in it with the possibility of overlapping holes with a spool connected through a rod to the piston of the pressure regulator, a channel system, characterized in that the command unit is supplemented Tel'nykh ejection chamber is provided with installed in it differential piston dividing the chamber at the inlet and outlet of the cavity, and an additional crane switch, designed as a sleeve with openings and arranged therein to overlap the openings spool connected to the differential piston; the throttle assembly is made in the form of a sleeve with an adjustable cross-section of the hole and with a spring-loaded piston placed in it with the possibility of overlapping the hole, having an adjustable stop, while the channel system in two single output lines connects the crane switches to each other and through the supply pipe to the camera input cavity discharge, and crane switches, the sleeve of the throttle assembly and the output cavity of the pressure regulator, respectively, with the additional crane switch separately connected to the sleeve of the throttle about the node and with the input cavity of the pressure regulator, and the main crane switch is connected to the output cavity of the ejection chamber, while the piston rod of the pressure regulator is rigidly connected to the spool of the main crane switch.

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