RU2211097C1 - Injector unit for injection of liquid into gas line - Google Patents

Abstract

FIELD: operation of equipment for compressed gases; gas, oil and other industries. SUBSTANCE: proposed injector unit includes lock mounted on branch pipe of pipe line including shut-off valve and lock chamber with seal, cylinder with seal, hollow plunger with injector at lower end and hollow rod on upper end. Brought to upper end of hollow rod is flexible pipe line provided with valve connected to delivery line of pump; inner cavity of cylinder is connected with delivery line of pump through regulating valve. Besides that, device may be provided with reservoir having media divider inside it; cavity of reservoir is filled with hydraulic fluid on one side of divider and is communicated with inner cavity of cylinder; cavity of reservoir on other side of media divider is communicated with delivery line of pump through regulating valve. Proposed injector unit may reliably operate at wide range of pressure differentials both in automatic controllable and non-controllable modes. Proposed device excludes penetration of gas from gas line into delivery line of pump and service reservoir in case check valve is leaky and ensures favorable operating conditions for friction pairs (when device is provided with hydraulic fluid reservoir). EFFECT: enhanced reliability. 2 cl, 2 dwg

Description

 The invention relates to the field of operation of equipment for compressed gases and may find application in gas, oil and other industries.

 A nozzle device for injecting a corrosion inhibitor into a gas pipeline is known, comprising a nozzle assembly installed on the gas pipeline, including a housing with a seal and an axial displacement of a hollow rod with a nozzle hydraulically connected to the pump (N. Obolentsev. Technological aspects of inhibitor protection of large pipelines diameter transporting untreated hydrogen sulfide-containing gas. - Thesis for the degree of Candidate of Technical Sciences, Moscow, 1980). This device is equipped with a mechanism for axial movement of the rod, comprising three racks, a chain transmission with sprockets, a worm gear with a handle that serves to manually move the hollow rod with the nozzle at the lower end to the working position.

 The disadvantages of the known devices include high metal consumption, the cumbersome drive of the axial movement of the rod, as well as the complexity and complexity of technological operations requiring the presence of a person.

 Also known is a device for aerosol inhibition of a gas pipeline equipped with a nozzle vertical displacement assembly made in the form of a cylindrical body, into which a hollow rod is placed. The upper threaded part of the hollow rod is connected to the flywheel, and the lower part with the nozzle installed at its end is connected by a flexible pipe to the metering pump (RU, Utility Model Certificate 13916, class F 17 D 1/05, 2000).

 A disadvantage of the known device is the complexity of the operations of the input and output of the nozzle from the pipeline, as well as possible gas leaks through the sealing of the hollow rod into the environment.

 The closest to the invention in technical essence and the achieved result is a device for injecting liquid into a compressed gas containing a nozzle assembly including a housing with a seal, a cylinder and a plunger with an axial channel and an opening in the wall for connecting the channel to the cylinder cavity connected to the nocyte (RU , Patent for invention 2068304, class 6 B 05 B 9/03, 1996). A nozzle is connected to the lower end of the plunger, and at the upper end, a solid rod is fixed, passed through the seal at the upper end of the cylinder. The nozzle is introduced into the gas pipeline automatically after the pump is started, and its withdrawal from the gas pipeline occurs after the pump ceases to supply liquid under the action of gas pressure on the nozzle and plunger.

 The disadvantages of the known device include the limited modes of its operation, since the nozzle is introduced into the gas pipeline and kept in working position only with a certain pump flow, the smallest value of which depends on the ratio of the diameters of the plunger and the rod, the gas pressure in the gas pipeline and the nozzle throughput; unregulated depth and speed of the nozzle I / O inside the gas pipeline; high hydraulic load on the seal of the plunger and false stem during fluid injection.

 The basis of the present invention is the creation of a nozzle device for injecting liquid into a gas pipeline, the design features of which would expand the scope of the device and the operating range of the pressure drop across the nozzle, its performance and minimum pump flow; provide nozzle input and output both in automatic uncontrolled mode and in controlled modes, as a result of which it would be possible to change the nozzle moving speed or even stop the nozzle input-output in any intermediate position; to increase the reliability of the device by reducing the pressure drop across the moving seals and providing more favorable working conditions of the rubbing pairs.

 This problem is solved by the fact that according to the invention, the rod is hollow, and a flexible conduit with a valve connected to the pressure line of the pump is connected to its upper end, while the internal cavity of the cylinder is connected to the pressure line of the pump through a control valve.

 In addition, the difference between the device is that it can be equipped with a container with a media separator inside, and the cavity of the tank on one side of the media separator is filled with hydraulic fluid and connected to the internal cavity of the cylinder, and the cavity of the tank on the other side of the media separator is connected through a control valve to the pressure line of the pump.

 The invention is illustrated by drawings, where figure 1 shows a General view of the device, and figure 2 is a variant of the device with additional capacity.

 The device comprises a lock 3 installed on the branch pipe 1 of the gas pipeline 2, including a shut-off valve 4 and a lock chamber 5 with a seal 6. A cylinder 7 is fixed to the lock chamber 5, the central opening 8 with a seal 9 is made in its upper end. Inside the lock 3 and cylinder 7 with axial displacement is provided by a hollow plunger 10, hereinafter referred to as a “plunger", on the upper end of which a hollow rod 11 is fixed, hereinafter referred to as a "rod", passed through a hole 8, and a nozzle 12 with a check valve 13 is fixed at the lower end Inonii with the cavity 10. The plunger rod 11 through a flexible conduit 14 and valve 15, and the cylinder 7 through a control valve 16 connected to the pressure line 17 of the pump 18 connected to supply tank 19 and having a bypass line 20.

 In addition, the device can be equipped with a tank 21 with a media separator 22 inside, and the cavity 23 of the tank 21 on one side of the media separator 22 is filled with hydraulic fluid and connected to the cylinder 7, and the cavity 24 of the tank 21 on the other side of the media separator 22 is connected through a control valve 16 to the pressure line 17 of the pump 18.

 The device operates as follows.

 The input of the nozzle 12 into the gas pipeline and its commissioning can be carried out in two ways.

 In the first input method, open the control valve 16 and start the pump 18. In this case, the liquid enters the cylinder 7 and, acting on the plunger 10, pushes it together with the nozzle 12 into the gas line 2. The lower part of the rod 11 thus enters the cylinder 7. This method input can be carried out at any supply of the pump 18, at any ratio of the diameters of the plunger 10 and the rod 11 and does not depend on the hydraulic resistance of the nozzle 12.

 After the nozzle 12 is inserted into the gas pipeline 2, the control valve 16 is closed, and the valve 15 is opened, and through the flexible pipe 14, the liquid flows through the rod 11 and the plunger 10 to the nozzle 12.

 In the second input method, the control valve 16 and the valve 15 are opened. In this case, the liquid is pumped 18 simultaneously to the cylinder 7 and through the pipe 14, the rod 11 and the plunger 10 to the nozzle 12.

 As a result of hydraulic resistance, when the fluid flows from the nozzle 12, a pressure drop is created on it, so the pressure of the liquid in the cylinder 7 will exceed the gas pressure in the gas pipe 2, which will lead to the downward movement of the plunger 10, rod 11 and nozzle 12. In this case, the fluid coming from the pump 18 along pressure line 17, will be divided into two streams.

 By controlling the control valve 16, it is possible to reduce the flow rate of the liquid entering the cylinder 7 and the speed of the nozzle 12, and by closing the control valve 16, stop the movement of the nozzle 12 in any intermediate position.

 After the end of the movement of the nozzle 12, which is visually controlled by the movement of the rod 11, the control valve 16 is closed. In this case, the fluid flow rate through the nozzle 12 will increase and equal to the supply of the pump 18, as a result of which the pressure drop across the nozzle 12 will increase and it will reach a steady injection mode. Then the pressure in the cavity of the cylinder 7, which depends on the gas pressure in the gas pipe 2 and on the ratio of the diameters of the plunger 10 and the rod 11, will be less than the pressure in the pressure line 17 during the steady-state injection mode, therefore, the pressure drops on the sealing elements of the plunger 10 of the rod 11 and will be less than, respectively, the injection pressure and the pressure drop across the nozzle 12.

 If necessary, you can stop the injection and leave the nozzle 12 in the gas pipe 2, for which they close the valve 15 with the closed control valve 16.

 The output of the nozzle 12 from the gas pipeline 2 can be carried out in two ways: bypassing the liquid from the cylinder 7 to the gas pipeline 2 or to the supply tank 19.

 In the first method for withdrawing the nozzle 12 from the gas pipeline 2, the liquid supply is stopped along the pressure line 17 (the pump 18 is stopped) and the control valve 16 is opened. As a result of the combined action of the gas pressure force tending to push it out of the gas pipeline 2 and the liquid pressure force the cylinder 7, which prevents this, the nozzle 12 will move upward, and the part of the liquid displaced from the cylinder 7 by the plunger 10 entering it will flow through the pipe 14 and the rod 11 into the cavity of the plunger 10 and flow from the nozzle 12 into the gas pipeline 2. Since the buoyancy force of gas is determined by the product of pressure in the gas line 2 by the cross-sectional area of the plunger 10 in the seal, and the force of the liquid pressure by the product of pressure in the cylinder 7 by the area of the ring, the outer diameter of which is equal to the diameter of the plunger 10 and the inner diameter to the diameter of the rod 11, the process the output of the nozzle 12 from the gas pipeline 2 in this way occurs only at certain ratios of the diameters of the plunger and the rod, the friction forces in the seals and the gas pressure in the gas pipeline 2 described in the literature (see Patent for invention, RU 2068304, cl. 6 V 05 V 9/03, 1996).

 Using the control valve 16, it is possible to control the process of withdrawal of the nozzle 12 from the gas pipeline 2: to suspend it in any intermediate position, and also to reduce, if necessary, the lifting speed of the nozzle 12.

 The second method of withdrawing the nozzle 12 is used in case of increased resistance to movement of the plunger 10 and rod 11 due to friction in the seals or at a low gas pressure in the gas pipe 2, insufficient to automatically lift the nozzle 12 after stopping the pump 18. To do this, close the valve 15, open the control valve 16 and bypass line valve 20 and allow fluid to pass from cylinder 7 to the supply tank 19. The check valve 13 thus prevents gas from entering the gas pipeline 2 into the internal cavities of the plunger 10, rod 11 and the pipeline and 14. Even when unpressurized return valve 13 closed valve 15 prevents gas in the pressure line 17, pump 18 and storage container 19.

 In the case when the device is equipped with an additional tank 21 with a media separator 22 inside, it works similarly to that described above. But at the same time, the seals of the rod 11 and the plunger 10 operate in more favorable conditions, since the hydraulic fluid filling the cavity 23 of the container 21 and the internal cavity of the cylinder 7 may have a higher lubricity and a higher viscosity than the injected liquid. In the case of injection of toxic or aggressive liquids, the working conditions of the personnel are also improved, since the possibility of leakage of harmful liquid through the stem seal 11 and its subsequent evaporation is eliminated.

The technical result obtained by the implementation of the invention is:
expanding the scope of the device in the operating range of the differential pressure on the nozzle, in terms of the ratio of the hydraulic resistance of the nozzle and the pump feed;
ensuring the input and output of the nozzle both in automatic uncontrolled and in controlled modes, as a result of which you can change the speed of the nozzle and stop the input / output of the nozzle in any intermediate position;
increasing the reliability of the device by reducing the pressure drop across the moving seals, preventing gas from entering the pressure line of the pump and the flow rate when the check valve is leaking, providing more favorable working conditions for rubbing steam (in the case when the device is equipped with a tank with hydraulic fluid).

Claims (2)

 1. A nozzle device for injecting liquid into a gas pipeline, comprising a lock installed on the pipe branch, including a shut-off valve and a lock chamber with a seal, a cylinder with a seal, a hollow plunger with a nozzle at the lower end and a rod at the upper end, characterized in that the rod is hollow and a flexible conduit with a valve connected to the pump pressure line is connected to its upper end, while the internal cavity of the cylinder is connected to the pressure line of the pump through a control valve.  2. The device according to claim 1, characterized in that it is equipped with a container with a media separator inside, and the cavity of the tank on one side of the media separator is filled with hydraulic fluid and connected to the internal cavity of the cylinder, and the cavity of the tank on the other side of the media separator is connected through a control valve to the pressure line of the pump.

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