RU2415307C1 - System and procedure for controlled build-up of pressure of low pressure gas - Google Patents

Abstract

FIELD: machine building. ^ SUBSTANCE: system consists of at least two parallel arranged ejectors. Additionally and parallel to ejectors there is installed a control valve of main for overflow of active fluid medium. The main of low pressure gas is connected to inputs of the ejectors; the main of high pressure fluid medium is connected to inputs of the ejectors and the control valve via a gate valve. Outputs of the ejectors are connected to an output main via the gate valves; the output of the said control valve is coupled with the output main in case of implementation of gaseous high pressure fluid medium, and with the main of high pressure fluid medium by means of the pump in case of implementation of fluid high pressure medium. ^ EFFECT: raised efficiency of system operation. ^ 15 cl, 1 dwg

Description

The invention relates to the field of moving fluids through pipelines, and in particular to a low pressure gas transportation system, and can be used when changing the dynamic and flow characteristics of a moving fluid, preferably when changing the flow rate of a moving gas in a pipeline.

A well-known (see Motor Sich ETD-1000 turboexpander power station. Composite catalog of oil and gas equipment and services, Russian volume. Publishing house "Fuel and Energy", 1999) is an ejection system for exhausting gases from turbine inter-labyrinth cavities. The ejection system according to a known source consists of a two-stage ejector assembly, into which active gas is supplied from the inlet pipe of the gas distribution station, the air-gas mixture from the interlabyrinth cavities of the turbine, and the gas-air mixture flows through the discharge pipe to the natural gas consumer line.

However, the use of the known system does not allow to change the pressure in the gas-air mixture line.

It is known (SU, copyright certificate 1721387) a gas control device, which is part of a gas distribution station, containing an input and an output line, between which a shut-off valve, a filter, a flow meter, a gas pressure regulator, a safety valve assembly and a gas odorization unit are installed

In this device, gas through a high pressure pipeline enters the process unit, at the inlet of which a shut-off valve with pneumatic actuator is installed, which serves to shut off the station in emergency cases. Then the gas is cleaned of impurities and condensate in the filter and sent through the metering unit to the gas pressure regulator, where pressure is reduced (reduced) to a predetermined value. After reduction, the gas passes through the safety valve assembly, which is triggered when a certain pressure is exceeded. Then the gas passes through the odorization unit, where it is subjected to odorization. The gas collected in the collector, coming from all of the above nodes, is sent to the ejector into the mixing chamber, while gas is supplied to the ejector nozzle from the inlet pipe. The ejected gas then goes to the consumer.

A disadvantage of the known technical solution should recognize its complexity.

Known (SU, patent 1239478) is a gas distribution station designed to reduce the gas pressure of a main gas pipeline and containing high and low pressure manifolds with a turbogenerator between them, connected via a backup and compensation lines to control valves, an ejector connected between the collectors and connected to the line by the mixing chamber cooling the generator, and the station further comprises a reactor connected at the inlet to the high pressure manifold, and at the outlet through the throttle to the chamber with Addressing the ejector.

A search in the patent literature did not reveal sources of information similar to the developed technical solution.

The technical problem, solved by implementing the developed technical solution, is to provide the ability to change the flow characteristics of the low- and high-pressure gaseous or liquid medium moved through the pipeline.

The technical result obtained by the implementation of the developed technical solution is to provide the ability to control the costs of high-pressure and low-pressure fluid flows in the pipeline.

To obtain the specified technical result, it is proposed to use the developed system of ejectors. The developed system of ejectors contains at least two parallel mounted ejectors, in parallel with which an additional control valve for the active fluid bypass line is installed, a low-pressure gas line is connected to the inputs of the ejectors, and a high-pressure fluid line is connected to the inputs of the ejectors and the control valve , the outputs of the ejectors through the shutoff valves are connected to the output line, the output of the specified control valve is connected if connection of a gaseous high-pressure fluid to the outlet line, and in the case of using a liquid high-pressure fluid by means of a pump to the line of high-pressure fluid. In a preferred embodiment, ejectors of different capacities are used, each of which is capable of regulating the pressure in the pipeline within ± 10% of the nominal value of the active or passive flow. In an advantageous embodiment, more than two ejectors are used. The number of ejectors used and their characteristics depend on the range of flow rates of high-pressure and low-pressure flows, as well as the accuracy of maintaining the parameters of the fluid in the pipeline. Typically, the performance of the ejectors used in conjunction with the specified control valve provides a change in the flow rate of low-pressure and high-pressure flows from 5 to 100%. When implementing the system, both manually adjustable valves and a valve, and automatically controlled valves and a valve can be used. Preferably, the system further comprises means for controlling the pressure of the low-pressure gas installed on the low-pressure fluid line both before the location of the ejectors and after the location of the ejectors. In the case of using automatically controlled valves and valves and in the presence of pressure control means in the low-pressure fluid line, it is possible to use an additionally introduced automatic control and pressure control unit in the mixture line, made with the possibility of automatic control of shut-off valves, to the inputs of which low-pressure gas pressure control devices are connected , and the unit outputs are connected to shut-off valves controlled automatically. However, it is possible to use and remote control automatically controlled valves and valves from the control room without the use of automation, but taking into account the real-time pressure measured in the low-pressure fluid line before and after the location of the ejectors.

When implementing the developed system of ejectors, at least two parallel-mounted ejectors are used, in parallel with which an additional control valve for the active fluid bypass line is installed, moreover, the low-pressure gas line is connected to the ejector inputs, and the high-pressure fluid line is connected to the ejector inputs by the shut-off valves. and a control valve, while the outputs of the ejectors through the shutoff valves are connected to the output line, the output of the specified control Pan connected in the case of high pressure gaseous fluid to the outlet line, and in the case of using a high pressure liquid fluid by the pump to the high pressure fluid line.

The developed technical solution is based on the use of ejectors for raising the pressure of a low-pressure fluid using a high-pressure fluid, in particular gas. Because consumption of active (high-pressure) or passive (low-pressure) gas can vary within wide limits, then the same principle is used as for nozzles. Instead of one ejector, several ejectors are installed in parallel, preferably with different capacities. One ejector can adjust within ± 10% of the nominal value of the active or passive flow. All this also applies to liquid-gas ejectors, which are used, for example, to compress gas in the gas industry or to create vacuum in columns at refineries.

The developed technical solution is shown in the drawing, with the following notation: the passive (low-pressure) gas supply line 1, the active (high-pressure) gas or liquid supply line 2, the output line 3, the ejectors 4, 5, 6, the control valve 7 of the active bypass line gas or liquid shut-off valves 8.

The developed technical solution works as follows.

Passive (low-pressure) gas is supplied to the ejectors along line 1. Active (high-pressure) gas or liquid is supplied through the line 2. Passive and active flows exit together along line 3. Ejectors are turned on or off by shut-off valves 8. The control valve 7 is turned on by the same valves. through which, if necessary, excess active gas is discharged.

Example 1. At refineries, hydraulic ejectors are used to create a vacuum in distillation columns; the vacuum value is 20–40 mm. Hg Four ejectors with a capacity of 10%, 20%, 40%, 40% are installed in the block of ejectors. Depending on the flow rate of the (passive) gas, various ejectors are connected from the column in various combinations. As a result of this, we can obtain the following combinations of active flow productivity: 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 110%, in addition, each ejector allows you to adjust the performance within 5% ÷ 10%.

Example 2. On the installation of a comprehensive gas preparation in the low-temperature separation unit, the weathering gas is subsequently pressurized by high-pressure gas and fed into the gas pipeline. Depending on the flow rate of high-pressure (active) gas, various ejectors can be connected. For example, the consumption of high-pressure (active) gas varies within 20% ÷ 100% of the nominal value. Ejectors with a capacity of 20%, 30%, 50% are installed. It turns out a set of active gas costs: 20%, 30%, 50%, 70%, 80%, 100%, as well as additional regulation by the ejectors themselves within 5% ÷ 10%.

Claims (15)

1. A system for controlled raising of pressure of a low-pressure gas, characterized in that it contains at least two parallel-mounted ejectors, in parallel with which an additional control valve for the active fluid bypass line is additionally installed, a low-pressure gas pipe is connected to the inputs of the ejectors, as well as through shut-off valves a high-pressure fluid line is connected to the inputs of the ejectors and the control valve, the outputs of the ejectors are connected through the shut-off valves to the output line, the output is indicated the associated control valve is connected in the case of using gaseous high-pressure fluid to the outlet line, and in the case of using liquid high-pressure fluid by means of a pump to the line of high-pressure fluid. 2. The system according to claim 1, characterized in that the ejectors of various capacities are used. 3. The system according to claim 1, characterized in that it contains more than two ejectors. 4. The system according to claim 1, characterized in that the performance of the ejectors used in conjunction with the specified control valve provides a change in the flow rate of low-pressure and high-pressure flows from 5 to 100%. 5. The system according to claim 1, characterized in that the manually adjustable valves and valve are used. 6. The system according to claim 1, characterized in that the automatically controlled valves and valve are used. 7. The system according to claim 1, characterized in that it further comprises means for controlling the pressure of the low-pressure gas. 8. The system according to claim 6 or 7, characterized in that it further comprises a unit for automatic control and regulation of pressure in the mixture line, configured to automatically control shut-off valves, to the inputs of which the means for controlling the pressure of low-pressure gas are connected, and the outputs of the unit are connected to automatic shut-off valves. 9. A method of controlled raising the pressure of a low pressure gas, characterized in that at least two parallel ejectors are used, in parallel with which an additional control valve for the active fluid bypass line is installed, moreover, a low pressure gas line is connected to the inlets of the ejectors, as well as through shut-off valves , the high-pressure fluid line is connected to the inputs of the ejectors and the control valve, while the outputs of the ejectors are connected through the shut-off valves to the output master ali, the output of said control valve is connected in the case of using gaseous high-pressure fluid to the output line, and in the case of using liquid high-pressure fluid by means of a pump to the line of high-pressure fluid. 10. The method according to claim 9, characterized in that they use an ejector of various capacities. 11. The method according to claim 9, characterized in that more than two ejectors are used in parallel with the installed ejectors. 12. The method according to claim 9, characterized in that they use manually adjustable valves and a valve. 13. The method according to claim 9, characterized in that they use automatically controlled valves and valve. 14. The method according to claim 9, characterized in that it additionally uses means to control the pressure of the low-pressure gas. 15. The method according to item 13 or 14, characterized in that they use automatic control of shut-off valves and the valve, taking into account the gas pressure in the mixture line.