SU1576736A1 - Pump-ejector unit - Google Patents

Abstract

The invention relates to inkjet technology, mainly to pumping-ejector installations for utilizing petroleum gas. The aim of the invention is to increase the productivity of gas due to the intensification of its separation from the liquid medium. The pump-ejector unit contains an inlet separator (BC) 1, a pump (H) 2 connected by a suction pipe (VP) 3 to BC 1 and a discharge pipe (NP) 4 to a liquid-gas ejector (HGE) 5, pipe for supplying a passive medium ( PPS) 6 of which is connected to the VS 1 and the gas supply line 7, and a liquid-gas separator (CGS) 8 with lines 9 and 10 of the compressed gas outlet and liquid discharge connected to the outlet (CGE 5, and the liquid transfer line (LPJ 11 to VP3 N 2. The unit is equipped with an oil separator (HC) 12 with lines 13 and 14 of gas supply and liquid outlet connected to the bypassing oil (LPN) 15 to the Sun 1. LPZH 11 is connected to the LPN 15 and to the HC 12. The HC 12 is equipped with a gas bypass line (LPG) 16, which through the gas supply line 13 is connected to the PPS 6 ZhGE 5. Production of wells goes to Sun 1, where it is separated into oil, water and gas. Water from Sun 1 enters H 2 and is fed through NP 4 to the active nozzle of ZhGE 5. ZHGE 5 pumps out gas from Sun 1 and the gas-liquid mixture enters ZGS 8. From OGS 8, compressed gas is supplied to the consumer, and water is supplied by LPJ 11 to H 2. Oil from aircraft 1 through LPN 15 is fed to NS 12. Separated gas LGE 5 is pumped out of HC 12 and oil is withdrawn to the consumer. During the operation of the plant, the water used to compress the gas in the HGE 5 is heated. Heated water from LPG 11 is supplied, depending on the working conditions, in LDL 15 or directly in HC 12. Heating of oil with hot water intensifies the process of gas separation from oil. Thus, by intensifying the separation of gas from oil by heating the oil and pumping out the gas by the ejector, an increase in gas productivity is achieved. 3 hp f-ly, 1 ill.

Description

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gas and liquid discharge connected to the output of HGE 5 and liquid transfer line (LR) 11 kVPZN 2. The unit is equipped with an oil separator (HC) 12 with lines 13 and 14 of gas supply and liquid drain connected by an oil transfer line (LPN) 15 to aircraft 1. LPZH 11 is connected to LPN 15 and NS 12. NS 12 is equipped with a gas bypass line (LPG) 16, which is connected to RPS 6 ZhGE 5 through gas supply line 13, Well production enters VS 1, where it is divided into oil, water and gas. Water from VS 1 enters N 2 and through NP 4 is fed to an active nozzle ZGZ 5. ZHGE 5 pumps out gas from VS 1 and the gas-liquid mixture enters ZGS 8. From ZGS 8 compressed gas, the invention relates to jet technology, mainly to pump ejector plants for utilization of petroleum gas,

The purpose of the invention is to increase the gas productivity due to the intensification of its separation from the liquid medium.

The drawing shows a diagram of a pump-ejector installation.

The pump-ejector unit contains an inlet separator 1, a pump 2 connected to the inlet separator 1 and the discharge 4 to the liquid-gas ejector 5, the inlet separator 6 of which is connected to the inlet separator 1 and the gas supply line 7, and the liquid-gas ejector 5 gas separator 8 with lines 9 and 10 of the discharge of compressed gas and liquid discharge connected to the outlet of the ejector 5 and line 11 bypassing the liquid to the suction nozzle 3 of the pump 2. The installation is equipped with an oil separator 12 with lines 13 and 14 of the gas supply and exhaust fluid, by The connected oil transfer line 15 to the inlet separator 1. The liquid transfer line 11 is connected to the oil transfer line 15 and to the oil separator 12, and the latter is equipped with a gas transfer line 16, which through the gas supply line 13 is connected to the nozzle 6 for supplying the passive medium of the ejector 5 .

When the installation of the production of wells enters the input separator 1, in which the separation of oil, water and gas. Water from the inlet separator 1 containing some oil in its composition, as a result of incomplete separation, flows to the pump 2 and through the discharge nozzle 4 to the consumer, and the water from the fluid 11 to H 2. The oil from VS1 through the LDL 15 enters HC 12. The separated gas from HC 12 is pumped out from the LGE 5, and the oil is withdrawn to the consumer. During the operation of the plant, the water used to compress the gas in LGE 5 is heated. Heated water from LPG 11 is supplied, depending on the working conditions, in LDL 15 or directly in HC 12. Heating of oil with hot water intensifies the process of gas separation from oil. Thus, by intensifying the gas separation from oil by heating the oil and pumping out the gas by the ejector, an increase in gas productivity of 1 3 Cp, f-ly, 1 sludge is achieved.

tive nozzle of a liquid-gas ejector 5. When a jet (liquid) of a liquid (water) is ejected from an active nozzle, gas that is pumped out of the inlet separator 1

and can flow through the gas supply line 7. From the liquid-gas ejector 5, the gas-liquid mixture enters the liquid-gas separator 8. In the separator 8, the compressed gas is separated from the water.

Compressed gas through line 9 of the compressed gas outlet enters the consumer, and water partially through line 10 discharge of liquid enters the consumer and partially through line 11 bypassing the liquid is supplied to the suction pipe 3 of pump 2.

Oil from the inlet separator 1 via the oil transfer line 15 enters the oil separator 12. The separated gas enters the gas supply line 13 and further along

the gas transfer line 16 is pumped out by the ejector 5. If necessary, part of the gas from the oil separator 12 can be discharged via the gas supply line 13 to the consumer. When the pump 2 is working

working fluid (water) due to the conversion of the energy expended to drive the pump into heat. Heated working fluid (water) from bypass line 11 is fed to oil line 15 bypass. The heated working fluid (water) can also be fed directly to the oil separator 12.

The choice of the line to which the heated working fluid (water) is supplied is determined by the capacity of the pipelines. If there is no decrease in the amount of oil supplied from the inlet separator 1 to the oil separator 12, the heated water can be supplied from

liquid transfer lines 11 to the oil transfer line 15, which will improve the process of heating the oil by increasing the duration of the contact. When the heated working fluid (water) is mixed with oil containing gas dissolved in it, oil separator 12 intensifies the process of gas evolution and increases the amount of gas extracted from oil due to its heating and temperature increase.

Claims (3)

Thus, by intensifying the process of separating the gas from the liquid media of the installation (oil and water), an increase in gas productivity is achieved. Claim 1. Non-hip-mounted installation comprising an inlet separator, a pump connected by a suction nozzle to the inlet separator and a discharge to a liquid-gas ejector, the inlet pipe of the passive medium of which is connected to the inlet separator and gas supply line, and a liquid-gas separator with the compressed gas removal and discharge lines connected to the ejector outlet and the liquid transfer line to the pump suction nozzle, in order to increase the gas throughput due to intensification of its separation from the liquid medium; the installation is equipped with an oil separator with gas supply and drain lines, connected by an oil transfer line to the inlet separator. 2. Installation pop.1. characterized in that the liquid transfer line is connected to the oil transfer line. 3. The installation according to claim 1, distinguishes from the fact that the liquid transfer line is connected to the oil separator. 4 Installation pop. 1, characterized in that the oil separator is equipped with a gas bypass line, which is connected via a gas supply line to the nozzle for supplying the passive medium of the ejector.