RU2615699C1 - System of collection, transportation and treatment of oil, gas and water - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: system comprises an input two-phase separator (2) with pipeline (3) of feeding the separated therein high-pressure gas to the consumer, a three-phase decanter-separator (5) with pipeline (6) of low-pressure gas discharge to the flare stack, a pipeline (7) of oilfield wastewater supply to water treatment unit connected to the buffer-separator (12) connected to the pipeline (14) of wastewater feeding into the horizontal flare (HFU) (15). A pump (16) and an ejector (17) of "liquid-gas" type are mounted on the pipeline (14), which receiving chamber is connected to the pipeline (6) of low-pressure gas discharge to the flare stack. Buffer-separator (12) gas outlet is connected to the pipeline (6) of low-pressure gas discharge to the flare stack. The system may be provided with an additional separator (21) connected to the ejector (17) via gas inlet and to the gas supply to the horizontal flare HFU (15) via gas outlet. Liquid yield in the additional separator (21) is connected to the input of the buffer-separator (12).

EFFECT: invention improves utilisation of oil and gas wastewater.

5 cl, 3 dwg

Description

The invention relates to the oil and gas industry, in particular to systems for collecting, transporting and preparing oil, gas and water.

A known system for collecting, transporting and preparing oil, gas and water, comprising a network of prefabricated multiphase production pipelines from production wells, a pressure pipe providing product transport to oil and water treatment plants, and an inlet two-phase separator with a high-pressure gas supply pipe and oil-water mixture discharge pipeline, three-phase sump separator with a low-pressure gas discharge pipeline to a flare pipe, with an oil output pipeline to an end stage separator a supply conduit for oilfield sewage water treatment unit, a two-phase separator and end stage coupled to low-pressure gas discharge conduit to a flare stack. [RF Patent No. 122304, publ. 11/27/2012].

In the known installation, the water treatment unit is an accessory of the preliminary water discharge installation, so that the water preparation for maintaining reservoir pressure is prepared in the immediate vicinity of the wells. At the same time, at the initial stage of oil field development prior to maintaining reservoir pressure or in the later stages when the volume of water exceeds that necessary to maintain reservoir pressure, there is a need to utilize oil field wastewater, the further use of which is not possible.

One of the ways to utilize oil field wastewater is to pump it into deep aquifers [Lanshakov VG, Borovskaya T.A. Organization of injection sites for excess produced water to prevent environmental pollution in the fields of the Khanty-Mansiysk Autonomous Okrug // Environmental protection in the oil and gas complex. - M .: VNIIOENG OJSC, 2015. - No. 5. - S. 28-33]. This method assumes the presence of absorbing wells, which is an expensive undertaking, and, in addition, such a method may damage the ecological safety of the region in the event of a possible uncontrolled overflow of utilized liquid into other aquifers.

There are also known methods for the thermal utilization of industrial effluents by evaporation of effluents in a natural gas flare with the simultaneous burning of organic and harmful impurities, for example, using a horizontal flare plant for these purposes [N. Sozonov, A. Beloborodov, D. Tenkovsky . Horizontal flare units of TyumenNIIgiprogaz LLC // Exposition Oil Gas. - M.:, 2012. - No. 7. - S. 32-33].

The use of horizontal flare plants requires a gas source for the burner of the plant, which is used as fuel for the combustion of oilfield wastewater separated in the separator. As such fuel, high-pressure gas is usually used, which is released from the production of wells in the inlet two-phase separator in the first separation stage. A part of the gas from the separator is supplied to the horizontal flare unit, and the rest of the gas is piped to the consumer. The low-pressure gas emitted in the subsequent stages of separation is sent for combustion in a flare pipe, since its further use, for example, as fuel in a horizontal flare installation is impossible due to the need to compress it, which requires the construction of a compressor station, which significantly increases the cost of object.

The task to which the stated solution is directed is to create a system for collecting, transporting and preparing oil, gas and water, which, with all its other functions, will provide an economical process for utilizing oil and gas wastewater by using low-pressure gas in this process.

The technical result is achieved by the fact that in the system for collecting, transporting and preparing oil, gas and water, which contains a network of prefabricated multiphase production pipelines from production wells, a pressure pipe providing transport of products to oil and water treatment plants and an input two-phase separator with a high-pressure gas supply pipeline and a water-oil mixture discharge pipeline, a three-phase sump separator with a low-pressure gas discharge pipeline to a flare pipe, with a discharge pipeline oil to the end-stage separator and with the oilfield wastewater supply pipeline to the water treatment unit, and the two-phase end-stage separator connected to the low-pressure gas discharge line to the flare pipe, the water preparation unit is a horizontal flare unit, and at the pipeline to the oil supply unit to this wastewater sequentially placed a buffer separator with gas and liquid outlets, a pump and a liquid-gas ejector, the receiving chamber of which is connected to the pipeline a low-pressure gas discharge house, wherein the gas outlet of the buffer-separator is connected to a low-pressure gas discharge pipe to the flare pipe.

Also, the gas supply to the burner device of the horizontal flare unit can be connected to the pressure gas supply pipe or the system can be equipped with an additional separator with gas and liquid outlets connected to its inlet with the outlet from the ejector, and the gas outlet in the additional separator is connected to the gas supply to the burner horizontal flare unit, and the liquid outlet in the additional separator is connected to the entrance to the buffer separator, and the exit from the ejector can be directly It is connected with the input device for supplying oilfield wastewater to a horizontal flare unit, and can be connected to it through an additional separator.

Distinctive features of the proposed system options, which include the use of pumping equipment to provide the necessary pressure of wastewater entering the ejector; in the use of an ejector to ensure compression of the low-pressure gas to the required pressure due to the use of the energy of the working fluid (waste water); the use of a separator for separating the resulting gas-liquid mixture and organizing the circulation of utilized wastewater with the involvement of low-pressure gas in the thermal utilization process allows the disposal of the generated low-pressure gas during the wastewater utilization process, which increases the efficiency of the process of collecting, transporting and preparing oil, gas and water and allows you to significantly increase the volume of high-pressure gas supplied to the consumer gas pipeline.

The invention is illustrated graphically, where in FIG. 1 shows a system for collecting, transporting and preparing oil, gas and water according to the first embodiment of its use using a high-pressure and low-pressure gas in a horizontal flare unit (hereinafter HFC); in FIG. 2 shows the same system according to the second variant of its execution without the use of high-pressure gas in HFCs; in FIG. Figure 3 shows the same system according to the third version of its implementation without the use of high-pressure gas in HFCs.

The system for collecting, transporting and preparing oil, gas and water contains an inlet pipe 1 connected to well clusters, an inlet oil and gas separator 2 with a pipe 3 for outputting the high-pressure gas separated therein to the consumer, a heater 4, a separator-water separator 5 with a pipe 6 for outputting the low-pressure gas to a flare pipe, a sewage outlet pipe 7 and a pipe 8 connected to an end stage separator 9 with a gas outlet pipe 10 connected to a low pressure gas supply pipe 6 to the flare pipe y and pipeline 11 output of commercial oil. The pipeline 7 is connected to the buffer separator 12 with the evolved gas outlet pipe 13 connected to the low pressure gas supply pipe 6 to the flare pipe and to the sewage water supply pipe 14 to the horizontal flare unit 15. A pump 16 and an ejector 17 of type liquid-gas. " The ejection nozzle of the ejector 17 is connected to the internal volume of the pipe 14, and its receiving chamber is connected to the low-pressure gas supply pipe 6 to the flare pipe.

According to the first embodiment of the proposed system, the discharge pipe 18 of the ejector 17 is connected to the horizontal flare unit 15. The burner device of the flare unit 15 is connected by a pipeline 28 to the high-pressure gas supply pipe 3 to the consumer.

According to the second embodiment of the proposed system, the discharge pipe 18 of the ejector 17 has a branching: the pipe 19 is connected to the HFC 15, the pipe 20 is connected to the separator 21. The separator 21 has a gas outlet pipe 22 connected to the HFC fuel system 15, and a liquid outlet pipe 23 connected with an inlet pipe 7 to the separator 12.

According to the third embodiment of the proposed system, the discharge pipe 18 of the ejector 17 is connected only with an additional separator 21. The fluid outlet in the additional separator 21 has a branching. In addition to the pipe 23 connected to the inlet pipe 7, the output of the separator 21 by the pipe 24 is connected to the HFC 15.

The system is as follows.

The gas-liquid (gas-oil) mixture from the well clusters through pipeline 1 enters the field oil treatment unit in the inlet oil and gas separator 2, where high-pressure gas is separated from the liquid (oil-water mixture). To intensify the process of separating water from oil in the production of wells from the dosing unit 25 through the pipeline 26 is the supply of the reagent (demulsifier).

High-pressure gas from separator 2 is sent through pipeline 3 to the consumer, and the oil-water mixture through the heater 4 is sent to the separator-water separator 5. In the separator-water separator 5, oilfield wastewater is discharged and the oil-oil mixture released due to heating and pressure reduction of the low-pressure gas are separated. From the separator-water separator 5, low-pressure gas is sent via pipeline 6 to the flare pipe for combustion, dehydrated oil is sent via pipeline 8 to the end separation stage, and the separated oilfield wastewater flows through pipeline 7 to the input of the separator-buffer 12. At the end separation stage in the separator 13, the final degassing of the dehydrated oil takes place. The low-pressure gas released in the separator is transported through pipeline 10 connected to pipeline 6 to a flare pipe, and commercial oil - through pipeline 11 to a freight fleet and then to a consumer.

From the separator buffer 12, the evolved gas through a pipe 13 connected to a pipe 6 is also sent to a flare pipe, and waste water through a pipe 14 is sent to a pump 16, through which it is fed to a HFC through an ejector 17 15 for disposal. In the ejector 17, water creates a vacuum in its intake chamber, due to which the low-pressure hydrocarbon gas released in the separators 5, 9, and 12 passes through the pipeline 27 to the ejector 17 and is carried away by the flow of wastewater.

In the system according to option 1 of its implementation, the gas-liquid mixture formed in the ejector 17 is sent via pipeline 18 to HFC 15 for disposal. As the fuel for HFCs, pressurized hydrocarbon gas is used, which is supplied via line 28, which is connected to line 3 from inlet separator 2.

In the system according to option 2, the gas-liquid mixture formed in the ejector 17 is sent via pipeline 18 to HFC 15 for disposal. Part of the gas-liquid mixture from the ejector 17 through the pipe 21 is sent to an additional separator 19, where it is divided into gas and liquid. Gas from the separator 19 through the pipe 22 is sent as fuel for the HFC 15, and the liquid through the pipe 23 to the inlet of the separator-buffer 12, forming a circulation loop.

In the system according to option 3, the gas-liquid mixture formed in the ejector 17 is sent via line 18 to an additional separator 21, where it is separated into gas and liquid. Gas from the separator 21 through the pipeline 22 is sent as fuel for the HFC 15, and the liquid, being divided into two streams, is sent: through the pipe 23 to the inlet of the separator-buffer 12 and through the pipe 24 to the HFC 15 for disposal.

The implementation of the proposed system, which allows the waste water to be disposed of thermally during the collection, transport and preparation of oil, gas and water, provides a more rational use of resources by utilizing low-pressure gas in the process of wastewater utilization, including the provision of HFC operation. The proposed system will increase the volume of high-pressure gas supplied to the pipeline.

Claims (5)

1. A system for collecting, transporting and preparing oil, gas and water, comprising a network of prefabricated multiphase production pipelines from production wells, a pressure pipeline providing product transport to oil and water treatment plants, and an inlet two-phase separator with a high-pressure gas supply pipe and placed on it with a pipeline for the withdrawal of water-oil mixture, a three-phase sump separator with a pipeline for discharge of low-pressure gas to the flare pipe, with a pipeline for oil output to the end stage separator and from pipes a wire for supplying oilfield wastewater to a water treatment unit, and a two-phase end-stage separator connected to a low pressure gas discharge pipe to a flare pipe, characterized in that the water treatment unit is a horizontal flare unit, and in series in a pipeline for supplying oilfield wastewater to this unit a buffer separator with gas and liquid outlets, a pump and a liquid-gas ejector, the receiving chamber of which is connected to the low-pressure discharge pipe, are placed gas, while the gas outlet of the buffer separator is connected to the pipeline discharge low pressure gas to the flare pipe. 2. The system according to claim 1, characterized in that the gas supply to the burner device of the horizontal flare installation is connected to the pressure gas supply pipe. 3. The system according to claim 1, characterized in that it contains an additional separator with gas and liquid outlets connected by its inlet to the outlet of the ejector, and the gas outlet in the additional separator is connected to the gas inlet to the burner device of a horizontal flare unit, and the liquid outlet in an additional separator is connected to the entrance to the buffer separator. 4. The system according to claim 3, characterized in that the exit from the ejector is connected to an input device for supplying oilfield wastewater to a horizontal flare unit. 5. The system according to claim 3, characterized in that the liquid outlet in the additional separator is connected to an input device for supplying oilfield wastewater to a horizontal flare unit.

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