RU2639003C1 - Method for production of high-viscosity oil - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method of production includes equipping the well with a casing pipe with two open zones on horizontal or inclined section, lowering the casing pipe of the lower tubing string with heat-resistant packer until the area between the opened zones is reached, lowering a submersible pump on the upper tubing string to first a opened zone, performing cyclic pumping of the heat carrier along the lower tubing string and lifting water-oil emulsion by the submersible pump to the surface. Prior to running, the lower tubing string with the heat-resistant packer is connected by its upper end to a bypass pipe mounted on the submersible pump, and they are lowered together on the upper tubing string. After completion of running into the upper tubing string, an additional pipe with annular gap and which is hydraulically connected to submersible pump outlet is introduced. When carrying out cyclical pumping, the heat carrier is delivered to the lower tubing string through the annular gap and a bypass pipe. The oil emulsion is lifted to the surface through the additional pipe.

EFFECT: improved efficiency of oil production by simplifying and accelerating the installation of equipment.

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Description

The invention relates to the oil industry, and in particular to a technology for the production of heavy and highly viscous oil from horizontal or deviated wells using heat.

A known method for the development of highly viscous oil, including the construction of horizontal and horizontal injection wells and producing wells, the cyclic injection of steam and associated gas into the injection well, and the selection of products from the production well with viscosity and temperature control of the selected products [RF Patent No. 2550635, ЕВВ 43/24 , 2015].

The disadvantage of this method is, firstly, in the high cost of drilling two horizontal wells, specially oriented in an oil-containing formation, and secondly, in the duration and complexity of the installation of submersible equipment.

A known method of thermal displacement of oil from a horizontal section of a well, comprising placing a casing in a well with two perforation zones at the beginning and end of a horizontal section, cementing the annulus to a horizontal section, lowering a tubing with centralizers and a packer separating the perforation zones into the casing from each other, the supply of coolant through the tubing and tubing and the selection of water-oil mixture through the perforation of the casing at the beginning of the horizontal section [Pa ent of the Russian Federation №2067168, E 21 B 43/24, 1996].

The disadvantage of this method is the fountain method of supplying the oil-water mixture to the surface, requiring continuous injection of the coolant into the oil-containing formation, which increases the energy intensity of the production process.

The closest in technical essence to the claimed one is a method of producing highly viscous oil from a well with an inclined direction, including equipping the section with a casing with two exposed zones at the beginning and end of the section, placing in this section a lower string of heat-insulated tubing with a heat-resistant packer that insulates the annulus between casing pipe and tubing string and between exposed areas, descent of the submersible pump on the upper tubing string within the bottom of the productive formation, but below the bottom an oblique direction to the first exposed zone, cyclic injection of the heat carrier into the formation from the lower column of heat-insulated tubing and selection of the oil-water emulsion by submersible pump [RF Patent No. 2436943, ЕВВ 43/24, 1996].

The disadvantage of the method adopted as a prototype is the length of installation of the submersible equipment due to the alternate descent of the pipe for steam injection and the submersible pump for the selection of the oil-water mixture.

The objective of the present invention is to increase the efficiency of production of highly viscous oil by simplifying and speeding up the installation of equipment.

The specified technical result is achieved by the fact that in the method of producing highly viscous oil from the well, including equipping the well with a casing pipe with two open zones in a horizontal or inclined section, lowering the tubing string with a heat-resistant packer into the casing before it takes up a position between the open zones, lowering the submersible pump on the upper tubing string to the first exposed zone, cyclic injection of coolant along the bottom tubing string and lifting the oil-water emulsion by the submersible pump to the surface, according to the invention Before descent, the lower tubing string with a heat-resistant packer is connected with its upper end to the bypass pipe mounted on the submersible pump, and together they are lowered onto the upper tubing string, into which, after the descent is completed, an additional pipe is inserted with an annular gap, and the coolant is delivered to the lower tubing string for pumping along the annular gap and the bypass pipe, and the rise of the oil-water emulsion to the surface is carried out through an additional pipe hydraulically connected to the pump discharge.

The drawing shows a diagram of the implementation of the proposed method for the production of highly viscous oil from a horizontal well.

A well is cased with a casing 1 having open zones 2 and 3 on a horizontal section. Prior to lowering the equipment, the formation is preheated by pumping a heat carrier, for example, steam, into the well through open zones 2 and 3. As a result, the viscosity of high-viscosity oil in the formation near these zones decreases to an acceptable value, and the oil becomes suitable for pumping by submersible pump.

Then, the lower tubing string 4 with a heat-resistant packer 5 at the end begins to be lowered into the well. The length of the lower tubing string 4 is selected depending on the distance between the exposed zones 2 and 3 on the casing 1. The upper end of the lower tubing string 4 is screwed into a support 6 mounted below the submersible pump 7, and the bypass pipe 8 corresponding to the length of the submersible pipe 8 is inserted into the support 6 from above. pump, and continue to descent into the well. To prevent overheating of the submersible pump 7, the bypass pipe 8 is covered with a layer of insulating material. A tee 9 is mounted on the free end of the bypass pipe 8 and the outflow of the submersible pump 7, from the opposite side of which the upper string of the tubing 10 is screwed and the assembled unit is lowered into it. The descent is completed when the heat-resistant packer 5 installed on the bottom string of the tubing 4 reaches the position between the exposed zones 2 and 3 in the casing 1, while the submersible pump 7 is in the horizontal section of the well. At the end of the descent, an additional pipe 12 is inserted into the upper tubing string 10 to the tee 9 with an annular gap 11 with sealing elements 13 at the end, which is hydraulically connected to the outlet of the submersible pump 7. Damage to both pipes is prevented by placing an additional pipe 12 inside the upper tubing string 10. as well as cable.

Upon completion of installation and operation of the heat-resistant packer 5, separating the annulus between the exposed zones 2 and 3, two hydraulic lines appear in the well. One line passes through the annular gap 11 between the additional pipe 12 and the upper tubing string 10, the bypass pipe 8 and the lower tubing string 4. The other line connects the annulus 14 between the lower tubing string 4 and the casing 1 through the submersible pump 7 with the additional pipe 12, coming to the surface.

Next, a cyclic injection is made from the surface of the coolant (arrows with an open tip), which are fed to the end section of the casing pipe 1 through the annular gap 11, the bypass pipe 8 and the lower tubing string 4. The coolant passes through the opened zone 3 into the preheated reservoir and is forced out water-in-oil emulsion, which enters through the opened zone 2 (arrows with a filled tip) into the annulus 13 between the lower tubing string 4 and the initial section of the casing 1. The displaced water The oil emulsion arrives at the intake of the submersible pump 7 and is pumped to the surface through an additional pipe 12. When the flow rate decreases, the pumping is stopped and the coolant is again pumped into the productive zone of the formation through the lower tubing string 4 to increase the fluidity of the oil. This is followed by pumping and cycles are repeated.

Claims (1)

A method of producing highly viscous oil from a well, including equipping the well with a casing pipe with two open areas in a horizontal or inclined section, lowering the tubing string with heat-resistant packer into the casing until it occupies a position between the open areas, lowering the submersible pump on the upper casing string -compressor pipes to the first exposed zone, cyclic injection of coolant through the lower column of tubing and lifting the oil-water emulsion with a submersible pump to the surface, about characterized in that before the descent, the lower column of tubing with a heat-resistant packer is connected with its upper end to the bypass pipe mounted on the submersible pump, and together they are lowered onto the upper column of the tubing, into which, upon completion of the descent, an additional pipe is introduced with an annular gap , for injection, the coolant is delivered to the lower column of tubing along the annular gap and the bypass pipe, and the rise of the oil-water emulsion to the surface is carried out via an additional pipe, ravlicheski related pumps output.

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