RU2545580C1 - Development method of hydrocarbon deposits - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: according to the method intervals of a well are completed opposite the gas-saturated part, so called gas cap, and oil-saturated part of a productive stratum. A tubing string is run in to the well. The gas cap is isolated by a packer. Gas is injected to the gas-saturated part of the productive stratum and the product is extracted by a borehole pump. Simulated completion opposite the gas-saturated part of the productive stratum is ensured by the creation of drainage channels oriented radially inward the stratum. Then two coaxially mounted tubing strings of a different diameter are run in to the well. The tubing string with a lesser diameter is run in to the level of the oil-saturated part of the stratum and equipped with the borehole pump connected by an exhaust line to the ground separator intended for the separation of associated gas. The tubing string with a bigger diameter is run in to the level of the gas-saturated part of the stratum and connected to a pressure line of the separated associated gas from the ground gas compressor. Oil is extracted through the tubing string of a lesser diameter. Injection of the separated gas is made through the tubing string of a bigger diameter. At that the separated gas under pressure is delivered to a space between packers in the gas-saturated part of the stratum over gas-oil contact (GOC) thus supporting energy of the stratum at a permanent level. As far as to oil extraction from the oil-saturated part of the stratum and injection of the separated gas to the gas-saturated part of the stratum, GOC boundary is shifted stage by stage as per the thickness of the stratum from its roof to the bottom thus ensuring the gradual oil draw-down rate.EFFECT: reduced labour costs at implementing associated gas injection to oil wells in order to maintain the reservoir pressure during operation of hydrocarbon deposits and improvement of their productivity.1 dwg

Description

The invention relates to the oil and gas industry and can be used in the technology of returning associated gas generated during the development and operation of oil or gas condensate fields to maintain reservoir pressure.

A known method for the development of hydrocarbon deposits (Pat. RF №2416023, declared. 29.10.2009, publ. 10.04.2011). According to the method, associated gas is pumped through injection wells into an absorbing horizon, which is used as a reservoir containing residual oil and / or gas and / or produced water, or a reservoir located below the reservoir. The initial associated gas injection pressure is maintained not lower than the opening pressure of natural cracks present in the absorbing horizon. Record the change in volumes and pressure of the injected associated gas. After stabilization of the injection regimes, a conclusion is drawn about the effect of associated gas injection on the reservoir.

The aim of the known method is the placement and temporary storage within the developed field of significant volumes of associated gas. In this case, the increase in pressure in the reservoir is of a secondary nature.

Also known is a technology for injecting gas into a gas “cap” located above the gas-oil contact (GOC), the purpose of which is to preserve the elastic energy (pressure) of the formation regardless of the amount of selected products (Pat. RF No. 2449115, “Method for the development of gas condensate deposits." 04/29/2010, published on 04/22/2012).

The method comprises the second opening of two intervals of the well: the upper opposite the gas cap and the lower opposite the part of the reservoir saturated with gas condensate, lowering the tubing into the well, isolating the gas cap with the packer and selecting products from both intervals in the mode depletion of reservoir energy.

The disadvantage of this method is the need to bring the exploited reservoir to the depletion mode, which is acceptable for a gas condensate deposit, since it intensifies the hydrate formation process, but is not acceptable for an oil reservoir, since it reduces its gas factor, which accordingly leads to an increase in oil viscosity and a decrease in reservoir productivity. In addition, the method does not use associated gas, but dry hydrocarbon gas specially supplied through the piping system, which is associated with additional labor costs due to the high cost of the process of conservation of dry gas reserves.

The objective of the invention is to reduce the labor costs of implementing the technology of pumping associated gas into oil wells to maintain reservoir pressure during the operation of hydrocarbon deposits and, accordingly, increase their productivity. At the same time, the task of associated gas utilization is simplified.

This problem is solved by the fact that in the method of developing hydrocarbon deposits, containing the second opening of two intervals of the well: the upper - opposite the gas-saturated part of the reservoir (gas "cap") and the lower - opposite the oil-saturated part of the reservoir, descent into the well of the tubing (tubing) , isolation of the gas cap by the packer, gas injection into the gas-saturated part of the reservoir and product selection using the borehole pump, a secondary opening opposite the gas-saturated part of the reservoir provides m of drainage channels radially directed into the depth of the formation, then two coaxially installed tubing of different diameters are lowered into the well, while smaller tubing is lowered to the level of the oil-saturated part of the formation and equipped with a borehole pump connected by a flow line to the ground separator for separation associated gas, and tubing of larger diameter is lowered to the level of the gas-saturated part of the formation and connected to the discharge line of the associated separated gas from the ground gas compressor.

The attached figure shows a diagram of the installation of equipment for the extraction of oil products installed in the well, and ground-based equipment for separating associated gas from oil.

Equipment for implementing the method comprises: casing 1, with two packers 2 and 3, separating the gas-saturated part 4 of the formation and the oil-saturated part 5 of the formation, while radially directed drainage channels 6 of great length deep into the formation are cut out in the gas-saturated part 4 and in the casing 1 , not less than 1 m, and opposite the oil-saturated part 5 of the formation perforation 7 of the casing string. Two coaxially installed tubing of different diameters was lowered into the casing 1, while the tubing 8 of a smaller diameter was installed at the level of the oil-saturated part 5 of the formation, equipped with a borehole pump 9 and connected by a flow line 11 to the ground separator 12 for separating associated gas from oil. Larger tubing 10 of a larger diameter is lowered to the level of the gas-saturated part 4 of the reservoir and connected to the discharge line 13 of the separated associated gas from the ground gas compressor 14. The rocking machine 15 drives the rod 16 of the well pump 9. Pos. 17 — GNC line. Pos.18 - the path of the separated gas in the tubing 10 and in the drainage channels 6 of the gas-saturated part of the reservoir. Pos.19 - the path of the removal of degassed oil. Pos.20 - flow line soda oil.

The claimed method is implemented using the specified equipment.

In the casing 1, using a perforator with an increased output of the cutting tool, for example, presented in RF patent 80499 "Device for radial drilling of cased wells", designed to form radial channels with a depth of tens of meters, cut horizontal drainage channels 6 deep into the gas-saturated part 4 of the reservoir , not less than 1 m, which are necessary for the free and deep penetration of the gas injected from the surface into the low-permeability pore space above the GNA 17.

Perforate 7 of the casing 1 opposite the oil-saturated part 5 of the formation by any known method, for example, using a drilling puncher type PS (“Drilling perforators PS-112-70, PSPM 112-70, PSPM 136-90: Catalog-book / OJSC AZIMUT "Ufa, Republic of Bashkortostan, 2012, - p.2 (085.5) 622.24 / B-60" Downhole equipment ").

Oil production equipment containing coaxially installed tubing of smaller diameter 8 and larger diameter 10 is lowered into the casing and the gas-saturated part 4 of the formation and the oil-saturated part 5 of the formation are separated in the casing by means of two packers 2 and 3. In this case, the tubing 8 of a smaller diameter is set at the level of the oil-saturated part. 5 of the reservoir and is equipped with a downhole pump 9 connected by a flow line 11 to a ground separator 12 for separating associated gas from oil. Larger tubing 10 of a larger diameter is installed at the level of the gas-saturated part 4 of the formation and is connected by the discharge line 13 of the separated associated gas to the ground compressor 14.

After equipping the well according to the specified scheme, the operating mode is as follows.

The rocking machine 15 drives the rod 16 of the downhole pump 9. Due to the depression on the oil-saturated part 5 of the formation created by the downhole pump 9, the oil begins to flow through the pressure drop between its reservoir level created by the gas “cap” above the GOC and bottomhole pressure the perforation interval 7 into the wellbore and then along the tubing 8 to the surface through the flow line 11 to the ground separator 12, where the oil and associated gas are saturated. The separated gas is then supplied to the gas compressor 14, from which it is supplied through the tubing space under pressure through the tubing 10 and through the deepened drainage channels 6 is pumped into the gas-saturated part 4 of the formation above the GOC, thereby maintaining the elastic energy of the formation at a constant level, which contributes to a stable level of oil recovery from the oil-saturated part of the 5th layer.

As the oil is taken from the oil-saturated part of the formation and the separated gas is injected into the gas-saturated part of the formation, the SOC boundary gradually moves along the thickness of the formation from the roofing to the bottom part and the effective oil-saturated power of the productive formation gradually decreases, which leads to a gradual decrease in oil selection. However, due to the application of the proposed method for maintaining stable gas-elastic energy of the formation, the decrease in its productivity does not exceed 5% per year, whereas when the formation is operated in the mode of depletion of its gas-elastic energy, the rate of decrease in productivity reaches 25-30% per month.

Claims (1)

A method of developing hydrocarbon deposits, containing a second opening of two intervals of the well: the upper one, opposite the gas-saturated part of the reservoir — the gas “cap” and the lower — opposite the oil-saturated part of the reservoir, lowering the tubing — tubing, isolation with the packer of the gas “cap”, injection gas into the gas-saturated part of the reservoir and the selection of products using a well pump, characterized in that the secondary opening opposite the gas-saturated part of the reservoir is provided by creating a radially equal to the depth of the formation of drainage channels, then two coaxially installed tubing of different diameters are lowered into the well, while tubing of a smaller diameter is lowered to the level of the oil-saturated part of the reservoir and equipped with a borehole pump connected by a flow line with a ground separator to separate associated gas, and larger tubing is lowered to the level of the gas-saturated part of the reservoir and connected to the discharge line of the associated separated gas from the ground-based gas compressor, then oil is drawn through the tubing of a smaller diameter meter, and the separated gas is injected through a tubing of a larger diameter, while the separated gas is supplied under pressure into the inter-packer space in the gas-saturated part of the formation above the gas-oil contact - GOC, maintaining the energy of the formation at a constant level, in addition, as oil is removed from the oil-saturated part of the formation and injecting the separated gas into the gas-saturated part of the formation, the GOC boundary is gradually moved along the thickness of the formation from the roofing to the plantar part, providing a gradual rate of decline in oil recovery.

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