RU2377393C1 - Complex for off - shore hydrocarbons field arrangement - Google Patents

Abstract

FIELD: oil-and-gas.

SUBSTANCE: invention related to hydrocarbon fields development, off - shore. Complex consists of sea platform, production well and equipment for pumping water into the well, which consists of pump with drive, its inlet connected with injection well. After pump at the water pine heat exchanger connected, installed in to exhaust device of gas- turbine drive, gas - turbine drive and free turbine, rotor connected to electrical generator, eclectically connected to pump for hydrocarbons drive.

EFFECT: reservoir pressure increase and better heating of solid hydrocarbons for its melting and evaporation.

3 cl, 1 dwg

Description

The invention relates to the field of development of a hydrocarbon field located in the water, including oil and gas hydrates.

A well-known platform for offshore drilling of oil and gas wells according to the patent of the Russian Federation No. 2166611, which has a drilling site installed on watercraft.

Disadvantage: low reliability of the device, its inability to withstand storms, currents and ice sheet displacement.

Known offshore drilling platform according to the application of the Russian Federation for invention No. 2007129582. The offshore drilling platform contains a base and supports.

The invention is known according to the patent of the Russian Federation for invention No. 2288320. The offshore platform contains a base and supports with a protective unit and an electric power source connected to energy consumers.

There is a method of gas production from solid gas hydrates, according to which nonequilibrium thermobaric conditions are created in a gas hydrate deposit by reducing pressure and supplying heat, while the heat supply is carried out by introducing a solid sorbent into the gas hydrate bed to absorb water with specific heat exceeding the heat of dissociation of solid gas hydrate (see patent RU 2159323, ЕВВ 43 / 00.1999).

The disadvantage of this method is the need to create ground-based structures for supplying a solid sorbent to the bed of gas hydrate through the well and subsequent regeneration of the sorbent, as well as the small contact area of the sorbent in the vertical wellbore with the rock containing gas hydrate.

Of the known methods, the closest to the proposed technical essence and the achieved result is a method of developing solid hydrocarbon deposits, including drilling a deposit by a system of wells grouped by the area of the reservoir with horizontal sections, in each group of which, through one row of wells, the coolant is injected into one reservoir, and from another, hydrocarbons are selected from other productive formations, and in adjacent groups of wells, productive the fins into which the coolant is injected and from which hydrocarbons are taken, see US patent No. 5016709, ЕВВ 43 / 24.1991.

A known device and method for the thermal development of solid hydrocarbons according to the patent of the Russian Federation No. 2231635, prototype. The technical result of this invention is to provide intensification of heat transfer processes between the layers and reduce the cost of production and injection of coolant. The method includes drilling a deposit crossing the formation with a well with a system of horizontal lateral sections, forming a thermal field in one of the layers and taking hydrocarbons from the other formation. In this case, the aforementioned well is drilled with two horizontal steps, respectively, in the upper productive and lower strata, from which at least two lateral horizontal shafts are drilled in each stratum, which are closed to each other on the design connecting trajectory with the formation of closed circulation channels between the strata. The near-borehole space is sealed by installing casing packers at the ends of the horizontal trunks and discrete perforations of the trunks are produced with the formation of two perforation sections at the beginning and end of each trunk. Then, under the influence of a pressure differential between the layers of hot water, the supply of chilled water from the upper layer to the upper one and the forced supply of chilled water from the upper layer to the lower one are carried out until the reservoir properties of the productive layer are restored. After that, the sections of the sidetracks between the perforation sections are closed by the annular packers to communicate the separated perforation sections with the near-well spaces. Moreover, in the process of operation, continuous circulation is maintained through the formed closed channels of hot water from the lower layer and chilled from the upper one. The resulting decomposition products of hydrates - gas and water are sent for separation in a separator.

This device and method can improve the efficiency of the process of heat exposure by implementing the principle of multi-level impact on the reservoirs and, as a result, increase the degree of oil recovery of hydrocarbons.

The disadvantages of the method and device include a large flow of coolant, the absence of a powerful energy source, as well as the difficulty of implementing a multi-level heat exposure scheme, which ultimately reduces the efficiency of the development process, increasing the unit cost of a unit of production.

Objectives of the invention: increasing reservoir pressure and improving the heating of solid hydrocarbons for their melting and evaporation of gas hydrates, if any.

The solution of these problems was achieved in an offshore drilling platform containing a production well and a device for pumping water into the well, which, in turn, contains a pump with a drive, the inlet of which is connected to a reservoir, and the outlet - to an injection well, characterized in that after the pump a water line is connected to a heat exchanger installed in an exhaust device of a gas turbine drive, which, in turn, contains a gas turbine engine and a free turbine, the rotor of which is connected to a pump for pumping oil. An electric generator is connected to the gas turbine drive, and an electric drive connected to the pump by an electrical connection to the generator is connected to the pump. The gas turbine engine comprises an air intake, a compressor, a combustion chamber and a turbine. An engine fuel system is connected to the combustion chamber, comprising a fuel pump with a drive, a flow regulator, and a shut-off valve.

The proposed technical solution has novelty, inventive step and industrial applicability, i.e. all the criteria of the invention. Novelty and inventive step are confirmed by patent research.

The invention is disclosed in the drawing, which shows a diagram of a complex for equipping an offshore hydrocarbon field based on an offshore drilling platform.

The offshore drilling platform 1 contains a base 3 installed on the supports 2. The base 3 is installed on the soil 4, below which there is a producing formation 5, under which there is an aquifer 6. The offshore drilling platform 6 has a production well string 7 and an injection well string 8.

The casing of the production well 8 is connected to the inlet to the separator 9, the first outlet of which is connected to the transfer pump 10, and the second outlet to the first input of the three-way valve 11. A water inlet 12 is connected to the second input of the three-way valve 10, and a water pump is connected to its output 13 with a drive 14. The water supply pipe 15 through a controlled valve 16 is connected to the inlet to the heat exchanger 17, the outlet of which is connected by the hot water supply pipe 18 to the injection well string 8. The transfer pump 10 is connected by a shaft 19 to the transfer drive Chiva pump 20.

The device includes at least one gas turbine drive 21, comprising a gas turbine engine 22 and a free turbine 23 with a rotor of a free turbine 24, which is connected to the electric generator 25 by a shaft 26.

In addition, the gas turbine engine 22 includes: an air intake device 27, a compressor 28, a combustion chamber 29 with nozzles 30, a turbine 31 with a turbine rotor 32, and an exhaust device 33 mounted behind a free turbine 23. A heat exchanger 17 is installed inside the exhaust device 33. the electric generator 25 is electrically connected 34 connected to the actuator 14 of the pump 13 and other consumers of electricity (not shown).

To the nozzles 30 of the combustion chamber 29 is connected a fuel system of the engine 35, comprising a pump 36 with a drive 37, a flow regulator 38, and a shut-off valve 39.

The fuel system of the engine 35 is connected to the main pipe 40, designed for pumping the produced product, which contains a valve 41. The system has a control unit 42 connected by electrical connections 34 to the actuators 14 and 37, the regulator 38 and the shut-off valve 39, as well as control sensors ( not shown).

During operation, the gas turbine engine 22 is started, for this, electrical commands are sent from the control unit 39 to the actuators 14 and 37 and the opening of the shut-off valve 39. The fuel (oil, or natural gas or gas hydrates) is fed through the fuel system of the engine 35 to the nozzles 30 of the chamber combustion 29, where it is ignited by electric igniters (electric igniters not shown).

As a result, the combustion products untwist the rotor of the turbine 32 and the rotor of the free turbine 24. The generator 25 generates electricity, which is supplied by electric connections 34 to the drive of the transfer pump 20 and to other consumers of electricity.

A pump for pumping hydrocarbons 10 is activated, which increases the pressure of the produced product (s) in the main line 40. At the same time, the pump 13 draws water either from the reservoir or from the separator 9, depending on the position of the three-way valve 11 and through the water supply pipe 15 through a controllable valve 16 water enters the heat exchanger 17, where it is heated by exhaust gases exiting the gas turbine actuator 21 into the exhaust device 33, and then through the hot water supply pipe 18 enters the injection well 1. The pressure in the reservoir 5 rises. In the presence of solid gas hydrates, they melt and become suitable for selection in production wells.

The use of a heat source using fossil fuels provides several advantages related to the fact that it is difficult to deliver fuel and a compact and powerful source of energy such as a gas turbine plant to remote areas of the country. In addition, the use of a closed heating circuit without spending water also gives an advantage, reduces pollution of the produced mixture.

The use of hot water, which has a high temperature and high heat capacity, as the main heat carrier, allows faster and more efficient heat treatment of the reservoir, which consists mainly of hydrocarbons in the solid phase and ice and does not pollute the environment, because water is continuously circulating in a closed loop, separating in a separator. In addition, heat recovery in the exhaust device of a gas turbine plant increases its efficiency. It provides automatic coordination of the distribution of power used for heating water and the drive of the compressor and pump for pumping oil and the separator. The proposed device allows you to:

- utilize previously unused energy of the gas turbine engine to heat the water before it is fed into the reservoir and to facilitate the decomposition of gas hydrates into gas and water during their production,

- maintain high reservoir pressure in the reservoir by injecting hot water,

- ensure the environmental friendliness of the hydrocarbon production process (oil, gas or gas hydrates) by returning formation water to the reservoir (or below it to the aquifer),

- to ensure the operation of a gas turbine installation on produced hydrocarbons.

Claims (3)

1. A complex for arranging an offshore hydrocarbon field, comprising an offshore platform, a producing well and a device for pumping water into the well, comprising, in turn, a pump with a drive, the outlet of which is connected to the injection well, characterized in that it is connected via a water line a heat exchanger installed in an exhaust device of a gas turbine drive, comprising, in turn, a gas turbine engine and a free turbine, the rotor of which is connected to an electric generator connected to an electric connection with the pump drive for pumping hydrocarbons. 2. The complex for arranging an offshore hydrocarbon field according to claim 1, characterized in that the gas turbine engine comprises an air intake, a compressor, a combustion chamber and a turbine. 3. The complex for arranging an offshore hydrocarbon field according to claim 2, characterized in that the engine fuel system is connected to the combustion chamber, comprising a fuel pump with a drive, a flow regulator and a shut-off valve.