RU2289071C1 - Method of supplying heat to bed of hydrocarbon deposited - Google Patents

Abstract

FIELD: production or use of heat.

SUBSTANCE: method comprises supplying water to the vortex heat generator, generating vortex flow of water inside the heat generator to provide cavitation flow, and drawing heat from the output flow. The water is supplied alternatively to several vortex generators that are arranged in series in the pipeline system through which the heat agent is supplied to the bed.

EFFECT: enhanced efficiency.

1 dwg

Description

The method of supplying heat to the reservoir is intended for use in thermal flooding technologies for the extraction of heavy oils. Using the proposed method, an increase in oil recovery in the production of heavy oil is achieved. It is used both in the geological mining industries and for heating liquids such as oil during their pumping in order to reduce the viscosity of the liquid and improve its rheological properties. Including in heating networks to provide additional heating along the route during pumping and to provide replenishment of heat losses during the passage of liquid along the route.

The invention is known "Unit heat generators", application RU No. 2001102815, publ. 05/27/2003, IPC F 25 B 29/00, including several heat generators of the same type, connected in series to a single unit, a water tank and a main pipeline. However, the purpose of the unit is a closed heating system. In addition, the unit requires the conversion of the coolant into a gas-vapor mixture to obtain a gas-vapor mixture, which, in turn, requires a complex electrolysis system. In addition, the device has a sophisticated coolant cleaning system. All of the above significantly complicates the design.

The invention is known "Method of operating a well and installation for its implementation", patent RU No. 2138622, publ. 07/10/1999, IPC E 21 B 43/00, consisting in lowering the auxiliary pipe into the well, supplying the medium to the cavity of the auxiliary pipe, filling the cavity of the auxiliary pipe and the cavity behind the mining elevator with heating medium, using an auxiliary pipe of constant or variable cross section and concentric or eccentrically lower it outside the mining hoist. The method eliminates the formation of deposits in the mining lift. However, the method has a narrow scope. In addition, the method uses heaters, for example electric, which, in turn, heat the coolant in a closed pipe. This significantly increases heat loss during its transfer to the oil reservoir and complicates the design. In addition, the method does not use the conversion of rotational energy into thermal energy.

Known invention "Device and method of cook for extending the life of oil fields", application RU No. 93013502, publ. 01/27/1996, IPC E 21 B 43/00, containing a pipe with a hydraulic turbine and a pump pumping heated water into the oil reservoir. Using this device, a method of controlled combustion of oil is implemented by supplying compressed air and water to the combustion chamber created in the oil reservoir. However, the device does not use the method of converting rotational energy into thermal energy.

Closest to the proposed technical solution is the invention "Method for producing heat", patent RU No. 2165054, publ. 04/10/2001, IPC F 24 J 3/00, in which a circuit is used in which a gradual increase in the temperature of the water supplied to the inlet of the vortex tube of the heat generator is carried out, the efficiency of heat generation ensures an increase in the temperature of the water supplied to the inlet of the vortex tube, up to a temperature of 90 ° C. However, the generation of heat requires a change and refinement of the temperature range of the water used to generate heat. In addition, the process requires additional measures to reduce the radiation hazard of neutron irradiation.

Currently, the production of heavy oils requires additional heating of the formation to increase oil production. To do this, heat must be supplied to the formation at the lowest cost. However, when, for example, heated water passes along the route when pumping and supplying hot water to the oil reservoir under high pressure, heat is significantly lost, and replenishment of heat requires complex and expensive units that provide heating of the supplied water throughout the route, i.e. Constant replenishment of heat loss during the passage of water along the route is required.

The technical result of the proposed technical solution is to simplify the design of the system for supplying heat to the reservoir, providing track heating in high pressure pipelines and supplying heat to the required temperature, intensifying the heat supply without intermediate losses, increasing the reliability of the system.

This technical result is carried out using the proposed method. To do this, water is supplied to the vortex heat generator (1), a vortex water flow is formed in it while providing a cavitation mode of the vortex flow flow by subsequent removal of heat received in the vortex heat generator from the effluent. The proposed method is characterized in that the formation of a vortex water flow in the heat generator is provided with the formation of a cavitation mode of the vortex flow with simultaneous resonant amplification. The water supply is carried out alternately in several vortex heat generators (1), located sequentially one after another in the piping system (2), through which the coolant flow into the reservoir. A vortex water flow is formed while ensuring a cavitation regime of the vortex flow and resonant amplification in each of the N heat generators, the output stream from the previous heat generator being translationally supplied as the input stream of the subsequent generator using its heat, and the vortex stream is formed translationally in front of each heat generator along the pipeline axis . In this case, the distance “L” between the outlet nozzle of the previous heat generator and the inlet nozzle of the subsequent heat generator is calculated according to the Bernoulli formula for a stationary fluid flow, due to which a laminar flow of supplied water is ensured. Heat is removed from the effluent of the last heat generator by supplying heated water to the oil reservoir (3). It is possible that the track heat generators (1) are installed in groups of N heat generators in the ground part of the high pressure pipe system and an additional group of K downhole heat generators (4) is installed in the injection well (5). In addition, to supply water from the pipeline (2) to the first vortex heat generator, a buffer tank (6) is installed, into which water is pumped under pressure using a centrifugal pump (7).

The proposed technical solution is illustrated by a drawing, which shows a schematic diagram of a thermal flooding method for the production of heavy oils.

The method is as follows.

In the ground part of the system, a heat generator is installed at the cluster pumping station (SPS), the water is heated through a buffer tank through a circulation tank to a temperature of 60-75 ° C. Next, the water enters the buffer tank, then through the pumping station the water enters the pipeline, which is coaxial with the longitudinal axis of the heat generator. In N heat generators of the above-ground part of the system, water is heated to a temperature of 80 ° C, after which the heated water through the above-ground part of the high-pressure pipeline enters the well, in which the vertical high-pressure pipeline is also located. From it, water sequentially enters the well heat generators built into the tubing, where additional water is heated to 85 ° C. The vertical tubing suspension is located in the production casing of the injection well to the oil reservoir. Heated with a series of heat generators in series, the water flows from the outlet pipe into the under-packer space of the production string and then into the oil reservoir.

Due to the fact that each subsequent heat generator additionally heats the pumped water, replenishment of heat losses in the areas of pumping water through the pipeline is provided. In addition, due to the coaxial arrangement of the pipeline and heat generators, as well as the absence of a tangential supply of additional water pressure to the heat generators, additional heating of the water is carried out along the route during pumping with the least loss of released heat energy. At the outlet of the heat generator, a simple turbulent flow in the outlet pipe is gradually inhibited and established, becoming a flow with a steady motion that smoothly changes its motion, i.e. laminar. Since it is necessary to observe the condition for ensuring the laminar flow at the inlet of each subsequent heat generator, they are located at intervals not more often than the distance required to stabilize the flow, which is calculated based on the Bernoulli formula.

The minimum losses and additional heating of water in the system is achieved through the use of a heat generator, in which the flow energy is extracted from the vortex water flow, which is formed while ensuring the cavitation regime of the vortex flow and resonant amplification in each of the heat generators. The presence of resonance perturbations superimposed on the vortex cavitation flow, allows to increase the efficiency of the release of the internal energy of the flow. Due to the pine feed flow at the inlet of each heat generator, the loss of this energy through the walls of the pipeline is reduced, because local losses of the flow head are significantly reduced due to the absence of local obstacles, for example, in the form of pipe bends.

The implementation of the technology of thermal flooding using the proposed method provides an increase in oil recovery in heavy oil production.

Claims (3)

1. The method of supplying heat to the reservoir of hydrocarbon deposits, which consists in supplying water to a vortex heat generator, forming a vortex water stream in it while providing a cavitation regime for the vortex flow, followed by removal of heat received in the vortex heat generator from the effluent, characterized in that the formation of the vortex flow water in it is provided with the formation of a cavitation mode of the vortex flow with simultaneous resonant amplification, the water supply is carried out alternately in several vortex heat heats arranged sequentially one after another in the piping system, through which the coolant flow is introduced into the formation, while the formation of the vortex water flow while ensuring the cavitation regime of the vortex flow and resonant amplification is carried out in each heat generator, and the output stream from the previous heat generator is progressively supplied as the input stream of the subsequent generator using its heat, and in front of each heat generator a vortex stream is formed translational along and a pipeline, while the distance between the outlet nozzle of the previous heat generator and the inlet nozzle of the subsequent heat generator is calculated according to the Bernoulli formula for a stationary fluid flow, which provides a laminar flow of supplied water, and heat is removed from the outlet flow of the last heat generator by supplying heated water to the oil reservoir. 2. The method of supplying heat to the reservoir of hydrocarbon deposits according to claim 1, characterized in that the line heat generators are installed in groups of N heat generators in the above-ground part of the high pressure pipe system and an additional group of K downhole heat generators is installed in the injection well. 3. The method of supplying heat to the reservoir of hydrocarbon deposits according to claim 1, characterized in that for supplying water from the pipeline to the first vortex heat generator, a buffer tank is installed in which water is pumped under pressure using a centrifugal pump.