RU118682U1 - Borehole Electrochemical Heater - Google Patents

Abstract

The utility model relates to the oil industry, namely, downhole heaters, designed, for example, for thermal impact on the bottomhole zone and the oil reservoir, and can be used in the production of highly viscous paraffin oil and natural bitumen, as well as for cleaning the borehole space from tar and paraffin deposits. A downhole electrochemical heater can be used to reduce viscosity and pressure in field pipelines during transportation of viscous liquids.

The utility model solves the problem of increasing the efficiency of a downhole electrochemical heater for heat treatment of wells with high viscosity paraffin oil and bitumen, reducing the viscosity of well production, as well as melting or preventing asphalt-resin-paraffin deposits.

The problem is solved by the proposed downhole electrochemical heater.

A downhole electrochemical heater is lowered into the well on tubing (tubing) below the level of the pump and filter and is attached to the tubing using a connecting thread. The heater is installed opposite the perforation zone, and contains a hollow cylindrical body (hereinafter referred to as the body), partially filled with a working electrolyte and acting as an electrode, and a central phase electrode installed in the body, the lower end of which is placed in the working electrolyte and equipped with a dielectric nozzle inserted into the centering groove of the body .

What is new is that the heater is equipped with a temperature sensor located at some distance, for example, 20 cm above the body and functionally connected to the controller of the control station, with the ability to automatically adjust the temperature for power.

New is the fact that the housing is divided into zones by fluoroplastic conical insulators with metal contacts.

Also new is the fact that the case, the central phase electrode and metal contacts are made of stainless steel, while the possibility of transferring heater power is determined by the ratio of the density and volume of the working electrolyte.

The technical and economic advantage of the proposed downhole electrochemical heater is to simplify the design by reducing the number of parts, as well as increasing the service life by increasing the corrosion resistance of the nodes and parts.

Tests of the claimed device showed its effectiveness and efficiency in the production of not only high-viscosity paraffin oils, but also when transporting well products through pipelines.

The proposed downhole electrochemical heater is durable, reliable and safe to operate.

It is effective for heat treatment of reservoir intervals, as well as for the melting or prevention of paraffin-hydrate plugs, asphalt-resinous, asphalt-resin-paraffin deposits in tubing and on sucker rods.

The device is also applicable for heating and reducing the viscosity of well products at the reception of deep pumps and at the wellhead or in a pit at the wellhead for associated heating and reducing the viscosity of the transported well products.

Description

The utility model relates to the oil industry, namely, downhole heaters, designed, for example, for thermal impact on the bottomhole zone and the oil reservoir, and can be used in the production of highly viscous paraffin oil and natural bitumen, as well as for cleaning the borehole space from tar and paraffin deposits. A downhole electrochemical heater can be used to reduce viscosity and pressure in field pipelines during transportation of viscous liquids.

Prerequisites for creating a utility model.

Analysis of the current level of technology in this field showed the following.

A significant part of the fields is characterized by high depletion of oil reserves and, consequently, hydrocarbon withdrawals from them are reduced. To maintain a high level of production at the present stage, it is rational to commission oil fields with hard-to-recover reserves. Previously, the development of these deposits was ineffective due to the lack of technologies that ensure the maximum possible and economically feasible extraction of hydrocarbons from the bowels. Of all modern technologies aimed at increasing oil recovery, and in particular the production of high-viscosity oils, thermal methods have no alternative.

A well-known electrode heater is known, comprising an electrode made in the form of a housing partially filled with electrolyte, a second electrode installed in the housing, the upper part of which is made in the form of a spring, and a piston mounted above the electrolyte with the possibility of axial movement, dividing the housing into two sealed chambers (Patent RF No. 2023144, CL E21B 43/24).

The disadvantage of this heater is the inability to provide a movable and at the same time tight connection of the piston with the working part of the housing under operating conditions characterized by high pressure and vapor temperature, which reduces the reliability.

Another disadvantage is the irrational use of the working chamber of the heater. The housing is divided into two sealed chambers, one of which is occupied by a spring, and only the volume of the second chamber is used for the working process, which significantly reduces the power of the heater when the electrolyte boils as a result of a small amount of electrolyte solution.

There is a downhole electrode heater used to break hydrate plugs, paraffins and solidified oil, comprising a casing acting as an electrode, an electrode placed inside the casing, a separator mounted above the electrolyte with the possibility of axial movement and forming a sealed chamber partially filled with electrolyte (Auth. USSR No. 1613588, CL E21B 43/24).

The disadvantages of this heater are the low rate of destruction of hydrate plugs, paraffins and solidified oil in the upper layers of the wells and the unreliability of work. The reason for this is not the tightness of the housing, as a result of which the pressure and the boiling temperature of the electrolyte in the sealed chamber increase with increasing depth of immersion of the heater in the well. This intense thermal regime is required for the heater to work in the upper layers of the wells, and not in the lower ones. In addition, oil containing various deposits, which make it difficult to move the piston separator and reduce the reliability of the heater, enters the body cavity.

The closest to the proposed technical solution is the well electrode heater adopted by us as a prototype, comprising an electrode made in the form of a tubular body partially filled with electrolyte, a second electrode coaxially mounted in the body, the lower end of which is placed in the electrolyte and equipped with a nozzle, while the body is made in the form of a single sealed chamber, and the second electrode is a metal rod, the nozzle of which is made of dielectric material and inserted into Trier housing groove, wherein the operating pressure in the chamber is determined by the calculated ratio of the height of the nozzle, the electrolyte volume, the maximum volume of the chamber and the strength characteristics of the body (RF Patent №2119577, Cl. E21B 36/04, E21B 43/24).

However, the use of this heater is associated with significant energy costs, due to the fact that this design has increased power, and the presence of metal parts contributes to the failure of the device due to the development of corrosion processes.

The utility model solves the problem of increasing the efficiency of a downhole electrochemical heater for heat treatment of wells with high viscosity paraffin oil and bitumen, reducing the viscosity of well production, as well as melting or preventing asphalt-resin-paraffin deposits.

The problem is solved by the proposed downhole electrochemical heater.

A downhole electrochemical heater is lowered into the well on tubing (tubing) below the level of the pump and filter and is attached to the tubing using a connecting thread. The heater is installed opposite the perforation zone, and contains a hollow cylindrical body (hereinafter referred to as the body), partially filled with a working electrolyte and acting as an electrode, and a central phase electrode installed in the body, the lower end of which is placed in the working electrolyte and equipped with a dielectric nozzle inserted into the centering groove of the body .

What is new is that the heater is equipped with a temperature sensor located at some distance, for example, 20 cm above the body and functionally connected to the controller of the control station, with the ability to automatically adjust the temperature for power.

New is the fact that the housing is divided into zones by fluoroplastic conical insulators with metal contacts.

Also new is the fact that the case, the central phase electrode and metal contacts are made of stainless steel, while the possibility of transferring heater power is determined by the ratio of the density and volume of the working electrolyte.

The utility model is illustrated by drawings, in which:

- figure 1 shows the layout of the electrochemical heater in the well;

- figure 2 shows the design of a downhole electrochemical heater;

- figure 3 shows the design of a fluoroplastic conical insulator.

The downhole electrochemical heater (Fig. 1) is lowered into the well below the level of pump 8 on the tubing 1, to which it is connected by means of a connecting thread (not shown in the drawings). In the interval of perforation 2 of the oil reservoir 3 above the downhole electrochemical heater 4, a filter is installed through one pipe (not indicated in Fig.) And then the whole arrangement is assembled. The current-carrying cable KRBK 5 is attached to the tubing 1 with clips for attaching cable 6 (according to the type of descent of the electric centrifugal pump - ESP). At the output, cable 5 is sealed with a stuffing box (not shown in FIG.). At the wellhead, a control station 7 is installed.

The downhole electrochemical heater 4 (FIG. 2) contains a current-supply cable 5 (FIG. 1), a housing 9, which also acts as a zero electrode, and serves as a working chamber for the electrolyte 13, and a central phase electrode 10 made in the form of a metal rod mounted in the housing 9. The end of the central phase electrode 10 is made of dielectric material in the form of a nozzle 11 and inserted into the centering groove 12 of the housing 9. The housing 9 is partially filled with a working electrolyte 13. The housing 9 is divided into zones by cone-shaped fluoroplastic and insulators 14 with metal contacts 15.

Above the downhole electrochemical heater, a temperature sensor 16 is placed, functionally connected with the controller (not shown) of the control station 7. The temperature sensor 16 is located above the heater in order to control the temperature of the produced fluid and control the power of the heater. The downhole electrochemical heater is equipped with a fixing unit 17.

Downhole electrochemical heater operates as follows.

When applying voltage to the electrodes 9 and 10, the working electrolyte 13 heats up and boils. The boiling temperature of the working electrolyte 13 depends on the vapor pressure of the solution in the housing of the heater 9, the pressure of which increases due to the tightness of the housing 9. With increasing temperature, the working electrolyte 13 boils and passes into a gaseous state. The level of the working electrolyte 13 decreases, the pressure in the housing 9 increases, and the contact area of the central phase electrode 10 with the working electrolyte 13 decreases. At the moment when the level of the working electrolyte 13 decreases to the upper edge of the dielectric nozzle 11, the electric circuit is interrupted, the heating of the working electrolyte 13 is stopped and the vapor pressure drops. The steam partially condenses, as a result of which the level of the working electrolyte 13 rises and again reaches the working part of the central phase electrode 10. The electric circuit closes, heating of the working electrolyte 13 is resumed. The fluoroplastic conical insulators 14 serve to accelerate the reaction during condensation of the working electrolyte 13, shortening the path of its movement to the central phase electrode 10 and increasing the efficiency of operation of the downhole electrochemical heater. The cycle repeats. The vapor pressure and temperature of the downhole electrochemical heater are stabilized at the operating value.

The technical and economic advantage of the proposed downhole electrochemical heater is to simplify the design by reducing the number of parts, as well as increasing the service life by increasing the corrosion resistance of the nodes and parts.

Tests of the claimed device showed its effectiveness and efficiency in the production of not only high-viscosity, paraffinic oils, but also when transporting well products through pipelines.

The proposed device is durable, reliable and safe to use; it is effective for heat treatment of formation intervals, as well as for the melting or prevention of paraffin-hydrate plugs, asphalt-resinous, asphalt-resin-paraffin deposits in tubing and on sucker rods.

A downhole electrochemical heater is also applicable for heating and reducing the viscosity of well products at the reception of deep pumps and at the wellhead or in a pit at the wellhead for associated heating and lowering the viscosity of the transported well products.

Claims (1)

A downhole electrochemical heater, lowered into the well on tubing below the level of the pump and filter and fixed to the tubing - tubing with a connecting thread, installed opposite the perforation zone and containing a hollow cylindrical body that is a working chamber for the electrolyte and partially filled with a working electrolyte and acting as an electrode, and a central phase electrode mounted in a hollow cylindrical body, the lower end of which is placed in the working electro cast and equipped with a dielectric nozzle inserted into the centering groove of the housing, characterized in that it is equipped with a temperature sensor located at a distance, for example 20 cm above the heater housing, and functionally connected to the controller of the control station, with the ability to automatically adjust the temperature by power, and the housing is divided into zones by fluoroplastic conical insulators with metal contacts, while the housing, the central phase electrode and metal contacts are made of stainless steel, with the possibility of transmission power of the heater is defined by the density and volume of the electrolyte.