RU9885U1 - HEAT LOCK - Google Patents

Abstract

1. Thermal lock, including an element that restrains heat flow, located at the bottom of the pipe string, characterized in that, as an element that restrains heat flow, it contains a set of bushings with annular recesses. 2. The lock according to claim 1, characterized in that one or more additional sets of bushings with annular undercuts are placed above a set of bushings with annular undercuts.

Description

The utility model relates to the oil industry and can be used to create a thermal lock on the bottom of a steam injection well.

A known packer containing a sleeve connected to a pipe string, a body with an annular groove, a barrel with a sealing element installed on it, a piston with a stopper, a support ring with pins installed in the body groove, a detachable latch interacting with a sleeve provided with a connected thread with the body of the running nut with a pin, and the nozzle is made with a window for placing the pin in it (1).

The disadvantages of the known packer is that the seal is freed from the axial compressive load by a long rotation of the pipe string, which complicates the packer removal process, especially in directional wells when using thermally insulated pipes, requires the use of additional technical means and pipes of an increased strength group.

The closest to the utility model in technical essence is a packer that acts as a thermal lock on

the bottom of the well, containing the barrel connected to the pipe string with a spring element installed on it, upper and lower

clamps, hydraulic conduit, a thrust sleeve mounted on the pipe string and a pipe placed between it and the upper clamp, made of a material with a linear expansion coefficient greater than that of the pipe string material (2).

E 21B 33/12

Thermal lock

en

The known device allows the movement of the sealing element relative to the place of landing in the production casing during cyclic changes in temperature, but it does not provide reliable operation, since it is difficult to install, remove and lift, especially when using thermally insulated pipes designed to pump the coolant into the reservoir.

The utility model solves the problem of improving the reliability of the thermal lock at the bottom of a steam injection well.

The problem is solved in that the thermal lock, including the element that restrains the heat flux located in the lower part of the pipe string, as the element that inhibits the heat flux, contains a set of bushings with annular recesses. One or more additional sets can be placed above the set of bushings with annular recesses bushings with ring grooves.

Signs of a utility model are:

1. a column of pipes;

2. element that delays heat flow;

3. use as an element that impedes heat flow, a set of bushings with annular recesses;

4.Placing above a set of bushings with ring grooves of one or more additional sets of bushings with ring grooves.

Signs 1,2 are common with the prototype, sign 3 is an essential hallmark of a utility model, sign 4 is a private sign of a utility model.

they do not provide the necessary tightness and work like a thermal lock. The low degree of reliability of the packers is explained by the mismatch between the materials of the sealing manhats and the extreme working conditions when steam is injected. At the same time, skipping the packer under conditions of tight operation of the pipe string above the packer is not an obstacle for further operation of steam injection wells, so how heat transfer through the resulting leaks is negligible.

Thermally insulated tubing experience compression load from the weight of the string, which contributes to the depressurization of threaded joints. During long-term operation of the packer, scale and mineral deposits accumulate on top of the packer equipment, which makes it difficult to break the packer during repair. Accident and complications during repair reach 10%. Significant labor costs when repairing a well equipped with a packer. They exceed 1.5-2.0 times the labor costs well repair without a packer.

The proposed utility model solves the problem of increasing the reliability of the thermal lock at the bottom of a steam injection well, as well as simplifying repair work and installing downhole equipment.

The problem is solved in that the thermal lock, including the element that restrains the heat flux located in the lower part of the pipe string, as the element that inhibits the heat flux, contains a set of bushings with annular recesses. One or more additional sets can be placed above the set of bushings with annular recesses bushings with ring

undercut.

Fig. Presents a thermal lock.

The thermal lock includes a set of bushings 2 with annular recesses located on the tubing string 1. The thermal lock is located in the borehole 4. One or more thermal locks can be placed on the tubing string 1 above the thermal lock (in FIG. shown).

Thermal lock works as follows.

When the string of tubing 1 is pumped coolant - steam entering the reservoir. The ring grooves 3 on the set of bushings 2 create additional resistance for convective heat transfer.

The descent, installation and lifting of the tubing string 1 with a set of bushings 2 are not difficult, because between the well 4 and the set of sleeves 2 there is a gap of the order of 5-6 mm. Concrete example

In accordance with FIG., The bottom of a steam injection well is equipped. The set of bushings 2 is made of aluminum with a total length of 1.5 m. The maximum diameter of the bushings 2 is less than the internal diameter of the borehole 4 by 5 mm. The well is equipped with a thermally insulated column of tubing 1.

To determine the heat loss, 3 m of water is drained from the annulus of a working steam injection well and its temperature is measured, which amounted to 50 ° C. These data indicate very low heat losses in the well equipped with a thermal lock.

The application of the proposed technical solution will improve the reliability of the thermal lock, simplify the descent, installation and lifting of downhole equipment during installation and repair.

Sources of information taken into account when preparing the application:

1. PatentSSSR No. 839447, class E 21 B 33/12, published. 1991 year

2. RF patent No. 1346760, class E 21 B 33/12, published. 1991 prototype.

-5 Formula

Claims (2)

1. Thermal lock, comprising an element that restrains the heat flux located at the bottom of the pipe string, characterized in that it contains a set of bushings with annular recesses as an element that inhibits the heat flux. 2. The lock according to claim 1, characterized in that one or more additional sets of bushings with annular undercuts are placed above a set of bushings with annular undercuts.