JPS62274191A - Heat-insulated tubular sliding joint - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION 3. DETAILED DESCRIPTION OF THE INVENTION TECHNICAL FIELD The present invention relates to a wellbore tube for isolating the temperature of a fluid from components of a tubing string, including fittings in the wellbore. The present invention relates to an insulated tubular assembly for transporting fluids to the surface and down-hole.

BACKGROUND OF THE INVENTION Insulated tubular assemblies for transporting hot fluids in relative isolation from the surrounding environment are known. A typical tubular assembly is disclosed, for example, in US Pat. No. 4,538,834. These assemblies are typically utilized to increase oil yield from oil wells by steam injection. Steam often has a temperature on the order of 650″F (343°C).

(steam injection tubular assembly or tubing) isolating this high temperature from the IJ song component to prevent deterioration of this component and directing the steam from the tubular assembly to the perimeter walls of the wellbore or other components within the wellbore. It is desirable to reduce the temperature losses lost to

Tubinges) IJ song, often connected to the wellbore casing far down in the wellbore.

Typically, a mechanism called a packer J is used to connect the downhole end of the tubing string to the wellbore. The packer includes a seal that prevents hot, high pressure air from flowing upwardly into the annulus between the tubing string and the wellbore casing. The packer thus prevents the upward flow of hot, high-pressure fluid, forcing this fluid into the oil-producing formation, thus driving the oil to an adjacent wellbore for recovery.

The packer securely attaches the ends of the tubing string to the well casing. Therefore, provision must be made to account for the longitudinal elongation of the tubing (string elongation) caused by changes in the temperature of the tubing string. 20 feet (6,096
To accommodate this stretch, which can exceed m), it is common to use expansion or slip joints. Such sliding joints are installed with a backer as an integral subassembly.
or may be provided as a completely separate unit at the bottom or top of the tubing string.

Insulated sliding joints are also useful in gas or fluid distribution systems that carry hot gases or fluids above ground and under water.

For above-ground distribution lines, slip joints can be placed anywhere along the line.

In the past, slip joints have created problems for steam injection oil recovery systems, whether integral with the packer or a separate mechanism from the bunker.

The slip joint has a seal that deteriorates prematurely at high temperatures, and this seal is located 5,000 feet (1.
, 524 m) or more, the cost of repair is expensive. The high temperature of the steam created a second problem with downhole packers and slip joints in that much of the heat from the steam was conducted through the body of the unit and outward into the wellbore casing. This heat loss is wasted and results in “reflux”.
Reflux also occurs when the surface of the packer or slip joint unit is heated to the appropriate temperature of the steam trapped within the annulus between the tubing string and the casing. The water content is
The high temperature of the surface of the packer or slip joint causes it to evaporate and rise up the wellbore. When this hot steam contacts the cooler surface of the casing higher up in the wellbore, it transfers much of its heat to the cooler surface and condenses. The condensed liquid flows downward under its own weight through the wellbore until it again contacts the hot packer or slip joint unit and repeats the evaporation cycle. Reflux transfers a large amount of thermal energy to the casing by increasing the overall heat transfer coefficient between the tubing string and the wellbore. All of these heat losses reduce the efficiency of the steam injection process.

Some attempts have been made to ameliorate the problem of seal degradation by selecting various seal materials that are more compatible with high temperatures. However, not all of these attempts were successful. The reflux problem was not successfully resolved.

Slip joints, regardless of their arrangement, must be insulated to prevent the heat losses mentioned above.

DISCLOSURE OF THE INVENTION It is an object of the present invention to provide an improved insulated sliding joint within a buffing force for use in insulated tubing or pipe systems.

Another object of the invention is to provide a method for transporting hot fluids.
J-Song provides a slip joint in a distribution system having concentric inner and outer tubes sealed to form an annular insulating chamber therebetween.

One object of the present invention is to provide a slidable mandrel for buffing forces, the slidable mandrel having an outer surface having a polished outer surface for sliding past the outer tube, preferably the packer internal seal. a tube and an inner tube concentric with and spaced apart from the outer tube to define an annular space therebetween, the annular space being sealed and preferably evacuated; This is best achieved by thermally isolating heat from the hot steam in the inner tube from the surface of the outer tube. The mandrel extends the entire length of the backer to thermally isolate the casing slip and other components of the backer as well as the packer internal and external seals.

The sliding mandrel can be used alone, spaced apart from the backer like another sliding joint, or can be used above ground or submerged in water in other heated fluid distribution systems.

The use of such a thermal isolation mandrel reduces heat flow to the outer surface of the tubing and thus reduces reflux effects within the annulus between the tubing string and the wellbore. Additionally, heat transfer to the backer or other slip joint components is reduced, thus increasing the material life of these components.

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a packer having a body 12. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. The body 12 includes a set of casing slips 14 that can be radially expanded by conventional means to engage and secure the body 12 to the wellbore casing.

The body also has an external seal 16 for sealing against upward migration of hot fluids between the body and the casing. The body has an internal seal 18 that seals between the slidable mandrel 20 and the body.

Mandrel 20 includes a fitting 22 that connects mandrel 20 to an uphole steam injection tubing string 24 and a lower fitting 26 that connects mandrel 20 to a downhole portion of tubing string 28.

The representative packer mentioned above is well known and has an address in Hampil, Texas.
This can be done manually through companies such as l Tool Company.

A unique feature of the invention is that the slidable mandrel 20
The inner tube 32 is arranged concentrically with the outer tube 34 and spaced apart from the outer tube 34, and an annular heat-insulating space 36 is provided between the outer tube 34 and the inner tube 32. The ends of the tubes are each sealed with frustoconical structures 40, 42. Preferably, the annular space 36 is evacuated, as described in U.S. Pat. No. 4.5.
It may be filled with an insulating material such as that described in No. 38.834. Preferably, a getter is provided in the annular space for absorbing gas moving into the annular space.
Materials are also provided.

The annular space 36 serves as a thermal barrier that prevents the transfer of heat from the inner tube 32, which carries hot steam or pond fluid or gas, to the outer tube 34, which is in contact with the components of the body of the packer or slip joint. Thermal isolation also reduces the temperature exposure of outer seal 16 and inner seal 18, thus extending their useful life. Thermal isolation reduces the temperature of the surface of the body, thus reducing the heat that helps create reflux within the annulus between the tubing string and the wellbore casing.

The outer tube 34 of the slidable mandrel is configured to form a better sealing surface with the seal 18 and to allow the outer tube 34 to slide against the seal 18 due to elongation of the tubing string as it is heated. It is preferable to have a research calendar so that you can do it. In an integrated packer embodiment, the casing slip secures the packer to the wellbore, and the tubing string extends as much as 20 feet (6,096 m) within a typical wellbore when heated with steam and expanded. Sometimes.

This stretching of the tubing string is accommodated by the mandrel as it slides downwardly within the packer to the position shown in FIG. As the tubing string cools when the steam injection is discontinued, the mandrel slides upward from the position shown in FIG. 1 to allow contraction of the length of the string.

In surface line embodiments, ground anchors and external line attachments typically secure the tubing to the ground at a location remote from the slip joint. Therefore, when the tubing is heated with hot fluid and expanded, it can stretch several feet.

This change in the tubing string is also accommodated by the mandrel.

Although the preferred embodiment of the invention has been illustrated and described,
It will be appreciated that various modifications will be apparent to those skilled in the art without departing from the principles of the invention. Therefore, the invention should not be limited to the specific forms shown in the drawings.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram of a typical wellbore packer employing a thermally isolated slip joint embodying the principles of the present invention. 12... Main body, 16... External seal, 18... Internal seal, 22... Upper joint,
24... Uphole steam injection tubing string, 14... Casing slip, 20... Slidable mandrel, 26... Lower joint, 28... Downhole portion of tubing string, 32... Inner tube, 34... Outer tube, 36
...An annular insulated space.

Claims (4)

[Claims] (1) A thermally isolated wellbore packer with an integral slip joint, comprising an outer body having a radially expandable casing slip, the casing slip extending into the hole at a location in the hole below the top of the hole. an external sealing means for sealing between the main body and the well bore, and an external sealing means disposed concentrically inside the main body and having an upper end and a lower end. an elongated sliding mandrel having an internal seal means for sealing between the mandrel and the body; and for connecting the lower end of the mandrel to an insulated tubing string capable of conveying hot fluid through the wellbore below the packer. lower coupling means for connecting the upper end of the mandrel to an insulated tubing string above the packer; an outer tube radially spaced from the inner tube to define an annular space therebetween; and means disposed within the annular space for increasing thermal isolation of the outer tube from the inner tube; A thermally isolated wellbore packer characterized in that heat from the tubing string is thermally isolated from the body seal and casing slip. (2) A thermally isolated downhole wellbore slip joint for a tubing string carrying high-temperature fluids, having an inner tube and an outer tube concentrically spaced apart, with an annular space between the inner tube and the outer tube. a slidable mandrel forming a tubing string, the annular space being insulated to thermally isolate the outer tube from the inner tube, and means for connecting one end of the mandrel to a first portion of the tubing string. and means for slidably coupling the other end of the mandrel to an opposite second portion of the tubing string separated from the first portion; and means for slidably coupling the other end of the mandrel to an opposite second portion of the tubing string separated from the first portion; means for sealing, and the mandrel is slidable along the sealing means to maintain a seal while the tubing string is thermally stretched. downhole wellbore slip joint. (3) the second portion of the tubing string includes a packing, the packing including a pair of removable slips for securing the packing against axial movement within the wellbore; 2. The sliding joint according to claim 2, further comprising an external sealing means for sealing between the and the packing. (4) An insulated sliding joint for a long and narrow pipe for conveying high-temperature fluids or gases, having an inner pipe and an outer pipe concentrically spaced apart, with an annular space between the inner pipe and the outer pipe. a slidable mandrel formed therein, said annular space being insulated to thermally isolate the outer tube from the inner tube, and means for connecting one end of the mandrel to a first portion of the tube; means for slidably coupling the other end of the mandrel to a second section on the opposite side of the tube, separated from the first section; and means for sealing between the second section of the tube and the outer tube of the mandrel. An insulated slip joint comprising: and wherein the mandrel is slidable along the sealing means to maintain a seal during thermal stretching of the tube.