RU2473005C1 - Thermally insulated tubing - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method involves application of silicate enamel coating to internal surface of internal pipe, and multi-layer screen heat insulation made on its external surface. Sorbent is used as gas absorber between layers of heat insulation. Cutting of cone-buttress thread is made on ends of external pipe. Internal pipe is arranged inside external pipe on centralisers. Sealing of inter-tube space by means of welding in vacuum using tight welds on the side of pipe ends, as well as creation of vacuum of 10^-8 10^-10 mm Hg in inter-tube space is provided. Sealing ring is arranged at the joint between thermally insulated pipes at their clutch coupling. Before enamel coating is applied to internal surface of internal pipe, its ends are upset outwards. Then, it is subject to cleaning by burning and shot-blasting action. Both external and internal surfaces of external pipe are subject to shot-blasting action. Prior to vacuum treatment, the internal pipe is heated from inside up to 300°C with an electric heater of tubular air heater type (TAH) by its being arranged inside the pipe throughout its length, after preliminary plugging of inter-tube space by means of welding on the side of one of its ends. At that, the temperature of external pipe shall be constantly monitored. If its temperature exceeds 24°C, the thermally insulated pipe is rejected. After vacuum treatment of inter-tube space, heat-insulating bushings are installed with pre-load into the outward upset ends. As sealing ring there used is ring of self-sealing type from elastic material. At that, heating of internal pipe is performed by means of TAH by arranging the latter inside the pipe throughout its length. Polypropylene or heat-resistant rubber is used as material for thermally insulating bushing and sealing ring. Application of silicate enamel coating is performed at least in two layers and two stages; at that, application of the second layer is performed after the pipe is cooled down to the room temperature.

EFFECT: improvement of the method.

9 cl, 3 dwg

Description

The invention relates to the field of oil and gas industry, in particular to the operation of the well, in particular to the production of viscous oils and bitumen by the thermal method by supplying coolant to the bottom of the well through a string of thermally insulated pipes and in other industries for thermal insulation of pipelines for transporting coolants.

Known thermally insulated pipe (see patent RU No. 2129202, E21B 17/00; 36/00, publ. 04/20/1999), the description of which also contains a method of manufacturing a thermally insulated pipe, which consists in performing multilayer screen insulation with placement between their layers sorbent as a getter, cutting a taper-resistant thread at the ends of the outer pipe, placing the inner pipe inside the outer pipe on the centralizers, sealing the tube with vacuum-tight seams from the ends of the pipes, creating an annulus nstve vacuum in the range of 10 ^{-4 to} 10 ³ Torr and screwing onto the ends of the outer pipe of the couplings.

The disadvantage of this method is the relatively high heat loss due to insufficient quality of the annular insulation. This is explained by the fact that insufficiently deep vacuum is created in the annulus - only 10 ³ -10 ^-4 mm Hg, as a result of which the air remaining there, having thermal conductivity, leads to heat loss. This becomes especially sensitive when the coolant has to be transported over long distances. In addition, a heat-insulated column made up of heat-insulated pipes made by the above method is short-lived due to corrosion of its inner surface during transportation of a heat carrier with a high temperature, as well as due to wear of threaded joints during repeated assembly and disassembly of a pipe string. The method is not technologically advanced.

A thermally insulated pipe is also known (see RU patent for utility model No. 66401, IPC E21B 17/00, 36/00 of May 21, 2007), the description of which also describes a method of manufacturing a thermally insulated pipe, including applying a silicate-enamel coating the inner surface of the inner pipe, the implementation on its outer surface of a multilayer screen insulation with the placement of sorbent as a getter between their layers, cutting tapered thread at the ends of the outer pipe, the placement of the inner pipe inside the outer pipe on ntratorah, sealing the annulus welded vacuum-tight seams by the pipe end, creating a vacuum in annular space 10 ^-8 -10 ^-10 mmHg and placing the o-ring at the junction of thermally insulated pipes when they are coupled.

The known method in technical essence is closer to the proposed one and can be adopted as a prototype. In the known method, the disadvantages of the above analogue are partially eliminated, however, it is not without a drawback, for example, in a thermally insulated pipe made in a known manner, heat losses still remain high, especially in sleeve joints of pipes. In addition, the operation of applying a silicate-enamel coating needs to be improved due to its low quality.

The objective of the present invention is to remedy the above disadvantages of the prototype.

The stated technical problem is solved by the described method, including applying a silicate-enamel coating on the inner surface of the inner pipe, performing on its outer surface a multilayer screen thermal insulation with placement of sorbent as a getter between their layers, cutting a taper-resistant thread at the ends of the outer pipe, placing the inner pipe on centralizers inside the outer pipe, sealing by welding of the annulus with vacuum tight seams from the ends of the pipes, creating in the inside in the vacuum space 10 ^-8 -10 ^-10 mm Hg and placing the o-ring at the junction of thermally insulated pipes when they are coupled.

What is new is that before applying the enamel coating on the inner surface of the inner tube, its ends are planted out and its inner surface is cleaned by bead-blasting after preliminary firing, while its outer surface and the inner surface of the outer tube are also shot-blasted, and before the operation evacuation of the inner pipe is heated from the inside to 300 ° C by an electric heater after pre-damping by welding the annulus from one side about, by constantly monitoring the temperature of the outer pipe, and if its temperature exceeds 24 ° C, then this thermally insulated pipe is rejected, after evacuation of the annular space, thermally insulating sleeves with an inner diameter not exceeding the inner diameter of the inner pipe are installed with an interference fit and as a sealing ring, an elastic ring of a self-sealing type is used.

Another feature of the method is that the inner pipe is heated using a heating element, placing the latter inside the pipe along its entire length, and polypropylene or heat-resistant rubber is used as the material for the thermally insulating sleeve and the sealing ring, and the silicate-enamel coating is applied at least two layers and in two steps, while applying the second layer is carried out after cooling the pipe to room temperature.

The above drawings explain the essence of the invention, in which Fig. 1 shows a thermally insulated pipe made by the proposed method, where the inner pipe is visible concentrically mounted on centralizers inside the outer pipe, as well as a thermally insulating material, in partial section.

In Fig.2 - the same as in Fig.1, thermally insulated pipes interconnected by means of a coupling.

Figure 3 is a view I of figure 2, a fragment of a sleeve connection of thermally insulated pipes, in a section.

The manufacture of thermally insulated pipes is as follows.

After preparatory operations, consisting in the selection of the inner and outer pipes 1 and 2, respectively, with the required thickness, diameter and length and in checking the quality of their manufacture, the ends 3 and 4 of the inner pipe 1 are planted out (see figure 1), and at the ends 5 and 6 of the outer pipe, they cut taper-resistant threads 7 and 8 under the couplings 9 and 10 (see figure 2) or a sub, which are made of high-strength steel.

Next, the inner surface of the inner pipe 1 is subjected to bead-blasting after preliminary firing with an inductor, which allows to reduce the processing time by bead-blasting. With this treatment, the inner surface of the pipe is cleaned of scale and corrosion products, acquiring a metallic luster. Both its outer surface and the inner surface of the outer pipe 2 are subjected to shot-blasting. At the end of pipe cleaning operations, a silicate-enamel coating is applied to the inner surface of the inner pipe 1 by spraying in at least two layers and in two steps (silicate-enamel coating is not shown )

After checking the continuity of the enamel coating, a multilayer screen thermal insulation 11 is wound on the outer surface of the inner pipe, as shown in Fig. 1, placing a sorbent between the layers as a getter. Then, the inner pipe with centralizers 12 is installed inside the outer pipe 2 and one of the ends 3 or 4 is sealed by welding, after which an electric heater is installed inside the inner pipe along its entire length and heated to a temperature of 300-400 ° C. At the same time, the temperature of the outer pipe is constantly monitored. If its temperature exceeds 24 ° C, then this thermally insulated pipe is rejected.

Then, through the valve 13, which is built in the hole 14 of the outer pipe 2, a vacuum is created in the annulus 15 by means of a vacuum pump in the range of 10 ^-8 -10 ^-10 mm Hg. Then, the valve is welded and the insulated sleeves 16 and 17 (see Fig. 1) with an inner diameter not exceeding the inner diameter of the inner pipe 1 are installed in the upset ends. At the same time, when the thermally insulated pipes are coupled in the joint, the sealing ring 18 of the self-sealing type of their elastic sealing material, for example heat-resistant rubber.

An example of a specific implementation of the method

For the manufacture of thermally insulated pipes according to the proposed method, steel pipes of the same length of 10 m, with a diameter of ⌀ 60 mm, and as an outer pipe with a diameter of ⌀ 89 mm were used as the inner pipe. After a visual inspection of the quality of their manufacture, the ends 3 and 4 of the inner pipe 1 were planted out in the factory, and at the ends 7 and 8 of the outer pipe, taper-resistant threads 7 and 8 were cut (see Fig. 1). Then the inner tube 1 was fired at a temperature of 300 ° C and subjected to cleaning of its inner and outer surfaces using a continuous shot cascade type apparatus "Cascade" with automatic refilling of the shot, ensuring continuous operation in automatic mode. The inner surfaces of the outer pipe 2 were also shot blasted. In accordance with TU 14-2R-370-2008, a silicate-enamel coating was applied to the inner walls of the inner pipe by spraying in two layers and in two steps, while the second layer was applied after cooling of the pipe to room temperature. A silicate-enamel coating protects the walls of the inner pipe from corrosion, and also prevents paraffin from depositing when used as lift pipes in production wells.

After cooling, the enameled inner tube was subjected to coating continuity monitoring and microcrack detection using an ultrasonic continuity monitoring apparatus (UKS), after which a thermally insulating screen insulation made of several layers was wound on it. Fiberglass and aluminum foil were used as such material and a getter was placed between the layers — a sorbent in the form of a tablet made of titanium, which sorbed air, nitrogen, water vapor, and other gaseous inclusions. As a thermally insulating material, a stinophone can also be used to accelerate the process of thermal insulation. It is produced by domestic industry and is widely used as a screen heat-insulating material. Thermally insulating screen insulation was fixed with clamps 12 (see figure 1), which simultaneously play the role of centralizers. Next, the thermally insulated pipe 1 was placed inside the outer pipe and one of the ends was sealed by welding, and the heater was passed through the other end along the entire length of the inner pipe and, at a current value of J = 200 A and at a voltage of U = 50 V, was heated to a temperature of 300 ° C , controlling the temperature with the help of the TRM-138 device (eight-channel universal meter). To control the temperature of the outer pipe, sensors were installed every 2 m. The temperature of the outer pipe was 24 ° C. This means that the insulation is satisfactory. After removing the heater from the thermally insulated pipe, the annular space was sealed by welding the ends, and then through the check valve 13 a vacuum of about 10 ^-8 mm Hg was created. using a vacuum pump ND-250. After that, the valve was brewed and bushings 16 and 17 made of heat-resistant rubber were installed with an interference fit in the upset ends of the inner pipe 1 (see Fig. 1). At the same time, a self-sealing type ring 18 of an elastically elastic material - rubber (see Fig. 3) was used as a sealing ring with a sleeve connection of thermally insulated pipes 2 and 19.

On this, the manufacture of a thermally insulated pipe is considered complete.

The technical and economic advantage of the invention is as follows.

The thermally insulated pipe manufactured by the proposed method can significantly reduce heat loss during transportation of the coolant, has high reliability and durability, which allows it to be used with high efficiency in both injection and production wells in the production of high-viscosity oils and bitumen, as well as oils containing paraffin .

Claims (5)

1. A method of manufacturing a thermally insulated pipe, including applying a silicate-enamel coating on the inner surface of the inner pipe, performing on its outer surface a multilayer screen thermal insulation with placement of a sorbent as a getter between their layers, cutting a taper-resistant thread at the ends of the outer pipe, placing the inner pipe on centralizers inside the outer pipe, sealing by welding the annulus with vacuum-tight seams from the ends of the pipes, creating an annulus ve vacuum 10 ^-8 -10 ^-10 mm Hg and placing the sealing ring at the junction of thermally insulated pipes when they are coupled, characterized in that before applying the enamel coating on the inner surface of the inner pipe, its ends are planted out and its inner surface is cleaned by bead-blasting after preliminary firing, while it is also subjected to bead-blasting the outer surface and the inner surface of the outer pipe, and before the evacuation operation, the inner pipe is heated from the inside to 300 ° C electron after the preliminary plugging by welding of the annular space from the side of one of the ends, constantly monitoring the temperature of the outer pipe, moreover, if its temperature exceeds 24 ° C, then this thermally insulated pipe is rejected, after evacuation of the annular space, the heat-insulating sleeves are installed with an interference fit an inner diameter not exceeding the inner diameter of the inner pipe, and a self-sealing ring of elastically elastic type is used as a sealing ring of material. 2. The method according to claim 1, characterized in that the heating of the inner pipe is carried out using a heating element, placing the latter inside the pipe along its entire length. 3. The method according to claim 1, characterized in that the material for the thermally insulating sleeve using polypropylene or heat-resistant rubber. 4. The method according to claim 1, characterized in that the application of the silicate-enamel coating is carried out in at least two layers and in two steps, the second layer being applied after the pipe has cooled to room temperature. 5. The method according to claim 1, characterized in that a heat-resistant rubber is used as a material for an elastic ring of a self-sealing type.

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