RU2787662C2 - Sealed heat-resistant radio-transparent non-magnetic housing for geophysical instruments immersed in a well - Google Patents

Abstract

FIELD: geophysical instruments.

SUBSTANCE: invention relates to a sealed heat-resistant radio-transparent non-magnetic casing for geophysical instruments immersed in a borehole. The casing contains an inner casing made of a reinforced polymer composite material. The casing also contains a row of hollow ceramic cylinders located end-to-end and fastened to each other and to the inner body with glue, and two adapters located end-to-end at both ends of the row of ceramic cylinders. The casing has an outer casing made of at least one layer of fiber-reinforced polymer composite material independently in the annular and axial directions. Places for embedding each of the adapters in the outer casing or at least one of its layers in case of a multilayer structure are sealed with at least one radial elastic seal in the form of a rectangular ring. Flats are made on the side surface of the adapters in the places of embedding into the outer casing, which do not coincide with the places of installation of elastic seals.

EFFECT: sealed heat-resistant radio-transparent non-magnetic casing creation.

1 cl, 1 dwg

Description

FIELD OF TECHNOLOGY

The invention relates to the field of geophysical research in wells, including during drilling, and can be used to place geophysical instruments for measuring the characteristics of rocks by non-contact electromagnetic and radio engineering methods inside an exploration string for deep vertical, inclined and horizontal drilling.

An additional field of technology for the present invention are vessels and casings for various fields of technology, operating at high external pressures.

BACKGROUND OF THE INVENTION

Known multiple solutions that allow you to place various geophysical instruments in the drill string. Among them, various shells (hulls, casings, containers) with radio-transparent and non-magnetic walls for geophysical research methods based on electromagnetic oscillations (eddy current, radio engineering, magnetometric) should be distinguished as a separate class.

Simultaneous requirements of non-magneticness and radio transparency fundamentally exclude the possibility of using any metals for the manufacture of shell walls.

At the same time, the depletion of traditional oil and gas fields and the widespread industrial development of hard-to-recover hydrocarbon reserves located at great depths where reservoir pressures exceed 1000 kgf / cm ² and reservoir temperatures - 100 ° C tighten the requirements for mechanical strength and thermal stability of geophysical instrument shells, made from non-metallic materials.

The most unfavorable combinations of influences are exposed to hermetic casings, which isolate the device both from mechanical contact with the downhole medium and from its pressure. Such products are made of high-strength non-metals, primarily fiberglass and ceramics.

There are many designs of fiberglass shells for geophysical instruments, as well as instruments combined with the shell, for example, "Device for electromagnetic logging while drilling" according to the patent of the Russian Federation 2231091, "Probe for electric logging" according to the patent of the Russian Federation 2352962, "High pressure housing" according to the patent Russian Federation 2386077, "Power shell of a radio-transparent high-pressure housing made of glass basalt plastic for electromagnetic well logging devices" according to the patent of the Russian Federation 2586227.

In the above constructions, the shell is a composite (fiberglass, basalt-plastic or combined glass-basalt-plastic) pipe, in the end parts of which embedded end elements are embedded at the production stage (which may be called "adapters" or "subs" by different authors). This design is relatively simple technologically, has the required characteristics of strength (pressure up to 600 kgf/cm ² ) and heat resistance (temperature up to 120°C) for use at depths of up to about 2.5 km.

A further increase in these indicators is hampered by the properties of polymeric binders used for the manufacture of composite materials. The fact is that the resistance of a composite material shell to external pressure is determined not only by the properties of the reinforcing fiber and the way it is laid, but also, to a greater extent, by the rigidity of the cured polymer binder, which significantly decreases near the glass transition temperature of the polymer. Even for the most heat-resistant epoxy polymers, it lies in the range of 125-155°C.

For this reason, for devices operating at great depths, other solutions are used, in particular, multilayer structures, the inner layer of which is made of high-strength non-magnetic metals, such as stainless steels or titanium, and the outer layer is made of fiberglass. The sensitive elements of such a device are placed between a layer of fiberglass and metal or in a layer of fiberglass. Such solutions are described, for example, in RF patent 2683465 "High pressure housing".

This design works at depths of more than 3.5 km, but the functionality of such devices is severely limited by the layout features. In addition, the tool in this design is not separable from the body, which increases the cost of the construction of the exploration string, since it requires the placement of tools at each horizon, and not moving one tool along the entire length of the string with a logging hoist, as in classical logging. The issue of powering such devices and transmitting data from them to the surface is difficult.

Therefore, there are applications for the design of casings, where the polymer composite shell is reinforced with heat-resistant rigid ceramics. These are "Radio-transparent housing for geophysical equipment" according to the RF patent for utility model No. 16316 and "The casing of the probe part of the downhole induction tool" according to the USSR author's certificate No. 1242603, taken as a prototype.

In the prototype, the casing consists of a number of hollow ceramic cylinders (rings) located end-to-end and tightly fitted to each other, two metal adapters located on both sides of the row of cylinders and tightly fitted to their end surfaces and an outer plastic (composite) cylinder, tightly fitting ceramic cylinders and adapters.

Such a design can operate at temperatures well above the glass transition temperature of the shell polymer, since compressive forces from external pressure are transmitted by rigid ceramic cylinders. At the same time, the casing retains radio transparency, non-magnetic properties and an internal cavity, which allows the use of classic descending logging probes with instruments.

At the same time, the prototype also has disadvantages that make it difficult to operate:

1. Ceramic cylinders, due to the peculiarities of their production technology, are manufactured with a significant variation in internal diameters, which leads to a stepped inner surface, which makes it difficult for geophysical instruments to pass through the casing as part of a logging probe.

2. Ceramics, despite its high strength, is a brittle material. When external pressure is applied to the casing, cracks form in the ceramic cylinders, leading to chipping and chipping into the internal cavity of the casing, which can also lead to difficulties in moving the logging probe up to its jamming and/or damage to its geophysical instruments by broken pieces of ceramics.

3. Cracks occurring in the ceramic cylinder can lead to its destruction and damage to the entire casing, with further destruction of the entire drill string.

4. The applied reinforcement scheme, when the reinforcing fiber strands are laid in a spiral pattern at a small angle to the longitudinal axis, is well suited for vessels operating at internal pressure, but is of little use for shells operating at external pressures.

5. The applied reinforcement scheme requires the presence of hooks (latches) on the adapters for strands of reinforcing fibers or a significant change in the angle of laying the fibers to embed them in the grooves of the adapters. The first solution is structurally and technologically complex, the second degrades the quality of the composite shell, making it inhomogeneous.

6. Through the non-sealed interface between the adapters and the body, well fluid penetrates, disrupting the normal operation of the geophysical instruments of the logging probe and the entire drill string.

THE PROPOSED TECHNICAL SOLUTION is aimed at eliminating the shortcomings of the prototype by introducing into the design of the inner case, adhesive joints of ceramic cylinders with the inner case and between themselves, manufacturing the outer case from a polymer composite material independently reinforced in the annular and axial directions, introducing elastic sealing elements between the adapters into the design and outer casing.

TECHNICAL RESULT consists in creating a high-strength heat-resistant radio-transparent non-magnetic sealed casing for geophysical instruments immersed in a well, having increased strength, smoothness of the inner surface, preventing jamming of the logging probe and damage to its geophysical instruments, preventing penetration of the well environment into the casing and the entire drill string.

THE ESSENCE OF THE PROPOSED TECHNICAL SOLUTION lies in the fact that in a well-known design, taken as a prototype, containing a number of hollow ceramic cylinders located end-to-end, two adapters located end-to-end at both ends of a row of ceramic cylinders, an outer casing made of reinforced polymer composite material, the following solutions are applied :

1. Hollow ceramic cylinders are installed on the inner body made of reinforced polymer composite material and fastened together and to the outer surface of the inner body with glue;

2. The outer casing is made of at least one layer of fiber-reinforced polymer composite material independently in the annular and axial directions;

3. Places for embedding each of the adapters into the outer casing or at least one of its layers in case of a multilayer structure are sealed with at least one radial elastic seal in the form of a rectangular ring.

EXPLANATION OF THE ESSENCE OF THE PROPOSED TECHNICAL SOLUTION is presented in Fig. 1.

The inner housing pos.1 is a pre-fabricated fiber-reinforced composite pipe. On the outer surface of the inner body with glue fixed ceramic cylinders pos.2, the end surfaces of which are also bonded together with glue. Adapters pos.3 end surfaces are bonded to the extreme ceramic cylinders and the inner case. On the outer surface of the adapters there are annular protrusions 4 and flats 5. The outer casing 6 consists of at least one layer of fiber-reinforced composite material. At the same time, the fibers 7 of the annular reinforcement impregnated with a polymeric binder are laid in a spiral at an angle of 82-87° to the longitudinal axis of the body, and the fibers 8 of the axial reinforcement independent of them are laid at an angle of 5-10° to the longitudinal axis of the body. The fiber laying is carried out in such a way as to cover the annular protrusions on the adapters and the radial elastic seals 9. The casing acquires its properties after the adhesive and the polymer binder of the composite material of the outer casing have cured.

The inner casing provides a smooth, stepless inner surface, prevents debris from separating from the ceramic cylinders and getting them inside the casing and the entire column. Ceramic cylinders provide rigidity and stability of the structure under external pressure. Adapters provide connection of the casing with other elements of the drill string. The outer casing holds the adapters and ceramic cylinders together, and also provides the transfer of axial forces and torques acting in the drill string between the adapters through the annular ledges and flats, respectively. Radial elastic seals provide a tight interface between the adapters and the outer housing.

The achievement of the claimed technical result is ensured by:

- increasing the strength of the casing - due to the independent reinforcement of the outer casing in the annular direction with fibers laid at a steep angle to the axis of the casing and fixing the ceramic cylinders on the inner casing and between themselves with glue;

- exclusion of jamming of the logging probe and damage to its geophysical instruments - due to the use of the inner case;

- exclusion of the penetration of the well environment into the casing and the entire drill string - due to the radial elastic seals between the adapters and the outer casing.

IMPLEMENTATION OF THE PROPOSED TECHNICAL SOLUTION

The proposed technical solution has been put into practice in a commercially available casing ALT 1282 having the following characteristics:

- outer diameter (along the outer shell of the outer case) - 80 mm;

- inner diameter (according to the inner diameter of the pipe of the inner body) - 42 mm;

- working pressure (external) - up to 1000 kgf/cm ² ;

- working temperature - up to 150°С;

- two-layer outer case;

- material of the internal and external case - heat-resistant epoxy fibreglass;

- material of ceramic cylinders - ceramics based on oxides and carbides of heavy metals;

- adapter material - chromium-containing non-magnetic steel.

Claims (1)

Sealed heat-resistant radio-transparent non-magnetic casing for geophysical instruments submerged into a well, containing a row of hollow ceramic cylinders located end-to-end, two adapters located end-to-end at both ends of a row of ceramic cylinders, an outer casing made of a reinforced polymer composite material, characterized in that the hollow ceramic cylinders are mounted on an inner body made of reinforced polymer composite material and bonded to its outer surface and to each other with adhesive, the outer body is made of at least one layer of polymer composite material independently reinforced with annular fibers laid in a spiral at an angle of 82-87 ° to the longitudinal axis of the body, and with fibers of the axial direction, laid in a spiral at an angle of 5-10° to it, the places for embedding each of the adapters into the outer body or at least one of its layers in a multilayer structure are sealed with at least one a radial elastic seal in the form of a ring of rectangular cross-section, flats are made on the side surface of the adapters in the places of embedding in the outer body, which do not coincide with the places of installation of elastic seals.

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