US20240183241A1

US20240183241A1 - Wellhead connection device and method for reducing axial stresses in a pipe run

Info

Publication number: US20240183241A1
Application number: US18/286,058
Authority: US
Inventors: Christian Hartmann; Tim Betschinski
Original assignee: Werner Hartmann GmbH and Co KG
Current assignee: Werner Hartmann GmbH and Co KG
Priority date: 2021-04-07
Filing date: 2022-03-31
Publication date: 2024-06-06
Also published as: EP4320333A1; WO2022214393A1; CN117355661A; DE102021108677A8; DE102021108677A1

Abstract

The invention relates to a wellhead connection device (10) for the top-side connection of a pipe run of a deep well. A wellhead connection device (10) according to the invention has a housing (12), which comprises a through opening (14), and a pipe connection element (36) arranged inside the through opening (14) in the housing (12). The pipe connection element (36) is arranged to be axially displaceable in the housing (12) in order to compensate for axial stresses during normal operation. The invention moreover relates to a method for reducing axial stresses in a pipe run which is firmly connected to a pipe connection element (36) of a wellhead connection device (10).

Description

The present invention relates to a wellhead connection device for the top-side connection of a pipe run of a deep well, having a housing, which comprises a through opening, and a pipe connection element arranged inside the through opening in the housing. The invention moreover relates to a method for reducing axial stresses in a pipe run, especially a pipe run of a deep well.
Wellhead connection devices for the top-side connection of a pipe run of a deep well are known in practice and thus from the prior art. A wellhead connection device is an element of a device technically known as a “wellhead”, which makes a fluidic connection between a pipe run and a pipeline system of an above-ground processing plant for the processing of media being transported through the pipe run. A wellhead having a wellhead connection device is generally installed on the ground surface or on the bottom of a body of water above a borehole or “well” of a deep well. The pipe run is arranged in the borehole of the deep well and usually cemented underground. Such a pipe run is accordingly formed by a long pipe or a plurality of pipes axially joined to each other. The pipe run can reach several hundred meters or even more than 1000 meters into the interior of the earth through the borehole. In general, various media such as gases or liquids are transported through the pipe run of a deep well. In particular, natural gases, water, and/or oil are transported. Natural gases for example are transported for the extraction of the gases from natural gas deposits or for the filling and emptying of artificial caverns. Such caverns can be created in particular by flushing out underground salt layers.
For making a fluidic connection between a pipe run located in a borehole and a wellhead connection device, the wellhead connection device comprises a pipe connection element, which basically has the geometry of a pipe piece and is connected to the top-side end of the pipe run such that it can receive a flow of fluid in the axial direction. The pipe connection element and the pipe run usually have an identical or substantially identical diameter.
A connection between the pipe connection element and the pipe run is generally established, in a first step, by positioning the housing of the wellhead connection device (also called the “tension spool” or “tubing/casing head” in technical parlance) with the through opening around the pipe run emerging from the borehole such that the top-side end of the pipe run is completely received by the through opening when the housing is in its normal working position. The through opening in the housing runs accordingly coaxially with the direction of principal extension of the pipe run. This direction shall be called here and afterwards the “axial direction”. The through opening can be configured cylindrical with constant diameter in the axial direction or with variable diameter in the axial direction. The diameter is always somewhat greater than the diameter of the pipe run. Since the pipe run and the through opening are usually vertically oriented, the positioning of the housing around the pipe run can be done by setting it down from above. In a second step, the pipe connection element is introduced from above into the through opening and set down on the pipe run from above. In a further step, the pipe connection element and the pipe run are joined. The joining of the pipe connection element and the pipe run is usually done by material bonding. But alternatively or in addition, it can also be carried out by form fitting and/or force locking, especially by wedging or clamping. It is additionally possible to stretch the pipe run elastically in the axial direction before or after the connection to the pipe connection element, which may provide benefits specific to an application.
In the wellhead connection devices known from the prior art, the pipe connection element arranged in the through opening of the housing is fixed in the radial direction by the housing inner wall. The radial direction here and in the following is every direction oriented orthogonally to the axial direction. In the axial direction, the pipe connection element is supported at least at the bottom, i.e., in the axial direction of extension of the pipe run. For example, the pipe connection element—due to its own weight and the additional weight of the pipe run attached to it—can sit on a shoulder of the housing formed radially inward in the through opening or on so-called landing bolts (bolts which can be screwed in via a thread). In this case, the outer diameter of the pipe connection element is somewhat larger than the outer diameter of the pipe run. Such a fastening of the pipe connection element is based on a pipe connection element known as a “mandrel hanger” in technical parlance.
Alternatively, it is also possible to realize the fastening of the pipe connection element on the basis of a pipe connection element known as a “slip-type hanger” (wedge hanger) in technical parlance.
When the pipe connection element is supported as described above and the pipe run is elastically pre-stretched axially, the pipe run strives for an elastic compression in the axial direction. However, such a compression is prevented by the underground cementing of the pipe run and the mounting of the pipe connection element connected to the pipe run in the housing of the wellhead connection device. Accordingly, the pipe run is subjected to a tensile strain and thus pretensioned. In the wellhead connection devices known in the prior art, the pipe run is additionally protected against shifting in the axial direction upward, so that the pipe connection element is rigidly mounted in the housing.
The wellhead connection device and the pipe run need to fulfill special, application-specific requirements. In particular, a good functional security of the wellhead connection device and good mechanical loading ability of the wellhead connection device are required. These requirements emerge from the above-described rigid mounting of the pipe connection element and the mechanical stresses occurring in the pipe connection element. Mechanical stresses can arise, for example, from the above-described elastic pre-stretching of the pipe run. In addition or alternatively, such stress may arise due to temperature fluctuations in the pipe run, for example, when the medium being transported is taken from great depth to the ground surface and heat is absorbed by the pipe run or heat is given off to the pipe run. Upon a rise in the temperature of the pipe run, the pipe run will expand, and upon temperature decrease it will contract. On account of the great length of the pipe run, a slight temperature change can already lead to a relatively large length change of the overall pipe run. However, the above-ground and underground fixation of the pipe run that is usually carried out prevents a length change, so that large thermally induced stresses arise in the axial direction in the pipe run and in the pipe connection element. Special requirements for the wellhead connection device and the pipe run are also dictated by geological circumstances. For example, earth movements can cause a shifting of the pipe run and/or an additional force acting on the pipe run, especially when an underground subsidence of earth layers occurs. Such underground earth movements can also cause stresses in the axial direction in the pipe run and in the pipe connection element if the pipe connection element is rigidly fixed in the axial direction on the ground surface. Such stresses can lead to undesirable damaging of the pipe run and/or the wellhead connection device.
A wellhead connection device is known, for example, from GB 2554102 A. The wellhead connection device comprises a housing, a pipe connection element arranged in the housing, and a pipe run carried by the pipe connection element. The wellhead connection device is configured such that the pipe run is movable relative to the housing. For this purpose, the pipe connection element is designed as a plurality of pipe connection elements resting against each other. The plurality of pipe connection elements can be moved upward in event of a vertical movement of the pipe run, but not downward. Accordingly, the movement occurs passively.
The invention is based on the problem of providing a wellhead connection device which is suited to reducing axially acting stresses in a pipe connection element and in a pipe run connected to the pipe connection element and which has an improved functional security. Moreover, the intention is to provide a method for reducing axial stresses in a pipe run.
The problem is solved according to the invention with the features of the independent claims. Further practical embodiments and benefits of the invention are described in connection with the dependent claims.
A wellhead connection device according to the invention for the top-side connection of a pipe run of a deep well has a housing, which comprises a through opening, and a pipe connection element arranged inside the through opening in the housing.
The pipe connection element is arranged to be axially displaceable in the housing in order to compensate for axial stresses during normal operation.
In addition, a fluid space is provided in the housing, functionally interacting with the pipe connection element, and is arranged such that the axial position of the pipe connection element during normal operation stands in functional connection with the fluid quantity and/or the fluid pressure in the fluid space. Accordingly, the axial position of the pipe connection element can be actively changed when the quantity and/or the pressure of the fluid in the fluid space changes. For example, the fluid space can be actively filled with and emptied of a liquid or a gas by a pump. Since the axial position of the pipe connection element is actively adjustable, the axial stresses in the pipe connection element and the pipe run can also be actively controlled. This is especially advantageous when a constant axial stress needs to be maintained. As described above, the pipe run can be elastically pre-stretched before or after the connecting to the pipe connection element. This elastic pre-stretching corresponds to an axial tensile stress in the pipe run, which for example is reduced in event of a temperature rise of the pipe run due to its expansion or which is increased in event of a temperature decrease of the pipe run due to its contraction. The change in the axial stress can be compensated by increasing the quantity and/or the pressure of the fluid in the fluid space standing in functional connection with the pipe connection element in its normal operation. Of course, the displacement of the pipe connection element can occur passively, even when the aforesaid fluid space is provided. For this purpose, the fluid can flow freely into and out from the fluid space, instead of being actively delivered to it or removed from it.
In one suitable modification of the wellhead connection device, a housing cover is arranged at one axial end of the housing. The housing cover can in particular be connected to the housing of the wellhead connection device at the top side of the through opening in gas-tight and position-fixed manner. In this position, in particular, the housing cover can be designed such that it limits the axial displacement ability of the pipe connection element. Alternatively or in addition to this, the housing cover can be designed to receive a fluid flow in the axial direction, so that the medium transported through the pipe run can pass through the cover and flow into the wellhead.
In practice, the pipe connection element can comprise at least one guide section formed radially on the outside and the at least one guide section is surrounded by a bearing element on the outside. Thanks to the guide section, the pipe connection element is supported in the bearing element such that the pipe connection element is immovable in the radial direction, but axially displaceable. The guide section and/or the bearing element can each have specially treated surfaces, such as a smooth and/or wear-resistant surface, which facilitate a displacement of the pipe connection element and/or prolong the service life of the wellhead connection device.
If the pipe connection element has at least one guide section according to the preceding description, the at least one guide section in one practical embodiment can be formed as a radially protruding collar along a portion of the axial length of the pipe connection element. In other words, the pipe connection element can have a section with an enlarged diameter in the axial direction, which serves as a guide section. The configuration of the guide section as a collar enables a precise positioning of the pipe connection element in the housing in the axial and radial direction and reduces the friction surface with the bearing element as compared to a pipe connection element with a guide section formed along the entire length of the pipe connection element. The segment of the pipe connection element having the collar can be distinguished from the rest of the pipe connection element by a greater wall thickness. The internal diameter of the pipe connection element in the axial direction is then constant, even when the outwardly protruding collar is present. In this way, the flow of the medium flowing through the pipe connection element is disturbed the least possible. If required, boreholes can be made in the axial direction through the collar. These can be used, for example, as a conduit or for leading through conduits or cables (so-called “control lines”).
In one practical embodiment of a wellhead connection device according to the invention with at least one guide section formed as a collar, the fluid space can directly border on the collar. In this case, a shoulder surface bordering on the collar and having a radially oriented direction of extension can serve as an active surface for the pressure in the fluid space acting on the pipe connection element. In other words, the shoulder surface of the collar can constitute a wall of the fluid space oriented transversely to the axial direction of the pipe connection element. Due to a change in the quantity of the fluid in the fluid space or the pressure of the fluid in the fluid space, a hydrostatic pressure is created in the fluid space. This pressure acts directly on the shoulder surface of the collar. Thus, by an active changing of the fluid quantity or the fluid pressure, a change in the axial position of the pipe connection element and/or a change in the axial stresses in the pipe connection element and the pipe run connected to it can be actively brought about.
In another practical embodiment of the wellhead connection device with at least one guide section, the housing and/or the housing cover is formed as a bearing element on the inside. The bearing element is then in particular a radially inward pointing surface or a surface segment of the through opening and/or the housing cover. Such a configuration can be realized in economical manner, since no additional elements are required.
If the housing cover comprises a bearing element, the housing cover can be configured for example as a pipe connection piece and it can be flanged onto the housing such that the pipe connection element is flush with the bearing element. If a bearing element is provided in the housing and in the housing cover, the pipe connection element can be precisely mounted and axially guided.
In addition or alternatively, at least one bearing sleeve serving as a bearing element can be arranged in the housing and/or in the housing cover and fixed to the housing. The bearing sleeve can consist of a different material from the housing and thus have especially suitable bearing properties, which cannot be realized by a guide section formed in the housing or in the housing cover. Desirable bearing properties are in particular a good wear resistance and low static friction and/or sliding friction at the radially inward oriented bearing side. For example, the positioning of the bearing sleeve in the housing and fixed to the housing can be realized by a press-fitting and/or by a radially inward pointing shoulder in the through opening.
In one suitable modification of a wellhead connection device having a bearing sleeve arranged in the housing, the bearing sleeve can be one-piece or multi-piece. The position of the bearing sleeve in the housing can be dictated in the axial direction by landing bolts and/or by retaining screws. The landing bolts and the retaining screws are elements with a substantially cylindrical shape. The described configuration as bolts and/or screws should be understood as only an example. Other elements or geometries can also be used, which fulfill the function of the landing bolts and/or retaining screws in the sense of the invention. The landing bolts and/or retaining screws can be arranged, for example, in radial boreholes in the housing, such that they protrude at least partially into the through opening. For this, the landing bolts and/or retaining screws can be led in particular from the outside through these boreholes and be anchored in them in suitable manner.
If landing bolts are provided, the one-piece or multi-piece bearing sleeve can bear by a surface pointing in the axial direction against a portion of the landing bolts protruding into the through opening and thereby be braced in the axial direction. If retaining screws are provided, these can press against a surface of the bearing sleeve pointing in the radial direction.
Thanks to the use of landing bolts and/or retaining screws, the mounting of the wellhead connection device can be realized especially easily and flexibly. This also makes possible an easy disassembly for purposes of repair.
In addition or alternatively, in practice at least one of the following means can be provided for the wellhead connection device:

- a) means of measuring the hydrostatic pressure in the fluid space and/or
- b) means of detecting the axial position of the pipe connection element within the housing and/or
- c) means of passive dampening of the pipe connection element displacement.

If there is provided at least one means of measuring the hydrostatic pressure in the fluid space, in addition to the changing of the axial position of the pipe connection element by the fluid present in the fluid space, the pressure acting conversely on the fluid from the pipe connection element can be measured. Then, the axial stresses in the pipe run and the pipe connection element can be calculated via the hydrostatic pressure of the fluid. If these axial stresses leave a target region by going beyond an upper or lower permissible stress limit, upward or downward, the position of the pipe connection element can be actively changed by bringing fluid into the fluid space or draining fluid from the fluid space. In this way, the pipe run can expand or contract and the axial stresses can be actively and specifically adjusted, in particular, compensated. Since the pressure in the fluid is hydrostatic, the fluid can be taken out from the housing of the wellhead connection device and the at least one means of measuring the hydrostatic pressure can be arranged there. For example, this at least one pressure measuring means can be arranged on a bypass of a fluid line through which the fluid space is supplied with the fluid. Hence, sufficient room is available for such a pressure measurement. Moreover, a defective pressure measuring means can be easily repaired or replaced.
If there is provided in addition or alternatively at least one means of detecting the axial position of the pipe connection element within the housing, it is possible to check whether the pipe run has been axially stretched, compressed, or shifted. Such a means can be for example an optical measuring means. If at least one means of measuring the hydrostatic pressure in the fluid space is not provided in addition, besides the means of detecting the axial position of the pipe connection element, then it can at least be decided on the basis of the measurement result of the position meter whether the fluid space should be actively supplied with additional fluid or whether fluid should be actively drained from the fluid space. If, in addition to the position meter, there is provided at least one means of measuring the hydrostatic pressure in the fluid space, a decision can be made additionally to supply the fluid space with fluid or to drain fluid from the fluid space on the basis of two different measurement results. In this way, measurement errors and/or defects of one of the measuring means can be recognized and the functional security of the wellhead connection device can be further enhanced.
If furthermore there is provided in addition or alternatively a means of passive dampening of the pipe connection element displacement, sudden mechanical strain acting on the pipe connection element and/or the housing can be passively regulated. A means of passive dampening can be, for example, a throttle check valve, arranged in the fluid line by which the fluid space is supplied with the fluid. The throttle check valve limits the flow velocity of the fluid flowing into or out from the fluid space. Thus, a sudden—i.e., abruptly occurring—axial position change of the pipe connection element is not possible, and the pipe connection element cannot be thrust against the housing by a disruptive event, for example by an underground earth movement. In simple manner, a compressible fluid can also be a means of passive dampening of the pipe connection element displacement, since a compressible fluid exerts an increasing back pressure, acting against the compression, as compression increases.
The invention further relates to a method for reducing axial stresses in a pipe run which is firmly connected to a pipe connection element, wherein a fluid space functionally interacting with the pipe connection element is provided according to the preceding specification. The method involves the steps of

- a) positioning of the pipe connection element in the housing such that the pipe connection element is situated in a middle position and the fluid pressure is within a target region;
- b) continuous or at least regular measuring of the hydrostatic pressure of the fluid;
- c) as soon as the pressure leaves the target region or threatens to do so by reaching a margin region, increasing or reducing the quantity of fluid present in the fluid space in order to maintain the hydrostatic pressure as much as possible within the target region or to bring the hydrostatic pressure back to the target region by axial displacement of the pipe connection element.

Thanks to such a method, it is possible to monitor axial stresses acting on the pipe run and on the pipe connection element and to regulate the stresses in specific manner, in particular, to reduce or even entirely compensate for them. For further benefits in connection with this method, reference is made the above-mentioned benefits of the wellhead connection device according to the invention. Further practical embodiments and benefits of the invention are described in the following in connection with the drawings. There are shown:

FIG. 1A a wellhead connection device according to the invention in a vertical cross section view with a pipe connection element in a first position;

FIG. 1B the wellhead connection device of FIG. 1A in a vertical cross section view with the pipe connection element in a second position;

FIG. 2 the wellhead connection device of FIG. 1A in a horizontal cross section view along the sectioning plane A-A.

FIGS. 1A and 1B show one embodiment of the present wellhead connection device 10 in various positions in the same vertical cross section view. The wellhead connection device 10 comprises a substantially cylindrical housing 12 with a substantially concentric cylindrical through opening 14 oriented in the axial direction.
The through opening 14 can also alternatively be formed in a different geometry (not shown).
The wall thickness of the housing 12 is large in comparison to the diameter of the through opening 14, in order to be able to absorb the increased mechanical loads in normal operation. At the axially lower end, the housing 12 is fashioned to form a flange socket 15 radially on the outside, by which the housing 12 can be firmly secured to a base. Alternatively, but not shown in the figures, the housing 12 can also be connected in another suitable manner to the base, for example by welding. Radially on the inside, the housing 12 comprises at its lower end a first group of grooves 16 for sealing rings (not shown). The sealing rings work together with the housing 12 and a pipe run (not shown) protruding into the through opening 14 of the housing 12 from below, so that the through opening 14 is sealed gas-tight against the surroundings at the bottom.
In the through opening 14 there is provided a bearing element in the form of a two-piece hollow cylindrical bearing sleeve 18, lying by an envelope surface against the inner wall of the housing 12.
The bearing sleeve 18 consists of a lower sleeve element 20 and an upper sleeve element 22. The sleeve elements 20, 22 border on each other in the axial direction and form, on the inside of the bearing sleeve 18, a common, substantially through-going surface 24, which serves as a bearing surface or a sliding surface. At an end of the lower sleeve element 20 pointing downward in the axial direction there is provided a radially inward directed shoulder 26. Also at the end of the upper sleeve element 22 pointing upward in the axial direction there is formed a radially inward directed shoulder 28. The shoulder 26 extends around the entire circumference along the inside of the lower sleeve element 20. The shoulder 28 is formed for a portion along the inside of the upper sleeve element 22. Sealing rings (not shown) are provided between the lower sleeve element 20 and the housing 12, being inserted in a second group of grooves 30 in the housing 12.
The sleeve elements 20, 22 are fastened in the housing 12 and fixed to the housing, i.e., arranged in fixed position. This fixation occurs in the radial direction by the bracing of the bearing sleeve 18 against the inner wall of the housing 12. In the axial direction, the lower sleeve element 20 is mounted by a downward pointing surface of the shoulder 26 against a plurality of landing bolts 32. At the top, the lower sleeve element 20 is mounted against the upper sleeve element 22. The upper sleeve element 22 is fixed by a plurality of retaining screws 34 pressing radially from the outside against the upper sleeve element 22 and anchored in the housing 12. For this fixation, the upper sleeve element 22 comprises on its envelope surface indentations at least some of which are engaged by the retaining screws 34 in the normal working position of the upper sleeve element 22.
The landing bolts 32 and the retaining screws 34 in the present case are arranged in boreholes provided radially in the housing 12. The boreholes, the landing bolts 32 and the retaining screws 34 are evenly distributed in the circumferential direction. Moreover, they are formed substantially rotationally symmetrical in regard to their longitudinal axis. The landing bolts 32 in the present case additionally have a section 33 which is polyhedral in cross section—in particular being square—and which protrudes from the boreholes into the through opening 14, while the lower sleeve element 20 rests by the bottom side of the shoulder 26 against their flat, horizontally oriented side surfaces.
A pipe connection element 36 is arranged in the bearing sleeve 18 in an axially displaceable manner. In FIGS. 1A, 1B the pipe connection element 36 is shown horizontally divided. The pipe connection element 36 is configured as a substantially rotationally symmetrical pipe piece and it is intended to be connected at an axially lower side to a pipe run. Accordingly, the pipe connection element 36 has approximately the same diameter as a normally connected pipe run. In the axial direction, roughly in the middle, the pipe connection element 36 has a radially protruding collar 38 serving as a guide section. In the region of the collar 38, the wall thickness of the pipe connection element 36 is locally increased. With the collar surface 40 pointing outward in the radial direction, the pipe connection element 36 can slide or be pushed along the surface 24 of the bearing sleeve 18 in the axial direction. The displacement travel of the collar 38 and that of the pipe connection element 36 is bounded in the axial direction by the shoulders 26, 28. A lower shoulder surface 42 bordering on the collar 38 comes to bear against the shoulder 26 of the lower sleeve element 20 with a radially oriented direction of extension when the lower end of the displacement travel of the collar 38 is reached, as shown in FIG. 1A. Alternatively, an upper shoulder surface 44 bordering on the collar 38 comes to bear against the shoulder 28 of the upper sleeve element 22 with a radially oriented direction of extent when the upper end of the displacement travel of the collar 38 is reached, as shown in FIG. 1B.
As can likewise been seen in FIG. 1B, a gas-tight hollow space serving as a fluid space 46 is formed between the pipe connection element 36 and the bearing sleeve 18 in the axial direction beneath the collar 38 when the lower shoulder surface 42 is not bearing against the lower shoulder 26. The fluid space 46 can be filled with a fluid through a feed borehole 48 provided in the collar 38 and/or a fluid line 50 fluidically connected to it. In this way, the fluid can also flow out from the fluid space. The fluid space 46 is closed gas-tight by sealing rings (not shown), which are produced in a third group of grooves 52 in the lower sleeve element 20 and which interact with the pipe connection element 36.
The fluid line 50 is laid in a spiral around the pipe connection element 36 at the upper end of the housing 12 in the axial direction. In FIGS. 1A, 1B, this arrangement can be seen from the divided representation of the pipe connection element 36. In addition or alternatively, more than the one illustrated winding of the line 50 around the pipe connection element 36 can also be provided and/or further lines and/or cables (e.g., “control lines”, not shown) can also be laid around the pipe connection element 36. For a secure holding of this line or these lines and/or cables, the diameter of the through opening 14 is locally enlarged at the upper end of the housing 12 in the vertical direction. Through a borehole 54 in this region, the fluid line 50 as well as any cables present (not shown) can be led out from the housing 12 into the surroundings. The fluid line 50 is connected there to a pump (not shown) and emerges into a storage container (not shown) filled with the fluid being transported.
When the fluid is being actively pumped into the fluid space 46, it exerts a pressure on the lower shoulder surface 42 of the collar 38 and the pipe connection element 36 is lifted in the axial direction. When the pipe connection element 36 is connected in normal operation to an immovable pipe run, that is to say, it cannot be simply lifted, yet the fluid is pumped into the fluid space 46, axial tensile stresses are exerted on the pipe connection element 36 and the pipe run connected to it. If, on the contrary, the quantity of fluid in the fluid space 46 is reduced, the pipe connection element 36 carried by the fluid will fall with the fill level of the fluid, if the pipe connection element 36 is movable in the axial direction. If the pipe connection element 36 is not movable, for example because the pipe run to which it is connected is rigid, the pipe connection element 36 cannot fall. Accordingly, axial tensile stresses will be reduced in the pipe connection element 36 and the pipe run connected to it, or axial compressive stresses will be introduced, if fluid is nevertheless being actively released from the fluid space 46. Thus, the fluid space 46 cooperates functionally with the pipe connection element 36 such that the axial position of the pipe connection element 36 in normal operation stands in a functional connection with the fluid quantity and/or the fluid pressure in the fluid space 46.
In the axial direction, there is arranged on the top side of the housing 12 a housing cover (also called a “packoff”) 56. The housing cover 56 is formed substantially as a pipe piece, having a flange socket 58 at the lower end oriented toward the housing 12. By means of the flange socket 58, the housing cover 56 is connected firmly in position and removably to the housing 12. At the top side, the housing cover 56 is connected to the rest of the wellhead (not shown). In the housing 12 and the surface of the housing cover 56 lying against it, a fourth group of grooves 60 is provided opposite, in which seals (not shown) can be inserted. The housing cover 56 has an axial cylindrical borehole 62, the diameter of which corresponds roughly to the diameter of the through opening 14. The axial, cylindrical borehole 62 and the through opening 14 are concentrically arranged.
In the borehole 62 of the housing cover 56 there is installed a further bearing sleeve 64, which is supported in the axial direction at the top against a shoulder 66 of the housing cover 56. Sealing rings are provided between the housing cover 56 and the bearing sleeve 64 mounted therein, which can be inserted in a fifth group of grooves 68 which is provided in the housing cover 56. The internal diameter of the bearing sleeve 64 arranged in the housing cover 56 corresponds to the outer diameter of the upper segment of the pipe connection element 36 in the axial direction. Thus, the upper segment of the pipe connection element 36 can be received by the bearing sleeve 64. On the inside of the bearing sleeve 64 arranged in the housing cover 56 there is provided a sixth group of grooves 70, in which sealing means can be inserted for sealing off the contact surface between the pipe connection element 36 and the bearing sleeve 64 arranged in the housing cover 56.
Thanks to the described design and the mentioned seals, the interior of the pipe run and the pipe connection element 36 is sealed gas-tight against the outside. Moreover, the fluid space 46 is sealed gas-tight with respect to the through opening 14, and the through opening 14 is sealed gas-tight with respect to the surroundings around the housing 12. In this way, the functional security of the wellhead connection device 10 is increased, since a medium being transported cannot easily escape from the wellhead connection device 10. In addition, a pressure can be monitored in the sealed-off through opening 14 and a warning signal can be put out when the pressure in the through opening leaves a target region.
FIG. 2 shows the wellhead connection device 10 in a horizontal cross section view along the sectioning plane A-A shown in FIG. 1 . The boreholes 54 run tangentially from the through opening 14 through the housing 12 and to the outside surroundings. Through the boreholes 54, a plurality of the above-described fluid lines 50 are laid, being connected to means 72 for measuring the hydrostatic pressure in the fluid space. Moreover, FIG. 2 shows the retaining screws 34 arranged evenly around the circumference of the housing 12, the evenly distributed landing bolts 32, the radially inward directed and partially formed shoulder 28 of the upper sleeve element 22 and the pipe connection element 36.
The features of the invention disclosed in the present specification, in the drawings, and in the claims, can be important both by themselves and in any desired combinations for the realization of the invention in its various embodiments. The invention is not limited to the embodiments described. It can be varied within the scope of the claims and taking account of the knowledge of the person skilled in the art.

LIST OF REFERENCE NUMBERS

10 Wellhead connection device
12 Housing
14 Through opening
15 Flange socket on housing
16 First grooves
18 Two-piece bearing sleeve in the housing
20 Lower sleeve element
22 Upper sleeve element
24 Sliding surface, surface
26 Shoulder of lower sleeve element
28 Shoulder of upper sleeve element
30 Second grooves
32 Landing bolts
33 Square section of landing bolts
34 Retaining screws
36 Pipe connection element
38 Collar of pipe connection element
40 Radially outward pointing collar surface
42 Lower shoulder surface of collar
44 Upper shoulder surface of collar
46 Fluid space
48 Feed borehole in the collar
50 Fluid line
52 Third grooves
54 Borehole at upper end of housing
56 Housing cover (“packoff”)
58 Flange socket on housing cover
60 Fourth grooves
62 Axial borehole in housing cover
64 Bearing sleeve in housing cover
66 Shoulder of housing cover
68 Fifth grooves
70 Sixth grooves
72 Means of measuring the hydrostatic pressure

Claims

1. A wellhead connection device (10) for the top-side connection of a pipe run of a deep well, having a housing (12), which comprises a through opening (14), and a pipe connection element (36) arranged inside the through opening (14) in the housing (12), wherein the pipe connection element (36) is arranged to be axially displaceable in the housing (12) in order to compensate for axial stresses during normal operation,

characterized in that

a fluid space (46) is provided in the housing (12), functionally interacting with the pipe connection element (36), and is arranged such that the axial position of the pipe connection element (36) during normal operation stands in functional connection with the fluid quantity and/or the fluid pressure in the fluid space (46).

2. The wellhead connection device (10) according to claim 1, characterized in that a housing cover (56) is arranged at one axial end of the housing (12).

3. The wellhead connection device (10) according to claim 1, characterized in that the pipe connection element (36) comprises at least one guide section formed radially on the outside and the at least one guide section is surrounded by a bearing element on the outside.

4. The wellhead connection device (10), characterized in that at least one guide section of the pipe connection element (36) is formed as a radially protruding collar (38) along a portion of the axial length of the pipe connection element (36).

5. The wellhead connection device (10) according to claim 4, characterized in that the fluid space (46) directly borders on the collar (38) and a shoulder surface (42) bordering on the collar and having a radially oriented direction of extension serves as an active surface for the pressure in the fluid space (46) acting on the pipe connection element (36).

6. The wellhead connection device (10) according to claim 2, characterized in that

a) the housing (12) and/or the housing cover (56) is formed as a bearing element on the inside

and/or

b) at least one bearing sleeve (64) serving as a bearing element is arranged in the housing (12) and/or in the housing cover (56) and fixed to the housing.

7. The wellhead connection device (10) having a one-piece or multi-piece bearing sleeve (64) arranged in the housing (12) according to claim 6, characterized in that the position of the bearing sleeve (64) in the housing is dictated in the axial direction by landing bolts (32) and/or by retaining screws (34).

8. The wellhead connection device (10) according to claim 1, characterized in that there are provided

a) means of measuring the hydrostatic pressure (72) in the fluid space (46) and/or

b) means of detecting the axial position of the pipe connection element (36) within the housing (12) and/or

c) means of passive dampening of the pipe connection element displacement.

9. A method for reducing axial stresses in the pipe run which is firmly connected to the pipe connection element (36) of the wellhead connection device (10) according to claim 1, characterized by the following steps:

a) positioning of the pipe connection element (36) in the housing (12) such that the pipe connection element (36) is situated in a middle position and the fluid pressure is within a target region;

b) continuous or at least regular measuring of the hydrostatic pressure of the fluid; and

c) as soon as the pressure leaves the target region or threatens to do so by reaching a margin region, increasing or reducing the quantity of fluid present in the fluid space (46) in order to maintain the hydrostatic pressure as much as possible within the target region or to bring the hydrostatic pressure back to the target region by axial displacement of the pipe connection element (36).