OA17650A - Assembly for producing a threaded connection for drilling and operating hydrocarbon wells, threaded connection and method for producing such a threaded connection. - Google Patents

Abstract

The invention concerns an set for producing a threaded connection, comprising a first (UCS), a second (BCS), a third (PIN-A) and a fourth (PINB) tubular component with an axis of revolution (10), the first tubular component being provided at each of its ends with a first (Tl) and a second (T2) threaded zone provided on the inner peripheral surface of the component, the second tubular component being provided at each of its ends with a third (T3) and a fourth (T4) threaded zone provided on the outer peripheral surface of the component, the third tubular component being provided at one of its ends with a fifth (T5) and a sixth (T6) threaded zone respectively provided on the inner and outer peripheral surface of the component, the fourth tubular component being provided at one of its ends with a seventh (T7) and an eighth (T8) threaded zone respectively provided on the inner and outer peripheral surface of the component, the first and sixth, third and fifth, second and eighth, fourth and seventh threaded zones being capable of cooperating with one another on makeup, the pitch of the first and sixth threaded zones being equal to the pitch of the fourth and seventh threaded zones, or the pitch of the second and eighth threaded zones being equal to the pitch of the third and fifth threaded zones, or the pitch of the first and sixth threaded zones being equal to the pitch of the third and fifth threaded zones and the pitch of the second and eighth threaded zones being equal to the pitch of the fourth and seventh threaded zones. The invention also concerns a threaded connection and a method for producing such a connection.

Description

ASSEMBLY FOR PRODUCING A THREADED CONNECTION FOR DRILLING AND

OPERATING HYDROCARBON WELLS, THREADED CONNECTION, AND METHOD

FOR PRODUCING SUCH A THREADED CONNECTION [001] The présent invention relates to threaded connections for drilling and/or operating hydrocarbon wells, and more precisely to the optimization of the overall performance of a connection in terms of effîciency and seal when the connection works under compression/tension.

[002] The term “threaded connections” means any assembly constituted by éléments which are substantially tubular in shape, metallic and capable of being connected together by makeup with a particular view to constituting either a stem for drilling a hydrocarbon well, or a riser for maintenance (also known as a work~over riser), or for operating such a well, such as a riser, or a casing or tubing string used in operating a well.

[003] Each tubular element comprises an end portion provided with a male threaded zone or a female threaded zone for making up with a corresponding end portion of an analogous element. When assembled in this manner, the éléments make up what is known as a connection.

[004] Such tubular threaded components of a connection are assembled under pre-set loads in order to respond to the interférence fit and sealing requirements imposed by the service conditions. Furthermore, it should be noted that the threaded tubular components may hâve to undergo several makeup-breakout cycles, in particular when in service.

[005] The conditions under which such threaded tubular components are used gives rise to an extensive range of mechanical loads which act on the sensitive portions of those components such as the threaded zones, abutting zones or the sealing surfaces.

[006] For this reason, connection design spécifications are complex, requiring taking a number of parameters into account simultaneously. Thus, it is recommended that the effîciency of the connection be preserved, as well as the thickness of the zone of the tubular components which bears the sealing surfaces, and that the risks of displacing the sealing contact points when the connection opérâtes under compression/tension should be improved.

[007] One type of solution was developed through connections of the VAM HTF© type, which use two threaded zones between which are a first sealing surface and a second sealing surface provided at the lip of the male end. That design means that good stability of the first seal located between the threaded zones can be obtained, however the second seal is located on a very thin lip which renders the fonction of that seal vulnérable. In addition, when the connection opérâtes in compression/tension, the second seal is not stable because of the alternating loads. Finally, the presence of a seal in the lip of the male end reduces the efficiency of the female end.

[008] Another type of solution was also developed in the document US 4 570 982 Al. That type of connection has three staggered threaded portions, which means that the tapers of the three threaded zones are not coïncident but are parallel. Between each of the threaded zones is a sealing surface and an abutment. However, positioning abutments adjacent to sealing surfaces weakens said surfaces because the abutments are zones which are under particular load when the amplitude of the loads is high. The threaded zones are not self-locking and exhibit gaps at the load flanks and/or the stabbing flanks. However, because of those gaps, the stability of the sealing surfaces is compromised when the connection opérâtes in compression/tension.

[009] One kind of solution was also developed with connections of the VAM Edge© type, which employ two self-locking threaded zones between which is a sealing surface. As was the case for the VAM HTF©, that design gives rise to good stability of the intermediate seal at the threaded zones, however in the case of a flush or semi-flush connection, the single sealing surface is insufficient as regards resisting both internai pressure and extemal pressure.

[0010] Connections hâve been developed such as, for example, VAM 21 SC80© connections. However, that type of connection is a T&C type connection, i.e. coupled, insofar as a female threaded element is provided which has a large extemal diameter and is short in length, coupled at each of its ends to a male threaded element with a reduced diameter and long length.

[0011] For this reason, the aim of the invention is to respond to the threefold aim consisting of preserving the efficiency of the connection, maximizing the thickness of the zone of the tubular components which bears the sealing surfaces, and avoiding risks of displacement of the sealed contact points when the connection opérâtes in compression/tension.

[0012] More precisely, the invention concems an assembly for producing a threaded connection, comprising a first, a second, a third and a fourth tubular component with an axis of révolution, the first tubular component being provided at each of its end surfaces with a first and a second threaded zone provided on the inner peripheral surface of the component, the second tubular component being provided at each of its ends with a third and a fourth threaded zone provided on the outer peripheral surface of the component, the third tubular component being provided at one of its ends with a fifth and a sixth threaded zone respectively provided on the inner and outer peripheral surface of the component, the fourth tubular component being provided at one of its ends with a seventh and an eighth threaded zone respectively provided on the inner and outer peripheral surface of the component, the first and sixth, third and fifth, second and eighth, fourth and seventh threaded zones being capable of cooperating together in pairs on makeup, the pitch of the first and sixth threaded zones being equal to the pitch of the fourth and seventh threaded zones AND/OR the pitch of the second and eighth threaded zones being equal to the pitch of the third and fifth threaded zones AND/OR the pitch of the first and sixth threaded zones being equal to the pitch of the third and fifth threaded zones AND the pitch of the second and eighth threaded zones being equal to the pitch of the fourth and seventh threaded zones.

[0013] Optional complementary or substitutional features of the invention are set out below.

[0014] The pitch of the first and sixth threaded zones may be equal to the pitch of the fourth and seventh threaded zones, and the sixth threaded zone of the third tubular component may hâve the same taper as that of the seventh threaded zone of the fourth tubular component, said taper being in the range 5% to 25%, corresponding to a tangent to the peak half angle in the range 0.025 to 0.125, and preferably a taper in the range 10% to 18%, corresponding to a tangent to the peak half angle in the range 0.05 to 0.09.

[0015] The pitch of the second and eighth threaded zones may be equal to the pitch of the third and fifth threaded zones, and the fîfth threaded zone of the third tubular component may hâve the same taper as that of the eighth threaded zone of the fourth tubular component, said taper being in the range 5% to 25%, corresponding to a tangent to the peak half angle in the range 0.025 to 0.125, and preferably a taper in the range 10% to 18%, corresponding to a tangent to the peak half angle in the range 0.05 to 0.09.

[0016] The third tubular component may hâve a terminal end surface extending substantially perpendicular to the axis of révolution, said end surface being provided with a first abutment surface which is capable of cooperating in abutment with a corresponding second surface provided on a shoulder of the first tubular component and said end surface being provided with a third abutment surface which is capable of cooperating in abutment with a corresponding fourth surface provided on a shoulder of the second tubular component.

[0017] The fourth tubular component may hâve a terminal end surface extending substantially perpendicular to the axis of révolution, said end surface being provided with a fîfth abutment surface which is capable of cooperating in abutment with a corresponding sixth surface provided on a shoulder of the first tubular component and said end surface may be provided with a seventh abutment surface which is capable of cooperating in abutment with a corresponding eighth surface provided on a shoulder of the second tubular component.

[0018] The outer peripheral surface of the third tubular component may hâve a shoulder provided with a first abutment surface which is capable of cooperating in abutment with a corresponding second surface provided on a shoulder of the first tubular component and its inner peripheral surface may hâve a shoulder provided with a third abutment surface which is capable of cooperating in abutment with a corresponding fourth surface provided on a shoulder of the second tubular component.

[0019] The outer peripheral surface ofthe fourth tubular component may hâve a shoulder provided with a fifth abutment surface which is capable of cooperating in abutment with a corresponding sixth surface provided on a shoulder of the first tubular component and its inner peripheral surface may hâve a shoulder provided with a seventh abutment surface which is capable of cooperating in abutment with a corresponding eighth surface provided on a shoulder of the second tubular component.

[0020] The outer peripheral surface of the third tubular component may hâve a non-threaded portion preceding its terminal end, provided with a first sealing surface which is capable of cooperating in a sealing interférence fit with a corresponding second surface provided on the first tubular component.

[0021] The inner peripheral surface of the third tubular component may hâve a non-threaded portion preceding its terminal end, provided with a third sealing surface which is capable of cooperating in a sealing interférence fît with a corresponding fourth surface provided on the second tubular component.

[0022] The outer peripheral surface of the fourth tubular component may hâve a non-threaded portion preceding its terminal end, provided with a fifth sealing surface which is capable of cooperating in a sealing interférence fit with a corresponding sixth surface provided on the first tubular component.

[0023] The inner peripheral surface of the fourth tubular component may hâve a non-threaded portion preceding its terminal end, provided with a seventh sealing surface which is capable of cooperating in a sealing interférence fit with a corresponding eighth surface provided on the second tubular component.

[0024] The sealing surfaces of the third and fourth tubular components may respectively be provided between the shoulders carrying abutment surfaces of said tubular components and the free end of said tubular components.

[0025] One of the at least one sealing surfaces may be a tapered surface, the other corresponding facing sealing surface being a toroid with a radius R in the range 2.5 to 60 mm.

[0026] The first and second tubular components may be intégral such that they form a single component, the pitch of the first and sixth threaded zones then being equal to the pitch of the third and fifth threaded zones and the pitch of the second and eighth threaded zones being equal to the pitch of the fourth and seventh threaded zones.

[0027] The invention also concems a threaded connection resulting from makeup of an assembly in accordance with any one of the assemblies described above.

[0028] The invention also concems a first method for producing a connection, characterized in that it comprises the following steps:

• providing an assembly for producing a threaded connection in accordance with the invention and in which the pitch of the first and sixth threaded zones is equal to the pitch of the fourth and seventh threaded zones and in that the sixth threaded zone of the third tubular component has the same taper as that of the seventh threaded zone of the fourth tubular component, said taper being in the range 5% to 25%, corresponding to a tangent to the peak half angle in the range 0.025 to 0.125, and preferably a taper in the range 10% to 18%, corresponding to a tangent to the peak half angle in the range 0.05 to 0.09;

• connecting the third tubular component with the second tubular component by makeup;

• connecting the fourth tubular component with the first tubular component by makeup;

• connecting the résultants of the preceding two steps by makeup.

[0029] Advantageously, the pitch of the first and sixth threaded zones is in the reverse direction to the pitch of the third and fifth threaded zones.

[0030] The invention also concerns a second method for producing a connection, characterized in that it comprises the following steps:

• providing an assembly for producing a threaded connection in accordance with the invention and in which the pitch of the second and eighth threaded zones is equal to the pitch of the third and fifth threaded zones and in that the fifth threaded zone of the third tabulai· component has the same taper as that of the eighth threaded zone of the fourth *

tubular component, said taper being in the range 5% to 25%, corresponding to a tangent to the peak half angle in the range 0.025 to 0.125, and preferably a taper in the range 10% to 18%, corresponding to a tangent to the peak half angle in the range 0.05 to 0.09;

• connecting the fourth tubular component with the second tubular component by makeup;

• connecting the third tubular component with the first tubular component by makeup;

• connecting the résultants of the preceding two steps by makeup.

[0031] Advantageously, the pitch of the first and sixth threaded zones is in the reverse direction to the pitch of the third and fifth threaded zones.

[0032] The invention also concems a third method for producing a connection, characterized in that it comprises the following steps:

• providing an assembly for producing a threaded connection in accordance with the invention and in which the first and second tubular components are intégral such that they form a single component, the pitch of the first and sixth threaded zones being equal to the pitch of the third and fifth threaded zones and the pitch of the second and eighth threaded zones being equal to the pitch of the fourth and seventh threaded zones;

• connecting by makeup the third tubular component with the component resulting from securing the first and second tubular components together;

• connecting by make up the fourth tubular component with the component resulting from securing the first and second tubular components together.

[0033] The features and advantages of the invention are disclosed in more detail in the description below, made with reference to the accompanying drawings.

[0034] Figure 1 is a diagrammatic view, in longitudinal section passing through the axis of the connection, of a connection resulting from connecting by makeup an assembly in accordance with one embodiment of the invention.

[0035] Figure 2 is a diagrammatic view, in longitudinal section passing through the axis of the connection, of a portion of an assembly in accordance with one embodiment of the invention.

[0036] Figure 3 is a diagrammatic view, in longitudinal section passing through the axis of the connection, of another portion of an assembly in accordance with an embodiment of the invention.

[0037] Figure 4 is a diagrammatic view, in longitudinal section passing through the axis of the 5 connection, of a detail of an assembly in accordance with one embodiment of the invention.

[0038] Figure 5 is a diagrammatic view, in longitudinal section passing through the axis of the connection, of another detail of an assembly in accordance with one embodiment of the invention.

[0039] Figure 6 is a diagrammatic view, in longitudinal section passing through the axis of the connection, of another detail of an assembly in accordance with an embodiment of the invention.

[0040] Figure 7 is a diagrammatic view, in longitudinal section passing through the axis of the connection, of another detail of an assembly in accordance with an embodiment of the invention. [0041] Figures 8A and 8B are test graphs.

[0042] Figure 1 shows an assembly for producing a threaded connection in accordance with one embodiment of the invention. This connection comprises an axis of révolution 10. It also comprises a first UCS, a second BCS, a third PIN-A and a fourth PIN-B tubular component with an axis of révolution 10.

[0043] The first tubular component UCS is provided at each of its end surface with a first, Tl, and a second, T2, threaded zone provided on the inner peripheral surface of the component. The 20 first tubular component UCS is a relatively short tube, i.e. in the range 100 to 800 mm. The term “threaded zone” means any zone belonging to the circumferential surface of a tubular component and which comprises a threading, the threading possibly being continuous, interrupted, multiple, simple, regular, irregular, etc. The threaded zones may be ofthe trapézoïdal, self-locking, dovetail or other thread type.

[0044] The second tubular component BCS is provided at each of its end surfaces with a third, T3, and a fourth, T4, threaded zone provided on the outer peripheral surface of the component. The second tubular component BCS is also a relatively short length tube, i.e. in the range 100 to 800 mm.

[0045] The third tubular component PIN-A is provided at one of its ends with a fifth, T5, and a sixth, T6, threaded zone respectively provided on the inner and outer peripheral surface of the component. The third tubular component PIN-A is a long length tube, i.e. in the range 1000 to 13000 mm.

[0046] The fourth tubular component PIN-B is provided at one of its ends with a seventh, T7, and an eighth, T8, threaded zone respectively provided on the inner and outer peripheral surface of the component. The fourth tubular component PIN-B is also a long length tube, i.e. in the range 1000 10 to 13000 mm.

[0047] In accordance with the invention, the first and sixth, third and fifth, second and eighth, fourth and seventh threaded zones are capable of cooperating together in pairs on makeup. The term “cooperate in pairs on makeup” means that the threads of the first threaded zone must be compatible in terms of forms, dimensions, taper, etc., with the threads of the sixth threaded zone.

This is the same for the threads of the third threaded zone and the threads of the fifth threaded zone, etc.

[0048] For this reason, the pitch of the first and sixth threaded zones must necessarily be equal to the pitch of the fourth and seventh threaded zones, or the pitch of the second and eighth threaded zones has to be equal to the pitch of the third and fifth threaded zones, or the pitch of the first and 20 sixth threaded zones has to be equal to the pitch of the third and fifth threaded zones and the pitch of the second and eighth threaded zones has to be equal to the pitch of the fourth and seventh threaded zones.

[0049] Advantageously, and in order to facilitate the progress of makeup, the threaded zones of the tubular components may hâve a taper, these tapers being denoted lia, 11b, lie, 1 ld on Figure 1. In 25 this configuration, the sixth threaded zone T6 of the third tubular component PIN-A must necessarily hâve the same taper 1 ld as that 11b of the seventh threaded zone T7 of the fourth i

tubular component PIN-B, or that the fifth threaded zone T5 of the third tubular component PIN-A has the same taper 1 la as that 1 le of the eighth threaded zone T8 of the fourth tubular component

PIN-B.

[0050] Advantageously, the taper is in the range 5% to 25%, corresponding to a tangent to the peak half angle in the range 0.025 to 0.125, and preferably a taper in the range 10% to 18%, this corresponding to a tangent to the peak half angle in the range 0.05 to 0.09.

[0051] Advantageously, the third and/or fourth tubular component may cooperate in abutment with the first and/or the second tubular component.

[0052] Thus, as can be seen in Figures 4 and 5, the third tubular component PIN-A has a terminal end surface extending substantially perpendicular to the axis of révolution 10. The end surface is provided with a first abutment surface Cl which is capable of cooperating in abutment with a corresponding second surface C2 provided on a shoulder of the first tubular component UCS.

[0053] Similarly, said end surface is provided with a third abutment surface C3 which is capable of cooperating in abutment with a corresponding fourth surface C4 provided on a shoulder of the second tubular component BCS.

[0054] Similarly, the fourth tubular component PIN-B has a terminal end surface extending substantially perpendicular to the axis of révolution 10. The end surface is provided with a fifth abutment surface C5 which is capable of cooperating in abutment with a corresponding sixth surface C6 provided on a shoulder of the first tubular component UCS.

[0055] Similarly, said end surface is provided with a seventh abutment surface C7 which is capable of cooperating in abutment with a corresponding eighth surface C8 provided on a shoulder of the second tubular component BCS.

[0056] In a variation, and as can be seen in Figures 6 and 7, the outer peripheral surface of the third tubular component PIN-A has a shoulder provided with a first abutment surface Cl which is capable of cooperating in abutment with a corresponding second surface C2 provided on a shoulder of the first tubular component UCS.

[0057] Similarly, the inner peripheral surface of the third tubular component PIN-A has a shoulder provided with a third abutment surface C3 which is capable of cooperating in abutment with a corresponding fourth surface C4 provided on a shoulder of the second tubular component BCS.

[0058] Similarly, the outer peripheral surface of the fourth tubular component PIN-B has a shoulder provided with a fiflh abutment surface C5 which is capable of cooperating in abutment with a corresponding sixth surface C6 provided on a shoulder of the first tubular component UCS.

[0059] Similarly, the outer peripheral surface of the fourth tubular component PIN-B has a shoulder provided with a seventh abutment surface C7 which is capable of cooperating in abutment with a corresponding eighth surface C8 provided on a shoulder of the second tubular component BCS.

[0060] Advantageously, the third and/or fourth tubular component may comprise sealing surfaces which are capable of cooperating in a sealing interférence fit with corresponding sealing surfaces provided on the first and/or the second tubular component.

[0061] Thus, as can be seen in Figures 4 and 5, the third tubular component PIN-A has a nonthreaded portionpreceding the terminal end, provided with a first sealing surface SI provided on its outer peripheral surface and which is capable of cooperating in a sealing interférence fit with a corresponding second surface S2 provided on the first tubular component UCS.

[0062] Similarly, the third tubular component PIN-A is provided with a third sealing surface S3 provided on its inner peripheral surface and which is capable of cooperating in a sealing interférence fit with a corresponding fourth surface S4 provided on the second tubular component BCS.

[0063] Similarly, the fourth tubular component PIN-B is provided with a fiflh sealing surface S5 provided on its outer peripheral surface and which is capable of cooperating in a sealing interférence fit with a corresponding sixth surface S6 provided on the first tubular component UCS.

[0064] Similarly, the fourth tubular component PIN-B has a non-threaded portion preceding the terminal end provided with a seventh sealing surface S7 provided on its inner peripheral surface and which is capable of cooperating in a sealing interférence fit with a corresponding eighth surface S8 provided on the second tubular component BCS.

[0065] Advantageously, one of the sealing surfaces is a tapered surface, the other corresponding facing sealing surface being a toroid.

[0066] Advantageously again, the toroid surface is a domed toroid convex surface the radius R of which is preferably in the range 2.5 to 60 mm. Too large a radius, i.e. > 60 mm, for the toroid surface induces identical disadvantages to those of a cone-on-cone contact. Too small a radius, i.e.

< 2.5 mm, of this domed surface induces an insufficient contact width.

[0067] Facing the toroid sealing surface, the tapered sealing surface is supported by a taper generatrix forming an angle with the axis 10 of the connection the tangent to the peak half angle of which is in the range 0.025 to 0.25, which corresponds to a taper in the range 5% to 50%.

[0068] The invention also concerns a method for producing a threaded connection which first of ail consists of providing an assembly in accordance with the invention in which the pitch of the first and sixth threaded zones is equal to the pitch of the fourth and seventh threaded zones and in which the sixth threaded zone T6 of the third tubular component PIN-A has the same taper as that of the seventh threaded zone T7 of the fourth tubular component PIN-B. Next, the third tubular component PIN-A is connected by makeup with the second tubular component BCS. Next, the fourth tubular component PIN-B is connected by makeup with the first tubular component UCS. To finish, the résultants of the two preceding steps are connected by makeup.

[0069] In another variation, first of ail, an assembly in accordance with the invention is provided in which the pitch of the second and eighth threaded zones is equal to the pitch of the third and fifth 20 threaded zones and in which the fifth threaded zone T5 of the third tubular component PIN-A has the same taper as that of the eighth threaded zone T8 of the fourth tubular component PIN-B. Next, the fourth tubular component PIN-B is connected by makeup with the second tubular component BCS. Next, the third tubular component PIN-A is connected by makeup with the first tubular component UCS. Finally, the résultants of the preceding two steps are connected by makeup.

[0070] In another variation, first of ail an assembly in accordance with the invention is provided in which the first, UCS, and the second, BCS, tubular components are secured together so as to form a single component. This securing together may be carried out by welding, bolting, screwing up, etc.

[0071] In addition, the pitch of the first and sixth threaded zones is equal to the pitch of the third and fifth threaded zones and the pitch of the second and eighth threaded zones is equal to the pitch of the fourth and seventh threaded zones. Next, the third tubular component PIN-A is connected by makeup with the component resulting from securing the first, UCS, and second, BCS, tubular components together. Next, the fourth tubular component PIN-B is connected by makeup with the component resulting from securing together of the first, UCS, and the second, BCS, tubular components.

[0072] Advantageously, the first, UCS, second, BCS, third, PIN-A, and fourth, PIN-B, tubular components may hâve threaded zones comprising reverse screw'ing directions. Thus the first, sixth, fourth and seventh threaded zones Tl, T6, T4 and T7 may hâve a “left handed” screw pitch, while the second, eighth, third and fifth threaded zones T2, T8, T3 and T5 may hâve a “right handed” screw pitch. Clearly, this has an influence for fitting of the assembly, since the components hâve to be made up in a predefîned order.

[0073] Similarly, the first, sixth, third and fifth threaded zones Tl, T6, T3 and T5 may hâve a “left handed” screw pitch, while the second, eighth, fourth and seventh threaded zones T2, T8, T4 and T7 may hâve a “right handed” screw pitch. This case is adapted to the configuration in which the first, UCS, second, BCS, tubular components hâve initially been secured together.

[0074] This means that the makeup torque during makeup of the assembly can be reached more easily, rendering inadvertent breakout when the made up connection is in service limited or even impossible.

[0075] Comparative simulations were carried out on VAM SLIJ-II connections and on connections in accordance with the invention. VAM SLIJ-II connections are intégral type connections comprising two staggered threaded zones separated by an intermediate abutment and two sealing surfaces, one inner and the other outer.

[0076] The graph in Figure 8A shows, in curve 1, the relative displacement of the inner sealing surfaces in contact for a carbon steel VAM SLIJ-II connection with an outer diameter of 9 7/8” (i.e.

250.83 mm), a nominal weight of 62.8 (i.e. a thickness of 15.88 mm) and with a P110 yield strength, i.e. 758 MPa.

[0077] Curve 2 of the graph in Figure 8A shows the relative displacement of the inner sealing surfaces in contact for a carbon steel connection of the invention with an outer diameter of 9 7/8” (i.e. 250.83 mm), a nominal weight of 62.8 (i.e. a thickness of 15.88 mm) and with a Pl 10 yield 10 strength, i.e. 758 MPa.

[0078] It can clearly be seen that curve 2 keeps close to the horizontal axis. This means that the connection of the invention is less sensitive to applied loads, irrespective of variations in internai pressure IP or extemal pressure EP, tensile stresses T, compressive loads C, or several of these in combination.

[0079] In contrast, curve 1 comprises portions which deviate substantially from the horizontal axis.

This means that the VAM SLIJ-II connection is more sensitive to the loads described above.

[0080] In the graph of Figure 8B, comparative results are shown between the relative displacement of the extemal sealing surfaces in contact of the VAM SLIJ-II connection of Figure 8A and the relative displacement of the sealing surfaces in contact of the connection of the invention, also in 20 Figure 8A. The conclusions are identical to those of Figure 8A.

[0081] It should be noted that this type of connection is particularly adapted to flush or semiflush type connections.

[0082] It should be noted that the extemal diameter of the first, UCS, third, PIN-A, and fourth,

PIN-B, tubular components may be different, or they may be equal. Preferably, the extemal diameter of the first tubular component UCS is greater than the extemal diameter of the third,

PIN-A, and fourth, PIN-B, tubular components.

[0083] The advantages of having a small relative displacement of the sealing surfaces means that too great a dulling of the surfaces, which could generate micro-grooves during multiple axial displacements and resuit in a loss of sealing during combined tensile and compressive loads, can be avoided.

[0084] This type of connection can be used to maximize the rôle of sealing surfaces of the first and second tubular components UCS, BCS and to limit the relative displacements thereof in tension and in compression. In addition, this type of connection means that good connection efficiency can be retained with vanishing threads.

Claims (19)

1. An assembly for producing a threaded connection, comprising a first (UCS), a second (BCS), a third (PIN-A) and a fourth (PIN-B) tubular component with an axis of révolution (W);

• the first tubular component (UCS) being provided at each of its end surfaces with a first (Tl) and a second (T2) threaded zone provided on the inner peripheral surface of the component;

• the second tubular component (BCS) being provided at each of its ends with a third (T3) and a fourth (T4) threaded zone provided on the outer peripheral surface of the component;

• the third tubular component (PIN-A) being provided at one of its ends with a fifth (T5) and a sixth (T6) threaded zone respectively provided on the inner and outer peripheral surface of the component;

• the fourth tubular component (PIN-B) being provided at one of its ends with a seventh (T7) and an eighth (T8) threaded zone respectively provided on the inner and outer peripheral surface of the component;

• the first and sixth, third and fifth, second and eighth, fourth and seventh threaded zones being capable of cooperating together in pairs on makeup;

• the pitch of the first and sixth threaded zones being equal to the pitch of the fourth and seventh threaded zones; AND/OR • the pitch of the second and eighth threaded zones being equal to the pitch of the third and fifth threaded zones; AND/OR • the pitch of the first and sixth threaded zones being equal to the pitch of the third and fifth threaded zones AND the pitch of the second and eighth threaded zones being equal to the pitch of the fourth and seventh threaded zones.

2. An assembly for producing a threaded connection according to claim 1, characterized in that pitch of the first and sixth threaded zones is equal to the pitch of the fourth and t

seventh threaded zones and in that the sixth threaded zone (T6) of the third tubular component (PIN-A) has the same taper as that of the seventh threaded zone (T7) of the fourth tubular component (PIN-B), said taper being in the range 5% to 25%, corresponding to a tangent to the peak half angle in the range 0.025 to 0.125, and preferably a taper in the range 10% to 18%, corresponding to a tangent to the peak half angle in the range 0.05 to 0.09.

3. An assembly for producing a threaded connection according to any one of the preceding claims, characterized in that the pitch of the second and eighth threaded zones is equal to the pitch of the third and fifth threaded zones and in that the fifth threaded zone (T5) of the third tubular component (PIN-A) has the same taper as that of the eighth threaded zone (T8) of the fourth tubular component (PIN-B), said taper being in the range 5% to 25%, corresponding to a tangent to the peak half angle in the range 0.025 to 0.125, and preferably a taper in the range 10% to 18%, corresponding to a tangent to the peak half angle in the range 0.05 to 0.09.

4. An assembly for producing a threaded connection according to any one of claims 1 to 3, characterized in that the third tubular component (PIN-A) has a terminal end surface extending substantially perpendicular to the axis of révolution (10), said end surface being provided with a first abutment surface (Cl) which is capable of cooperating in abutment with a corresponding second surface (C2) provided on a shoulder of the first tubular component (UCS) and said end surface is provided with a third abutment surface (C3) which is capable of cooperating in abutment with a corresponding fourth surface (C4) provided on a shoulder of the second tubular component (BCS).

5. An assembly for producing a threaded connection according to any one of claims 1 to 4, characterized in that the fourth tubular component (PIN-B) has a terminal end surface extending substantially perpendicular to the axis of révolution (10), said end surface being provided with a fifth abutment surface (C5) which is capable of cooperating in abutment t

with a corresponding sixth surface (C6) provided on a shoulder of the first tubular component (UCS) and said end surface is provided with a seventh abutment surface (C7) which is capable of cooperating in abutment with a corresponding eighth surface (C8) provided on a shoulder of the second tubular component (BCS).

6. An assembly for producing a threaded connection according to any one of claims 1 to 3, characterized in that the outer peripheral surface of the third tubular component (PIN-A) has a shoulder provided with a first abutment surface (Cl) which is capable of cooperating in abutment with a corresponding second surface (C2) provided on a shoulder of the first tubular component (UCS) and its inner peripheral surface has a shoulder provided with a third abutment surface (C3) which is capable of cooperating in abutment with a corresponding fourth surface (C4) provided on a shoulder of the second tubular component (BCS).

7. An assembly for producing a threaded connection according to claim 6, characterized in that the outer peripheral surface of the fourth tubular component (PIN-B) has a shoulder provided with a fifth abutment surface (C5) which is capable of cooperating in abutment with a corresponding sixth surface (C6) provided on a shoulder of the first tubular component (UCS) and its inner peripheral surface has a shoulder provided with a seventh abutment surface (C7) which is capable of cooperating in abutment with a corresponding eighth surface (C8) provided on a shoulder of the second tubular component (BCS).

8. An assembly for producing a threaded connection according to any one of the preceding claims, characterized in that the outer peripheral surface of the third tubular component (PIN-A) has a non-threaded portion preceding its terminal end, provided with a first sealing surface (SI) which is capable of cooperating in a sealing interférence fit with a corresponding second surface (S2) provided on the first tubular component (UCS).

9. An assembly for producing a threaded connection according to any one of the preceding claims, characterized in that the inner peripheral surface of the third tubular component »

« (PIN-A) has a non-threaded portion preceding its terminal end, provided with a third sealing surface (S3) which is capable of cooperating in a sealing interférence fit with a corresponding fourth surface (S4) provided on the second tubular component (BCS).

10. An assembly for producing a threaded connection according to any one of the preceding claims, characterized in that the outer peripheral surface of the fourth tubular component (PIN-B) has a non-threaded portion preceding its terminal end, provided with a fifth sealing siuface (S5) which is capable of cooperating in a sealing interférence fit with a corresponding sixth surface (S6) provided on the first tubular component (UCS).

11. An assembly for producing a threaded connection according to any one of the preceding claims, characterized in that the inner peripheral surface of the fourth tubular component (PIN-B) has a non-threaded portion preceding its terminal end, provided with a seventh sealing siuface (S7) which is capable of cooperating in a sealing interférence fit with a corresponding eighth surface (S8) provided on the second tubular component (BCS).

12. An assembly for producing a threaded connection according to claims 6 to 11 together, characterized in that the sealing suifaces of the third and fourth tubular components (PIN-A and PIN-B) are respectively provided between the shoulders carrying abutment surfaces of said tubular components (PIN-A and PIN-B) and the free end of said tubular components.

13. An assembly for producing a threaded connection according to any one of claims 8 to 12, characterized in that one of the at least one sealing suifaces is a tapered surface, the other corresponding facing sealing siuface being a toroid with a radius R in the range 2.5 to 60 mm.

14. An assembly for producing a threaded connection according to any one of the preceding claims, characterized in that the first (UCS) and second (BCS) tubular components are intégral such that they form a single component, the pitch of the first and sixth threaded zones being equal to the pitch of the third and fifth threaded zones and the pitch of the second and eighth threaded zones being equal to the pitch of the fourth and seventh threaded zones.

15. A threaded connection resulting from making up an assembly according to any one of claims 1 to 14.

5

16. A method for producing a connection, characterized in that it comprises the following steps:

• providing an assembly for producing a threaded connection in accordance with claim 2;

• connecting the third tubular component (PIN-A) with the second tubular component (BCS) by makeup;

• connecting the fourth tubular component (PIN-B) with the first tubular component (UCS)

10 by makeup;

• connecting the résultants of the preceding two steps by makeup.

17. A method for producing a connection, characterized in that it comprises the following steps:

• providing an assembly for producing a threaded connection in accordance with claim 3;

• connecting the fourth tubular component (PIN-B) with the second tubular component (BCS)

15 by makeup;

• connecting the third tubular component (PIN-A) with the first tubular component (UCS) by makeup;

• connecting the résultants of the preceding two steps by makeup.

18. A method for producing a connection according to claim 16 or claim 17, characterized in

20 that the pitch of the first and sixth threaded zones is in the reverse direction to the pitch of the third and fifth threaded zones.

19. A method for producing a connection, characterized in that it comprises the following steps:

• providing an assembly for producing a threaded connection in accordance with claim 14;

• connecting by makeup the third tubular component (PIN-A) with the component resulting

25 from securing the first (UCS) and second (BCS) tubular components together;

connecting by makeup the fourth tubular component (PIN-B) with the component resulting from securing the first (UCS) and second (BCS) tubular components together.