RU172778U1 - COUPLING THREADED PIPE CONNECTION - Google Patents

Abstract

The utility model relates to sleeve threaded pipe joints. The conical trapezoidal thread of the pipes and couplings is made with a negative angle of inclination of the supporting surface of the thread profile equal to 3 ° 30'-11 ° 30 'and a positive angle of inclination of the guide surface of the thread profile equal to 10 ° 30'-18 ° 30'. On the outer surface of the pipe between the threaded section and the smooth locking part, a cylindrical groove is made parallel to the axis of the pipe, with a diameter equal to the diameter along the bottom of the cavity of the conical trapezoidal thread in the plane of intersection of the conical trapezoidal thread with a cylindrical groove and a length of 5-12 mm. On the inner surface of the coupling between the threaded section and the smooth locking part, a cylindrical bore is made parallel to the axis of the coupling, the length corresponding to the length of the cylindrical groove in the pipe. The cylindrical bore in the coupling forms an annular groove with inclined lateral surfaces at an angle of 25-35 ° to the line perpendicular to the axis of the coupling, with a diameter along the bottom of the groove larger by 0.1-1.5 mm of the diameter of the socket of the thread of the coupling in the plane of intersection of the thread with the groove. After assembling a threaded connection with an interference fit, a cylindrical groove on the pipe and a cylindrical groove in the sleeve form an annular cavity, which is a hydraulic shutter for collecting sealing grease. An increase in operational reliability is achieved. 2 s.p. f-ly, 11 ill.

Description

The utility model relates to sleeve threaded pipe joints, mainly for equipping oil and gas wells, and can be used to connect casing pipes in vertical and inclined columns for production, transportation of oil and gas from the bowels of the Earth from deep and ultra-deep horizons with difficult geological conditions and aggressive environments.

Two basic requirements are imposed on sleeve threaded pipe joints that are used in the construction of oil and gas wells: this is to ensure high strength of the joint (not less than the strength of the main body of the pipe) and high tightness under difficult operating conditions, which are characterized by the work of the joint under the action of alternating axial and bending loads and torques.

The necessary strength and tightness of the threaded pipe joints are ensured by the choice of the type of thread, preliminary thickening of one or two ends of the pipe, the use of heat treatment, additional sealing on the thread using Teflon (PTFE ring), the use of metal-to-metal sealing surfaces, the presence of a special stop ledge and other

A sleeve coupling of pipes is known (see document SU 857427 A, publ. 08.28.1981), in which thin-walled casing pipes with an outer diameter to wall thickness ratio of more than 22 contain nipple and sleeve parts with a conical triangular thread, and the pipe end is lengthwise from its end to the main plane of the thread is made with a constant wall thickness. This technical solution allows to increase the strength of the connection of thin-walled casing with a triangular thread on the nipple and coupling parts by increasing the thickness of the pipe wall under the thread. The disadvantages of this connection is the insufficient strength of the threaded connection and its low tightness when equipping oil and gas wells for hydrocarbon production at great depths and in difficult geological conditions.

Known pipe coupling threaded connection (see document RU 2186284 C2, publ. 07.27.2002), including a sleeve and two pipe ends, in which the sealing is carried out by contacting the ends of the pipes through the o-ring. The ends of the pipes are made in the form of mutually opposite cones diverging with respect to the inner surface of the pipe. The sealing ring is made in the form of articulating, having convergent mating conical surfaces. Between the coupling and the joint ring a clearance is made with the possibility of ensuring the necessary movement of the latter in the radial direction. The angle of inclination of the conical surfaces corresponds to the angle of friction of the materials used. The disadvantages of this connection is the insufficient strength of the threaded connection and its low tightness when equipping oil and gas wells for hydrocarbon production at great depths and in difficult geological conditions.

Known sleeve threaded pipe connection (see document UA 69703 A, publ. September 15, 2004, adopted as a prototype), including a sleeve on the inner surface of which, starting from the ends, there are two threaded sections with a smooth locking sealing part between them and two located along one axis of the end of the pipes, on the outer surface of which, starting from the end in the direction of the main body of the pipe, a smooth locking sealing part that comes into contact with the smooth locking sealing part of the coupling is sequentially located and a threaded part the current that comes into contact with the threaded section of the coupling, in which the pipe and the coupling are made of steel of the same class, the tensile strength of the coupling material (σ _VM ) differs from the tensile strength of the pipe material (σ _VT ) in accordance with the condition σ _VM ≤0.94 σ _VT or σ _VM ≥1.06 σ _VT . Moreover, the sealing surfaces of the sealing locking part of the coupling connection have different strength limits of the material from which they are made. The disadvantages of this connection are the insufficient strength of the threaded connection under the action of, first of all, tensile forces due to the weight of the oil pipe string (casing and tubing). In addition, the strength of the threaded connection decreases with the additional action of bending forces during inclined drilling. The insufficient strength and tightness of the threaded connection of oilfield pipes does not provide hydrocarbon production from deep horizons in difficult geological conditions, including at elevated gas pressure.

The purpose of the utility model is to improve the coupling threaded connection of pipes, increasing the strength and tightness of the connection.

EFFECT: increased operational reliability of a connection.

The technical result is achieved due to the fact that the sleeve threaded pipe connection includes a sleeve on the inner surface of which, starting from the ends, there are two threaded sections with a smooth locking sealing part between them and two coaxially located pipe ends, on the outer surface of which, starting from the end in the direction of the main body of the pipe, a smooth locking seal is sequentially located; the part that comes into contact with the smooth locking sealing part of the coupling, while the smooth locking parts of the pipe and coupling are made in the form of two joined sealing and thrust conical surfaces with different tapers located on the pipes between the threaded section and the pipe end, and on the coupling - between the threaded section and the body of the coupling, and the threaded section that comes into contact with the threaded section of the coupling, and on the threaded sections of the pipes and the coupling a tapered trapezoidal thread with a taper of 1:16 and a pitch of 5.08 is made m with different angles of inclination of the support and guide surfaces of the thread profile relative to the line perpendicular to the axis of the thread, the conical trapezoidal thread of pipes and couplings is made with a negative angle of inclination of the support surface of the thread profile equal to 3 ° 30'-11 ° 30 'and a positive angle of inclination of the guide surface of the profile threads equal to 10 ° 30'-18 ° 30 ', on the outer surface of the pipe between the threaded section and the smooth locking part, a cylindrical groove is made parallel to the pipe axis, with a diameter equal to the diameter along the bottom of the cavity trapezoidal thread in the plane of intersection of the conical trapezoidal thread with a cylindrical groove and a length of 5-12 mm, on the inner surface of the coupling between the threaded section and the smooth locking part, a cylindrical bore is made parallel to the axis of the coupling, the length corresponding to the length of the cylindrical groove on the pipe, and the cylindrical bore in the coupling forms an annular groove with inclined lateral surfaces at an angle of 25-35 ° to the line perpendicular to the axis of the coupling, with a diameter along the bottom of the groove larger by 0.1-1.5 mm di meter troughs of the thread coupling a thread crossing with the plane of the groove, wherein after assembly the threaded connection cylindrical bore with an interference fit on the tube and the cylindrical groove in the sleeve form an annular cavity, which is a hydraulic seal for sealing grease collection. The taper angles of the sealing surfaces of the smooth locking parts of the pipe and the coupling in contact with each other when assembling the threaded connection are 15-25 ° relative to the axis of the connection, and the mating radius between the sealing surface of the smooth locking part of the pipe and the cylindrical groove is 3-6 mm. The taper angles of the thrust surfaces of the smooth locking sealing parts of the pipes and the coupling in contact with each other when assembling the threaded joint are 12-18 ° relative to the line perpendicular to the axis of the threaded joint, and a conical bore with a taper angle of 4-8 relative to the pipe axis is made on the inner surface of the pipe ends in the direction of its end.

The causal relationship between the totality of features and the technical result is as follows.

An increase in the strength of the male threaded pipe joint is achieved by using a profile of a tapered trapezoidal thread, in which the angle of inclination of the supporting surface is negative and equal to 3 ° 30'-11 ° 30 ', and the angle of inclination of the guide surface is positive and equal to 10 ° 30'-18 ° 30 ', with other standard thread parameters according to API5B. The presence of a negative angle of inclination of the support surface of the profile of the conical trapezoidal thread prevents the separation of the pipe from the sleeve due to the action of the radial component of the tensile force. In this case, the action of the radial component of the force on the thread turns prevents the formation of a radial clearance between the threads of the pipe and coupling, which helps to increase the tightness of the connection. The selection of negative inclination angles of the supporting surface of the profile of the conical trapezoidal thread within 3 ° 30'-11 ° 30 'is due to the following. With an increase in the thinness of the casing pipes - an increase in the ratio of the outer diameter of the pipe Dt to its wall thickness St (Dt / St), the likelihood of uncoupling the threaded sleeve connection under the action of large tensile forces during operation of the casing string increases. Therefore, with an increase in the ratio Dt / St, the value of the negative angle of inclination of the support surface of the thread profile can be increased. At the same time, an excessive increase in this angle (more than 11 ° 30 ') affects the decrease in the strength of the thread profile due to a decrease in the cross section of the thread winding. The choice of a positive angle of inclination of the guide surface of the thread profile within 10 ° 30'-18 ° 30 'is due to the following. On the one hand, an increase in the positive angle of the guide surface of the thread profile can compensate for a decrease in the cross section of the thread thread with an increase in the negative angle of the supporting surface of the profile of the tapered trapezoidal thread. The limitation of the positive angle of the guide surface of the thread profile is the increase in the moment of screwing (unscrewing) of the threaded connection by increasing the area of the contact surface of the pipe and coupling threads. The optimal choice is the angle of inclination of the support and guide surfaces of the thread profile, which in specific cases of casing operation provides the necessary strength of the threaded connection, its tightness, which leads to increased operational reliability.

Reliable tightness of the threaded connection between the pipe and the coupling, and hence the increase in operational reliability, is achieved by contacting the sealing and thrust conical surfaces of the smooth locking parts of the pipes and the coupling. The choice of rational parameters of sealing and thrust conical surfaces provides reliable tightness when creating sufficient contact stresses during assembly of the connection by the metal-to-metal method. The presence of persistent conical surfaces on the pipe and in the coupling stabilizes the amount of torque when making up the pipe and the coupling, which is especially important in drilling rigs where it is difficult to regulate the amount of torque. The choice of the taper angles of the sealing surfaces of the smooth locking part of the pipe and coupling within 15-25 ° relative to the axis of the connection, contacting each other during the assembly of the threaded connection, is determined by the operating conditions of the casing pipes, namely, significant external and internal pressures, the action of bending moments during inclined drilling and significant tensile loads during deep drilling. It is also necessary to take into account the real roughness of the contacting surfaces of the pipes and couplings.

Improving the reliability during operation of a threaded joint is also ensured by the formation of an annular cavity for sealing lubrication due to cylindrical surfaces on the pipe and coupling located between the threaded section and the smooth locking sealing part. The parameters of the annular cavity contribute to the retention of lubricant in the connection, which prevents scuffing and seizing during assembly of the connection, and also contribute to the exit of the thread-forming tool when threading. The length of the cylindrical groove on the pipe in the range of 5-12 mm is due to the need to create an annular cavity to keep the rational amount of lubricant, while with a decrease in the diameter of the connecting pipes, the length of the groove can be reduced.

The choice of the parameters of the annular groove in the coupling is due to the following. The diameter along the bottom of the groove is taken to be large by 0.1-1.5 mm of the diameter of the thread depression of the coupling in the plane of intersection with the groove to prevent damage to the threads. At the same time, the size of the groove diameter in the coupling determines the required volume of the annular cavity for collecting sealing lubricant. Exceeding the diameter of the annular groove weakens the body of the coupling and its strength.

The choice of the angles of inclination of the lateral surfaces of the annular groove within 25-35 ° to the line perpendicular to the axis of the coupling is due to the technology of profiling the grooves on the machine.

The adopted parameters of the conical bore of the inner surface of the pipe end at an angle of 4-8 ° prevent gas turbulence at the junction of the pipe end with the sleeve, which prevents the appearance of metal corrosion and thereby increases the life of the threaded connection. The magnitude of the taper angle of the bore of the inner surface of the end of the pipe is determined structurally to ensure equidistance of the inner surface of the threaded connection.

The choice of the radius of coupling between the sealing surface of the smooth castle part of the pipe and the cylindrical groove equal to 3-6 mm is due to the need to create a smooth transition between two surfaces: cylindrical and conical.

Improvement of the sleeve threaded pipe joint to increase the reliability of its operation by increasing the strength and tightness by changing the profile of the tapered trapezoidal thread and improving the sealing conditions on the tapered sections of the smooth locking part of the threaded joint.

The inventive coupling threaded pipe connection is illustrated by drawings where:

in FIG. 1 shows a sectional perspective view of a male threaded pipe joint;

in FIG. 2 and 3 — coupling and pipe, respectively, in section;

in FIG. 4 is a view I in FIG. 2;

in FIG. 5 is a view II in FIG. 3;

in FIG. 6 is a profile of a conical trapezoidal thread of a pipe with forces acting on it under tension of the joint;

in FIG. 7 - threaded section and smooth locking part of the coupling with an annular groove;

in FIG. 8 is a view III in FIG. 7;

in FIG. 9 - threaded section and smooth locking part of the pipe with a cylindrical groove;

in FIG. 10 - coupling of a cylindrical groove with a sealing surface at the end of the pipe;

in FIG. 11 - an annular cavity between the pipe and the coupling.

In FIG. 1-11 are indicated: (1) - coupling; (2) - pipes that are connected using a sleeve (1); (1.2) - threaded sections of the coupling; (2.2) - threaded pipe sections; (1.3) - smooth locking sealing part of the coupling; (1.31) and (1.32) - sealing and thrust surfaces of the smooth locking part of the coupling; (2.3) - smooth locking sealing part of the pipe; (2.31) and (2.32) - sealing and thrust surfaces of the smooth castle part of the pipe; (1.4) - ends of the coupling, (2.4) - ends of the pipe, (1.5) - cylindrical bore in the coupling, (2.5) - cylindrical groove of the end of the pipe; (1.6) and (1.7) are the supporting and guiding surfaces of the thread profile on the coupling, respectively; (2.6) and (2.7) are the supporting and guiding surfaces of the profile of the conical trapezoidal thread on the pipe, respectively; (1.8) and (1.9) - the top and bottom of the profile of the conical trapezoidal thread on the coupling, respectively; (2.8) and (2.9) - the top and bottom of the profile of the conical trapezoidal thread on the pipe, respectively; (2.10) - conical bore on the pipe; (3) - an annular cavity forming a hydraulic shutter.

Dt and St - the diameter and wall thickness of the pipe, which are connected using a sleeve; 00 ₁ - the axis of the threaded coupling, along which the pipes connected by the coupling are coaxially located, α ₁ is the taper angle of the supporting surface of the profile of the conical trapezoidal thread of the pipe relative to the line perpendicular to the axis 00 ₁ ; α ₂ - the angle of taper of the guide surface of the profile of the conical trapezoidal thread of the pipe relative to the line perpendicular to the axis 00 ₁ ; P _N , Pz and Pr are, respectively, the normal, axial and radial components of the force acting on the thread of the pipe under tension of the threaded connection: K is the length of the annular groove in the coupling; Q is the length of the cylindrical groove on the outer surface of the pipe end; L is the length of the sealing surface of the smooth locking part of the coupling; N is the length of the sealing surface of the smooth locking part of the pipe; β ₁ - the angle of inclination of the lateral surface of the grooves in the coupling; γ ₁ and γ ₂ are the taper angles of the sealing and thrust surfaces of the smooth locking part of the coupling, respectively, β ₂ is the taper angle of the bore of the inner surface of the pipe end, γ ₃ and γ ₄ are the taper angles of the sealing and thrust surfaces of the smooth locking part of the pipe, respectively; R is the mating radius between the cylindrical groove and the sealing surface on the pipe; Dn is the diameter of the cylindrical groove at the end of the pipe; Dк - the diameter of the cylindrical bore in the coupling.

The proposed sleeve threaded connection, mainly for the arrangement of oil and gas wells, contains a sleeve (1) and pipes connected with it (2) (Fig. 1-3). The connected pipes have an outer diameter Dt and a wall thickness St. The pipes (2) in the coupling (1) are aligned with the axis 00 ₁ , which is the axis of the threaded connection. On the inner surface of the coupling, starting from the ends (1.4), two threaded sections (1.2) are made. Between the threaded sections (1.2) are two smooth locking parts (1.3).

On the outer surface of the ends of the pipes (2) starting from the end face (2.4), a smooth locking part (2.3) and a threaded section (2.2) are successively made. The threaded sections of the coupling (1.2) and pipes (2.2) are in contact with each other using a tapered trapezoidal thread (taper 1:16) with a pitch of 5.08 mm and a profile height of 1.785 mm. The width of the groove of the thread profile on the sleeve is 2.505 mm, the width of the peaks of the thread of the profile on the sleeve is 2.575 mm, the width of the groove of the profile of the thread on the pipe 2.605 mm, the width of the top of the profile of the thread on the pipe is 2.475 mm. The conical thread of pipes and couplings is made with a negative angle of inclination of the support surface (2.6) of the thread profile α ₁ = - (3 ° 30'-l1 ° 30 ') and a positive angle of inclination of the guide surface (2.7) of the thread profile α ₂ = 10 ° 30' -18 ° 30 '(Fig. 4 and 5). The use of a thread profile with a negative angle leads to a change in the direction of the radial forces Pr, which prevent the pipe from coming out of engagement with the sleeve. The value of Pr is associated with axial Pz and normal P _N force relations (Fig. 6):

Thus, the used thread profile allows to increase the limit values of tensile loads. In addition, such a threaded connection prevents the occurrence of a radial clearance when loading the connection with tensile force.

This is important to ensure the tightness of threaded joints operating at excessive pressures.

The choice of angles α ₁ and α ₂ within the specified limits provides the necessary strength of the threaded connection with increased tensile forces, as well as the tightness of the threaded connection.

In the proposed connection, its main tightness is ensured by the presence of smooth locking sealing parts (1.3) and (2.3) respectively on the coupling and pipes, while sealing is carried out by the metal-to-metal method by contacting the corresponding conical sealing surfaces (1.31) and (1.32) on the coupling and (2.31) and (2.32) on the pipes (Fig. 7-9). The angle of inclination forming the conical sealing surfaces on the coupling (1.31) and pipes (2.31) γ ₁ = 15-25 °. Additional sealing of the threaded connection is carried out using thrust conical surfaces (1.32) on the coupling and (2.32) on the pipe, which are located at an angle γ ₂ = 12-18 ° and form a kind of lock that restricts the movement of the pipe in the coupling. As a result of this, the tightness during assembly of the joint is limited and the magnitude of the torque during the pipe and coupling make-up is stabilized, which is especially important in drilling rigs when assembling pipe columns above the wellhead, since in the field there is no possibility of objective control of the torque.

On the outer surface of the pipe between the threaded section (2.2) and the smooth locking part (2.3), a cylindrical groove (2.5) with a diameter of Dn and a length of Q = 5-12 mm was made (Fig. 9). The diameter Dn of the cylindrical groove (2.5) is equal to the diameter along the bottom of the thread depression in the plane of intersection of the thread with the cylindrical groove.

The mating radius between the smooth sealing surface (2.31) and the cylindrical groove (2.5) is made equal to R = 3-6 mm (Fig. 10). On the inner surface of the coupling between the threaded section (1.2) and the smooth locking sealing part (1.3), a cylindrical bore with a diameter Dk parallel to the axis of the coupling and a length K corresponding to the length of the groove on the pipe Q is made, with the sides of the groove located at an angle β ₁ = 25-35 ° to the line perpendicular to the axis of the coupling.

The diameter Dk of the cylindrical bore of the coupling along the bottom of the groove (1.5) is larger by 0.1-1.5 mm of the diameter of the cavity of the thread of the coupling in the plane of the intersection of the thread with the groove, which prevents damage to the threads and facilitates the repeated screwing-unscrewing of the threaded connection during its operation on fisheries.

The groove (1.5) provides the outlet of the thread-forming tool on the one hand, and the sealing threaded grease is preserved on the other hand due to the fact that the groove (1.5) in the sleeve and the groove (2.5) on the pipe form an annular cavity (3), which is a hydraulic shutter for collecting sealing grease (Fig. 11).

The distance T from the end of the pipe to the end of the cylindrical groove (2.5) can be in the range of 9-18 mm.

The distance N from the end of the pipe to the end of the conical section (2.31) at the point of its intersection with the cylindrical groove (2.5) can be within 3-5 mm. Moreover, T = Q + N. The distance M in the coupling corresponds to the distance T on the pipe, i.e. M≈T. Moreover, K≈Q, a L≈N.

When contacting the sealing surfaces (1.31), (1.32) and (2.31), (2.32), an enclosed space for lubrication is formed, which, when the threaded connection is finally fixed with an interference fit, moves along the contacting surfaces, preventing seizures and jamming. A conical groove (2.10) is made on the inner surface of the end of the pipe at an angle β ₂ = 4-8 ° to ensure equal passage of the inner surface of the threaded connection (Fig. 9).

The operation of the threaded coupling of oilfield pipes, mainly casing, is as follows. A phosphate-coated sleeve is used to assemble the joint, and a threaded sealing lubricant is applied to the threaded end of the pipe to facilitate the assembly process and to prevent scuffing and seizing.

When assembling the connection, the pipe (2) and the coupling (1) are first screwed together using a tapered thread. During make-up, the conical smooth sealing surfaces (1.3) and (2.3) move together. As a result of diametrical deformations of these surfaces, a sealing sealing unit is created by the metal-to-metal method. With further relative movement of the pipe (2) and the coupling (1), the conical contact surfaces of the pipe (2.32) and the coupling are force contacted, as a result of which contact stresses arise on their surfaces, the value of which is determined by the value of the contacting surface areas (1.31) and (2.32) . The end of the assembly process of the coupling coupling (1) and pipe (2) is accompanied by the interaction of their thrust surfaces (1.31) and (2.32). The conical surfaces (1.31) and (2.32) are made in such a way that when they are subjected to the axial force that occurs when the pipe and the coupling are screwed, the radial component of this force is directed to the connection axis. This makes the joint less critical to exceeding the make-up torque and increases its operational reliability. This is especially important when assembling threaded joints in drilling rigs, where it is difficult to regulate the torque when making up the pipe with the coupling.

The implementation on the pipe and coupling of cylindrical grooves and grooves forming an annular cavity, eliminates the effect of scoring that occur during threading during removal of the thread-forming tool. As a result, when screwing a threaded joint, the sections of the thread exit are located in the groove and grooves, which excludes the influence of the thread surface on the run-off section on the accuracy of the interaction between the sealing surfaces of the pipe and coupling.

The execution on the inner surface of the pipe end of the conical groove at an angle β ₂ as a result of the assembly of the threaded joint prevents the turbulence of the gas flow from appearing at the junction of the pipe end with the sleeve, which eliminates metal erosion for this reason.

The value of the angle β ₂ = 4-8 ° is selected constructively to ensure equidistance of the inner surface of the threaded connection.

Before assembling the factory connection of pipes with couplings, the latter were phosphated according to the technological instruction. Before assembling the factory connection, Rusma 1 sealing grease was applied to the threaded ends of the pipes in accordance with the recommendations of API RSAЗ. This improves the assembly process of pipes with couplings and avoids scuffing and jamming, as well as jamming. In addition, the sealing grease protects the threaded joint from corrosion.

Then casing pipes with couplings were subjected to hydraulic testing on a hydraulic press, developing a maximum pressure of 1400 atm. The fluid pressure during hydraulic testing was determined depending on the size of the pipes (Dt × St) and the grade of steel.

A threaded joint increases operational reliability by increasing strength and increasing tightness when using oilfield pipes for oil and gas production from great depths in difficult geological conditions.

Claims (4)

1. Socket threaded pipe connection, including a sleeve, on the inner surface of which, starting from the ends, there are two threaded sections with a smooth locking sealing part between them and two coaxially located pipe ends, on the outer surface of which, starting from the end in the direction of the main body of the pipe sequentially located smooth locking sealing part, which comes into contact with the smooth locking sealing part of the coupling, while the smooth locking parts of the pipe and coupling are made in the form of two joined sealing and thrust conical surfaces with different tapers, located on the pipes between the threaded section and the pipe end, and on the coupling - between the threaded section and the coupling body, and the threaded section that comes into contact with the threaded section of the coupling, and on the threaded sections of the pipes and coupling made conical trapezoidal thread with a taper of 1:16 and a pitch of 5.08 mm with different angles of inclination of the support and guide surfaces of the thread profile relative to the line perpendicular to the axis of the thread, characterized in that the conical trapezoidal thread of pipes and couplings is made with a negative angle of inclination of the support surface of the thread profile equal to 3 ° 30'-11 ° 30 'and a positive angle of inclination of the guide surface of the thread profile equal to 10 ° 30'-18 ° 30' on the outer surface of the pipe between a threaded section and a smooth locking part made a cylindrical groove parallel to the axis of the pipe, with a diameter equal to the diameter along the bottom of the cavity of the conical trapezoidal thread in the plane of intersection of the conical trapezoidal thread with a cylindrical groove and a length of 5-12 mm, on light on the internal surface of the coupling between the threaded portion and a smooth cylindrical locking part is formed a bore parallel to the axis of the coupling, the length corresponding to the length of the cylindrical groove on the pipe, and the cylindrical bore in the coupling forms an annular groove with inclined side surfaces at an angle of 25-35 ° to the line perpendicular to the axis of the coupling, with a diameter along the bottom of the groove by 0.1- 1.5 mm of the diameter of the thread depression of the coupling in the plane of the intersection of the thread with the groove, while after assembling the threaded connection with an interference fit, the cylindrical groove on the pipe and the cylindrical groove in the coupling form an annular cavity, which is a gy ravlichesky the shutter to capture the seal lubrication. 2. The sleeve threaded pipe joint according to claim 1, characterized in that the taper angles of the sealing surfaces of the smooth locking parts of the pipe and the coupling in contact with each other during assembly of the threaded joint are 15-25 ° relative to the joint axis, and the mating radius between the sealing surface is smooth the castle part of the pipe and the cylindrical groove is made equal to 3-6 mm. 3. Socket threaded pipe connection according to any one of paragraphs. 1 or 2, characterized in that the taper angles of the thrust surfaces of the smooth locking sealing parts of the pipes and the coupling in contact with each other when assembling the threaded connection are 12-18 ° relative to the line perpendicular to the axis of the threaded connection, and a conical bore is made on the inner surface of the ends of the pipes with a taper angle of 4-8 ° relative to the axis of the pipe in the direction of its end.

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