RU162301U1 - THREADED CONNECTION WITH TAPED EXTENDED MULTI-THREADED THREAD - Google Patents

Abstract

1. A threaded connection with a tapered elongated thread, comprising a female element having an internal thread, and a male element having at the end a corresponding external tapered thread with a constant angle of inclination φ of the forming cone along the hollows of the thread along the entire length L (without running), and sequentially a threaded groove located behind it to exit the thread-forming tool, characterized in that the tapered elongated thread is multi-thread, and the nominal width of the threaded groove is calculated by formula is: l = 2P + b, where: l- zarezbovoy groove width; Ρ - thread pitch; b - the width of the sizing tooth of the top thread to the trapezoidal profile or tooth width sizing of the middle line of the thread of the triangular profilya.2. Connection according to claim 1, characterized in that the tolerances for the width of the grooves are set within up to plus 5.0 mm. 3. Connection according to claim 1, characterized in that the elongated conical thread has a triangular profile. Connection according to claim 1, characterized in that the elongated conical thread has a trapezoidal profile. Connection according to claim 1, characterized in that the elongated conical thread has radial and end sealing elements. Connection according to claim 1, characterized in that the bottom of the threaded groove is cylindrical. 7. Connection according to claim 1, characterized in that the bottom of the threaded groove is tapered at an angle equal to the slope of the generatrix of the thread depression φ.

Description

The utility model relates to pipe production, namely to the production of oil assortment pipes, for example, tubing and casing, with threaded conical joints of a triangular and trapezoidal profile, including with sealing elements designed for oil and gas production, as well as for well construction .

Known designs of tubing (tubing) and casing (OT) with a conical triangular (rounded) or trapezoidal thread cut at their ends (outer) and in the couplings (inner), as well as threads with radial and end sealing elements (GOST 633-80 "Tubing and couplings for them. Technical conditions" p. 2.13.1, p. 2.13.2, p. 2.14.1, and p. 2.14.2, drawing 5, drawing 6, drawing .9, drawing 10, GOST 632-80 "Casing pipes and couplings to them. Technical conditions" p. 2.13.1, p. 2.13.2, p. 2.14.1, p. 2.14.2, p. 2.15. 1, p. 2.15.2, drawing 5, drawing 6, drawing 8, drawing 9, drawing .12; “API 5 B Standard of Technical Requirements, 15th edition,“ Requirements for cutting, calibration and thread control of casing, tubing and tubing ”, Fig. 3, Fig. 4, Fig. 5, Fig. 6 , Fig. 8, Fig. 9, tables: No. 6, No. 9, No. 12, No. 13).

In the design of these connections, a single-start external conical thread of a triangular or trapezoidal profile with a slope angle φ of the generatrix of the cavity from the pipe end to the run, which corresponds to a taper (K) of 1/16, is made. Then, the slope angle of the generatrix of the troughs of the thread increases to a value of φ ₁ in the thread run-away section.

The disadvantages of the described threaded connections include:

- reduced permissible axial load of the thread (up to 30%) compared with the pipe body,

- low wear resistance of threads, especially for tubing, which during operation are screwed and unscrewed many times,

- seizure of threads at the beginning of make-up,

- low productivity when assembling pipes in a column.

Known threaded connection of tubing [US Pat. RF №125289, publ. 02/27/2013], having on the direct male element and female element, respectively, the external and internal conical threads of a triangular profile, made multiple-thread with a thread, which is determined from the expression T = n · Pmm.

Using the utility model allows to increase the speed of make-up - unscrewing the threaded connection during assembly-disassembly of pipes in the column. However, disadvantages remain associated with a decrease in axial loads and low wear resistance of the thread.

Closest to the claimed utility model in technical essence (prototype) is a pipe connection with a tapered elongated thread of a triangular profile [Pat. RF №2386072 publ. 04/10/2010], comprising a female element (sleeve) having an internal thread and a male element (pipe) having at the end a corresponding external conical thread and a consecutively located indicator of the relative position of the pipe and sleeve made in the form of a threaded groove. At the same time, at the end of the covered element (pipe), an external conical thread of a triangular profile of an increased length L is made with a constant slope angle φ of the forming cone along the hollows of the thread along the entire length (without runoff), and a threaded cylindrical groove with a width is made at a distance L from the pipe end l _n to exit threading tools, which also serves as an indicator of the relative position of the pipes and couplings, with the bottom diameter D _n, the length of the female element (clutch) L _m increased with the length of the male thread lementa L, wherein the threaded pipe end enters into the sleeve without rotating for at least six thread on its end, while the sleeve has an inner end lead-in chamfer situated at an angle (β) of 65 ° -70 ° to the end face of the sleeve with a diameter d ₀ in plane end faces of the coupling.

The invention provides an increase in the permissible axial load on “stragging”, an increase in the quality of assembly of pipes into the string, using only a triangular profile thread and the disadvantages associated with the low speed of assembly-disassembly of pipes into the string.

The objective of this utility model is to increase the assembly speed of tubing and casing with elongated tapered threads of a triangular or trapezoidal profile, including those with radial and end sealing elements, to increase the service life, to improve the conditions and quality of assembly of threaded joints.

The technical result is to reduce the time of screwing-unscrewing pipes and increase productivity when performing hoisting operations in the fields, improve the conditions and quality of assembly, as well as increase the service life of oil grade pipes with elongated tapered triangular and trapezoidal threads, including radial and end sealing elements.

The problem is solved due to the fact that in a threaded connection with a tapered elongated thread of a triangular or trapezoidal profile, incl. with radial and end sealing elements containing a female element (sleeve) having an internal thread and a male element (pipe) having at the end a corresponding external conical thread with a constant slope angle φ of the forming cone along the hollows of the thread threads along the entire length L (without running) and sequentially located behind it by a threaded groove for the exit of the thread-forming tool, according to a utility model, a multi-pass con is executed at the end of the male element (pipe) and in the female element (sleeve) Ceska triangular thread or trapezoidal profile, and the width of the groove zarezbovoy, calculated from design features of threading tools, used for thread cutting, according to the formula:

ln = 2З + b, where:

ln is the width of the threaded groove;

P is the thread pitch;

b is the width of the calibrating tooth at the apex for the threads of the trapezoidal profile or the width of the calibrating tooth along the midline of the thread of the triangular profile;

the bottom of the threaded groove can be cylindrical or conical at an angle equal to the slope of the generatrix of the thread depression φ, and the permissible deviation to the width of the threaded groove l _{n is} set to plus 5.0 mm.

The essence of the utility model is illustrated by the following drawings.

FIG. 1 - conical threaded connection with multi-start elongated thread of a triangular profile assembly.

FIG. 2 - conical threaded connection with multi-start elongated thread of trapezoidal profile with radial and mechanical seals by elements assembled.

FIG. 3 is a view of a threaded cylindrical groove.

FIG. 4 is a view of a threaded conical groove.

In FIG. 1 pipe (male element) pos. 1 assembled with a sleeve (female element) pos. 2, interconnected by an elongated multi-thread conical thread of a triangular or trapezoidal profile pos. 3. At the end of the thread on the pipe pos. 1 (Fig. 1) at a distance L from the end of the pipe, a threaded groove with a nominal width l _{n was made} . The position of the end face of the coupling relative to the beginning of the threaded groove corresponds to the screwing of the pipe with the coupling during machine screwing with the nominal parameters of the thread of the pipes and couplings.

In FIG. 2 pipe (male element) pos. 1 assembly with a sleeve (female element) pos. 2, interconnected by an elongated multi-start tapered thread of a trapezoidal profile pos. 3, with a radial pos. 4 and end pos. 5 sealing elements. At the end of the thread on the pipe pos. 1 (Fig. 2) at a distance L from the end of the pipe, a threaded groove with a nominal width l _{n was made} . The position of the end face of the coupling relative to the beginning of the threaded grooves corresponds to screwing the pipe with the coupling during machine screwing until the sealing end of the pipe comes into contact with the sealing stop of the coupling.

In FIG. 3 shows a view A with a cylindrical threaded groove, pos. 6.

In FIG. 4 is a view A with a conical threaded groove in pos. 7 with a slope angle φ of the bottom of the groove equal to the slope angle of the generatrix of the thread depression.

Work performed on the manufacture and screwing up, unscrewing prototypes of tubing and casing with conical multi-thread threads of a triangular and trapezoidal profile, including with radial and end sealing elements, and grooves behind the thread, made cylindrical or conical (at an angle equal to the slope angle φ of the forming thread depression), at a distance L from the pipe end face, with a nominal width l _n calculated by the formula ln = 2P + b, s a tolerance of plus 5 (five) mm, showed the possibility of using the proposed solutions of the utility model in the production of tubing and casing pipes intended for the construction and operation of wells for the purpose of oil and gas production.

The application of the claimed utility model in the production of oil assortment pipes, for example tubing and casing with threads of a triangular and trapezoidal profile, including radial and end sealing elements, allows you to:

- increase the speed of assembly, disassembly of threaded joints, thereby reducing the time of screwing-unscrewing pipes and increase productivity when performing tripping operations in the fields, because the speed of screwing-unscrewing of multi-thread threads is proportional to the number of thread starts, for example, with double thread, the speed of screwing-unscrewing of threaded joints doubles;

- to improve the quality of the assembly due to more favorable conditions for centering the external thread of the pipes relative to the internal thread of the couplings at the beginning of make-up (“bait”) due to the presence of several approaches and minimizing the likelihood of distortions of the thread of a triangular and trapezoidal profile;

- to increase the service life of threaded joints by reducing the multiplicity of mating surfaces of the thread elements and radial sealing elements in the process of making multi-thread threads of triangular and trapezoidal profiles.

- due to the fulfillment of a cylindrical or conical groove behind a tapered elongated multi-thread, at an angle equal to the slope angle s of the forming thread depression at a distance L from the pipe end face, with a nominal width l _n calculated by the formula ln = 2P + b, the thread-forming tool for cutting multiple-thread is provided carvings.

Claims (7)

1. A threaded connection with a tapered elongated thread, comprising a female element having an internal thread, and a male element having at the end a corresponding external tapered thread with a constant angle of inclination φ of the forming cone along the hollows of the thread along the entire length L (without running), and sequentially a threaded groove located behind it to exit the thread-forming tool, characterized in that the tapered elongated thread is multi-thread, and the nominal width of the threaded groove is calculated by formula is: l _n = 2P + b, where: l _n is the width of the threaded groove; Ρ - thread pitch; b is the width of the calibrating tooth at the apex for the threads of the trapezoidal profile or the width of the calibrating tooth along the midline of the thread of the triangular profile. 2. The connection according to claim 1, characterized in that the tolerances for the width of the grooves are set within up to plus 5.0 mm. 3. The compound according to claim 1, characterized in that the elongated conical thread has a triangular profile. 4. The compound according to claim 1, characterized in that the elongated conical thread has a trapezoidal profile. 5. The connection according to claim 1, characterized in that the tapered elongated thread has radial and end sealing elements. 6. The connection according to claim 1, characterized in that the bottom of the threaded groove is cylindrical. 7. The connection according to claim 1, characterized in that the bottom of the threaded groove is tapered at an angle equal to the slope angle of the thread cavity φ.

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