RU2208123C2 - Protector for drill pipe with welded tool joint and method of protector installation - Google Patents

Abstract

FIELD: oil and gas producing industry particularly, device and method of protection of drill pipe surface from wear. SUBSTANCE: protector has nondetachable body from rigid material and provided with longitudinal hole for fitting on pipe with diametrical clearance accommodating member fastening protector body to pipe surface. In this case longitudinal hole in protector body is made with minimal diametrical size which is larger than outer diameter of pipe end upset for welding tool joint part but smaller than outer diameter of welded tool joint part. Method of protector installation on drill pipe includes fitting of protector body on pipe and its subsequent fastening to pipe in required position. In so doing, protector body is fitted on pipe in course of pipe manufacture before welding to pipe end of the second tool joint part. Fastening of protector body to pipe is accomplished by filling of circular clearance between them with melt of circular clearance between them with melt and by its hardening. EFFECT: extended process potentialities and increased reliability of protector. 2 cl, 3 dwg

Description

 The proposed technical solution relates to the field of protecting the surface of drill pipes from wear and can be used in the oil and gas industry when drilling wells.

Known elastic protectors for drill pipes made in the form of an integral body having a longitudinal hole for putting on the pipe, the diameter of which is smaller than the outer diameter of the pipe in the place of its fastening (see, for example, GOST 6365-74. Rubber rings for drill pipes. Technical conditions. )
The tread is worn on the finished pipe with locks, for which its inner hole is forced to expand to ensure the passage of the locking part at the pipe end, the diameter of which is much larger than the diameter of the pipe body. The tread is fixed on the pipe surface due to the friction forces arising between the latter and the tread that is put on it with a diametric interference, creating contact pressure.

 The disadvantage of these protectors is the need to use for their manufacture only highly elastic materials that do not have the necessary wear resistance, especially when drilling abrasive rocks in an open hole. Another disadvantage is the low adhesion strength of the tread to the pipe, limited by the elastic and strength properties of the tread material.

Closest to the claimed technical essence is a tread containing a one-piece body made of rigid (inelastic) material, having a longitudinal hole for putting on with a diametrical clearance on the pipe, and an element for securing the housing on the pipe surface located in the specified gap (see, for example, p. 1687762, MKI ⁵ E 21 V 17/10. Tread for drill pipe). Mounting of the tread is carried out by putting on its body on a finally manufactured pipe with locking parts at the ends. For this, the longitudinal hole in the tread housing is made with a diametric size exceeding the outer diameter of the locking part. The tread body is secured to the pipe due to friction forces from mechanical pressures created by eccentric bushings inserted into the diametrical clearance.

 The disadvantage of this tread is its limited technological capabilities, due to the impossibility of the necessary reduction of its outer diameter due to the restrictions imposed by the minimum diametrical size of its longitudinal hole. Another disadvantage is its low operational reliability, due to the mechanical nature of the mounting of the tread housing on the pipe.

 The aim of the invention is the expansion of technological capabilities and increase the operational reliability of the tread.

 The essence of the invention lies in the fact that the longitudinal axial hole in an integral tread housing made of rigid (inelastic) material is made with the smallest diametric size, which is smaller than the outer diameter of the locking part, but larger than the upset diameter at the end of the pipe for welding the locking part. This allows, if necessary, to reduce the outer diameter of the housing to the diameter of the locking part and lower, and thereby expand the technological capabilities of the use of the tread.

 The possibility of mounting on the pipe a tread body having a reduced diametrical size of the axial hole is provided by the proposed method, which involves putting it on the pipe during its production until the second (last) locking part is welded to its end. After welding, the longitudinal movement of the body can occur only within the pipe between the locking parts at its ends.

 As one of the possible methods, a method is proposed for securing a tread body worn on a pipe by feeding a melt (for example, one of cast aluminum alloys) into the diametrical gap between it and the outer surface of the pipe and its subsequent solidification. In this case, the connection of the intermediate layer formed with the surface of the pipe is due to the adhesion forces and contact stresses arising during the cast shrinkage of the melt, and the connection with the body is mainly due to the geometry of the longitudinal hole, which may have, for example, an oval or square section, and also adhesion forces. The casing can be fixed both before and after welding to the pipe of the second locking part.

 In general, the design of the tread and the method of its installation increase its operational reliability, since they exclude the possibility of any emergency situations in case of destruction of the fastener.

 The drawing shows the elements of the pipe and tread and the basic operations for its installation for the case of fixing the tread body to the pipe after welding to it a second locking part.

The tread housing 1 (a) has a longitudinal hole with the smallest diametrical dimension d ₁ . The pipe 3 has upset ends 2, one of which can be welded lock part 4. The free upset end of the pipe has an outer diameter d ₁ . The locking part has an outer diameter of d ₂ . The smallest diametrical dimension d _{2 of the} longitudinal hole in the tread body is larger than the diameter of the upset pipe end, but smaller than the outer diameter d _{3 of the} locking part.

 During installation, the tread body 1 is put on the pipe by longitudinal movement along it, starting from the upset end (b). In this case, between the surfaces of the pipe and the opening of the housing, a diametrical gap 5 is formed.

 Further, depending on the capabilities of the technological equipment, either the second locking part 6 (c) can be welded together with related operations (removal of burr, heat treatment of the seam) and subsequent fastening of the tread body to the pipe, or vice versa. When fixing, the body is positioned on the pipe, it is equipped with the necessary removable technological equipment and the gap is filled with melt 7. The melt is solidified by heat removal to the mass of the pipe and the tread body or by using additional forced cooling.

 The wear resistance parameters of the outer surface of the housing can, if necessary, be adjusted by known methods (material selection, hardfacing, gumming, installation of additional elements, etc.).

Claims (2)

 1. A protector for a drill pipe with welded locks, comprising an integral body made of rigid material, having a longitudinal hole for putting on with a diametrical clearance on the pipe, and an element for securing the housing on the pipe surface located in the specified gap, characterized in that the longitudinal hole in the tread body is made with the smallest diametrical size, which is larger than the outer diameter of the upset at the end of the pipe for welding of the locking part, but smaller than the outer diameter of the welded locking part.  2. A method of mounting a tread on a pipe, including putting the tread body on the pipe and securing it to it in the required position, characterized in that the tread body is put on the pipe during production until the second locking part is welded to its end, and secured to the pipe is produced by filling the annular gap between them with the melt and its solidification.