OA20878A - Elliptical design for male thread clearance - Google Patents

Abstract

A drill string comprising: an elongate hollow main length section (101); a male spigot portion ( 108) provided at the second end ( 106) having an externally threaded section (107) and a non-threaded shank (109) positioned axially intermediate the main length section (101) and the threaded section (107); the shank (109) having a transition section (206) positioned adjacent the main length section (101) or a radially projecting shoulder (110) at the second end (106), the transition section (206); wherein the cross-sectional shape profile of the outer surface of the transition section (206) in the plane of the longitudinal axis (204) comprises a segment of an ellipse having semi-major axis (a); a semi-minor axis (b) wherein the ratio of the semi-major to semi-minor axes (a:b) is within the range 2b˂a˂8b.

Description

Elliptical design for male thread clearance

Field of invention

The present invention relates to a drill string rod to form part of a drill string having a male 5 spigot portion provided at one end of the rod and in particular, although not exclusively, to a spigot portion having a threaded section and a non-threaded shank configured to minimise stress concentrations.

Background art

Percussion drilling is used to create a long borehole via a plurality of elongate drill string rods coupled together end-to-end by interconnected male and female threaded ends. The well-established technique breaks rock by hammering impacts transferred from the rock drill bit, mounted at one end of the drill string, to the rock at the bottom of the borehole.

Typically, the energy required to break the rock is generated by a hydraulically driven piston that contacts the end of the drill string (via a shank adapter) to create a stress (or shock) wave that propagates through the drill string and ultîmately to the base rock level.

Conventional male and female threaded couplings are described in US 4,332,502; US 20 4,398,756; US 1,926,925; US 5,169,183; EP 1705415; GB 2321073 and US 4,687,368.

When the male and female threaded ends of neighbouring drill rods are coupled to create the drill string, the joint is typically subjected to bending moment during drilling. These bending moments fatigue the coupling and may lead to breakage within the threaded portion of the joint. Typically, it is the threaded male spigot that is damaged and détermines the operational lifetime of the coupling.

In particular, the transition between the different diameters of the threaded male spigot and the main length of the drill rod (or an annular shoulder at the rod end required for ‘shoulder contact’ couplings) provides a région for potentially high stress concentrations due to bending moments and tensile loads. Conventionally, the outside diameter of the rod at the transition axially between the threaded male spigot and the main length or shoulder

is flared radially outward with a curved shape profile having a single radius curvature that is as large as can be accommodated between the two régions. However, for a typical threaded coupling stressed by 200 MPa in tension, the transition région reaches a stress level of approximately 300 MPa. Fatigue and possible breakage are therefore very likely, 5 and the multiple threaded couplîngs represents a significantly weaker région of the drill string. Drill rods are typically replaced periodically according to their predetermined lifetime to try and avoid fracture of the male spigot during use which would cause significant disruption to a drilling operation. EP2845991 discloses a design to reduce i stress in this région wherein the outside diameter of the rod axially between the threaded 10 male spigot and the main length or shoulder is flared radially outward with a curved shape profile having a double radius curvature, however the level of stress in the transition région is still higher than desired. There is therefore a need for a drill rod that addresses these problems.

Summarv of the Invention

It is an objective of the présent invention to provide a drill string rod having a male threaded coupling part that is optimised to minimise the lîkelîhood of stress concentrations at the transition région between the end of the main length section of the rod and the spigot 20 to extend the operational lifetime of the rod and minimise fatigue and the risk of breakage in use. It is a further spécifie objective to provide a drill rod that is compatible with existing drilling apparatus and methods that comprises an enhanced capacity to withstand large bending moments and tensile loads.

The objectives are achieved by specifically configurîng a transition région positioned axially at the interface with the end of the main length section, or an annular shoulder at the end of the main lengfh section. The présent invention provides a drill rod coupling that exhibits reduced stress concentrations compared to known designs at the junction of the male spigot with the main length section résultant from incident bending moments or tensile loads.

-3According to a first aspect of the présent invention there is provide a drill string rod to form a part of a drill string, the rod comprising: an elongate hollow main length section extending axially between a first end and a second end; a male spigot portion provided at the second end having an externally threaded section and a non-threaded shank positioned axially intermediate the main length section and the threaded section; the shank having a transition section positioned adjacent the main length section or a radially projecting shoulder at the second end, the transition section having an outside diameter that increases in a direction from the spigot portion to the main length section or the shoulder; wherein the cross section shape profile of the outer surface of the transition section in the plane of the longitudinal axis comprises a segment of an ellipse having semi-major axîs (a); a semiminor axis (b) and an exponential factor (n) according to the équation:

characterised in that the ratio of the semi-major to semi-minor axes (a:b) is within the range 2b<a<8b.

Advantageously, this provides a male coupling end exhibiting enhanced stiffness and that is more résilient to bending moments and tensile forces. The transition section is configured to eliminate or at least minimise stress concentrations at the section where spigot projects axially from shoulder. If the ratio of the lengths of the semi-major to semiminor axes are above or below this the stress concentrations increase. Consequently, the risk of breakage is reduced and so the operation lifetime of the rod is increased. Optionally, the transition section may also comprise segments wherein the shape profile is straight and / or different curved profile.

Optionally, the non-threaded shank is divided axially into a straight part, positioned axially closest to threaded section, and a curved transition section, positioned axially closest to the side surface. It may be advantageous to increase the distance between the shoulder and threaded part. In this case it will be bénéficiai to include a straight section as well.

Altematively, the non-threaded shank has only a curved transition section extending ail the way from the side surface to the threaded section. When the non-threaded shank is shorter

it is advantageous that there is only a curved transition section, i.e. no straight section, as this aids in keeping the stress concentration as low as possible.

Preferably, the ratio of the semi-major to semi-minor axes (a:b) is within the range

2.5b<a<6b. Advantageously, within the narrowed ratio range the stress concentrations at the section where the spigot projects axially from the shoulder are further reduced meaning that there is enhanced capacity to withstand large bending moments and tensile stresses.

Preferably, the semi-minor axis (b) is proportionate to the dimension ofthe threaded ' section according to the following équation:

wherein Di is the diameter of the threaded section between opposing troughs and Dy is the diameter of the threaded section between opposing helical ridges. Advantageously, the length of the semi-major axis (b) is as large as possible, as this provides an elliptical shape with no sharp ends and therefore having the lowest stress concentration. However, if the length of the semi-major (b) is too high, there would effectively be no shoulder and so energy cannot be transferred effectively between the male and female ends, which would resuit in the female end of the rod breaking.

Preferably, the exponential factor (n) is in the range 1 < n < 3. Advantageously, this provides a transition section having an elliptical profile with the lowest stress concentration.

Optionally, a vertex of the ellipse is positioned at a tangent with the annular side surface of 25 the shoulder. Altematively, the vertex of the ellipse undercuts the annular side surface of the shoulder. Different load cases may benefit from different forms ofthe ellipse.

Optionally, the x-axis of the ellipse îs parallel to the longitudinal axis. Altematively, the xaxis of the ellipse is tilted with respect to the longitudinal axis. Different load cases may 30 benefit from different forms of the ellipse.

Optionally, the profile of the outer surface of the transition section in the plane of the longitudinal axis comprises a quarter segment of an ellipse. Alternatively, the crosssectional shape profile of the outer surface of the transition section in the plane of the longitudinal axis comprises greater than a quarter segment of an ellipse. Alternatively, the 5 cross-sectional shape profile of the outer surface of the transition section in the plane of the longitudinal axis comprises a less than quarter segment of an ellipse. Different load cases may benefit from different forms of the ellipse.

Within the spécification, reference to ‘curvature' encompasses a smooth or graduai change 10 in surface profile and a plurality of sequential linear increases (or decreases) in diameter that collectively may be regarded as a ‘curved’ shape profile. For example, the term 'curvature' encompasses relatively small linear step changes such that an edge or middle région of each step may be considered to collectively define a curve.

Preferably, the rod comprises a shoulder projecting radially from the main length section wherein an outside diameter of the shoulder is greater than an outside diameter of the main length section and the transition section of the shank. Such a configuration allows for the conventional 'shoulder contact' coupling between the male spigot and the female sleeve that is preferred over the alternative ‘bottom contact' due to the larger diameter and surface 20 area contact between the rod ends at the région of the male and female parts.

Preferably, a side surface of the shoulder that is in contact with the transition section comprises an annular radially outer région that is aligned substantially perpendicular to the longitudinal axis. The curved transition section therefore does not continue over the full 25 radial length of the annular side surface to provide a fiat annular surface for contact by the annular end face of the female sleeve.

Optionally, the threaded section comprises at least one axially extending helical ridge and groove, wherein an outside diameter of the shank axially between the threaded section and 30 the transition section is substantially equal to an outside diameter of the threaded section at an axial and a radial position corresponding to the ridge of the threaded section.

Optionally, the threaded section comprises a plurality of threads formed as a double or

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triple hélix etc. Such configurations can be selected to achieve a desired threaded profile having desired mechanical and physical properties.

Optionally, a cross sectional area of the shank is at least equal to a cross sectional area of 5 the main length section in a plane perpendicular to the longitudinal axis over a full axial length of the shank between the threaded section and the main length section or the shoulder. Optionally, the diameter of the threaded section is siightly smaller than the diameter of the main length section. Accordingly, the shank is configured to be robust during bending moments and tensîle loads and to avoid création of stress concentrations 10 résultant from changes in diameter along the length of the rod.

Preferably, the first end comprises a female hollow portion having an internai threaded section to engage with the threaded section of the male spigot portion of a neighbouring rod of the drilI string. Preferably, an internai diameter of the threaded section of the female 15 portion is substantîally equal to an outside diameter of the main length section. The present coupling therefore provides a région that is enlarged in diameter and cross-sectional area (perpendicular to the longitudinal axis of the rod) relative to the elongate hollow main length section.

According to a second aspect of the present invention there is provided a drill string comprising a drill string rod as claimed herein.

Brief description of drawings

A spécifie implémentation of the present invention will now be described, by way of example only, and with reference to the accompanying drawings in which:

Figure 1 is an external view of a drill string formed from a pluraiity of elongate drill rods connected end-to-end by cooperating male and female threaded couplings according to a 30 spécifie implémentation of the present invention;

Figure 2 îs an external side view of the drill rod end of Figure 1 at the région of the male coupling according to a spécifie implémentation of the présent invention wherein the nonthreaded shank îs dîvided axially into a straight part and a curved transition section;

Figure 3 îs an external side view of the drill rod end of Figure 1 at the région of the male coupling according to an alternative implémentation of the présent invention wherein the non-threaded shank has only a curved transition section;

Figure 4 is a magnified view of a shank part of the male coupling according to one 10 embodiment of the invention wherein the vertex of the elliptical profile of the transition section is at a tangent to the shoulder;

Figure 5 is a magnified view of a shank part of the male coupling according to an alternative embodiment of the invention wherein the elliptical profile of the transition 15 section undercuts the annular side surface of the shoulder.

Figure 6 is a magnified view of a shank part of the male coupling according to an alternative embodiment of the invention wherein the elliptical profile of the transition section is tilted.

Figures 7a-g are safety factor images comparing the prior art (fig. 7a) to different embodiments of the invention (figs. 7b-g)

Detailed description of preferred embodiment of the invention 25

Referrîng to figure 1, a drill string comprises a plurality of interconnected drill string rods 100. Each rod 100 comprises a main length section 101 having a first end 105 and a second end 106. An outside diameter of the main length section 101 increases at each end 105, 106 to form a radially flared end coupling région 103, 104 respectively. A part of 30 each coupling région 103, 104 comprises a threaded portion to allow the régions 103, 104 to engage one another and form a secure threaded coupling 102 to interconnect a plurality of rods 100 to form the drill string. In particular, the male end 103 comprises an annular

-8shoulder 110 from which projects axially a male spigot 108. A spigot 108 is divided axially into an endmost threaded section 107 and a non-threaded shank 109 positioned axially intermediate threaded section 107 and the shoulder 110. An internai bore 113 extends axially through the main length section 101 and the spigot 108 of uniform internai diameter. The female end 104 comprises a hollow sleeve 111 having cooperating threads 112 formed at the internai surface of the sleeve 111 so as to cooperate with the threaded turns of the male threaded section 107. When the male and female ends 103, 104 are coupled, an axially endmost annular surface 115 ofthe female sleeve 111 abuts against the shoulder 110 such that an annular end face 114 of the male spigot 108 is housed fully within the sleeve 111.

Referring to Figure 2, the tubular main length section 101 comprises a cylindrîcal external surface 200 that is flared radially outward at the shoulder 110 to provide an annular concave région 201 that terminâtes at a cylindrîcal surface 202 located at the shoulder 110. A diameter and cross-sectional area of the surface 202 in a plane perpendicular to the axis 204 is accordingly greater than a corresponding diameter or cross-sectional area (in a parallel plane) of the main length surface 200. The shoulder 110, in particular the cylindrîcal surface 202 is terminated at the spigot side by an annular side surface 203 aligned perpendicular to the axis 204. The spigot 108 projects axially from a radially inward région of the surface 203 and is alîgned coaxial with the main length section 101 and the annular shoulder 110. As illustrated in Figure 1, the spigot 108 comprises a generally tubular configuration such that an internai diameter of the bore within the spigot 108 is equal to the internai diameter of the bore 113 extending through the main length section 101.

The threaded section 107, according to the spécifie implémentation, comprises a pair of helical tums 209 that extend axially front shank 109 to spigot end 114. In particular, a pair of helical ridges 207 and troughs 208 extend axially over section 107.

Figure 2 shows the non-threaded shank 109 may be divided axially into a straight section 205, positioned axially closest to threaded section 107, and a curved transition section 206, positioned axially closest to the side surface 203. An external surface of straîght section

-9205 is substantially parailel to axis 204 whilst the external surface of transition section 206 tapers radially outward in a direction from the threaded section 107 to contact against the annular side surface 203. A combined axial length of the straîght parts 205 and the transition section 206 could be equal to, greater than or less than an axial length of shoulder surface 202 but less than an axial length of threaded section 107. Accordingly, a diameter or cross-sectional area ofthe straîght section 205 is less than a diameter or crosssectional area of the transition section 206. Additionally, a diameter or cross-sectional area of the straîght part 205 is approximately equal to a diameter or cross-sectional area of the threaded section 107 at an axial and radial position correspondîng to the radially outermost part of peak 207.

Figure 3 shows that altematively, the non-threaded shank 109 may hâve only a curved transition section 206 extending ail the way from the side surface 203 to the threaded section 107. in other words, there could be no straîght length part 205.

Referring to figures 2 and 3, the transition section 206 may be considered a transition région between spîgot 108 and the annular shoulder 110. As illustrated in Figures 2 and 3, the transition section 206 încreases in diameter and cross-sectional area from threaded section 107 to the shoulder 110, such that the extemal surface profile of the transition section 206 in a plane along axis 204 is curved according to a graduai curvature having a profile correspondîng to quarter segment of a perimeter of an ellipse 214, or slightly more or slightly less than a quarter segment of an ellipse 214. The ellipse 214 has a semi-major axis (x) and a semi-minor axis (y). Preferably, there is no abrupt change along the length of the transition section 206 from a first radius to a second radius, instead there is a continuous and gradua] change in the radius along the length ofthe transition section 206. Optionally, the transition section 206 may also comprise segments wherein the shape profile is straîght and / or has a different curved profile, which could be posîtioned at eîther end ofthe elliptical profile or as an interruption part way along the elliptical profile.

The équation of an ellipse is defined by a Lamé curve when n=2:

-10Wherein:

x is the co-ordinate on the x axis;

y is the co-ordinate on the y axis;

a is the semi-major axis (x);

b is the semi-minor axis (y);

n détermines the shape of the curve. n=2 defines an ordînary ellipse. n<2 a hypoellipse and n>2 a hyperellipse.

The elliptical profile 214 is shown on expanded view of the transition section 206 in Figure 4.

In the présent invention the ratio of the major to minor axes, (a: b) is within the range 2b<a<8b, preferably, 2b<a<6b, more preferably 2.5b<a<6b, even more preferably 2.5b<a<5.75b.

Preferably, the semi-minor axis (b) is as large as possible. More preferably the semi-minor axis (b) is proportionate to the diameter of the threaded section 107 of the male spigot portion 108 according to the following équation:

Wherein (as shown on Figure 4):

Di = diameter of the threaded section 107 between opposing troughs 208;

Dy = diameter of the threaded section 107 between opposing helical ridges 207.

Preferably, the exponential factor n is in the range 1 < n < 3, preferably 1.8 < n < 2.2, most preferably 2.

The équation ofthe elliptical profile ofthe transition section 206 can be measured using a contour measuring machine. The contour measuring machine drags a needle over the surface ofthe transition section 206, then the equipment will try to fit different géométries and then output the équation of shape profile measured.

Ateach endpoint of the semi-major axis (x) is a vertex 215 of the ellipse 214 and at each endpointof the minor axis (y) there is a co-vertex 216 ofthe ellipse 214. Optionally, the vertex 215 of the ellipse is positioned at a tangent with the annular side surface 203 of the shoulder 110, as shown in Figure 4.

Figure 5 shows an alternative design, where the vertex 215 of the ellipse 214 undercuts the annular side surface 203 ofthe shoulder 110.

Optionally, the x-axis of the ellipse 214 is parallel to the longitudinal axis 204, as shown in 10 Figure 4.

Figure 6 shows an alternative wherein the x-axis of the ellipse 214 is tilted with respect to the longitudinal axis of 204.

It should be appreciated that any combination ofthe position ofthe vertex 215 can be combined with any orientation ofthe x-axis with respect to the longitudinal axis 204 as described hereinabove.

The profile of the transition section 206 provides a male coupling end exhibiting enhanced 20 stiffness and that is more résilient to bending moments and tensile forces with respect to conventional couplings. Additionally, transition section 206 is configured to eliminate or at least minimise stress concentrations at the section where spigot 108 projects axially from shoulder 110.

Figures 7a-g show safety factor images captured using the Dang van crîterîon using rotating bending as the load case for different transition section 206 profiles as shown in Table 1 :

Figure	Transition section profile	Safety factor
7a (prior art)	Double radii: First radiî = 20 mm and second radîi = 4 mm	3.8
7b (invention)	Elliptical: a = 10 mm and b = 4.65 mm	3.9

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7c (invention)	Elliptical: a = 13 mm and b = 4.65 mm	4.2
7d (invention)	Elliptical: a = 16 mm and b = 4.65 mm	4.4
7e (invention)	Elliptical: a = 21 mm and b = 4.65 mm	4.7
7f (invention)	Elliptical: a = 26 mm and b = 4.65 mm	5.0
7g (invention)	Elliptical: a = 31 mm and b = 4.65 mm	4.7

Table 1: Description of transition section profiles used in the safety factor images.

The risk for failure is increased as the value of the Dang van criterion in decreased. Thus, darker colours mean higher risk for failure. By comparing figure 7a (prior art) to figures

7b-g (embodiments of the present invention) it can be seen that the risk of failure occurring has decreased for the inventive profiles. The stress images were captured using implicit analysis in LS-Dyna and the Dang van criterion is extracted using the nCode software. Table 1 also shows the safety factor measured from this equîpment, a higher safety factor is better and îndicates lower stress. It can be seen from the resuits in Table I that all the inventive samples hâve a higher safety factor compared to the prior art version.

Claims (12)

1. A drill string rod to form a part of a drill string, the rod (100) comprising:

an elongate hollow main length section (101) extending axially between a first end (105) and a second end (106);

a male spigot portion (108) provided at the second end (106) having an externally threaded section (107) and a non-threaded shank (109) positioned axially intermediate the main length section (101) and the threaded section (107);

the shank (109) having a transition section (206) positioned adjacent the main length section (101) or a radially projecting shoulder (110) at the second end (106), the transition section (206) having an outside diameter that increases in a direction from the spigot portion (108) to the main length section (101) or the shoulder (110);

wherein the cross-sectional shape profile of the outer surface of the transition section (206) in the plane of the longitudinal axis (204) comprises a segment of an ellipse (214) having semi-major axis (a); a semi-minor axis (b) and an exponential factor (n) according to the équation:

characterised in that:

the ratio of the semi-major to semi-minor axes (a:b) is within the range 2b<a<8b.

2. The rod (100) according to claim 1, wherein the non-threaded shank (109) is divided axially into a straight part (205), positioned axially closest to threaded section (107), and a curved transition section (206), positioned axially closest to the side surface (203).

3. The rod (100) according to claim 1, wherein the non-threaded shank (109) has only a curved transition section (206) extending ail the way from the side surface (203) to the threaded section (107).

-144. The rod ( 100) according to any precedîng claim, wherein the ratio of the semi-major to semi-minor axes (a:b) is within the range 2.5b<a<6b.

5. The rod (100) according to any precedîng claim, wherein the semi-minor axis (b) is proportionate to the dimension of the threaded section (107) according to the following

5 équation:

wherein Di is the diameter of the threaded section (107) between opposing troughs (208) and Dy is the diameter of the threaded section (107) between opposing helical ridges (207).

10

6. The rod (100) according to any precedîng claim, wherein the exponential factor (n) is in the range 1 < n < 3.

7. The rod (100) according to any precedîng claim, wherein a vertex (215) of the ellipse (214) is positioned at a tangent with the annular side surface (203) of the shoulder (110).

8. The rod (100) according to any of claims 1-6, where the vertex (215) of the ellipse (214) undercuts the annular side surface (203) of the shoulder (110).

9. The rod (100) according to any precedîng claim, wherein the x-axis of the ellipse (214) 20 is parallel to the longitudinal axis (204).

10. The rod (100) according to any of claims 1-8, wherein the x-axis of the ellipse (214) is tilted with respect to the longitudinal axis (204).

25 II. The rod (100) according to any of the precedîng claims, wherein the cross-sectional shape profile of the outer surface of the transition section (206) in the plane of the longitudinal axis (204) comprises a quarter segment of an ellipse (214).

12. The rod (100) according to any of claims 1-10, wherein the cross-sectional shape

30 profile of the outer surface of the transition section (206) in the plane of the longitudinal axis (204) comprises greater than a quarter segment of an ellipse (214).

13. The rod (100) according to any of daims 1-10, wherein the cross-sectional shape profile of the outer surface of the transition section (206) in the plane of the longitudinal axis (204) comprises less than a quarter segment of an ellipse (214).

14. A drill string comprising a drill string rod (100) according to any preceding claim.