US20240229567A9

US20240229567A9 - Coupling for connecting downhole tubulars with reduced stress

Info

Publication number: US20240229567A9
Application number: US18/278,772
Authority: US
Inventors: Tomas Jansson; Anders NORDBERG
Original assignee: Sandvik Mining and Construction Tools AB
Current assignee: Sandvik Mining and Construction Tools AB
Priority date: 2021-02-26
Filing date: 2022-02-25
Publication date: 2024-07-11

Abstract

A coupling for connecting downhole tubulars includes a tubular body, a female coupling part, a male coupling part, and at least one of: a male screw thread formed on an outer surface of the body, and a female screw thread formed in an inner surface of the body. The at least one thread having a thread-form including a crest, a root, and a pair of flanks. The crest and the root are each cambered about a respective first and second camber radius, R_b, R_b−T along the entire length of the thread-form, and each camber radius, R_b, R_b−T, is greater than an outer diameter of the coupling. The male screw thread has a camber radius, R_bm, and the female screw thread has a camber radius, R_bf, wherein each camber radius (R_b, R_b−T) is between 700-1900 mm.

Description

FIELD OF INVENTION

The present disclosure generally relates to a cambered thread for a drill string coupling and in particular, although not exclusively, for a drill string utilized for percussive rock drilling.

BACKGROUND

EP 1 511 911/U.S. Pat. No. 8,066,307 discloses a screw joint for a drill run or drill string for percussive rock drilling including male and female screw threads on the elements to be joined together to form a drill string, characterized in that the male thread and the female thread have a trapezoidal shape; that the threads have a conical inclination along the length of the threads with a cone angle smaller than 7 degrees, and in that the flank angles between the flanks of the threads and the line that is tangential with the apices of the threads is smaller than 45 degrees.
U.S. Pat. No. 4,121,862 discloses a tubular connection having a tapered pitch diameters at the entrance and exit of the thread. US2006/118340 discloses a screw joint having a trapezoidal shape and slight conical inclination.
The conical thread of the EP '911 patent is not optimal for distributing bending load evenly across the length thereof nor does the conical thread result in expedient coupling and uncoupling time. The wear resistance of the conical thread of the EP '911 patent leaves room for improvement. EP3536894 discloses a cambered thread wherein the crest and the root of the thread are each cambered about a respective first and second camber radius along the entire length of the thread-form, and each camber radius is greater than an outer diameter of the coupling, which provides improved coupling characteristics and stiffness when subject to bending loads. However, there is a requirement to provide a coupling with a reduced level of stress, has a reduced risk of premature breakage and increased the lifetime.

SUMMARY OF THE INVENTION

The present disclosure generally relates to a cambered thread for a drill string coupling and in particular, although not exclusively, for a drill string utilized for percussive rock drilling. In one embodiment, a coupling for connecting downhole tubulars includes: a tubular body; a female coupling part; a male coupling part; and at least one of: a male screw thread formed on an outer surface of the body, and a female screw thread formed in an inner surface of the body. The at least one thread has a thread-form including a crest, a root, and a pair of flanks. The crest and the root are each cambered about a respective first and second camber radius. Each camber radius is greater than an outer diameter of the coupling characterized in that each camber radius (R_b, R_b−T) is between 700-1900 mm, preferably between 800-1700 mm, more preferably between 900-1500 mm, even more preferably 1050-1400 mm, even more preferably 1100-1300 mm.
Advantageously, this provides a threaded coupling wherein the stress is reduced as low as possible as an average along the length of the thread. Consequently, the wear along the length of the thread occurs more evenly due to an even distribution of contact pressure while bending so that premature failures are less likely. If the radius is too small the stress concentrations become too large and will result in premature failures/reduced tool life, and if the camber is too small it will not couple the threads tight enough for it to stay together while drilling.
Preferably, the male screw thread has a camber radius, R_bm, and the female screw thread has a camber radius, R_bf, and the ratio of the male thread camber radius to the female thread camber radius, R_bm/R_bf, is >1.0 and ≤1.1, preferably between 1.01 and 1.05, even more preferably between 1.01 to 1.03. Advantageously, this provides a threaded coupling wherein the stress is reduced as low as possible as an average along the length of the thread. Further, within this ratio the stress is most evenly distributed along the length of the thread and the presence of concretion peaks of high stress in localised regions are avoided. Consequently, the wear along the length of the thread occurs more evenly and so premature failures are less likely to happened and the lifetime of the parts are therefore increased.
In one aspect of the embodiment, each flank is straight, and each flank is connected to an adjacent crest and/or root by a respective arc.
In another aspect of the embodiment, a centerline of the thread-form perpendicular to an arc of each camber radius is inclined relative to a longitudinal axis of the coupling by an acute and nearly perpendicular first angle adjacent to a start of the at least one thread and inclined by a second angle adjacent to an end of the at least one thread, and the second angle is less than the first angle.
In another aspect of the embodiment, each camber radius is at least 5 times greater than an outer diameter of the coupling. In another aspect of the embodiment, the thread-form is asymmetric. In another aspect of the embodiment, the thread-form is trapezoidal. In another aspect of the embodiment, a sweep angle of the at least one thread ranges between one and 10 degrees. In another aspect of the embodiment, the root and the crest are concentric. In another aspect of the embodiment, an arc length of the root and an arc length of the crest are equal. In another aspect of the embodiment, an arc length of the root and an arc length of the crest are not equal.
In another aspect of the embodiment, a connection includes: a female coupling part having the female thread; and a male coupling part having the male thread and screwed into the female thread. One of the flanks is a contact flank and the other flank is a non-contact flank when the couplings are in compression. Each flank is straight. Each thread-form has a centerline perpendicular to an arc of each respective camber radius. Each flank has a flank angle inclined relative to the respective centerline. Each contact flank angle is greater than the respective non-contact flank angle.
Optionally, each non-contact flank angle is less than 45 degrees. Since the EP '911 patent defines flank angle as being measured from the thread apex, then the EP '911 teaching translates to flank angles being greater than 45 degrees. Minimizing the non-contact flank angle facilitates uncoupling and facilitates transmission of the shockwave during uncoupling.
In another aspect of the embodiment, each coupling is made from a metal or alloy. The male coupling part has an outer diameter portion, a reduced diameter portion having the male thread, and a shoulder connecting the two portions. The shoulder is engaged with an end of the female coupling part to form a metal to metal seal.
In another aspect of the embodiment, a drill rod for percussive drilling includes: a rod body; a female coupling part having the female thread and welded to a first end of the rod body; and a male coupling part having the male thread and welded to a second end of the rod body. Optionally, an outer diameter of the couplings ranges between 5 and 20 centimetres, and each camber radius is greater than one meter.
In another aspect of the embodiment, a drill string includes a drill rod.

BRIEF DESCRIPTION OF DRAWINGS

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

FIG. 1 illustrates a drill rod having a male coupling and a female coupling, each coupling including a cambered screw thread, according to one embodiment of the present disclosure;

FIG. 2A illustrates a cambered helix for designing the cambered threads. FIG. 2B illustrates parameters of the cambered threads;

FIGS. 3A-3G illustrate formulas for the cambered helix;

FIG. 4 illustrates a profile of the male cambered thread;

FIGS. 5A and 5B are enlargements of portions of FIG. 4 ;

FIG. 6 illustrates a profile of the female cambered thread;

FIGS. 7A and 7B are enlargements of portions of FIG. 6 ;

FIG. 8 illustrates the male and female couplings screwed together.

FIG. 9 a-c show safety factor images captured using the Dang van criterion using rotating bending as the load case. FIG. 9 a show the Dang van criterion when the camber radius is inside the preferred range while FIGS. 9 b and 9 c shows the Dang van criterion when the radius is above and below the preferred range respectively.

DETAILED DESCRIPTION

FIG. 1 illustrates a drill rod 1 having a female coupling 2 and a male coupling 4, each coupling including a respective cambered screw thread 2 t, 4 t, according to one embodiment of the present disclosure. The drill rod 1 may be made from a metal or alloy, such as steel. The drill rod 1 may also be case hardened, such as by carburization. Each coupling 2, 4 may be attached, such as welded 5, to an intermediate rod body 3 so as to form longitudinal ends of the drill rod 1. Each weld 5 may be seamless, such as a friction weld. The drill rod 1 may have a flow bore formed therethrough. The drill rod 1 may have a length of 6 meters.
A drill string (not shown) may be formed by screwing together a plurality of drill rods 1 together (FIG. 8 ) along with a drill bit at one end and a shank adapter at the other end. The drill bit and shank adapter may also have either of the cambered screw threads 2 t, 4 t. The drill string may be used for percussive rock drilling with a top hammer (not shown) or downhole hammer (not shown). If a downhole hammer is used, the hammer may have each of the cambered screw threads 2 t, 4 t for assembly as part of the drill string.
Alternatively, the drill rod 1 may have a pair of male couplings 4 and a sleeve (not shown) having a pair of female couplings 2 may be used to connect a pair of drill rods together. Alternatively, the cambered screw threads 2 t, 4 t may be used to connect other types of downhole tubulars, such as oilfield drill pipe, oilfield casing or liner, oilfield production tubing, or oilfield sucker rod.
The male coupling part 4 may have a tubular body with an outer diameter upper portion for connection to a lower end of the rod body 3, a reduced diameter lower portion having the external male thread 4 t formed in an outer surface thereof, and a shoulder 4 s connecting the upper and lower portions. The upper portion of the male coupling part may have a plurality of wrench flats formed in an outer surface thereof. The flow bore in the upper portion may include a nozzle and a portion of a throat. The throat may extend through the shoulder 4 s and the lower portion.
The female coupling part 2 may have a tubular body with a lower portion for connection to an upper end of the rod body 3. The female coupling part 2 may have the internal female thread 2 t formed in an inner surface thereof adjacent to the flow bore thereof. The flow bore may be sized to receive the reduced diameter lower portion of the male coupling part 4 of another drill rod (FIG. 8 ). The male coupling part 4 may be screwed into the female coupling part 2 until the shoulder 4 s abuts a top 2 p of the female coupling, thereby creating a metal-to-metal seal for isolating the flow bore and fastening the two drill rods together. The flow bore of the female coupling part 2 may include a diffuser located adjacent to a lower end of the female thread 2 t.
Alternatively, the male coupling part 4 may be connected to an upper end of the rod body 3 and the female coupling part 2 may be connected to a lower end of the rod body. In this alternative, the nozzle of the male coupling part 4 would be a diffuser and the diffuser of the female coupling part 2 would be a nozzle.
FIG. 2A illustrates a cambered helix 6 for designing the cambered threads 2 t, 4 t. FIG. 2B illustrates parameters of the cambered threads 2 t, 4 t. FIGS. 3A-3H illustrate formulas for the cambered helix 6. To design the cambered threads 2 t, 4 t, one or more thread parameters, such as a start diameter D₀, an end diameter D₁, and a (linear) length L, may be specified utilizing dimensions of the drill rod 1. Once the thread parameters have been specified, a camber radius R_bmay be calculated utilizing the formula of FIG. 3A. The camber radius R_bmay extend from a centerpoint CP and may define crests of the male thread 4 t and roots of the female thread 2 t. The thread parameters may be specified such that the camber radius R_bis greater than, such as 5 or 10 times greater than, an outer diameter of the coupling parts 2, 4. The outer diameter of the coupling parts 2, 4 may range between 5 and 20 centimeters and the camber radius R_bmay be greater than one meter, such as ranging between 1.05 meters and 1.7 meters.
Once the camber radius R_bhas been calculated, a sweep angle γ may be calculated utilizing the formula of FIG. 3B. The sweep angle γ may range between one and ten degrees. Once the sweep angle γ has been calculated, the cambered helix 6 may be generated using the parametric formulas of FIGS. 3C-3G. The cambered helix 6 may be used to define an outline of the cambered threads 2 t, 4 t. In the parametric formulas, R(t) may be a radial coordinate of the cambered helix about a longitudinal axis GL of the drill rod 1. The convention of the formulas of FIGS. 3E-3G may be negative (shown) for a left-handed thread and positive for a right-handed thread.
The female 2 t and male 4 t threads may be complementary such that the male thread of one drill rod 1 may be screwed into the female thread of another drill rod (FIG. 8 ). To facilitate screwing and unscrewing of the threads 2 t, 4 t, the male 4 t and female 2 t threads may be similar but not be identical mirror images of each other. The above discussed design process may be performed once for the female thread 2 t and again for the male thread 4 t. Each of the female 2 t and male 4 t threads may be double threads.
To reduce the stress in the threaded coupling each camber radius R_b, R_b−T should be between 700-1900 mm, preferably between 800-1700 mm, more preferably between 900-1500 mm, even more preferably 1050-1400 mm, even more preferably 1100-1300 mm.
Preferably, the ratio of the camber radius on the male thread R_bmto the camber radius on the female thread R_bfshould be between >1.0 and ≤1.1, preferably between 1.01 and 1.05, even more preferably between 1.01 to 1.03.
If the ratio is ≤1.0, then a high concentration of stress in the region of a first male thread 20 will be present. If the ratio is above 1.1 then a high concentration of stress in the region of the endmost male thread 22 will be present.
Alternatively, the cambered threads 2 t, 4 t may be right-handed threads. Alternatively, each of the female 2 t and male 4 t threads may be a single thread or triple threads.
FIG. 4 illustrates a profile 7 m of the male cambered thread 4 t. FIGS. 5A and 5B are enlargements of portions of FIG. 4 . Once the outline of the male thread 4 t has been generated, the profile 7 m may be determined. The profile 7 m may start at a standoff distance X₀from the shoulder 4 s. The profile 7 m may end at a point where the crest of the profile intersects an axis G₁parallel to the longitudinal axis GL and offset to the end diameter D₁. The sweep angle γ may define the arcuate extent of the profile 7 m from start to end and may range between one and 10 degrees.
Referring specifically to FIG. 5A, a thread-form of the profile 7 m may include a first crest A₁. The thread-form may have a trapezoidal shape. The first crest A₁may be an arc with the (outer) camber radius R_band may extend to a second arc A₂. The centerline C_Lmay be inclined relative to the offset axis G₁at an acute and nearly perpendicular first angle δ₀. The second arc A₂may have a radius less than one percent of the outer camber radius R_b. The second arc A₂may extend from the first crest A₁to a non-contact flank E₁. The second arc A₂may be tangential to the first crest A₁and the non-contact flank E₁.
The non-contact flank E₁may be a straight line inclined at a first flank angle α relative to the centerline C_L. The first flank angle α may range between 35 and 55 degrees or the first flank angle may be less than 45 degrees. The non-contact flank E₁may extend from the second arc A₂to a third arc A₃. The third arc A₃may have a radius less than one percent of the outer camber radius R_b. The third arc A₃may extend from the non-contact flank E₁to a first root A₄. The third arc A₃may be tangential to the non-contact flank E₁and the first root A₄. The thread-form may have a height T between the first root A₄and a second crest A₇. The first root A₄may be an arc with an inner camber radius R_b−T and may extend from the third arc A₃to a fifth arc A₅. The height T may be less than one percent of the outer camber radius R_bsuch that the inner camber radius R_b−T is also greater than the outer diameter of the male coupling part 4, as discussed above for the camber radius. The first root A₄may be concentric with the first crest A₁. The centerline C_Lmay be perpendicular to an arc of each camber radius R_b, R_b−T.
The fifth arc A₅may have a radius less than one percent of the camber radius R_b. The fifth arc A₅may extend from the first root A₄to a contact flank E₂. The fifth arc A₅may be tangential to the first root A₄and the contact flank E₂. The contact flank E₂may be a straight line inclined at a second flank angle θ relative to the centerline C_L. The second flank angle β may range between 40 and 45 degrees. The first flank angle α may be less than the second flank angle β, thereby resulting in an asymmetric thread-form. The contact flank E₂may extend from the fifth arc A₅to a sixth arc A₆. The sixth arc A₆may extend from the contact flank E₂to the second crest A₇. The sixth arc A₆may be tangential to the contact flank E₂and the second crest A₇. The second crest A₇may be an arc with the outer camber radius R_b.
The thread-form may have an (arc length) pitch P between a start of the profile 7 m and a center of the second crest A₇. The first crest A₁may have an arc length X₁which may also be equal to one-half the arc-length of the second crest A₇. The first root A₄may also have an arc length equal to twice that of the arc length X₁.
Alternatively, the crests and roots may have different arc lengths. Alternatively, the second flank angle may be less than 45 degrees.
Referring specifically to FIG. 5B, due to the camber of the profile 7 m about each camber radius R_b, R_b−T, the centerline C_Lof the thread-form adjacent to the end of the profile 7 m may be inclined relative to the offset axis G₁at a second acute angle δ₁which is less than the first angle δ₀.
FIG. 6 illustrates a profile 7 f of the female cambered thread 2 t. FIGS. 7A and 7B are enlargements of portions of FIG. 6 . Once the outline of the female thread 2 t has been generated, the profile 7 f may be determined. The profile 7 f may start at a standoff distance X₀from the top 2 p. The profile 7 f may end at a point where the root of the profile intersects an axis G₁parallel to the longitudinal axis GL and offset to the end diameter D₁. The standoff distance X₀of the female profile 7 f may differ slightly from the standoff distance of the male profile 7 m. The sweep angle γ may define the arcuate extent of the profile 7 f from start to end and may range between one and 10 degrees.
Referring specifically to FIG. 7A, a thread-form of the profile 7 f may include a first root A₁. The thread-form may have a trapezoidal shape. The first root A₁may be an arc with the outer camber radius R_band may extend to a second arc A₂. The outer camber radius R_bof the female profile 7 f may differ slightly from the outer camber radius of the male profile 7 m. The centerline C_Lmay be inclined relative to the offset axis G₁at an acute and nearly perpendicular first angle δ₀. The second arc A₂may have a radius less than one percent of the outer camber radius R_b. The second arc A₂may extend from the first root A₁to a non-contact flank E₁. The second arc A₂may be tangential to the first root A₁and the non-contact flank E₁. The non-contact flank E₁may be a straight line inclined at a first flank angle α relative to the centerline C_L. The first flank angle α may range between 35 and 55 degrees.
The non-contact flank E₁may extend from the second arc A₂to a third arc A₃. The third arc A₃may have a radius less than one percent of the outer camber radius R_b. The third arc A₃may extend from the non-contact flank E₁to a first crest A₄. The third arc A₃may be tangential to the non-contact flank E₁and the first crest A₄. The thread-form may have a height T between the first crest A₄and a second root A₇. The first crest A₄may be an arc with an inner camber radius R_b−T and may extend from the third arc A₃to a fifth arc A₅. The inner camber radius R_b−T of the female profile 7 f may differ slightly from the inner camber radius of the male profile 7 m. As shown by the pair of phantom lines extending from endpoints of the first crest A₄, the centerline C_Lmay extend through a midpoint of the first crest A₄. The centerline C_Lmay be perpendicular to an arc of each camber radius R_b, R_b−T. The height T may be less than one percent of the outer camber radius R_bsuch that the inner camber radius R_b−T is also greater than the outer diameter of the female coupling 2 as discussed above for the camber radius.
The fifth arc A₅may have a radius less than one percent of the outer camber radius R_b. The fifth arc A₅may extend from the first crest A₄to a contact flank E₂. The fifth arc A₅may be tangential to the first crest A₄and the contact flank E₂. The contact flank E₂may be a straight line inclined at a second flank angle β relative to the centerline C_L. The second flank angle β may range between 40 and 45 degrees. The first flank angle α may be less than the second flank angle β, thereby resulting in an asymmetric thread-form. The asymmetric thread-form is further illustrated by projections of the flanks E₁, E₂intersecting at a point offset from the centerline C_L. The second flank angle β of the female profile 7 f may differ slightly from the second flank angle of the male profile 7 m. The contact flank E₂may extend from the fifth arc A₅to a sixth arc A₆. The sixth arc A₆may extend from the contact flank E₂to the second root A₇. The sixth arc A₆may be tangential to the contact flank E₂and the second root A₇. The second root A₇may be an arc with the outer camber radius R_b.
The thread-form may have an (arc length) pitch P between a start of the profile 7 m and a center of the second root A₇. The first root A₁may have an arc length X₁which may also be equal to one-half the arc-length of the second root A₇. The arc length X₁of the female profile 7 f may differ from the arc length of the male profile 7 m. The first crest A₄may also have an arc length less than twice that of the arc length X₁.
Alternatively, the roots and crests may have the same arc lengths.
Referring specifically to FIG. 7B, due to the camber of the profile 7 m about each camber radius R_b, R_b−T, the centerline C_Lof the thread-form adjacent to the end of the profile 7 m may be inclined relative to the offset axis G₁at a second acute angle δ₁which is less than the first angle δ₀.
Reference to the contact flanks E₂and the non-contact flanks E₁is for the context of drilling when the drill string is in compression. When tripping the drill string from the drilled hole and unscrewing the drill rods, the drill string is in tension and the contact flanks E₂become the non-contact flanks and the non-contact flanks E₁become the contact flanks, as shown in FIG. 8 .
FIG. 8 illustrates the male 4 and female 2 coupling parts screwed together. Once the thread profiles 7 m,f have been generated, each profile may be adapted to create the geometry of the respective cambered thread 4 t, 2 t, such as by truncation thereof. The cambered curvature of each thread 2 t, 4 t along the longitudinal axis G L may result in an frusto-ogive shape.
FIG. 9 a-c show safety factor images captured using the Dang van criterion with rotating bending as the load case for couplings having different camber radius sizes, as described in Table 1 below:

TABLE 1

Dang van criterion

	FIG.	R_b(mm)	Dang van

9a (inventive)	1050	7.0
9b (comparative)	2000	6.5
9c (comparative)	666	4.8

The images were captured using the Dang van criterion. Using implicit analysis in LS-Dyna the Dang van criterion is extracted using the nCode software. The risk for failure is increased as the value of the Dang van criterion in decreased. Thus, darker colours mean higher risk for failure. For the camber radius that is inside the preferred range it is possible to balance the Dang van criteria and reach a high value in the whole female thread. For both the radius that is above the preferred range in 9 b and when the radius is below the preferred range in 9 c it is not possible to balance the Dang van criteria and a lower value is reached and thus a higher risk of failure.

Claims

1. A coupling for connecting downhole tubulars, comprising:

a tubular body;

a female coupling part;

a male coupling part; and

at least one of:

a male screw thread formed on an outer surface of the body, and

a female screw thread formed in an inner surface of the body,

wherein the at least one thread has a thread-form including a crest, a root, and a pair of flanks, wherein the crest and the root are each cambered about a respective first and second camber radius along the entire length of the thread-form, and wherein each first and second camber radius is between 700-1900 mm.

2. The coupling according to claim 1, wherein each first and second camber radius is between 800-1700 mm.

3. The coupling according to claim 1, wherein the male screw thread has a camber radius and the female screw thread has a camber radius (Rbf) and the ratio of the male thread camber radius to the female thread camber radius (Rbm/Rbf) is >1.0 and ≤1.1.

4. The coupling according to claim 1, wherein each flank of the pair of flanks is straight, and each flank is connected to an adjacent crest and/or root by a respective arc.

5. The coupling according to claim 1, wherein a centerline of the thread-form perpendicular to an arc of each first and second camber radius is inclined relative to a longitudinal axis of the coupling by an acute and nearly perpendicular first angle adjacent to a start of the at least one thread and inclined by a second angle adjacent to an end of the at least one thread, and the second angle is less than the first angle.

6. The coupling according to claim 1, wherein each first and second camber radius is at least 5 times greater than an outer diameter of the coupling.

7. The coupling according to claim 1, wherein the thread-form is asymmetric.

8. The coupling according to claim 1, wherein the thread-form is trapezoidal.

9. The coupling according to claim 1, wherein a sweep angle of the at least one thread ranges between one and 10 degrees.

10. The coupling according to claim 1, wherein the root and the crest are concentric.

11. The coupling according to claim 1, wherein an arc length of the root and an arc length of the crest are equal.

12. The coupling according to claim 1, wherein an arc length of the root and an arc length of the crest are not equal.

13. A connection, comprising:

the coupling according to claim 1, wherein the female coupling part has the female thread, and the male coupling part having the male thread is screwed into the female thread, wherein one of the flanks of the pair of flanks is a contact flank and the other flank is a non-contact flank when the female and male coupling parts are in compression, wherein

each flank is straight,

each thread-form has a centerline perpendicular to an arc of each respective first and second camber radius,

each flank has a flank angle inclined relative to the respective centerline, and

each contact flank angle is greater than the respective non-contact flank angle.

14. The connection according to claim 13, wherein each non-contact flank angle is less than 45 degrees.

15. The connection according to claim 14, wherein each coupling is made from a metal or alloy, wherein the male coupling part has an outer diameter portion, a reduced diameter portion having the male thread, and a shoulder connecting the two portions, and wherein the shoulder is engaged with an end of the female coupling part to form a metal to metal seal.

16. A drill rod for percussive drilling, comprising:

a rod body; and

the coupling according to claim 1, the female coupling part having the female thread being welded to a first end of the rod body, and the male coupling part according to any of claims 1-12 having the male thread being welded to a second end of the rod body.

17. The drill rod according to claim 16, wherein an outer diameter of the female and male couplings ranges between 5 and 20 centimeters, and wherein each first and second camber radius is greater than one meter.

18. A drill string comprising a drill rod (1) according to claim 16.