Patent Publication Number: US-2022235884-A1

Title: Threaded connection for hammering interconnected tubular members

Description:
FIELD OF THE INVENTION 
     The invention relates to a threaded connection for hammering interconnected tubular members into a ground for exploration and production of a hydrocarbon well. The ground may be any type of ground such as onshore land or offshore seabed. The invention also relates to a method for hammering said interconnected tubular members in the ground for exploration and production of a hydrocarbon well. 
     BACKGROUND OF THE INVENTION 
     Hammering is used onshore and offshore to drive a string of interconnected tubular members into a ground. A drive chaser is placed on top of the string tubular members to apply hammering impact forces to the string. This is a time efficient and therefore relatively cheap way to drive the string of tubular members into the ground. 
     SUMMARY OF THE INVENTION 
     The known threaded connections for hammering interconnected tubular members into the ground for exploration and production of a hydrocarbon have the disadvantage that they may not obtain or maintain the required sealing characteristics or get damaged. Said known threaded connections may have the disadvantage that it is not possible or difficult or time consuming to determine if the required degree of sealing has been achieved during make-up. Said known threaded connections may have the disadvantage that the degree of sealing is negatively affected by the hammering or that the threaded connection is damaged by the hammering such that its general performance is impaired. 
     BRIEF DESCRIPTION OF THE INVENTION 
     The invention has the objective to provide an improved, or at least alternative, a threaded connection for hammering interconnected tubular members in a ground for exploration and production of a hydrocarbon well. Said threaded connection comprises;
         a pin member comprising an external shoulder, a pin nose and a tapered pin threaded portion located between the external shoulder and the pin nose,   a box member comprising an internal shoulder, a box nose and a tapered box threaded portion located between the internal shoulder and the box nose, wherein   the pin threaded portion and the box threaded portion are configured to engage each other during rotational make-up of the threaded connection,   the pin threaded portion and the box threaded portion comprise hooked threads providing radial interference between crests of the pin threaded portion and roots of the box threaded portion and/or between crests of the box threaded portion and roots of the pin threaded portion at final make-up of the threaded connection,   facing load flanks of the hooked threads of the pin threaded portion and the box threaded portion are in contact with each other at final make-up of the threaded connection,   facing stab flanks of the hooked threads of the pin threaded portion and the box threaded portion are located at a flank distance from each other at final make-up of the threaded connection,   the pin member comprises a sealing surface located between the pin nose and the pin threaded portion,   the box member comprises an elastomeric sealing member located between the internal shoulder and the box threaded portion,   the sealing surface and the elastomeric sealing member are configured to form a radial seal at final make-up of the threaded connection,   the box nose is in contact with the external shoulder at final make-up of the threaded connection, and   the pin nose is located at a shoulder distance from the internal shoulder at final make-up of the threaded connection.       

     The threaded connection is configured to have the box nose in contact with the external shoulder at final make-up. This allows that one can determine during rotational make-up of the threaded connection when final make-up is achieved by checking if the box nose is in contact with the external shoulder. This is an effective and efficient way to determine when the final make-up of the threaded connection is reached. 
     For threaded connections that will be hammered it is very important that the correct configuration of final make-up is reached in order to ensure the impact forces induced by hammering are transferred along the correct path from the pin member to the box member. If the threaded connection is hammered into the ground without having the external shoulder and the box nose in contact with each other, the impact forces created during hammering would primarily be transferred from the pin member to the box member via the engaged pin and box threaded portions. This creates a high risk that the pin and box threaded portions are damaged by for example galling and plastic deformation. 
     In use, the tubular members which are interconnected via the threaded connection are hammered into the ground after final make-up of the threaded connection has been reached. As mentioned, this is to ensure that the impact forces induced by hammering are transferred along the correct path from the pin member to the box member. The pin member is positioned on top of the box member during the hammering. In said situation, the impact forces are primarily transferred from the pin member to the box member via the external shoulder and box nose being in contact with each other. The fact that the impact forces induced by the hammering first move through the external shoulder being in contact with the box nose provides a relevant degree of protection against the impact forces for the engaged pin and box threaded portions and the radial seal. 
     The effects of the impact forces on the threaded connection are further reduced by the fact that at final make-up facing stab flanks of the hooked threads of the pin threaded portion and the box threaded portion are located at a flank distance from each other at final make-up of the threaded connection and that there is radial interference between crests and roots of the pin and box threaded portions. The flank distance between stab flanks allows that the pin and box threaded portions can move over some distance relative to each other under the impact forces of the hammering. This movement between the pin and box threaded portions together with the friction forces created by the radial interference and acting against said movement forms an energy absorption buffer to absorb energy from the impact forces before facing stab flanks come in contact. 
     The threaded connection is configured to have the pin nose located at a shoulder distance from the internal shoulder at final make-up. This way it is avoided that the sealing effect of the radial seal formed by the sealing surface and the elastomeric member and being located between the pin nose and the engaged pin and box threaded portions is impaired by deformations of the sealing surface created by interference forces between the pin nose and the internal shoulder. In addition, the shoulder distance between the internal shoulder and the pin nose also avoids that the impact forces induced by hammering create deformations in the sealing surface of the radial seal. Furthermore, the fact the impact forces not only first move through the external shoulder being in contact with the box nose but also through the energy absorbing engaged pin and box threaded portions provides a further degree of protection against the shock waves for the radial seal. 
     The impact forces induced by hammering create shock waves which move through the threaded connection. A shock wave first creates compression and subsequently tension in the threaded connection. The engaged pin and box threaded portions are the only parts in the threaded connection which take up the tensile forces in the threaded connection. The hooked threads with their facing load flanks being in contact with each other at final make-up ensure that the threaded connection is able to withstand the tension created by the shock waves. In addition, the hooked threads help to maintain contact between the external shoulder and the box nose when the shock waves move through the threaded connection. 
     In an embodiment of the threaded connection according to the invention, the threaded connection defines a central axis. The tapered pin threaded portion is located between the external shoulder and the pin nose when seen along the central axis. The tapered box threaded portion is located between the internal shoulder and the box nose when seen along the central axis. The sealing surface is located between the pin nose and the pin threaded portion when seen along the central axis. The elastomeric sealing member is located between the internal shoulder and the box threaded portion when seen along the central axis. The term “between” is in this document in several situations used in a similar manner to indicate that it relates to the situation when seen along the central axis. 
     In an embodiment of the threaded connection according to the invention, the external shoulder comprises an external contact surface being in contact with a box nose contact surface of the box nose at final make-up, and the external contact surface and the box nose contact surface extend perpendicular to the central axis of the threaded connection. 
     In an embodiment of the threaded connection according to the invention, radial interference between crests of the pin threaded portion and roots of the box threaded portion and/or between crests of the box threaded portion and roots of the pin threaded portion at final make-up of the threaded connection is between, and including, 0.05 mm and 0.25 mm. 
     In an embodiment of the threaded connection according to the invention, the threaded connection is configured to have the pin nose and the internal shoulder in contact with each other while the facing stab flanks are not in contact with each other at final make-up and under a predetermined compressive force working on the threaded connection in a direction of the central axis. 
     In an embodiment of the threaded connection according to the invention, the facing stab flanks are more spaced from each other than the pin nose and internal shoulder when seen along the central axis. 
     In an embodiment of the threaded connection according to the invention, the shoulder distance is larger than 0 mm and smaller than 0.3 mm at final make-up of the threaded connection. Preferably, the shoulder distance is larger than 0 mm and smaller than 0.24 mm at final make-up of the threaded connection. The shoulder distance is measured in axial direction along the central axis. 
     In an embodiment of the threaded connection according to the invention, the flank distance is between, and including, 0.1 mm and 0.25 mm at final make-up of the threaded connection. The flank distance is measured in axial direction along the central axis. 
     In an embodiment of the threaded connection according to the invention, the threaded connection comprises at least one anti-rotational key and at least one key slot configured to receive the anti-rotational key in a locking position in which at least part of the anti-rotational key extends between the pin member and the box member to prevent rotational movement of the pin member and the box member relative to each other at final make-up of the threaded connection. 
     In an embodiment of the threaded connection according to the invention;
         the box member comprises a box lip section extending from the box nose towards the box threaded portion and comprising a box lip inner surface provided with box ribs extending around the central axis,   the pin member comprises a pin member shoulder section which forms the external shoulder,   the at least one anti-rotational key comprise a key body section and a key cutting section,   in the locking position, the key body section is located in the key slot and the key cutting section is located between the box inner lip surface and the pin member, and   the key cutting section is provided with cutting edges for cutting through the box ribs in a cutting direction transverse, preferably perpendicular, to the box ribs during the placing of the respective key in the locking position.       

     In an embodiment of the threaded connection according to the invention, the threaded connection is at final make-up free from any radial seal provided between the external shoulder and the engaged pin threaded portion and box threaded portion. 
     In an embodiment of the threaded connection according to the invention, the pin member comprises a pin member inner surface, the box member comprises a box member inner surface, and the pin member inner surface and the box member inner surface extend flush to each other at final make-up of the threaded connection. 
     In an embodiment of the threaded connection according to the invention, the pin member inner surface and the box member inner surface are both located at an inner member surface radius R1 from the central axis. 
     In an embodiment of the threaded connection according to the invention;
         the pin member comprises a pin pipe part having a pin pipe part outer surface located at a pin pipe part outer surface radius R2 from the central axis,   the pin member comprises a pin member shoulder section which forms the external shoulder and is located between the pin pipe part and the pin threaded portion,   the pin member comprise a pin connector part extending from the pin member shoulder section until the pin nose,   the box member comprises a box pipe part having a box pipe part outer surface located at a box pipe part outer surface radius R3 from the central axis,   the box member comprises a box member shoulder section which forms the internal shoulder and is located between the box pipe part and the box threaded portion,   the box member comprise a box connector part extending from the box member shoulder section until the box nose,   at final make-up, the pin connector part and the box connector part define together an outer connector surface located at an outer connector radius R4 from the central axis, and   the outer connector radius R4 is larger than each of the pin pipe part outer surface radius R2 and the box pipe part outer surface radius R3.       

     In an embodiment of the threaded connection according to the invention, the outer connector radius R4 is between, and including, R2+13 mm and R2+19 mm. 
     In an embodiment of the threaded connection according to the invention, the outer connector radius R4 is between, and including, R3+13 mm and R3+19 mm. 
     In an embodiment of the threaded connection according to the invention, the pin pipe part outer surface radius R2 is equal to the box pipe part outer surface radius R3. 
     In an embodiment of the threaded connection according to the invention;
         a pin transition area having a pin transition radius R5 is located between the pin pipe part outer surface and the outer connector surface,   a box transition area having a box transition radius R6 is located between the box pipe part outer surface and the outer connector surface, and   the pin transition radius R5 is larger than the box transition radius R6.       

     In an embodiment of the threaded connection according to the invention, the pin transition radius R5 is between, and including, 2 times and 5 times than the box transition radius R6. 
     In an embodiment of the threaded connection according to the invention, the pin transition radius R5 is between, and including, 10 mm and 20 mm and the box transition radius R6 is between, and including, 2 mm and 8 mm. 
     In an embodiment of the threaded connection according to the invention, the pin member and the box member comprise a single step thread formed by the pin threaded portion and box threaded portion, respectively. 
     In an embodiment of the threaded connection according to the invention, the pin and box threaded portions extend under a taper angle α between, and including, 6° and 11° relative to the central axis. 
     In an embodiment of the threaded connection according to the invention, the pin threaded portion and the box threaded portion comprise multi threads which are configured to be made-up by rotational make-up over between, and including, 180° and 360°. 
     In an embodiment of the threaded connection according to the invention, the internal shoulder comprises an internal stop surface facing a pin nose stop surface of the pin nose and located at the shoulder distance at final make-up, and the internal stop surface and the pin nose stop surface extend under a stop angle β of between, and including, 6° and 10° relative to a virtual perpendicular line extending perpendicular to the central axis of the threaded connection. 
     In an embodiment of the threaded connection according to the invention, the threaded connection is configured to reach final make-up when contact between the box nose and the external shoulder is achieved during rotational make-up. 
     In an embodiment of the threaded connection according to the invention, the threaded connection is configured to be hammered into the ground after final make-up has been reached and with the pin member positioned on top of the box member during the hammering. 
     In an embodiment of the threaded connection according to the invention, the pin member comprises a pin pipe part having a pin pipe part outer surface located at a pin pipe part outer surface radius R2 from the central axis and 2×R2 is between, and including, 508 mm and 1016 mm (between, and including, 20 inch and 40 inch). 
     In an embodiment of the threaded connection according to the invention, the box member comprises a box pipe part having a box pipe part outer surface located at a box pipe part outer surface radius R3 from the central axis and 2×R3 is between, and including, 508 mm and 1016 mm (between, and including, 20 inch and 40 inch). 
     In an embodiment of the threaded connection according to the invention, the threaded connection is configured to interconnect tubular members having an outer diameter between, and including, 508 mm and 1016 mm (between, and including, 20 inch and 40 inch). 
     The invention further relates to a method for hammering interconnected tubular members into a ground, such as onshore land or offshore seabed, for exploration and production of a hydrocarbon well, said tubular members being interconnected via a threaded connection according to the invention, wherein the method comprises hammering the interconnected tubular members after final make-up of the threaded connection has been reached and with the pin member positioned on top of the box member during the hammering 
    
    
     
       BRIEF DESCRIPTION OF THE INVENTION 
       Embodiments of the threaded connection and the method according to the invention will be described by way of example only, with reference to the accompanying schematic drawings in which corresponding reference symbols indicate corresponding parts, and in which: 
         FIG. 1A  schematically shows a cross sectional view of an embodiment of a pin member of a threaded connection according to the invention, 
         FIG. 1B  schematically shows an enlarged view of part of the pin threaded portion, the sealing surface and the pin nose of the pin member of  FIG. 1A , 
         FIG. 1C  schematically shows an enlarged view of part of the pin threaded portion and the external shoulder of the pin member of  FIG. 1A , 
         FIG. 1D  schematically shows a further enlarged view of part of the pin threaded portion of the pin member of  FIG. 1A , 
         FIG. 2A  schematically shows a cross sectional view of an embodiment of a box member of a threaded connection according to the invention, 
         FIG. 2B  schematically shows an enlarged view of part of the box threaded portion, the elastomeric sealing member and the internal shoulder of the box member of  FIG. 2A , 
         FIG. 2C  schematically shows an enlarged view of part of the box threaded portion, the box lip section and the box nose of the box member of  FIG. 2A , 
         FIG. 2D  schematically shows a further enlarged view of part of the box threaded portion of the box member of  FIG. 2A , 
         FIG. 3A  schematically shows a cross sectional view of the pin member of  FIG. 1  and the box member of  FIG. 2  connected to tubular members, 
         FIG. 3B  schematically shows a cross sectional view of an embodiment of the threaded connection according to the invention and comprising the pin member and the box member of  FIG. 3A , 
         FIG. 3C  schematically shows an enlarged view of the engaged pin threaded portion and box threaded portion of the threaded connection of  FIG. 3B , 
         FIG. 3D  schematically shows an enlarged view of the external shoulder and the box nose of the threaded connection of  FIG. 3B , 
         FIG. 3E  schematically shows an enlarged view of the internal shoulder and the pin nose of the threaded connection of  FIG. 3B , 
         FIG. 3F  schematically shows an alternative embodiment of the engaged pin threaded portion and box threaded portion of the threaded connection of  FIG. 3B , 
         FIG. 4A  schematically show a cross sectional view perpendicular to the central axis of the pin member of  FIG. 1 , 
         FIG. 4B  schematically show a cross sectional view along IV-IV of  FIG. 4A , 
         FIG. 4C  schematically show a view in perspective of an embodiment of an anti-rotational key of the pin member of  FIG. 1 , and 
         FIG. 4D  schematically show the view of  FIG. 4B  with the anti-rotational key of  FIG. 4C  located in the locking position. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     An embodiment of the threaded connection  1  according to the invention is shown in the  FIGS. 3A-E . Said threaded connection  1  comprises the pin member  5  shown in the  FIGS. 1A-D  and  4 A-D and the box member  9  shown in the  FIGS. 2A-D . The threaded connection  1  is configured for hammering interconnected tubular members  2  into a ground, such as onshore land or offshore seabed, for exploration and production of a hydrocarbon well. 
     The  FIGS. 1A-D  show cross sectional views of the pin member  5  of the threaded connection  1 . The pin member  5  comprises an external shoulder  6 , a pin nose  7  and a tapered pin threaded portion  8  located between the external shoulder  6  and the pin nose  7  when seen along the central axis  24 . 
     The  FIGS. 2A-D  show cross sectional views of the box member  9  of the threaded connection  1 . The box member  9  comprises an internal shoulder  10 , a box nose  11  and a tapered box threaded portion  12  located between the internal shoulder  10  and the box nose  11  when seen along the central axis  24 . 
     The pin threaded portion  8  and the box threaded portion  12  are configured to engage each other during rotational make-up of the threaded connection  1  (see  FIG. 3B ). The pin threaded portion  8  (see  FIG. 1D ) and the box threaded portion  12  (see  FIG. 2D ) comprise hooked threads  13  providing radial interference between crests  14  of the pin threaded portion  8  and roots  15  of the box threaded portion  12  and between crests  14  of the box threaded portion  12  and roots  15  of the pin threaded portion  8  at final make-up  16  of the threaded connection  1  (see  FIG. 3C ). 
     In an alternative embodiment of the threaded connection  1  according the invention, the hooked threads  13  provide at final make-up  16  radial interference only between crests  14  of the pin threaded portion  8  and roots  15  of the box threaded portion  12  or only between crests  14  of the box threaded portion  12  and roots  15  of the pin threaded portion  8 . The latter alternative embodiment is shown in  FIG. 3F . Said embodiment comprises a clearance between the between crests  14  of the pin threaded portion  8  and roots  15  of the box threaded portion  12 . 
     Hooked threads  13  have a positive stab flank angle at the stab flanks  18  and a negative load flank angle at the load flanks  17 . Facing load flanks  17  of the hooked threads  13  of the pin threaded portion  8  and the box threaded portion  12  are in contact with each other and facing stab flanks  18  of the hooked threads  13  of the pin threaded portion  8  and the box threaded portion  12  are located at a flank distance  19  from each other at final make-up  16  of the threaded connection  1  (see  FIG. 3C ). 
     The pin member  5  comprises a sealing surface  20  located between the pin nose  7  and the pin threaded portion  8  when seen along the central axis  24 . The box member  9  comprises an elastomeric sealing member  21  located between the internal shoulder  10  and the box threaded portion  12  when seen along the central axis  24 . The sealing surface  20  and the elastomeric sealing member  21  are configured to form a radial seal  22  at final make-up  16  of the threaded connection  1  (see  FIG. 3C ). 
     The box nose  11  is in contact with the external shoulder  6  at final make-up  16  of the threaded connection  1  (see  FIG. 3D ). The pin nose  7  is located at a shoulder distance  23  from the internal shoulder  10  at final make-up  16  of the threaded connection  1  (see  FIG. 3E ). 
     In  FIG. 3B , the threaded connection  1  interconnects two tubular members  2  which are attached the pin member  5  and the box member  9  by welding seams  3 . The horizontal direction  71  and vertical direction  72  are indicated. The threaded connection  1  is configured to be hammered into the ground after final make-up  16  has been reached and with the pin member  5  positioned on top of the box member  9  during the hammering. In said situation, the hammering will occur on the upper tubular member  2  in the direction shown by arrow  4  in  FIG. 3B . The threaded connection  1  is configured to interconnect tubular members  2  having an outer diameter between, and including, 508 mm and 1016 mm (between, and including 20 inch and 40 inch). 
     The radial interference between crests  14  of the pin threaded portion  8  and roots  15  of the box threaded portion  12  and between crests  14  of the box threaded portion  12  and roots  15  of the pin threaded portion  8  at final make-up  16  of the threaded connection  1  is between, and including, 0.05 mm and 0.25 mm. Said radial interference improves the function as energy absorption buffer of the engaged pin and box threaded portions  8  and  12 . 
     The threaded connection  1  is configured to have the pin nose  7  and the internal shoulder  10  in contact with each other while the facing stab flanks  18  are not in contact with each other at final make-up  16  and under a predetermined compressive force working on the threaded connection  1  in a direction of the central axis  24 . 
     When seen along the central axis  24 , the facing stab flanks  18  are more spaced from each other than the pin nose  7  and the internal shoulder  10 . 
     This way, the pin nose  7  and the internal shoulder  10  protect the engaged pin and box threaded portions  8  and  12  against undesired high impact forces during hammering. 
     Tests revealed that surprisingly good results were achieved when the shoulder distance  23  is larger than 0 mm and smaller than 0.3 mm, preferably larger than 0 mm and smaller than 0.24 mm, at final make-up  16  of the threaded connection  1 . These tests also indicated that surprisingly good results were achieved when the flank distance  19  is between, and including, 0.1 and 0.25 mm at final make-up  16  of the threaded connection  1 . The shoulder distance  23  and the flank distance  19  are measured in axial direction along the central axis  24 . 
     The pin member  5  comprises a pin member inner surface  38 , the box member  9  comprises a box member inner surface  39 , and the pin member inner surface  38  and the box member inner surface  39  extend flush to each other at final make-up  16  of the threaded connection  1  (see  FIG. 3B ). 
     The pin member inner surface  38  and the box member inner surface  39  are both located at an inner member surface radius R1 from the central axis  24  (see the  FIGS. 1A and 2A ). The pin member  5  comprises a pin pipe part  40  having a pin pipe part outer surface  41  located at a pin pipe part outer surface  41  radius R2 from the central axis  24 . The pin member  5  comprises a pin member shoulder section  33  which forms the external shoulder  6  and is located between the pin pipe part  40  and the pin threaded portion  8 . The pin member  5  comprise a pin connector part  43  extending from the pin member shoulder section  33  until the pin nose  7 . 2×R2 (R2 times two) is between, and including, 508 mm and 1016 mm (between, and including, 20 inch and 40 inch). 
     The box member  9  comprises a box pipe part  44  having a box pipe part outer surface  45  located at a box pipe part outer surface radius R3 from the central axis  24 . The box member  9  comprises a box member shoulder section  46  which forms the internal shoulder  10  and is located between the box pipe part  44  and the box threaded portion  12 . The box member  9  comprise a box connector part  47  extending from the box member shoulder section  46  until the box nose  11 . 2×R3 (R3 times two) is between, and including, 508 mm and 1016 mm (between, and including 20 inch and 40 inch). 
     At final make-up  16 , the pin connector part  43  and the box connector part  47  define together an outer connector surface  48  located at an outer connector radius R4 from the central axis  24 . The outer connector radius R4 is larger than each of the pin pipe part outer surface  41  radius R2 and the box pipe part outer surface radius R3. 
     The outer connector radius R4 is between, and including, R2+13 mm and R2+19 mm. The outer connector radius R4 is between, and including, R3+13 mm and R3+19 mm. The pin pipe part outer surface  41  radius R2 is equal to the box pipe part outer surface radius R3. 
     A pin transition area  49  having a pin transition radius R5 is located between the pin pipe part outer surface  41  and the outer connector surface  48 . A box transition area  50  having a box transition radius R6 is located between the box pipe part outer surface  45  and the outer connector surface  48 . The pin transition radius R5 is larger than the box transition radius R6. The pin transition radius R5 is preferably between, and including, 2 and 5 times larger than the box transition radius R6. The pin transition radius R5 is preferably between, and including, 10 mm and 20 mm and the box transition radius R6 is between, and including, 2 mm and 8 mm. 
     The pin member  5  and the box member  9  comprise a single step thread  51  formed by the pin threaded portion  8  and box threaded portion  12 , respectively. This means that no further steps of threads are provided on the threaded connection  1 . 
     The pin and box threaded portion  8  and  12  extend preferably under a taper angle α between, and including, 6° and 11° relative to the central axis  24  (see the  FIGS. 1B and 2B ). The taper angle α is measured with respect to the centre line  101  of the pin threaded portion  8  and the centre line  102  of the box threaded portion  12  (see the  FIGS. 1D and 2D ). The taper angle α is shown relative to a virtual parallel line  70  extending parallel to the central axis  24 . In the hammering position of the threaded connection  1  shown in  FIG. 3B , the virtual parallel line  70  extends in the vertical direction  72 . 
     The pin threaded portion  8  and the box threaded portion  12  comprise multi threads which are configured to be made-up by rotational make-up over between, and including, 180° and 360°. 
     The internal shoulder  10  comprises an internal stop surface  52  facing a pin nose stop surface  53  of the pin nose  7  and located at the shoulder distance  23  at final make-up  16 , and the internal stop surface  52  and the pin nose stop surface  53  extend preferably under a stop angle β of between, and including, 4° and 12° relative to a virtual perpendicular line  73  extending perpendicular to the central axis  24  of the threaded connection  1  (see the  FIGS. 1B and 2B ). In the hammering position of the threaded connection  1  shown in  FIG. 3B , the virtual perpendicular line  73  extends in the horizontal direction  71 . 
     The internal stop surface  52  and the pin nose stop surface  53  are inclined away from the external shoulder  6  when seen along the virtual perpendicular line  73  in a direction away from the central axis  24 . 
     The stop angle β of the internal stop surface  52  and the pin nose stop surface  53  ensure that the pin nose  7  tends to move towards the box member  9  instead of away. 
     The threaded connection  1  is at final make-up  16  free from any radial seal  22  provided between the external shoulder  6  and the engaged pin threaded portion  8  and box threaded portion  12 . Such a radial seal  22  would be affected too much by the shock waves induced by the hammering and would therefore not form a reliable seal. 
       FIG. 4A  shows a cross sectional view perpendicular to the central axis of the pin member of  FIG. 1A . The cross sectional view of  FIG. 1A  is along I-I of  FIG. 4A . The cross sectional view of  FIG. 4B  is along IV-IV of  FIG. 4A .  FIG. 4C  shows the anti-rotational key of the pin member of  FIG. 1 .  FIG. 4D  show the view of  FIG. 4B  with the anti-rotational key of  FIG. 4C  located in the locking position (without the box member). 
     The threaded connection  1  comprises two anti-rotational keys  27  and two key slots  28  configured to receive the anti-rotational keys  27  in a locking position  29  in which part of the anti-rotational key  27  extends between the pin member  5  and the box member  9  to prevent rotational movement of the pin member  5  and the box member  9  relative to each other at final make-up  16  of the threaded connection  1 . This situation is shown in  FIG. 4D  without the box member  9 . 
     The box member  9  comprises a box lip section  30  extending from the box nose  11  towards the box threaded portion  12  and comprising a box lip inner surface  31  provided with box ribs  32  extending around the central axis  24  (see  FIG. 2C ). 
     The at least one anti-rotational key  27  comprise a key body section  34  and a key cutting section  35  (see  FIG. 4C ). In the locking position  29 , the key body section  34  is located in the key slot  28  and the key cutting section  35  is located between the box inner lip surface and the pin member  5 . The key cutting section  35  is provided with cutting edges  36  for cutting through the box ribs  32  in a cutting direction  37   37  transverse, preferably perpendicular, to the box ribs  32  during the placing of the respective key in the locking position  29  (see  FIG. 4D ). 
     As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention, which can be embodied in various forms. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention in virtually any appropriately detailed structure. Further, the terms and phrases used herein are not intended to be limiting, but rather, to provide an understandable description of the invention. 
     The terms “a” or “an”, as used herein, are defined as one or more than one. The terms multiple and plurality, as used herein, is defined as two or more than two. The term another, as used herein, is defined as at least a second or more. The terms including and/or having, as used herein, are defined as comprising (i.e., open language, not excluding other elements or steps). Any reference signs in the claims should not be construed as limiting the scope of the claims or the invention. 
     It will be apparent to those skilled in the art that various modifications can be made to the shown threaded connection and method according to the invention without departing from the scope as defined in the claims.