RU2809637C2 - Threaded fastening device with locking device - Google Patents

Abstract

FIELD: threaded fastening device.

SUBSTANCE: threaded fastening device contains locking clamps (14), the loose end of which is driven by cam profiles inside a rotatable ring (19). Clamps are created by removing material from the main body (11) of the nut and changing from a locked state to a released state and vice versa through elastic bending deformation. The locking surface (16) on the inside of the clamps has the same threads as the main part of the nut.

EFFECT: ensuring reliable locking even after several screwing/unscrewing cycles, ease of use.

27 cl, 2 dwg

Description

The present invention relates to a threaded fastening device including friction locking means to prevent accidental loosening due to, inter alia, mechanical disturbances such as vibrations, inertial effects, etc.

In many applications it is useful to secure a screw connection against accidental unscrewing, which often involves significant risks. This is especially common in aeronautics, and in particular with respect to the bolts that assemble the two halves of each landing gear wheel, between which the tire is enclosed.

Threaded fastening devices are known that are equipped with snap-type locking systems, allowing locking only in discrete angular positions, in particular according to DE 39 35 753 A1, US 2019/00 48 918 A1, US 6,036,236 and WO 2009/001 421 A1. In some applications where a specific tightening torque must be met, these locking systems are not suitable due to the fact that the relative angular position corresponding to the recommended torque does not necessarily correspond to one of the discrete angular positions that provide locking capability.

Threaded fasteners equipped with a friction locking agent prevent this problem. Nut locking washers are known which act automatically when the nut reaches a tightened state. Also known are nuts which include a locking means in the threaded hole, or nuts which are partially deformed, in particular oval shaped, so as to create friction during screw rotation. These known systems quickly become ineffective after a small number of locking and unlocking cycles.

CN 105 485 129 A describes a nut extended axially by a collar with an internal thread. Axial recesses subdivide the collar into several locking clamps adapted for deflection relative to a practically tangent axis. A memory ring surrounds the collar and compresses it around the bolt under certain temperature conditions. The ring must exert very significant forces in order to provide this function.

DE 33 20 679 A1 describes, with reference to FIG. 94, a device which is similar, but in which the locking force is provided by an internally tapered sleeve screwed inside the spacer sleeve. Numerous additional parts are necessary, the locking action is laborious, and it appears that the risk of the bushing coming loose and bushing and sleeve loss has not been eliminated.

DE 10 2017 213 047 A1 provides an internal thread, which is not located in the main part of the nut, but in a separate, deformable sleeve. To lock, the transverse bolt radially presses the deformable sleeve. This locking means requires a complete reconstruction of the screwing device and does not exclude the loosening of the cross bolt.

US 2019/012 0279 A1 describes other devices having a deformable sleeve.

US 2016/02 29 226 A1 illustrates a landing gear wheel formed from two wheel halves assembled by bolts. The connection is ensured by threads - or turns - of thread passing through the transverse punctures of the bolt.

GB 332 463 A describes a locking threaded fastening device in which a locking clip, configured and positioned to engage a complementary thread, extends in a direction that is substantially circular about the locking axis between an attached end connected to the main body and an end that is loose in the radial direction.

The invention relates to a threaded fastening device with friction locking in the screwed state, containing:

- a main body having a threaded cylindrical surface designed to threadably engage complementary threads;

- at least one clip connected at least indirectly to the main body and having a locking surface on its side facing, in use, towards the complementary thread, configured and positioned to come into locking contact with the complementary thread, at least one clip extends in a direction that is substantially circular with respect to the axis of the cylindrical surface, between an attached end connected to the main body and an end that is loose in a substantially radial direction; And

- an acting element that can move between a locking and a released position to selectively place the clamp into a locking state in which the locking surface exerts locking pressure on a complementary thread, and accordingly into a released state of the corresponding screwing and unscrewing movement.

Such a device is known from DE 20 2013 006 947 U1. The clamp or clamps, which are substantially circular, may have a very small overall size in the axial direction while being movable with a reasonable amount of force and applying an effective locking force to the threads.

It is an object of the present invention to provide a threaded fastening device that provides frictional locking when screwed, which at least partially satisfies the following objectives: provides reliable locking even after several screwing/unscrewing cycles, is easy to use, requires moderate actuation forces , no requirement for special design of the screw fastener itself or the elements that must be fastened with this fastener, no requirement for components or accessories that are at risk of being lost, no damage to the threads, no requirement for modification of the element carrying complementary threads, and only the presence of minimal influence on the weight and dimensions of the fastening device.

According to the invention, the fastening device is characterized in that the actuating element is an actuating ring mounted in rotation relative to the main part around the axis of the threaded cylindrical surface. Thus, simple rotation of the actuating ring makes it possible to place the fastening device in a locked state or, conversely, in a released state.

In an embodiment, the actuating element is configured to exert on the side of the clamp facing away from the locking surface a force directed, in use, toward the complementary thread, returning the clamp to a released state through elasticity.

According to an embodiment, the actuating element presses the clamp while bending to transition from a released state to a locked state. The circular clamp according to the invention exhibits, in particular, much lower bending resistance compared to the axial tabs of some of the previous documents discussed above.

In a useful embodiment, at least in the locking state, the locking surface of the clamp is closer to the attached end of the clamp compared to the interaction region between the clamp and the acting element, so as to cause the clamp to experience bending stress between the blocking surface and the interaction region, when the clamp is in the locking state. Thus, there is a beneficial leverage effect on the clamp that reduces the actuation force required relative to the drive force desired for locking. In addition, the area of bending stress - or folding - between the acting element and the locking surface serves to limit the pressure between the locking surface and the complementary thread. This protects the fastening device.

Preferably, but not limitingly, the attached end of the clamp is rigidly connected to the main body. In an embodiment, the clamp and body are formed from a single piece of material, joining together at the attached end of the clamp. In this way, production is simplified while at the same time making the embodiment particularly reliable.

In an embodiment, the locking surface of the clamp refers to a threaded cylindrical surface. Thus, in the locking state, the locking surface is perfectly aligned with the complementary thread.

Preferably, in order to facilitate maintenance operations and make them more reliable, the actuating element is attached to the main part permanently or in a manner that prevents disassembly other than by means of a tool. Thus, the impact element cannot be lost during use relative to the main part.

The ring is preferably configured as a protective cover protecting at least one clamp.

In an embodiment, the ring is held axially relative to the main body by a retaining ring. This arrangement is advantageous in terms of overall size. In addition, access to the retaining ring, which would make disassembly of the ring possible, is hidden or impossible, which prevents any intervention, in particular any disassembly, from compromising the safety expected of the fastening device according to the invention.

For this axial positioning relative to the main part, provision can be made for a locking ring, which must be partially accommodated in the free space located between the clamp and the remaining main part. This solution is advantageous in terms of machining and space requirements.

In an embodiment, the retaining ring is immobilized against rotation relative to one of the body and ring and includes at least one projection that engages with at least one recess provided in the other of the body and ring so that to limit the angular movement of the ring relative to the main body. This solution allows the locking ring to provide axial immobilization of the actuating ring and limit its rotational movement. According to an advantageous development of this embodiment, the recess includes at least one protrusion, which the protrusion can traverse by means of elasticity, as in the case of a reinforced point. This reinforced point stabilizes the angular position of the acting ring relative to the main part in the event of random movements caused by vibrations or other disturbing influences.

Preferably, the actuating ring and the clamp interact via respective mating cam profiles. This mode of action provides the force required for blocking in terms of direction and intensity.

In an embodiment, the cam profile of at least one of the actuating ring and the clamp relates to a corresponding ellipse centered on the axis of the cylindrical surface.

In another or the same embodiment, the mating profiles define a reinforced point for moving the actuating ring between its locking and released positions.

The benefit of such a reinforced point in moving the acting element has been described above in general terms. The reinforced point can be made in various ways in addition to those already described.

In a very general and non-limiting manner, it is useful to provide a locking means that restricts the movement of the actuating element in its displacements, allowing it to occupy its locking and releasing positions, respectively. Advantageously, this locking means may comprise an excessive thickness of the actuating element extending between the two ends of the clamp. The purpose here is to fundamentally prevent any handling error in which excessive actuating force would drive the actuating element beyond its normal movement.

In addition, in a general and non-limiting manner, the device usefully includes means indicating the position of the actuation element.

In an embodiment, the device contains an interlocking system that immobilizes the acting element in each of its positions, locking and, accordingly, releasing, relative to the main part. Here, it is a case of stabilizing the actuating element against unwanted mechanical excitations in order to avoid spontaneous changes in its position and/or to avoid its oscillation in a related manner adapted to indicate a malfunction. In an embodiment, the interlocking system includes a tooth that moves between two stops and, between the two stops, a convexity that the tooth can traverse by elastic deformation. This constitutes another way of creating a reinforced point, the function of which has already been discussed above. In each position, blocking and, accordingly, releasing, the acting element, the tooth is immobilized between the stop mentioned above and the convexity.

Typically, the fastening device is a nut.

In an embodiment, the main body includes a tubular wall provided internally with a threaded cylindrical surface, and at least one clamp is at least partially defined by removing material from said tubular wall.

Preferably, but not in a limiting manner, the fastening device combines, in a single independent unit, the main body with its threaded cylindrical surface, at least one locking element and a control element. The device according to the invention thus constructed is used similarly to a conventional fastening device, eliminating the need to place the actuating element in a locking position after screwing, or in a released position before unscrewing. Complex manipulation is not necessary and no additional assembly needs to be performed.

In an embodiment, the at least one clamp comprises a plurality of clamps distributed around the axis of the threaded cylindrical surface. The actuating element is common to all clamps.

Other features and advantages of the invention will become more apparent from the description given below in relation to non-limiting examples.

On the attached drawings:

Fig. 1 is a partial axial section through a bolted connection using a fastening device according to the invention;

Fig. 2 is a perspective view of a first embodiment of a nut according to the invention;

Fig. 3 is a perspective view of the main body of the nut of FIG. 2, with its two clamps;

Fig. 4 is a partial perspective view of the nut of FIG. 2, with a partial cross-section of the acting ring;

Fig. 5 is a half view of the nut in cross section, perpendicular to the axis, in the released state;

Fig. 6 is a view similar to FIG. 5, but in a locked state;

Fig. 7 is a partial perspective view of a second embodiment of the invention;

Fig. 8 is a partial view of the third embodiment, in cross section along two different axial planes;

Fig. 9 is a partial perspective view of a fourth embodiment of a nut according to the invention;

Fig. 10 is an exploded perspective view of the nut of FIG. 9;

Fig. 11 is an axial schematic view illustrating the nut of FIG. 9 in released state; And

Fig. 12 is a view similar to FIG. 11, but illustrating a blocked state.

The preceding and following descriptions are to be understood as containing not only the specific features and specific combinations described, but any more or less generalized feature or combination of features, even derived from one or more part(s) of a phrase or paragraph, independently of the rest of the phrase or paragraph, providing Such a feature or combination of features may impart originality to the invention and may make it possible for it to solve a problem formulated in relation to the prior art.

In the example shown in FIG. 1, two parts 1, 2, partially shown, are assembled adjacent to each other in the mating plane 3 by means of fasteners 4 (only one is shown) extending transversely to the mating plane 3. Each fastener 4 includes a bolt 5 having a head 6 and a thread 7, and a nut 8 screwed onto the thread 7, which will be called a "complementary thread". The nut 8 is provided with a locking means 9 which engages a complementary thread 7 in the vicinity of the free end of the bolt 5. The reference 10 denotes the axis common to the bolt 5 and the nut 8. The bolt 5 is a standard bolt for this type of application; it does not include any special means for locking the nut other than necessarily a small additional axial length. The design and production of the locking means 9 is thus limited by the limited axial length available on the bolt.

In the example in FIG. 2-6, a nut 8 equipped with a locking means 9 includes an annular body 11 having a threaded cylindrical inner surface 12 designed to threadably engage a complementary thread 7 in FIG. 1. Along its outer perimeter, the main body 11 has tool engagement devices 13 for driving rotation during screwing and unscrewing (not shown).

The locking means 9 comprises two clips 14 attached to the main body 11 and having on its side 15, facing, in use, the complementary thread, a locking surface 16 configured and positioned to selectively come into frictional locking abutment on the complementary thread 7. The clips 14 are distributed evenly around the axis 10 of the threaded cylindrical surface 12. The clamps 14 are adapted to a locking condition in which their locking surface 16 is in locking contact with a complementary thread 7, which prevents the bolt 5 and nut 8 from rotating relative to each other under the influence of unwanted excitations such as vibrations, inertial effects, changes in wheel load, changing thermal stresses, etc. The clamps 14 are also adapted to a released state in which the pressure of the locking surfaces 16 on the complementary threads 7 is largely relieved, allowing free rotation relative to the bolt 5 and nut 8.

According to the invention, each clamp 14 extends in a direction that is substantially circular with respect to the axis 10 of the cylindrical surface 12, between an attached end 17 attached to the main body 11 and an unattached end 18 in a substantially radial direction. The clips are identical to each other and are all oriented in the same circular direction starting from their attached end 17. In the example, the attached end 17 of each clip is rigidly attached to the nut body 11. More specifically, in this example, the clip and body are derived from a single piece of material while being joined together at the attached end 17 of the clip, as shown in FIG. 3. The change in state of the clamp, between the released and locked states, is allowed by the flexural elasticity of the clamp itself, between its attached end 17 and its loose end 18.

In the preferred example shown, the locking surfaces 16 are related to the threaded cylindrical surface 12. In the locking state, the locking surfaces 16 can thus perfectly align with the complementary thread 7 without damaging it. In the released state, the locking surface 16 slides along the complementary thread in the same kinematic screwing and unscrewing relationship as the threaded cylindrical surface 12.

The locking means 9 also includes an actuator 19 that can be moved between the locking and released positions to selectively place the clamps 14 in the locking state of the relative screwing and unscrewing movement and, accordingly, in the releasing state of the relative screwing and unscrewing movement.

In the embodiment shown, the acting element is configured to exert, on the engagement region 21 of each clamp 14 provided on the side 20 of the clamp facing away from the locking surface 16, a force directed, in use, to the complementary thread 7 to produce a locking condition. The return of the clamps 14 to the released state occurs through elasticity. In the example, the released state is the resting state of the clamp 14. The elasticity that causes the clamp to return from the locking state to the released state is the flexural elasticity of the clamp.

At least in the locking state, the locking surface 16 of the clamp 14 is closer to the attached end 17 of the clamp compared to the interaction region 21, as clearly shown by observing the right clamp in FIG. 3. In the locking state, the clamp is thus subjected to bending stress between the locking surface 16 and the engagement region 21 (FIG. 6). Thus, there is a beneficial leverage effect that reduces the force that must be applied by the actuator 19 to the clamp 14 for the desired fit between the locking surface 16 and the complementary thread 7. In addition, the bending stress region between the actuator 19 and the locking surface 16 serves to limit the pressure between the locking surface 16 and the complementary threads 7. The above pressure limitation protects the entire fastening device from excessive forces that would otherwise be applied to the actuator 19 due to abuse.

In the example, the actuating element 19 is an actuating ring mounted in rotation relative to the main body 11 about the axis 10 of the threaded cylindrical surface 12. The actuating ring 19 is configured as a protective cover for the clamps 14. The clamps occupy an annular housing 22, the base of which is defined by the main body 11, the perimeter of the peripheral the wall 23 of the acting ring 19, and the ceiling by the upper collar 24 of the acting ring 19.

The actuating ring 19 and the clamps 14 interact through corresponding mating cam profiles 25, 26 and 27 (Figs. 5 and 6).

In the example (see FIGS. 5 and 6), the cam profiles of the actuating ring include, for each clamp 14, a bulge 25. In the released position (FIG. 5), corresponding to the released state of the clamps, each bulge 25 is opposite the groove 26 of the interaction area 21 of the corresponding one of the clamps 14. The clamps are thus allowed to assume, by elastic recovery, their released state, allowing for screwing and unscrewing. In the locking position (FIG. 6), corresponding to the locking state of the clamps, the bulges 25 are in contact with the bulge 27 provided adjacent the loose end 18 of each clamp. The clamp is thus pressed toward the complementary thread 7 such that the locking surface 16 of the clamp assumes a position in locking contact with the complementary thread 7.

The mating cam profiles 25, 26 and 27 define a reinforced point for moving the actuating ring 19 between its locking and released positions. As shown in FIG. 6, the actuating ring reaches its locking position only when the inner bulge 25 of the ring slightly exceeds the apex of the bulge 27 of the clamp 14. This stabilizes the locking state from vibrations and other mechanical disturbances.

In an embodiment, the device includes a locking means that restricts the movement of the actuating element 19 between its locking and released positions. In the example in FIG. 2-6, the actuation ring 19 includes on its inner side wall excessive thicknesses 28 embedded in a circumferential direction between the clamps. Excessive thicknesses 28 are adjacent to the loose ends 18 of the clamps in the released state and to the attached ends 17 of the clamps 14 in the locked state. These excessive thicknesses prevent operational errors that would consist of displacement of the acting element 19 beyond one or the other of its locking and releasing positions, respectively.

As can be understood by observing FIG. 3, the main body 11 and clamps 14 can be created from a single piece by starting from a blank including the main body 11 and a tapered axial tubular extension, then removing material in the tubular extension to leave only the clamps 14 remaining attached to the main body 11 by means of a bridge of material 29. The milling 30 makes a recess in the inner surface of the clamps in order to limit their locking surface 16 to the area adjacent to the attached end 17 (Figs. 3 and 4), as described above.

In an embodiment, the actuating ring 19 has a rotating tool engagement means 31 (FIG. 2) that can be used to rotate the actuating ring 19 relative to the main body 11 between two angular positions of the actuating ring, namely the locking and releasing positions. In this example, the engaging means comprises two engaging devices 31 in the form of recesses formed facing away from the main body 11.

In an embodiment, the fastening device combines, in a single independent unit, the main part 11 with its threaded cylindrical surface 12, at least one clamp 14 and the actuating element 19. For this purpose, the actuating ring 19 is immobilized in the axial direction relative to the main part 11, in a manner not shown in FIG. 2-5, but examples of which will be given with reference to the following drawings.

In an embodiment, the actuating element 19 is permanently connected to the main body 11 or in a manner that prevents disassembly except with the help of a tool, so as not to be lost in use relative to the main body.

The rotation direction of the actuating ring 19 from the released position to the locking position is advantageously the direction of screwing the nut, so as to avoid the tendency for the actuating ring to unscrew the nut when entering the locked state after screwing.

The embodiment in FIG. 7, which will be described only by way of its differences from the embodiment of FIG. 2-6 includes interlocking means for stabilizing the position of the actuating element 19 when it is not actuated, and in particular to avoid that the actuating element has play visible through small movements when it is not actuated, in one direction or the other between its released and blocking positions, respectively.

For this purpose, the main part 11 carries two stoppers 41 and a bulge 42 placed halfway between the two stops 41. The actuating element 19 carries a tooth 43. In each of the blocking and released positions, respectively, of the actuating element 19, a tooth 43 is immobilized between the bulge 42 and the corresponding one of the stops 41. When the actuating element is moved from one to another of its above-mentioned positions, the tooth 43 is elastically deflected to pass the convex 42, with the effect of a reinforced point, to then interlock between the convex 42 and the other stop 41.

When interlocking means are provided, the mating cam profiles 25, 26 and 27 (FIGS. 5 and 6) of the actuating ring 19 and clamps 14 are no longer needed to provide the force point function. However, rigid stops, such as excessive thicknesses 28, which prevent operating errors prone to occur under high force or torque, are preferably retained.

In the illustrated embodiment, the tooth 43 is visible from the outside. Its position indicates the locked or released state, respectively, of the fastening device. The main body 11 bears alignment marks 44, 45 which indicate two possible positions.

The embodiment in FIG. 8, which will be described only by way of its differences with the embodiment of FIG. 2-6 is an example for axially immobilizing the actuator ring 19 relative to the main body 11. An open elastic locking ring 46 is inserted into a peripheral groove 47 of the inner wall of the actuator ring 19. At the same time, a locking ring is inserted into the free space 48 between the main body 11 and clamps 14 (see the right side in Fig. 8). The attached ends 17 of the clips that interrupt the free space 48 include, opposite the slot 47, a slot 49 (left side in FIG. 8) also receiving a retaining ring.

The locking ring 46 is open and thus includes two ends 51. Preferably, the two ends 51 are located in a circular space between the two jaws and are shaped to abut the two jaws related to the circular movement, so that the locking the ring is practically immobilized from rotation relative to the main part 11.

In the embodiment of FIG. 9-12, which will be described only by its differences with the previous embodiment, the retaining ring 46 is located as before in the peripheral groove 47 of the inner surface of the peripheral wall of the actuating ring 19. But this groove is now located facing the peripheral groove 52 formed in the clamps 14. The ends 51 of the retaining ring now also project radially outward into a recess 53 of the actuator ring 19. The circumferential dimension of the recess 53 thus limits the angular movement of the actuator ring 19 relative to the body 11. The recess 53 includes at least one convexity 54 that the engaging ends 51 can pass through the elasticity of the retaining ring 46, this passage creating the effect of a reinforced point.

In the embodiment of FIG. 9, the outer periphery of the actuating ring 19 includes the same engagement device rotation profile 61 as the profiles 13 of the main body 11. It is ensured that in the released state, said engagement devices conform in the axial direction so as to simultaneously engage the rotary tool.

In this embodiment, as shown in FIG. 11 and 12, the cam profiles of the actuator ring 19 and the clamp 14 relate to a corresponding ellipse centered on the axis 10. On the main body 11, thus more specifically here on the clamps 14, the major axis of the ellipse extends substantially through the loose ends 18 of the clamps. The difference between the major axis and the minor axis of these ellipses is, for example, 1 mm. In fig. The 11 major axes are superimposed, making it possible for the clamps to be in a released state. In fig. 12, the minor axis of the actuating ring 19 has been brought closer to the loose ends 18 located on the major axis, which compresses the clamps into a locking state.

In this embodiment, locking is determined by a force applied to the clamps directly behind the locking surface. There is no longer a circular distance between the blocking surface and the interaction area of the actuating ring and the clamp. The optimum force corresponds to the prescribed torque to be applied to the actuator ring 19. Due to the convex surface (convexes 54 in FIG. 9) against which the ends 51 of the locking ring 46 move, the optimal angular position of the actuator ring in the locking state is stabilized regardless of the mentioned position.

In this embodiment, the clamps can be thinner in the radial direction, which allows the impact ring 19 to be radially thicker. This thickness creates recesses 53 that are relatively deep and thus more effective in controlling the movements of the actuator 19.

Of course, the invention is not limited to the examples described and shown.

Features of different embodiments may lead to other combinations.

For example, it is possible to use a locking ring 46 in FIG. 9 in combination with a recess such as 53 but including only a single protrusion 54 separating, with the effect of a reinforced point, a well-defined corner locking position and a corner release position, entirely in combination with clips such as the clips in FIG. 2-6, but actuated through mating cam profiles, not necessarily creating the effect of a reinforced point.

The actuator 19 of the embodiments in FIG. 1-8 may include engagement devices such as 61 in FIG. 9-12, and vice versa, the acting element 19 in FIG. 9-12 may include engagement devices such as 31 in FIG. 1-8. Other embodiments of the engaging devices are also possible.

The interlock system 41-43 and/or alignment marks 44, 45, associated as described or otherwise, or not, can be created in a variety of ways and are applicable to all embodiments.

The locking device may be applied to a threaded portion other than a nut.

Claims (31)

1. Threaded fastening device, lockable when screwed, containing: a body having a threaded cylindrical surface configured to threadably engage complementary threads; at least one clip connected indirectly or directly to the main body and having a locking surface on its side facing, in use, towards the complementary thread, configured and positioned to come into locking contact with the complementary thread, at least one clip extends in a direction that is substantially circular with respect to the axis of the cylindrical surface, between the attached end connected to the main part and the end that is unattached in a substantially radial direction; And an acting element that is moved to a locking or released position to selectively place the clamp into a locking state in which the locking surface exerts locking pressure on the complementary thread, and accordingly into a release state of the respective screwing and unscrewing motion; characterized in that the actuating element is an actuating ring (19) mounted with the possibility of rotation relative to the main part (11) around the axis (10) of the threaded cylindrical surface (12). 2. The device according to claim 1, characterized in that the actuating element (19) is configured to exert on the side (15) of the clamp facing away from the blocking surface (16), a force directed, during use, to the complementary thread (7), The return of the clamp to the released state is accomplished by elasticity. 3. Device according to claim 1 or 2, characterized in that the actuating element (19) presses the clamp (14) by bending in order to move from the released state to the locked state. 4. Device according to claim 1 or 2, characterized in that, at least in the locked state, the locking surface (16) of the clamp is closer to the attached end (17) of the clamp compared to the area (21) of interaction between the clamp (14) and an actuator (19) so as to cause the clamp to experience bending stress between the blocking surface (16) and the interaction region (21) when the clamp is in the blocking state. 5. Device according to one of paragraphs. 1-4, characterized in that the attached end (17) of the clamp is rigidly connected to the main part (11). 6. Device according to one of paragraphs. 1-5, characterized in that the clamp (14) and the main part (11) are made of a single piece of material, while at the same time being connected together at the attached end (17) of the clamp. 7. Device according to one of paragraphs. 1-6, characterized in that the locking surface (16) of the clamp relates to a threaded cylindrical surface (12). 8. Device according to one of paragraphs. 1-7, characterized in that the acting element (19) is permanently attached to the main part (11) or in such a way that it can only be disassembled using a tool. 9. Device according to one of paragraphs. 1-8, characterized in that the impact ring (19) is designed as a protective cover protecting the clamp (14). 10. Device according to one of paragraphs. 1-9, characterized in that the actuating ring (19) is held in the axial direction relative to the main part (11) by means of a locking ring (46). 11. The device according to claim 10, characterized in that the retaining ring includes two ends (51) shaped to come into contact with at least one clamp (14) by means of circular movement, so that the retaining ring is substantially immobilized from rotations relative to the main part (11). 12. Device according to claim 10 or 11, characterized in that for its axial positioning relative to the main part (11) the locking ring (46) is partially located in the free space (48) located between the clamp (14) and the main part (11) . 13. Device according to one of paragraphs. 1-10, characterized in that the locking ring (46) is immobilized from rotation relative to one of the main part (11) and the acting ring (19) and includes at least one projection (51), which interacts with at least one a recess (53) provided in the main body or actuating ring so as to limit the angular movement of the actuating ring (19) relative to the main body (11). 14. Device according to claim 13, characterized in that the recess (53) includes at least one convexity (54), which the protrusion (51) can pass through the elasticity of the locking ring with a reinforced point effect. 15. Device according to one of paragraphs. 1-14, characterized in that the acting ring (19) and the clamp (14) interact through corresponding mating cam profiles (25, 26, 27). 16. The device according to claim 15, characterized in that the cam profile of at least one of the acting ring (19) and the clamp (14) belongs to a corresponding ellipse centered on the axis (10) of the threaded cylindrical surface (12). 17. Device according to claim 15, characterized in that the mating cam profiles (25, 26, 27) define a reinforced point for moving the actuating ring (19) between its blocking and released positions. 18. Device according to one of paragraphs. 14, 15, characterized in that the movement of the actuating element (19) between the locking and released positions passes at least one reinforced point in order to stabilize the locked state of the clamp (14) relative to mechanical excitations, such as vibrations and inertial effects that can occur using. 19. Device according to one of paragraphs. 1-18, characterized in that it contains an interlocking system (41, 42, 43), which stabilizes the acting element (19) in each of its positions, blocking and, accordingly, releasing relatively unwanted mechanical excitations. 20. The device according to claim 19, characterized in that the interlocking system contains a tooth (43), which is placed between two stops (41) interacting with the tooth to limit the movement of the acting element (19) relative to the main part (11), and between two stops of the convexity (42), which the tooth (43) can pass by means of elastic deformation with the effect of a reinforced point. 21. Device according to one of paragraphs. 1-18, characterized in that it contains a locking means (28, 43), which limits the movement of the acting element (19) in its displacements into the blocking and released positions. 22. The device according to claim 21, characterized in that the locking means comprises at least one excessive thickness (28) of the actuating element (19) protruding between the two ends of the clamp. 23. Device according to one of paragraphs. 1-22, characterized in that it contains means (44, 45) indicating the position of the acting element (19). 24. Device according to one of paragraphs. 1-23, characterized in that said fastening device is a nut. 25. The device according to claim 24, characterized in that the main part (11) includes a tubular wall provided inside with a threaded cylindrical surface (12), and in that at least one clamp (14) is at least partially determined by removing material from said tubular wall. 26. Device according to one of paragraphs. 1-25, characterized in that said fastening device combines, in a single independent unit, the main part (11) with its threaded cylindrical surface (12), at least one clamp (14) and an actuating element (19). 27. Device according to one of paragraphs. 1-26, characterized in that at least one clamp contains several clamps (14) distributed around the axis (10) of the threaded cylindrical surface (12), the acting element (19) is common to all clamps.

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