EP1382418A1 - Schraubvorrichtung bestehend aus einer Schraube mit Spezialkopf und einem für diesen Kopf geeigneten Steckschlüssel - Google Patents

Abstract

The screwdriver chuck is designed to engage with screw heads that have stepped layers (4, 8), one with teeth and a smaller smooth one to receive the tips (22) of the chuck's jaws (17). The chuck consists of a socket (10) with a hexagonal shank (12) and two cavities (13, 14) for the screw head and jaws to receive the screw head. A third cavity (15) contains an axial core that presses against the end face of the screw head.

Description

The present invention relates to a screwing device involving a screws whose head is specially adapted for a grasping and screwing in a screwing device such as, for example, a screwdriver / unscrewer motorized.

Generally, we know that the screw heads are shaped according to tools which are used to secure their screwing or unscrewing and possibly the nature of the material into which the screw is screwed.

• des formes de guidage coopérant avec des formes correspondantes de l'embout pour assurer un centrage de la vis coaxialement à l'axe de rotation de l'embout,
• des formes aptes à coopérer avec des moyens de retenue de la douille pour maintenir la tête de la vis engagée dans l'embout avec possibilité d'extraction, préalablement et pendant l'opération de vissage,
• des moyens de couplage qui coopèrent avec des moyens correspondants de l'embout pour permettre à ce dernier d'entraíner la vis en rotation. Habituellement, le processus de centrage est obtenu en utilisant des têtes de vis dont la surface cylindrique, prismatique, voir même conique, est sensiblement complémentaire à au moins une portion de la surface intérieure de l'embout dans laquelle elle vient axialement s'engager.

Thus, in the case where the screwing / unscrewing is carried out by means of a screwdriver equipped with a screwing bit, the head of the screw must necessarily comprise three types of shape:

• guide shapes cooperating with corresponding shapes of the end piece to ensure centering of the screw coaxially with the axis of rotation of the end piece,
• forms capable of cooperating with means for retaining the socket to keep the head of the screw engaged in the end piece with the possibility of extraction, beforehand and during the screwing operation,
• coupling means which cooperate with corresponding means of the nozzle to allow the latter to drive the screw in rotation. Usually, the centering process is obtained by using screw heads whose cylindrical, prismatic, or even conical, surface is substantially complementary to at least a portion of the interior surface of the end piece in which it axially engages.

The means for retaining the screw head inside the bit can be produced in various ways, namely: elastic clamp, O-rings elastically deformable, permanent magnets, gripping jaws, etc.

The coupling means for driving the screw in rotation are intervene, at the level of the head, concave forms (for example cruciform impressions), convex shapes (for example, teeth) or flats (flats), these shapes being intended to come into engagement with shapes of the screwdriver bit to transmit a screwing torque.

In order to improve the gripping function of the screw head by the screwdriver bit, US Pat. No. 6,240,811 proposes a screw having a head with circular edge and, set back from said edges, a portion polygonal inscribed in a circle of diameter smaller than that of the head but higher than that of the threaded rod of the screw.

The screwing / unscrewing of this screw is obtained by means of a bit comprising two movable grip and drive jaws axially inside a socket and being able to tilt one with respect to the other by closing against each other when moving to the inside of the socket thanks to the action of a conical shape of the socket on a corresponding shape of the jaws.

The inner ends of the jaws have conformations substantially complementary to those of the screw head and the portion subheader.

Thanks to these arrangements, in the open position of the jaws, it is possible to engage the head of a screw between the above conformations.

Then causing a displacement of the screw / jaw assembly towards inside the end piece, the jaws are closed.

The head of the screw is then trapped in the jaws whose ends engage on the polygonal sub-header portion.

The gripping, centering and coupling functions are exclusively here secured by the jaws.

It turns out that this solution has a number of drawbacks.

Because they serve to ensure the transmission of the drive torque in screw rotation, the jaws must have relatively large dimensions important and be made of a very resistant material. In addition, the mechanism associated with the jaws must be designed and dimensioned so as to ensure an effective grip of the jaws on the sub-head portion of the screw (on which is exercised by the training couple). As a result, the tip of screwing is necessarily long and bulky, which makes it unusable in a number of applications.

Furthermore, in the closed position, the part of the jaws engaging on the sub-head portion of the screw protrudes outside the socket. Thereby, during screwing, the jaws may therefore come into contact with the parts that we are fixing and damaging them.

This drawback also results from the angular (or even serrated) shape of the sub-head portion of the screw which comes into contact with the part to be screwed. It is especially manifest when the screw engages obliquely in the piece to screw.

The invention therefore more particularly aims to remove these disadvantages.

It proposes, for this purpose, a screwing device involving a screw comprising a head preferably having at its periphery conformations intended to cooperate with a screwing tool to exert on the screw a torque and a cylindrical sub-head portion, the diameter is less than that of the head but greater than that of the threaded rod of the screw, the connection between this cylindrical portion with the periphery of the head and with the end of the rod being effected by means of radial shoulders.

This screw is specially designed for a screwdriver bit comprising a socket capable of being rotated, for example, by a screwdriver / unscrewer, this socket having at one of its ends a coaxial cavity opening to the outside so that it can receive the head of the opinion. The inner surface of the socket which delimits this cavity presents conformations capable of engaging with those of the head of the screw, so to be able to ensure the transmission of the tightening torque. This tip is provided gripping means which engage in the space between the two above shoulders, during the introduction of the screw head inside the nozzle until it comes into abutment against the above-mentioned cylindrical sub-head portion, at the end of engagement.

Thanks to these provisions, the rotation drive function is ensured separately from the gripping function.

The drive function is directly ensured by the tip socket which can be shaped like a conventional pipe wrench and present in consequently a minimum thickness, taking into account the torque it must exercise on the screw.

The gripping means no longer having a rotational drive function may therefore have reduced dimensions without, however, lose efficiency.

The centering means can be provided both by the sleeve and by the gripping means: this arrangement allows the use of head screws relatively flat which could slightly swivel in a nozzle classic screwing. In this case, the action of the gripping means on the part cylindrical sub-head confirms this centering at the end of introduction of the screw in the socket.

According to a particularly advantageous embodiment of the invention, the screw sleeve comprises a coaxial core, fixed relative to the sleeve, which extends in the aforesaid cavity, so as to delimit, inside this one, a substantially cylindrical anterior volume inside which can introduce the head of the screw and an annular volume in which are mounted axially movable the aforesaid gripping means, these means of gripping comprising gripping members which engage in said gripping anterior volume of the socket.

The gripping means, the wall of the sleeve delimiting the above-mentioned volume annular, as well as the coaxial core, are shaped so that that they occupy an open position when they are in a position front limit switch, position in which the screw head can be engaged in the anterior volume and a closed position when they occupy a rear end position, position in which the screw head is located trapped inside the anterior volume and abuts on the face anterior of the core, the axial displacement of the gripping means of the open position to the closed position being obtained by the action of the head of the screw on said gripping means during its introduction inside the previous volume.

Advantageously, the aforesaid gripping means may consist of jaw having in their front part a notch in which the peripheral edge of the screw head can engage in position closed, the front edge of the jaws then coming into abutment on the part cylindrical screw head.

The nucleus may successively include an anterior part cylindrical, a cylindrical central part of smaller diameter and a rear part flaring backwards so as to constitute a ramp.

The jaws may have in the vicinity of their rear ends a face exterior provided with a groove in which an elastic ring and a oblique inner face intended to cooperate with the rear part of the core of so as to cause, during an axial displacement of the jaws towards the rear, a tilting of said jaws causing them to close.

The socket may advantageously include, in the bottom of the cavity, a annular flare in which the rod can partially engage, after elastic deformation to lock the jaws in the closed position, the unlocking is then only obtained by exerting a pull on the jaws axial of sufficient amplitude for the rod to deform elastically can escape the flare.

Les figures 1 à 3 sont des vues respectivement en coupe axiale, en vue de côté et en vue de dessus d'une tête de vis selon l'invention.

Les figures 4 et 5 sont des vues en perspective de la vis illustrée sur les figures 1 à 3.

Les figures 6 et 7 sont les coupes axiales d'un embout de vissage, en position de vissage (fig. 6) et en position d'insertion/extraction d'une vis (fig. 7).

Les figures 8 et 9 sont des vues de l'extrémité de la visseuse dans laquelle s'engagent les vis, ces vues correspondant respectivement aux positions illustrées sur les figures 6 et 7.

La figure 10 est une vue de face d'une variante d'exécution de l'embout de vissage.

La figure 11 est une coupe axiale selon A-A' de l'embout représenté figure 10, en position fermée des mors.

La figure 12 est une coupe axiale selon A-A' de la figure 10, en position ouverte des mors.

La figure 13 est une vue à plus grande échelle d'une fraction de la coupe représentée figure 11.

An embodiment of the invention will be described below, by way of nonlimiting example, with reference to the appended drawings in which:

Figures 1 to 3 are views respectively in axial section, in side view and in top view of a screw head according to the invention.

Figures 4 and 5 are perspective views of the screw illustrated in Figures 1 to 3.

Figures 6 and 7 are the axial sections of a screwdriver bit, in the screwing position (fig. 6) and in the insertion / extraction position of a screw (fig. 7).

FIGS. 8 and 9 are views of the end of the screwdriver in which the screws engage, these views corresponding respectively to the positions illustrated in FIGS. 6 and 7.

Figure 10 is a front view of an alternative embodiment of the screwdriver bit.

Figure 11 is an axial section along AA 'of the nozzle shown in Figure 10, in the closed position of the jaws.

Figure 12 is an axial section along AA 'of Figure 10, in the open position of the jaws.

FIG. 13 is an enlarged view of a fraction of the section shown in FIG. 11.

In the example shown in Figures 1 to 5, only the head of the screw was represented with only the start of the rod, it being understood that the invention is not limited to a particular type of screw. So this screw could present a classic type thread or a self-tapping thread ending in a point autoperforante.

This screw head 1 has a curved upper face 2 with in the center a injection cuvette 3. The presence of this cuvette only exists in the case where the head is molded. On the other hand, in the case of cold forging (rolling), the upper side of the head will be continuously domed. The peripheral edge 4 of the head 1 is serrated and here comprises fifteen teeth 5 separated by indentations 6 forming an angle of approximately 117 °.

This head 1 is connected to a coaxial rod 7 via a cylindrical sub-head portion 8 whose diameter is substantially equal to the distance between the bottom of the notches and the axis X, X 'of the screw. In this example, the height of the cylindrical portion 8 is substantially equal to the height of the head 1. The diameter of the rod 7 of the screw, at its connection to the cylindrical portion 8, is much less than that of the head 1 (approximately 50%), the connection between the cylindrical portion 8 with the peripheral edge 4 of the head 1 and with the end of the rod 7, effected by means of radial shoulders R ₁ , R ₂ .

Of course, this screw can be screwed using a hand tool having a tubular end piece whose internal profile corresponds to the external shape serrated head 1.

However, it is particularly suitable for the screwdriver bit illustrated in Figures 6 to 9 which essentially comprises a tubular sleeve 10 closed on one side by a bottom 11 extended coaxially by a rod 12 of hexagonal section intended to engage in the chuck of a screwdriver.

• une première chambre 13 destinée notamment à recevoir la tête 1 de la vis, cette chambre 13 présentant une section à profil dentelé (denture 16) sensiblement complémentaire de celui de la tête 1 de la vis,
• une deuxième chambre 14 dans laquelle s'engagent des mâchoires de préhension 17 lorsque la tête 1 de la vis est engagée dans la première chambre 13, et
• une troisième chambre 15 dans laquelle coulisse un noyau 19 d'actionnement des mâchoires 17, cette chambre 15 étant équipée d'un dispositif (non représenté) permettant au noyau 19 de se déplacer axialement dans les chambres 13, 14, 15 entre deux positions stables correspondant respectivement aux positions "ouverte et fermée" des mâchoires 17, en passant par un état instable dans l'intervalle des deux positions stables.

This socket 10 has on the side opposite the rod a coaxial cavity comprising three successive chambers 13, 14, 15, namely:

• a first chamber 13 intended in particular to receive the head 1 of the screw, this chamber 13 having a section with serrated profile (teeth 16) substantially complementary to that of the head 1 of the screw,
• a second chamber 14 in which grip jaws 17 engage when the head 1 of the screw is engaged in the first chamber 13, and
• a third chamber 15 in which slides a core 19 for actuating the jaws 17, this chamber 15 being equipped with a device (not shown) allowing the core 19 to move axially in the chambers 13, 14, 15 between two stable positions corresponding respectively to the "open and closed" positions of the jaws 17, passing through an unstable state in the interval between the two stable positions.

The jaws 17 consist of steel tongues comprising each, at one of their ends (outside of the socket), an edge oblique 20 and, on the side opposite this edge, a defined lateral notch 21 by a C-shaped profile whose two parallel branches are spaced from each other by a distance slightly greater than the thickness of the head 1 of the screw.

This notch 21 defines with the extreme edge 22 of the tongue a protrusion of width at most equal to the height of the cylindrical portion sub-head 8 of the screw.

Furthermore, each tab comprises, in its part opposite to the notch 21 on the same side as the latter, a protuberance 23 intended to engaging on a shoulder 24 of the core.

• une position rentrée dans laquelle les bords extrêmes 22 arasent l'extrémité antérieure de la douille 10, les échancrures 21 se trouvant en conséquence à l'intérieur de la douille 10 de manière à retenir la tête 1 de la vis, et
• une position déployée dans laquelle les extrémités des languettes ressortent de la douille 10 et sont orientées radialement vers l'extérieur de manière à ce que les échancrures 21 soient suffisamment espacées les unes des autres pour pouvoir recevoir la tête 1 de la vis.

Each tongue partially engages and can axially slide in a guide groove 25 formed in the inner surface of the sleeve 10, at the level of the first chamber 13, so as to be able to assume two axially offset positions, namely:

• a retracted position in which the end edges 22 level off the front end of the sleeve 10, the notches 21 being consequently located inside the sleeve 10 so as to retain the head 1 of the screw, and
• a deployed position in which the ends of the tongues protrude from the sleeve 10 and are oriented radially outward so that the notches 21 are sufficiently spaced from each other to be able to receive the head 1 of the screw.

To be able to obtain such a spacing, the bottom of the guide grooves 25 extends obliquely to the axis of the sleeve 10 and widens towards the end of the latter.

Furthermore, the anterior ends of the tongues comprise, on the opposite side protrusions 23, notches through which a coaxial rod passes elastic 26 whose action tends to keep their oblique parts 20 against oblique bottoms of the gorges 25.

Thanks to these arrangements, in the deployed position (illustrated in FIG. 7), the head of the screw between the jaws, at the level of the cavities 21, the top of the head 1 abutting on core 19.

An axial pressure is then exerted on the screw which causes displacement axial of the core 19 / jaw 17 assembly towards the inside of the sleeve 10.

During this movement, the jaws 17 close due to the action of the oblique bottoms on the oblique edges 20 of the tongues.

• Le profil dentelé de la douille 10 est en prise avec celui de la tête 1 de la vis de manière à pourvoir lui transmettre un couple de vissage.
• Les protubérances 22 des languettes ne ressortent pas de la douille 10 et ne peuvent donc pas endommager la pièce à visser. Il en est de même pour les dentures 16 de la douille 10 qui se terminent grâce à un chanfrein légèrement en amont de l'orifice de la douille 10.
• Le centrage de la vis est assuré à la fois par l'engrènement des profils dentelés de la douille (denture 16) et du bord dentelé de la tête 1 de la vis et par l'action des protubérances 22 contre la portion cylindrique sous-tête 8 de la vis.
• Les mâchoires 17 ne participent pas à l'entraínement en rotation et ne subissent donc pas de contraintes importantes : leur mécanisme peut donc être allégé et mieux adapté à leurs fonctions de préhension et de centrage.
• L'entraínement en rotation de la vis est directement assuré par la douille 10. De ce fait, on utilise de façon optimale la forme tubulaire de cette douille pour assurer la transmission du couple de vissage.

This movement continues until the jaws 17 are in the retracted position (second stable position). In this position, the head 1 of the screw is trapped in the socket 10, position in which:

• The serrated profile of the sleeve 10 is engaged with that of the head 1 of the screw so as to provide it with a screwing torque.
• The protrusions 22 of the tongues do not protrude from the socket 10 and therefore cannot damage the part to be screwed. It is the same for the teeth 16 of the socket 10 which terminate by means of a chamfer slightly upstream of the orifice of the socket 10.
• The centering of the screw is ensured both by the engagement of the serrated profiles of the sleeve (toothing 16) and of the serrated edge of the head 1 of the screw and by the action of the protrusions 22 against the cylindrical sub-head portion. 8 of the screw.
• The jaws 17 do not participate in the rotational drive and therefore do not undergo significant constraints: their mechanism can therefore be reduced and better suited to their gripping and centering functions.
• The rotational drive of the screw is directly provided by the sleeve 10. As a result, the tubular shape of this sleeve is optimally used to ensure the transmission of the tightening torque.

The disengagement of the screw, out of the socket, is carried out by exerting a force tension between screw and bushing 10. Under the effect of this traction, the assembly jaws 17 / core 19 is attracted towards the outside of the sleeve 10 and undergoes a displacement towards the deployed position.

During this movement, the tongues are held on the bottom oblique grooves 25 and are deployed away from each other.

At the end of the stroke (deployed position), the ends of the tabs are sufficiently spaced from each other so that the head 1 of the screw can be checked out.

In the example illustrated in FIGS. 10 to 13, the screwing bit 30 has been designed for a screw 31 having a conformation similar to that of Figures 1 to 5, it being understood that, as previously mentioned, the invention is not limited to this single type of screw.

This end piece 30 comprises a tubular socket 32, of external shape cylindrical, closed by a bottom 33 extended coaxially by a rod 34, of hexagonal section, intended to engage in the chuck of a screwdriver.

This socket 32 has, on the side opposite the rod 34, a coaxial cavity open on the side opposite the bottom 33 and having, in its front part, a cross section with serrated profile 35 substantially complementary to that of the head 3 of screw 31.

In this example, the sleeve 32 includes three internal axial grooves 36 to 120 ° from each other, inside which three respective jaws engage 37. These jaws each consist of a tongue of thickness that is substantially equal to the width of the axial grooves 36 and which is cut so as to have a substantially straight outer face 38 and an inner face successively comprising, going from the rear towards the front, a face oblique 39, a curved recess (leave) 40, followed by a straight portion 41 substantially axial forming an acute angle with the oblique face 38, a steep front radial recess 42 bordering, on the inside, a notch 43 and a radial protuberance 44 limiting the notch 43 on the outside. This protrusion 44 ends radially set back with respect to the portion straight 42.

In its rear part, the rectilinear external face 38 includes a notch 45 in which an elastic ring 46 coaxial with the end piece 30 engages.

Furthermore, the screwing tip 30 further comprises a core 47 constituted by a cylindrical rod having a threaded end 48 intended to come screw into a coaxial threaded hole opening into the bottom of the cavity of the socket 32. This core 47 comprises beyond its threaded part 48 successively a conical part 49 tapering towards the outside of the sleeve 30, a cylindrical part 50 of small diameter, a step 51 to rounded edge and a large diameter cylindrical part.

This core 47 delimits with the socket 32, on the one hand a substantially cylindrical front volume V ₁ , the external cylindrical surface of which is serrated, this front volume V ₁ having a shape at least in part substantially complementary to that of the head 31 'of the screw 31, and, on the other hand, a posterior annular volume V ₂ in which the jaws 37 partially engage.

Thanks to these arrangements, the jaws 37, guided in the axial grooves 36, can move between a front end position (open position illustrated in figure 12) and a fixed rear end position (closed position illustrated in Figures 11 and 13).

In the front end position, which is illustrated in FIG. 12, the recess 40 of the inside face of the jaws 37 abuts on the tiered edge 51 of the core 47. Under the effect of the elastic ring 46, the rear part of the inside face of the jaws 37 encloses the portion cylindrical 50 of the core 47. The jaws 37 are rocking on the edge rounded 51 of the tier and are therefore kept in the open position, position in which their outer face 38 comes to bear on the front edge 53 of the socket 32.

In this open position, the space between the protrusions 44 is sufficient to allow the passage of the head 31 'of a screw 31. This can therefore engage in the volume delimited by the notches 43 until it comes to rest on the steep front recesses 42 which border the notches 43.

By exerting a force tending to engage the head 31 'of the screw 31 inside the sleeve 32, an axial displacement of the jaws 37 is caused to the rear.

During this movement, the oblique portion 39 of the inner face of the jaw 37 slides first on the cylindrical part 50, then on the part oblique 49 of the core 47 causing the closing of the jaws 37 which tilt around the rounded edges 51 of the tier until they come apply to the cylindrical surface 52 of the core.

In this position, which is illustrated in FIG. 11, the peripheral border of the head 31 'of the screw 31 is trapped in the notches 43 of the jaw 37, while at the end of the race the elastic ring 46 snaps into place, after having been elastically deformed in an annular cavity 54 provided in the bottom 33 of the socket 32 opposite the rear part of the part oblique of the core 47.

This snap-in ensures axial locking of the jaws 37 in closed position of the jaws.

Jaw unlocking cannot then be obtained, for example at the end of the screwing the screw, only by exerting a relative traction between screw and bit, in order allow the elastic band to escape from the throat by deforming elastically.

Thanks to these arrangements, a gripping with centering is obtained particularly effective, in particular because the head 31 ′ of the screw 31 is is trapped in the notches 43, the protrusions 44 coming in support on the sub-cylindrical portion of the screw 31. The threshold of unlocking of the jaws 37 may be determined by an appropriate choice of the elasticity and possibly the shape of the rod.

Furthermore, an important advantage of the previously described solution consists in that, in the closed position, the head 31 ′ of the screw 31 comes directly in contact with the core, which is fixed to the socket 32. As a result, the axial forces generated on the rod 34, in the direction of the screw 31, are directly reflected on the head 31 'of this screw. So this type of tip 32 can be used in particular for the screwing of self-drilling percussion screws in a material such as, for example, aerated concrete.

Another advantage of this solution is that the core is removable and is therefore interchangeable with cores whose anterior surface has a form specifically designed for the type of screw you want to screw. So, this anterior face could, for example, have a slightly concave and include in its central part a protuberance intended to come and engage in a central cavity of complementary shape provided in the head of the screw. Conversely, the shape of the central part of the anterior face of the core may be concave, so as to be able to receive a protuberance coaxial of complementary shape provided in the head of the screw.

Claims (19)

Screwing device involving a screw and a gripping and screwing end of a screwing device,
characterized in that : the head of the screw has at its periphery (4) conformations intended to cooperate with the end piece to exert on the screw a screwing torque, and a cylindrical sub-head portion (8) whose diameter is less than that of the head (1) but greater than that of the threaded rod (7) of the screw and which extends between the planes of two shoulders (R ₁ , R ₂ ), while the tip comprises, on the one hand, a socket (10) capable of being rotated and having at one of its ends a coaxial cavity opening to the outside, so as to be able to receive the head (1 ) of the screw, the inner surface of the sleeve (10) which delimits this cavity having at least one conformation capable of coming into engagement with that of the head (1) of the screw, to ensure a torque of screwing and, on the other hand, gripping means (17) which engage in the space between the planes of the said shoulders (R ₁ , R ₂ ) to come to bear on the said cylindrical portion (8). Screwing device according to claim 1,
characterized in that the aforesaid tubular sleeve (10) is closed on one side by a bottom (11) extended coaxially by a rod (12) of hexagonal section intended to engage in the mandrel of a screwdriver, this sleeve having at least two successive chambers, namely: a chamber (13) intended in particular to receive the head (1) of the screw, this chamber (13) having a section with a serrated profile (toothing (16)) substantially complementary to that of the head (1) of the screw, a second chamber (14) in which engage gripping jaws (17) when the head (1) of the screw is engaged in the first chamber (13). Device according to claim 2,
characterized in that the aforesaid bush comprises a third chamber (15) in which slides an actuating core of the jaws (17), this chamber (15) being equipped with a device allowing the core to move axially between two stable positions . Device according to one of the preceding claims,
characterized in that the above-mentioned jaws consist of steel tongues each comprising, at one of their ends situated on the outside of the sleeve, an oblique edge (20) and, on the side opposite to this edge, a lateral notch (21) delimited by a profile in the form of (C) whose two parallel branches are spaced from each other by a distance slightly greater than the thickness of the head (1) of the screw. Device according to claim 4,
characterized in that the aforementioned notch (21) defines with the end edge (22) of the tongue a protuberance of width at most equal to the height of the cylindrical sub-head portion (8) of the screw. Device according to one of claims 4 and 5,
characterized in that each tongue comprises in its part opposite the notch (21), on the same side as the latter, a protuberance (23) intended to come into engagement on a shoulder (24) of the core. Device according to one of claims 4 to 6,
characterized in that each tongue partially engages and can slide axially in a guide groove (25) formed in the inner surface of the sleeve (10), at the level of the first chamber (13), so that it can take two axially offset positions, namely: a retracted position in which the end edges (22) level the front end of the sleeve (10), the notches (21) being accordingly inside the sleeve (10) so as to retain the head (1 ) of the screw, and a deployed position in which the ends of the tongues protrude from the socket (10) and are oriented radially outwards so that the notches (21) are sufficiently spaced from one another to be able to receive the head (1) of the opinion. Device according to claim 7,
characterized in that the bottom of the guide grooves (25) extends obliquely with respect to the axis of the sleeve (10) and widens towards the end of the latter. Device according to one of claims 6 to 8,
characterized in that the front ends of the tongues comprise, opposite the protrusions (23), notches through which an elastic coaxial rod (26) passes, the action of which tends to hold their oblique parts (20) against the oblique bottoms grooves (25). Device according to claim 1,
characterized in that the screwing sleeve (32) comprises a coaxial core (47) fixed relative to the sleeve (32) which extends in the aforesaid cavity, so as to delimit, inside the latter, a substantially cylindrical anterior volume (V ₁ ) inside which the head (31 ′) of the screw (31) can be introduced and an annular volume (V ₂ ) in which the abovementioned gripping means are mounted axially mobile, these gripping means comprising gripping members which engage in said anterior volume (V ₁ ) of the sleeve. Device according to claim 10,
characterized in that the gripping means, the wall of the sleeve (32) delimiting the aforesaid annular volume (V ₂ ), as well as the coaxial core (47), are shaped so that these gripping means (37 ) occupy an open position when they are in a front end position, position in which the head (31 ') of the screw (31) can be engaged in the front volume (V ₁ ) and a closed position when they occupy a rear end position, position in which the head (31 ') of the screw (31) is trapped inside the front volume (V ₁ ) and abuts on the front face of the core (47 ), the axial displacement of the gripping means (37) from the open position to the closed position being obtained by the action of the head (31 ') of the screw (31) on said gripping means (37) during its introduction inside the anterior volume (V ₁ ). Device according to claim 11,
characterized in that the aforesaid gripping means consist of jaws (37) having in their front part a notch (43) in which the peripheral edge of the head (31 ') of the screw (31) can engage closed position, the front edge of the jaws (37) then coming into abutment on the sub-cylindrical part of the screw (31). Device according to one of claims 10 to 12,
characterized in that the core (47) successively comprises a cylindrical front part (51), a cylindrical central part (50) of smaller diameter and a rear part (49) which widens towards the rear so as to constitute A ramp. Device according to one of claims 12 and 13,
characterized in that the jaws (37) have, in the vicinity of their rear ends, an outer face provided with a groove (45) in which engages an elastic ring (46) and an oblique inner face (39) intended to cooperate with the rear part of the core (47) so as to cause, during an axial displacement of the jaws (37) towards the rear, a tilting of said jaws (37) causing their closure. Device according to one of claims 12 to 14,
characterized in that the aforesaid bushing (32) comprises, in the bottom of the cavity, an annular flare (54) in which the ring (46) can partially engage, after elastic deformation to lock the jaws (37) in position closed. Screwing bit used in the screwing device according to one of the preceding claims,
characterized in that it comprises, on the one hand, a socket (10) capable of being driven in rotation and having at one of its ends a coaxial cavity opening to the outside so as to be able to receive the head (1) of the screw, the inner surface of the sleeve (10) which delimits this cavity having at least one conformation capable of coming into engagement with that of the head (1) of the screw, so as to be able to ensure a torque of screwing and, on the other hand, gripping means (17) which engage in the space between the planes of the above shoulders (R ₁ , R ₂ ) to engage the said cylindrical portion (8). End piece according to claim 16,
characterized in that the screwing sleeve (32) comprises a coaxial core (47), fixed relative to the sleeve (32), which extends in the said cavity, so as to delimit, inside the latter ci, a substantially cylindrical anterior volume (V ₁ ) inside which the head (31 ') of the screw (31) can be introduced and an annular volume (V ₂ ) in which the above-mentioned means are axially movable gripping (37), these gripping means (37) comprising gripping members (43) which engage in said anterior volume (V ₁ ) of the sleeve (32), and in that the gripping means (37) , the wall of the sleeve (32) delimiting the aforesaid annular volume (V ₂ ), as well as the coaxial core (47), are shaped so that the gripping means (37) occupy an open position when they are in a front end position, position in which the head (31 ') of the screw (31) can be engaged in the volum e front (V ₁ ) and a closed position when they occupy a rear end position, position in which the head (31 ') of the screw (31) is trapped inside the anterior volume (V ₁ ) and abuts on the front face of the core (47), the axial displacement of the gripping means from the open position to the closed position being obtained by the action of the head (31 ') of the screw (31) on said gripping means (37) during its introduction inside the anterior volume (V ₁ ). End piece according to claim 17,
characterized in that the aforesaid gripping means consist of jaws (37) having in their front part a notch (43) in which the peripheral edge of the head (31 ') of the screw (31) can engage closed position, the front edge of the jaws (37) then coming into abutment on the cylindrical sub-head part of the screw (31), and in that the core (47) successively comprises a cylindrical front part (52), a part cylindrical central unit (50) of smaller diameter and a rear part (49) widening towards the rear so as to constitute a ramp. End piece according to either of Claims 17 and 18,
characterized in that the jaws (37) have, near their rear ends, an outer face (38) provided with a groove (45) in which an elastic ring (46) engages and an oblique inner face intended to cooperate with the rear part of the core (47) so as to cause, during an axial displacement of the jaws (37) towards the rear, a tilting of said jaws (37) causing them to close, and in that the said sleeve comprises in the bottom of the cavity, an annular flare (54) in which the rod (46) can partially engage, after elastic deformation to lock the jaws (37) in the closed position.

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