FR2743399A1 - Screw with single rotational direction head - Google Patents

Abstract

The screw has a head (12) provided with device enabling it to be rotated and a threaded shank (14). The head has the shape of a disc of diameter (D) greater than the root diameter (d) of the threaded shank. On its periphery are two raised zones (18,20) separated from the shank. These zones each have axial engaging faces (18a,20a) and ramps (18b,20b) opposite these faces. The two faces are located diametrically opposite so as only to allow an engaging tool (24) to rotate in a single rotational direction (R1) of the screw. The engaging faces are turned in the direction (R'1) opposite to the direction (R1) in which the screw thread (16) is wrapped round from the head and the ramps are inclined in the same direction as the thread.

Description

 The present invention relates to a screw comprising at least a first head provided with first means to allow the rotation drive and a threaded barrel.

 For certain particular applications, it may be desirable to allow only one direction of rotation of the screw.

 For example, in a first type of application for which the first head is a single head, it may be necessary to allow only the screwing and to ensure that the screw cannot be unscrewed. We thus endow the assembled assembly with the screw of a safety against any uncontrollable disassembly since, since the screw cannot be unscrewed, this assembly can only be disassembled if it is partially destroyed.

 For a second type of application, it may be desired to allow only unscrewing using the first head of the screw. In this case, the screw preferably has a second head connected to the first by a breaking neck and it is possible to tighten it using the second head until a predetermined tightening torque beyond which the breaking neck is broken. Then, using the first head, which remains alone secured to the threaded barrel, it is possible to loosen the screw for disassembly, but it is impossible to continue to tighten the screw beyond the maximum desired torque. This is a safety measure to prevent the desired maximum torque from being exceeded.

 We know, from the French patent application published under the number 2 220 160, a single-head screw, provided with projecting bosses on its transverse end face. After tightening the screw, only two bosses, which allow the rotary drive only in the direction of loosening, remain on this head. The operation consisting in making these bosses requires a delicate surfacing of the end of the head.

 The present invention aims to ensure that the first means for permitting rotational drive, produced in an extremely simple and economical manner, only allow rotational drive in one direction.

 For this purpose, said first head has the overall shape of a disc with a diameter greater than the current diameter of the threaded barrel and has, on its periphery, two zones raised so as to move away from the barrel, these zones each having a substantially axial grip face and a ramp opposite to this grip face, the two grip faces being located in substantially diametrically opposite positions and being arranged so as to allow the engagement of a rotary drive tool only in one direction of rotation of the screw.

 The raised areas are made by a simple partial cutting operation, extremely fast, which can be easily carried out and does not require any particular precision.

The invention will be well understood and its advantages will appear better on reading the detailed description which follows, of embodiments shown by way of nonlimiting examples. The description refers to the accompanying drawings in which:
FIG. 1 is an elevation view of a screw according to the invention according to a first embodiment,
FIG. 2 is a top view of FIG. 1,
FIG. 3 is an elevation view showing a screw according to a second embodiment, and
- Figure 4 is a top view of Figure 3.

 FIG. 1 shows a screw 10 comprising a first head 12 and a threaded barrel 14 provided with a thread 16.

 The diameter D of the first head is greater than the current diameter "d" of the threaded barrel, this current diameter being the diameter which the barrel has over most of its length. The head 12 generally has the shape of a flat disc, with the exception of two peripheral zones 18 and 20 raised axially in the direction moving away from the barrel. In other words, the head 12 has a substantially planar end transverse face 12 ′, from which the two zones 18 and 20 project.

 In the example shown, the head 12 is connected to the barrel by means of a frustoconical portion 22 which widens from the barrel towards the head. It extends beyond this frustoconical portion over a distance "e".

 The head could also be directly connected to the barrel, without a frustoconical portion. Its diameter is however greater than that of the barrel, so that its axial periphery projects radially beyond the axial periphery of the barrel.

 The raised areas 18 and 20 each have a substantially axial grip face, respectively 18a and 20a. More precisely, these faces are generally each included in a plane defined by the axial direction of the screw and by a transverse direction. They are therefore substantially perpendicular to the transverse end face 12 'of the first head 12.

 The raised areas 18 and 20 also each have a ramp, respectively 18b and 20b, opposite the grip face.

 The two grip faces 18a and 20a are located in substantially diametrically opposite positions. They are therefore located on either side of the head of the screw, but may not be exactly arranged along a diameter of this head, so as to allow the insertion of a tool, such as the blade a screwdriver, shown in broken broken lines and indicated by the reference 24 in Figure 2, between the two grip faces and arranged according to a diameter.

 As can be seen in FIG. 2, when it is desired to have a tool engaged on the first head 12, it is only possible to make the blade of this tool cooperate with the two gripping surfaces so as to drive the screw in rotation in a direction opposite to the direction towards which the gripping faces are directed. Thus, the blade 24 of the tool shown diagrammatically in FIG. 2 can only rotate the screw in the direction of rotation R1 by pressing on the faces 18a and 20a. If an attempt is made to pivot this blade in the other direction, that is to say in the direction R'1 towards which the faces 18a and 20a are turned, it slides on the head and on the ramps 18b and 20b without being able to be blocked by any surface. It is therefore not possible to turn the screw in direction R'1.

 -The screw shown in Figures 1 and 2 has a single head. The gripping faces 18a and 20a only allow it to rotate in the direction R1, that is to say in the direction of its screwing. Indeed, the thread 16 of the threaded barrel is wound, when considered from the head 12, that is to say in the direction of the arrow F directed from the head 12 towards the threaded barrel, in the direction of rotation R1. The gripping faces 18a and 20a are turned in the direction R'1 opposite to the direction of rotation R1, and the ramps 18b and 20b are inclined in the same direction as the thread 16.

 Figures 3 and 4 show a screw according to the invention according to a second embodiment. In these figures, elements similar to those of the screw in FIGS. 1 and 2 are given the same references increased by 100. The screw 110 therefore has a first head 112 and a threaded barrel 114. The head 112 is similar to the head 12 Figures 1 and 2 and is provided with raised peripheral zones 118 and 120.

 The screw 110 further comprises a second head 140 provided with second means to allow the drive in rotation and a rupture neck 142 located between the first head 112 and the second head 140 and connecting them to each other .

 In the example shown, the second head 140 has axial grooves 144. A grip key 146, for example made of plastic, is force-fitted or molded onto this second head, and the grooves 144 prevent it from turning by compared to that head. The screw can therefore be tightened manually without tools by operating the socket key 146.

 Of course, the second head 140 could be provided with all types of means enabling it to rotate, such as a slot for inserting the blade of a screwdriver, or a polygonal contour for engaging a screwing wrench.

 Whatever the embodiment chosen for these second rotational drive means, it is possible to screw the screw through the second head 140 until the rupture neck 142, which occurs when the a predetermined desired maximum tightening torque has been reached.

We see that, unlike the embodiment of Figures 1 and 2, the grip faces 118a and 120a are rotated in the same direction as the direction in which the net 116 is wound when considered in the direction
F going from the first head to the barrel 114. This winding direction is designated by the reference R2.

 On the other hand, the ramps 1 18b and 120b are inclined in the opposite direction to the thread 116.

 Thus, after the rupture of the rupture neck 142, it is possible to arrange a rotary drive tool similar to the tool 24 of FIG. 2 engaged against the grip faces 1 18a and 120a, tool using which it is then possible to drive the screw in rotation only in the direction R'2 of the unscrewing opposite to the direction of rotation R2.

 The raised zones 18, 20, 118 and 120 are produced by cutting radially, in two substantially diametrically opposite positions, the overflow zone of the first head beyond the threaded barrel or the frustoconical connection portion, and by axially raising a side of this cutout. One of the faces of the cutout will constitute the grip face, while the other face, which is opposite to it, remains in its normal position as indicated by the reference 150 in FIG. 3.

 In fact, before these partial cuts, the first head 12 or 112 has the shape of a flat disc, the thickness of which is clearly less than the diameter.

 The gripping faces can project beyond the transverse end face 12 ′, 112 ′ of the first head of the screw over a height H substantially equal to the thickness E of the first head. This makes it possible both to provide the gripping faces with a height sufficient to effectively allow the engagement of a tool under satisfactory conditions, while carrying out the partial lifting operation only over an amplitude admissible by the material. , usually metal, without deterioration.

 As seen in Figures 1 and 2, the transverse dimensions "t" of the gripping faces can be substantially equal to the width "e" of the overflow of the axial periphery of the first head 12, 112 beyond the periphery of the threaded barrel 14, 114. If the frustoconical portion 22 of connection is present, this overflow width is measured from the junction of the frustoconical portion and the first head.

Claims (6)

1. Screw comprising at least a first head (12, 112) provided with first means for allowing the rotation drive and a threaded barrel (14, 114),  characterized in that said first head (12, 112) generally has the shape of a disc of diameter (D) greater than the current diameter (d) of the threaded barrel (14, 114) and has, on its periphery, two zones ( 18, 20; 118, 120) raised so as to move away from the barrel, these zones each having a substantially axial grip face (18a, 20a; 118a, 120a) and a ramp (18b, 20b; 118b, 120b ) opposite this grip face, the two grip faces being located in substantially diametrically opposite positions and being arranged so as to allow a tool (24) for driving in rotation to come into engagement only in one direction of rotation of the screw (R1, R'2). 2. Screw according to claim 1, characterized in that the grip faces (18a, 20a) are turned in the direction (R'1) opposite to the direction (R1) in which the thread (16) is wound from the first head (12), while the ramps (18b, 20b) are inclined in the same direction as the net. 3. Screw according to claim 1, characterized in that it further comprises a second head (140) provided with second means for allowing the drive in rotation and a rupture neck (142) connecting this second head to the first (112), and in that the two gripping faces (118a, 120a) are turned in the same direction (R2) as the direction in which the net (116) is wound from the first head (112) , while the ramps (118b, 120b) are inclined in the opposite direction to the thread (116), so that the gripping surfaces allow only the engagement of a rotary drive tool in the direction of unscrewing. 4. Screw according to any one of claims 1 to 3, characterized in that the grip faces (18a, 20a; 1 18a 120a) protrude beyond the transverse end face (12 ', 112') of the first head (12, 112) over a height (H) substantially equal to the thickness (E) of said first head. 5. Screw according to any one of claims 1 to 4, characterized in that the transverse dimensions (t) of the gripping faces (18a, 20a, 118a, 120a) are substantially equal to the width (e) of the overflow of the axial periphery of the first head (12, 112) beyond the periphery of the threaded barrel (14, 114). 6. Screw according to any one of claims 3 to 5, characterized in that the second head (140) of the screw (110) is provided with a socket key (146).