CH619518A5 - - Google Patents

Description

The present invention relates to a hollow head fixing element and more particularly to the drive device of such an element. The latter comprises a multi-lobe cell into which a correspondingly shaped drive tool is introduced. The end face of the hollow head comprises an auxiliary or breakdown slot which makes it possible to drive the element using a normal tool, such as a screwdriver or the like, which is engaged in said cell .

As will be seen in more detail below, hollow head fasteners comprising an auxiliary drive means in the form of a breakdown slot are well known. By way of example, they are described by United States patents No. 2,556,155, No. 2,395,476, No. 2,359,898, No. 2,322,509, No. 2,173,707, N No. 2,140,449, No. 1,910,182, No. 422,307, No. 6,729 and by British Patent No. 1,027,698.

These prior patents mainly describe fastening elements with a primary drive cell delimited by flat surfaces which intersect to form a drive means, either hexagonal or square. The numerous drawbacks of the drive means of the hexagonal or square type are due to their relatively sharp corners and result in a low conversion efficiency of the torque exerted in the drive torque. In addition, hexagonal or square type cells are subjected in the radial direction to intense forces which can lead to failure during their training. As a result, in recent years, lobular drive means or systems, such as that described in U.S. Patent No. 3,584,667, have been shown to be more effective than hexagonal or square and have been widely used in industry.

Although arrangements of the lobed type have been proposed comprising a drive means or auxiliary breakdown slot, for example in the aforementioned US Pat. No. 2,556,155, the overall design of these systems involves a reduction in the efficiency of the primary drive system which is due to the presence of the slot. More particularly, these auxiliary slots of the prior art open into the cell in locations such that they have the effect of removing a volume of material which would normally constitute part of the surface against which the lobe of the tool d training is meant to wear. This results in an impairment of the functional characteristics of the primary drive system, that is to say of its ability to support and transmit the torque. To give this primary system the overall resistance it needs, normally in the prior art models, deepening of the cell is used, which is intended to increase the depth of engagement and the contact surface. In certain cases, the circumferential wall which delimits the alveolus is thickened. These modifications tend to complicate the production of the fastening elements and that of the tools necessary for the formation of the cell.

As noted above, lobed drive systems are widely used. They include lobes which, in section, have curved surfaces. The present invention relates to a system of this type. Such a system, which includes curved lobes, offers certain advantages by the fact that it allows a drive tool to be inserted fairly easily in the cell. From this point of view, in accordance with industrial standards and practice, the dimensions of the terminal part of the drive tool are slightly smaller than those of the cell, in order to facilitate mutual engagement of these parts. During the drive of the fixing element, the contact between the surfaces of the corresponding lobes is not total because of this difference in dimensions. In fact, it has been found that the lobes are in contact only on relatively small surface areas which are determined by the length of the contacting surfaces and the depth to which the drive tool is engaged in the aoleole of the 'element of

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fixation. However, it should be noted that the degree of contact between the surfaces obtained with lobed drive systems is much higher than that which can be obtained with more conventional hexagonal or square systems. In addition, and as described in great detail in the aforementioned US Pat. No. 3,584,667, the small drive angle results in an effective conversion of the torque exerted into radial torques, which are produced during the drive of the fastener and which can lead to a rupture of the wall of the cell.

The present invention therefore relates to the fastening element defined in claim 1, the main or primary drive system of the lobed cell type further comprises an auxiliary drive or recovery means, the presence of which does not have significant influence on the operating characteristics of the main system.

The invention will be described in more detail with reference to the attached drawing by way of nonlimiting example and in which:

Figure 1 is a perspective view of a fastener according to the invention and of the terminal part of a drive tool which can come into engagement with said element;

Figure 2 is a plan view of the drive head of the member shown in Figure 1;

Figure 3 is a partial section of a fastening element 'of the invention and shows the end part of a drive tool intended to be engaged in the cell of said element;

and Figure 4 is a partial section of the drive head of a fastener of the invention, in which the tool is engaged, the corresponding lobes being in contact as they are while the fastener is entrained sinis-trorsum.

We will first describe the features of the new improved drive system and the corresponding tool. Next, their mode of cooperation will be described, in conjunction with FIG. 4.

Figure 1 shows a fastener 10 which comprises an elongated rod 12 having at one end a head 14 of larger dimension. The opposite end of the rod 12 may include a thread 16 of conventional design or any other desirable means for engaging the fastener with a workpiece (not shown). The head 14 comprises a primary drive system in the form of a lobed cell 20. A drive tool 22 shown comprises an end portion 24 of lobed form which is intended to be engaged in the cell 20.

Figures 2 to 4 show the particular shape of the cell 20 which constitutes the primary drive system of the fastening element 10. From this point of view, the cell 20 is delimited by an internal surface of the wall of the head which can be described as being lobed and which consists of several alternating grooves 30 and lobes 32. The grooves 30 and the lobes 32 are constituted by a first series of concave surfaces 34 and, by a second series of convex surfaces 36 which connect regularly as shown in FIG. 4. The surfaces 34 and 36 are oriented axially with respect to the 'cell, the bottom wall 37 of which is conical,

as shown in Figure 3,

It can be seen in FIG. 4 that the radius of curvature 40 of the surfaces 34 of the first series is much smaller than the radius of curvature 42 of the surfaces 36 of the second series. In the embodiment shown, the ratio between these dimensions is of the order of 4 or 5: 1. Consequently, the circumferential length of the convex surfaces 36 of the second series is much greater than that of the surfaces 34 of the first and it results from this relationship of the lobes 32 which are oriented radially inwards.

The particular model of cell 20, which is shown and which has been described above, is essentially that which is described in the patent of the United States of America No. 3,584,667 cited above. However, the cell 20 represented is only one of the types of lobed drive cell which can be implemented in the present invention.

The end portion 24 of the drive tool 22 has a corresponding shape which includes multiple lobes. More particularly, this end portion 24 comprises lobes and grooves 50, 52 respectively, arranged alternately, which, of course, have an opposite shape with respect to those of the cell 20, so as to match the opposite lobes and grooves 32 and 30 of the latter. That is to say that, while the surface 36, whose radius of curvature 42 is the largest, delimits the lobes 32 of the cell, the surfaces whose radius of curvature is smallest delimits the lobes 50 of the end part of the drive tool.

In accordance with standards and constant industry practice, the surfaces which delimit the lobes 50 and the grooves 52 of the drive tool have dimensions slightly smaller than those of the corresponding surfaces of the cell, which delimit the grooves. 30 and the opposite lobes 32. In practice, these differences in dimensions are constantly observed by all the manufacturers of fasteners and tools, thus making it possible to provide a small clearance between the respective parts when the end portion 24 of the tool is engaged in the cell. 20. The radial clearance, which is visible in FIG. 4, of course varies from one part to another and depends on the actual manufacturing tolerances of the corresponding parts. For this purpose, the manufacturers of fasteners and tools have determined size standards for the various accepted drive systems, such as that of the embodiment described which is sold under the trade name TORX.

FIG. 4 shows how the lobes 32 and 50 come into contact when the sinistrorsum drive device is rotated. It should be noted that the lobes 32 and 50 are in contact only along the surfaces 60, as can be seen in FIG. 4. This contact is due to the slightly smaller dimensional tolerances of the end portion 24 intended to spare the radial clearance necessary so that it can be easily engaged in the cell. The contact zone 60 is disposed radially outward from the innermost point of the lobe 32 and, relative to the lobe 50, radially inward from its outermost point. In addition, if the tool 22 is turned in the opposite direction, for example to tighten the fastening element 10, the contact zones 60 ′ are located on the opposite sides of the lobes 50 and 32.

Finally, the head 14 may possibly include a slight counterbore 64, which can be seen in FIGS. 1 and 3, intended to facilitate the engagement of the tool in the cavity 20. It can also be seen in FIG. 3 that the upper surface of the lobes 32 of the cell comprises an inclined surface 65 which is intended to allow the end portion 24 to engage even more easily in the cell. Although the aforementioned inclined surface 65 and counter bore 64 are advantageous, they are of course only optional with regard to the present invention.

The fastening element according to the invention comprises an auxiliary or secondary drive means which is used in connection with the primary drive system constituted by the lobe-20 socket. It should be noted from this point of view that the cell 20 has lobes of a shape such that at least two grooves 30 are diametrically opposite. Consequently, first and second slots 72, 74 cut on the end face of the head 14 are preferably aligned radially s

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on the center of curvature of a concave curved surface 34 of the corresponding groove 30. When the tool 22 is removed, the slots 72, 74 of the cell 20 provide the space necessary for the introduction of a tool d secondary drive (not shown) in the form of a screwdriver or the like.

Each slot is delimited by two spaced and parallel side walls 75, 76 (FIG. 4), an oblique or inclined end wall 78 and a flat bottom wall 80 which is generally perpendicular to said side walls 75 and 76. The latter extend axially from the end face 82 of the head 14 and radially inwards from the oblique end wall 78 to the concave curved surface 34 which delimits the corresponding groove.

It is particularly important to note that said side walls 75 and 76 intersect the curved surface 34 at locations 84 and 86, as shown in FIG. 4. These locations 84 and 86 are arranged along the surface 34 radially outside parts of the surfaces 36 which delimit the contact zones 60 and 60 '. As a result, when the tool 22 bears against the wall of the cell 20, the entire surface of each lobe 32 resists the force exerted by the lobe 50 despite the presence of the auxiliary or breakdown slots 72 and 74. Consequently, and as indicated above, the functional characteristics of the primary drive system which is constituted by the cell 20 are in no way altered by the presence of the auxiliary drive hub constituted by the slots 72 and 74.

It should also be noted that the slots 72 and 74 terminate before the peripheral wall 90 of the head 14. Consequently, the wall of the cavity 20 of the head 14 is circumferentially continuous. This is important because slots which fully pass through the wall of the head tend to reduce the overall strength of the fastener. More particularly, when the fixing element is mounted and a torque is applied to it to tighten it firmly against the part, the rod 12 undergoes a tensile force when the head 14 bears against the part. If the auxiliary slots pass entirely through the head, the forces exerted on the latter tend to cause the wall which delimits these slots to collapse or deform and then prevent an auxiliary tool from being inserted therein.

The particular model of cell 20 described above corresponds to that of the aforementioned United States patent No. 3,584,667 which is sold under the trade name TORX. This model makes it possible to obtain a drive angle io 92 of the order of 10 to 20 °. In the technique of fasteners, the drive angle is between a line passing along the contact surfaces 60 and the radial axis of the corresponding lobe 50. In practice, the smaller the drive angle 92 , the higher the efficiency of the drive system, that is to say the ratio of the torque exerted on the drive torque transmitted to the element, is high. Therefore, the exerted torque which is transmitted from the tool to the fixing element can be divided into a vector which does not fulfill any useful function and into a tangential vector which represents the driving torque exerted on the element. . The smaller the drive angle 92, the larger the tangential vector and therefore the higher the efficiency of the drive system.

Consequently, when the fixing element of the invention is used with the drive system of the particular type shown in the drawings and described in the aforementioned United States patent, it makes it possible to get some additional benefits. More particularly, because the radial force or the elements of the torque are extremely small, the thickness of the wall can be reduced, which therefore allows significant savings in raw material. In addition, due to the absence of damaging radial forces, it is possible to extend the slots 72 and 74 to a point very close to the peripheral wall, without any risk of weakening the drive head. As a result, the range of dimensions of the tools which can be used with the auxiliary drive slots is increased.

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1 sheet of drawings

Claims (6)

619,518 2 1. Hollow head fastening element comprising a rod at one end of which is arranged an enlarged head comprising a multi-lobe drive cell, the surface of the wall of the lobed cell being constituted by a first series of curved surface concave and by a second series of convex curved surfaces, said surfaces connecting regularly to delimit grooves and alternating lobes of the cell, at least two grooves being diametrically opposite, said cell being intended to accommodate the terminal part of a tool drive the corresponding shape of which comprises multiple lobes, each lobe of said end portion bearing against a first region of the surface of the wall of the cell when the dextrorsum fastener is rotated and against a second region opposite of said surface of the cell wall when the sinistrorsum fastener is rotated, said first and second regions being mainly located in said convex curved surfaces of the wall, fastening element characterized in that it comprises an auxiliary drive means (72 and 74) formed in said head (14) and comprising first and second opposite slots (72 and 74) which cooperate with said cell (20) so as to allow. the introduction of another drive tool for driving said fixing element (10), each slot (72 or 74) being associated with one of the diametrically opposite grooves (30) and opening into the socket (20) by one of the concave curved surfaces (34) which delimit said grooves (30), each slot (72 or 74) being partially delimited by two spaced and parallel side walls (75 and 76) extending axially from the face of end of said head (14) and towards the outside of the cell (20), the surfaces of said side walls (75 and 76) intersecting said concave curved surface (34) of the corresponding groove (30) at locations (84 and 86) spaced along said surface (34) and arranged radially outward of said first and second regions (60 and 60 ') in contact with the lobes (50) of the drive tool, so that the presence of said slots (72 and 74) does not reduce the dimensions of the surface of said areas against which pe Can carry the lobes (50) of the drive tool (22). 2. Fastening element according to claim 1, characterized in that each slot (72 or 74) comprises an end wall whose surface (78) is disposed below the peripheral surface of the head (14) so that the wall of said cell (20) is continuous all around its circumference. 3. Fastening element according to one of claims 1 and 2, characterized in that the radius of curvature (42) of the surfaces (36) of the second series is at least twice the radius of curvature (40) of the surfaces (34) of the first series, so that the circumferential length of said lobes (32) is greater than that of said grooves (30). 4. Fastening element according to any one of claims 1 to 3, characterized in that said rod (12) comprises a threaded part (16). 5. Fastening element according to any one of claims 1 to 4, characterized in that each slot (72 or 74) comprises a flat bottom wall (80) which is substantially perpendicular to said side walls (75 and 76) and to the 'axis of said cell (20). 6. Fastening element according to any one of claims 1 to 5, characterized in that the depth of each slot (72 or 74) is equal to or less than half the depth of said grooves (30) of the cell.