DE202012000041U1 - Hexalobular external force attack and hexalobular tool for the operation of a hexalobular internal force attack - Google Patents

Abstract

Hexalobular external force attack (10; 110), characterized in that its end face (16; 116) is rounded towards the outside at the outer edge.

Description

Although hexalobular force attacks have the advantage that very large forces can be transmitted via small force attacks, but often there is the problem that the nut with stationary tool does not or only with difficulty slipping on the screw head, or a tool for operating a hexalobulären Innenkraftangriffs difficult is to introduce. Frequently, such hexalobular force attacks, which are also referred to as inner or Außenlensechsrund applied in applications in which a guided by a handling unit tool is placed laterally with its nut on the screw head. Here it happens that then the praise of the nut on the praise of the drive and the nut slips only with wobbling on the apparatus on the drive. If the worker forgets the wobbly, or the workers do not do it physically, the nut sits not at all or only partially on the drive and this is then destroyed or over-tightened when applying very high torques.

So far, you could solve the problem of difficult placement of the tool in hexalobular force attacks only by shaking and pressing the screwing or by switching to another force attack with more play between the screw drive and tool, for example, on a conventional hexagon drive.

It is therefore an object of the present invention to provide a hexalobular external force attack and a hexalobular tool for actuating a hexalobular Innenkraftangriffs in which the placement of the tool is facilitated by the fact that the tool slips much easier on the drive, so much less axial force and no Wobbles on the tool are required.

According to the invention, this object is achieved by a hexalobular external force attack, whose end face is rounded at the outer edge to the outside.

It is particularly preferred if the cross section of the individual lobes is also rounded or arcuate parallel to the axis of rotation of the external force attack to the end face.

So that this rounding does not lead to a reduction of the transmittable torque, it is further proposed to form the rounding of the praise in the release direction with a much larger radius and over a greater distance parallel to the axis of rotation of the force application, as in the tightening direction.

Further, the present object is achieved by a tool with hexalobular for actuating a hexalobulären Innenkraftangriffs, wherein the end face of the tool is rounded at the outer edge to the outside.

Again, it is preferred if the cross section of the individual praise parallel to the axis of rotation of the tool to the end face is also rounded or arcuate.

In order to get no losses in the torque to be transmitted, here too, it is particularly preferred that the rounding of the Laben is executed in the release direction with a much larger radius and over a greater distance parallel to the axis of rotation of the tool, as in the tightening.

The present invention will be explained below with reference to the embodiment shown in the accompanying drawings. It shows.

1 a Außensechsrund force attack for a screw, wherein on the right of the axis of rotation, the execution method according to the prior art is shown, while on the left the development of the invention is shown; and

2 another embodiment of the present invention with asymmetrically rounded praise.

1 shows an external force attack 10 for a screw 12 , where half of the representation to the right of the axis of rotation 14 shows the state of the art how such hexalobulären or hexagon round force applications that are available, for example under the names TORX ^® and TORXPLUS ^® in the market, has now been executed.

The left half, so the representation left of the rotation axis 14 shows the embodiment of the invention in an external force attack 10 the same wrench size, in order to highlight in this way the individual details of the invention in contrast to the prior art particularly clearly.

The illustrated external force attack 10 according to the prior art has at its head end face 16 As shown in the right half of the picture, only a bevel of 15-35 ° at the edge. This then goes with a sharp edge in the individual praise or praise 18 above.

In contrast, the praise goes 18 ' on the left side of the illustrated external force attack 10 with a radius R flowing in the face over. The radial rounding with the radius R is on this lobe, which is shown exactly from the side 18 ' particularly recognizable.

At the adjacent praise 18 '' can be seen in the upper part, that the praise invention also a rounding 20 in tangential or circumferential direction. That means the praise 18 ' . 18 '' a rounded top shape of its cross section parallel to the axis of rotation 14 or along the circumference of the force application 10 exhibit.

In the illustrated embodiment, the tangential rounding is round with a radius r. Likewise, however, a differently shaped rounding, for example, with an elliptical or parabolic shape is also conceivable.

2 shows a further embodiment of the invention. In this embodiment, it is achieved that even by rounding the praise no reduction of the possible tightening torque occurs. For this purpose is in 2 the rounding in the tangential or circumferential direction formed asymmetrically.

In the 2 illustrated screw 112 also has an outer six-round force attack or hexalobular outside force attack 110 on. Again, the face is 116 designed so that they have a large radius R in the vertical side walls 119 . 121 the praise 118 passes. As it is the illustrated screw 112 as usual, a right-hand screw acts on the right side wall 119 the forces when tightening the screw, while the forces when loosening the screw on the left side wall 121 be transmitted.

To the inventive rounding of the upper end of the praise 118 no torque transmission capability to lose, here is only the left side wall 121 , about when tightening the screw 112 no forces are transmitted, with a large radius r 'over a long distance parallel to the axis of rotation 114 the screw 112 rounded, while the right side wall 119 with a very small radius r '' and only over a very short distance parallel to the axis of rotation 114 the screw 112 is trained.

For a left-hand screw, of course, the design of the right and left side walls of praise would have to be swapped accordingly.

The present invention requires less axial force and less physical effort to thread hexalobular force attacks.

So far, in the prior art in the above problems has been transferred to another force attack, mostly on the classic hexagonal force attack, but this is disadvantageous because the hexalobular force attacks in terms of weight, cost, transmissible torque and wear by far the best drive are.

The production of a rounded off-round hexagonal force application according to the invention is also very simple, since such hexalobular internal force attacks, both for screws and for corresponding tools, are produced from a cylindrical blank. According to the invention, the blank must then first be rounded off at the outer edge of its end face. Only then does the usual rolling or press forming take place in the hexalobular form. In this case, by appropriate reshaping of the forms readily the tangential or along the circumference extending rounding can be applied. The production costs are therefore only minimally higher than in the case of an external hexagonal force attack according to the prior art.

According to the tools slide easily on the drive as soon as only slight pressure is built up.

According to the prior art, the experts were always convinced that force attacks of all kinds should be as square and edged with possible parallel to the forces acting with the tools parallel surfaces to the highest possible torque transmission at the lowest risk of deformation or damage to achieve the tools and the force attacks.

Deviating from this general opinion of the experts, the present invention proposes for the first time intentionally to round off force attacks or tools to allow for a significantly lower torque-transmitting capability, a much easier touchdown of the tool. Here, the embodiment according to claim 3 and 6 is particularly preferred because here the loss of torque-transmitting capacity in the much more important tightening direction is practically negligible.

Claims (6)

Hexalobular external force attack ( 10 ; 110 ), characterized in that its end face ( 16 ; 116 ) is rounded at the outer edge to the outside. Hexalobular external force attack ( 10 ; 110 ) according to claim 1, characterized in that the cross section of the individual praise ( 18 ; 118 ) parallel to the axis of rotation ( 14 ; 114 ) of the external force attack ( 10 ; 110 ) to the face ( 16 ; 116 ) is also rounded or arcuate. Hexalobular external force attack ( 110 ) according to claim 2, characterized in that the rounding of the praise ( 118 ) in the release direction with a much larger radius (r ') and over a greater distance parallel to the axis of rotation ( 114 ) of the force attack ( 110 ) is formed, as in the tightening direction. Hexalobular tool with external force attack for actuating a hexalobulären Innenkraftangriffs, characterized in that the end face of the external force attack is rounded at the outer edge to the outside. Hexalobuläres tool according to claim 4, characterized in that the cross section of the individual praise parallel to the axis of rotation of the tool to the end face also rounded or arcuate. Hexalobuläres tool according to claim 5, characterized in that the rounding of the praise is formed in the release direction with a much larger radius and over a greater distance parallel to the axis of rotation of the tool, as in the tightening.

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