DE3742070A1 - Self-securing screw - Google Patents

Abstract

The intention is to provide a screw which can rotate easily in one direction, but cannot be rotated in the other direction, at least not when a tool is attached on the screw head (16). The screw according to the invention comprises two parts (3, 4). The two parts (3, 4) can be fitted together to form a screw with a circular-cylindrical outer surface (1), said two parts coming into contact with one another at at least three points (5, 6; two can be seen in the Figure). In this arrangement, one point (6) has to lie in the vicinity of the outer surface (1). From the other two points (5), which lie one behind the other in the axial direction, a gap (9) extends to the outer surface (1). Consequently, the two parts (3, 4) can be tilted with respect to one another, thus enlarging the external diameter of the screw. Suitable arrangement of the points of contact (5, 6) results in the screw being rotatable in only one direction. <IMAGE>

Description

The invention relates to a self-locking screw.

A screw is supposed to be created which is easily rotatable in one direction, but which is in the other Don't let the direction turn, at least not if you start with the screw head. in the generally the direction in which the screw can be turned will be chosen that the screw can be screwed in but not screwed out, i.e. in the Clockwise for right-hand screws and counter-clockwise for left-hand screws. On this way a screw is created that is theft-proof or not un can be resolved intentionally.

This object is achieved according to the invention in that the self-locking Screw consists of two parts, that the two parts to a screw with a circle cylindrical outer surface can be assembled, the two parts in this position touch each other at at least three points, two points on one axially parallel straight lines and the third point near the outer surface of the Screw lies, the surroundings of these points of contact on one of the parts flat or concave and flat or convex on the other part and the normals on each of these environments run approximately normal to the screw axis that the axis-parallel straight line is off-center and there is a gap from it to the outer surface the screw extends so that the two parts around the axis-parallel straight line against each other while increasing the diameter of the screw against each other are tiltable and that the tangential plane of the concave or flat reverse  Exercise the third point, the outer surface of the screw at about a right angle cuts and that the normals on the concave or flat surroundings of the First and second point the outer surface of the screw approximately in the right Cut the angle, but go to the side of the screw axis.

The interface between the two parts thus has an axially parallel section in which the three points of contact lie. One of these points, the third, is close to the outer surface of the screw, the tangential plane being approximately normal to the outer surface of the screw through the point of contact, ie that the normal lies thereon approximately in the circumferential direction of the screw. Since the power transmission - apart from frictional forces - takes place in the direction of these standards, the power transmission takes place essentially in the circumferential direction and one part of the screw rotates the other part when it is turned in the direction where this point of contact is subjected to pressure.

However, if you turn one part in the opposite direction, this part tilts along the axis-parallel straight line through the two other points of contact (the first and second point of contact) because of this straight line Gap extends to the outer surface of the screw. The straight line runs off-center and the gap in such a direction that the diameter the screw enlarged during tilting.

The outer surface of the screw is of course not an exact circular cylinder more, so that strictly speaking one no longer speak of a diameter should. In this context, the largest distance should be under diameter two points of the outer surface of the screw can be understood (of course always viewed in section normal to the screw axis).  

If the screw is screwed into a nut or elsewhere, it will achieved by this increase in diameter that the screw jams; they the more you try to solve them, the more you jam.

It must of course be ensured that the two parts actually tilt and not one part rotates the other. This will make him is enough that the normals on the tangential surfaces in the first two Points of contact (this is essentially the direction of power transmission) cut the outer surface of the screw at approximately a right angle; the force is thus initiated approximately in the radial direction, causing the other part is prevented. To at all a power transmission To achieve rotation of a part, it is necessary that the above mentioned Normally do not cut the screw axis. The cutting angle of the normal the outer surface of the screws can never be exactly a right angle be.

To avoid axial forces that are ultimately absorbed by the thread the normals should be on the tangential planes of contact points are normal to the screw axis.

This description speaks of the angle between straight lines, too then if they don't cut each other. This means the angle between the one straight line and an auxiliary straight line, the one straight line cuts and runs parallel to the other straight line.

It is useful if the two parts have a separation surface that one Has section that is generated by axially parallel lines, so that the two parts capable of holding a circular cylindrical screw  result in touching each other at least in two axially parallel distances. Thereby, that the two parts meet each other along stretches and not just in at least Touch three points, the load is in the places where the touch takes place, significantly reduced.

The production of part of the screw is particularly simple if the Ab cut the parting surface of this part is flat and axially parallel. It is there not necessary that the flat section goes through the screw axis. In front especially with screws that are intended for higher loads, it can be advantageous if the part that carries the screw head (and therefore the Absorbs forces in the screw) has a larger cross-sectional area than the other part.

The manufacturer is especially for screws with a not very large diameter especially easy if the flat and axially parallel section through the Screw axis goes.

If the section of the parting surface of one part is flat and axially parallel, is the simplest embodiment of the portion of the interface of the other part characterized in that it consists of two levels and axially parallel sub-areas exist, which are connected by a convex bend are connected.

If the section of the parting surface of one part through the screw axis goes, according to the invention one partial surface of the section of the other Also partly go through the screw axis and contain it, the Angle between the partial surfaces is approximately 15 ° and in one Partial area is the ratio of the widths on both sides of the screw axis  is about 1: 5.

Screws of the type described above can be turned in the direction in which they clamp when you try to turn the screw head when you turn the part that does not support the screw head. If this part is inaccessible, for example because it is covered by the nut into which the screw was screwed, the screw can no longer be loosened. In order to enable loosening of the screw when it is accessible from the rear, it is proposed according to a further feature of the invention that the separation surface of the two parts, in addition to the section produced by axially parallel stretches, has a flat, preferably normal to the screw axis at each of its two ends Have section so that the separation surface is step-shaped. Thus, in the axial direction of the screw , one end is formed by one part and the other end by the other part. If the screw is screwed into a nut, both parts are accessible.

It is then expedient if one of the parts has a customary end Screw head, but the other part has a slot at its end, Phillips or hexagon socket or a hexagonal outer contour, the maximum diameter is less than the core diameter of the screw points. This allows the screw to work from both sides with the appropriate mechanism can be turned, but both parts of the screw can also be used be screwed into a nut from one side.

On the basis of the accompanying drawings, the subject of the invention will be closer wrote.

Fig. 1 shows schematically a section through a screw in the area of the axis-parallel straight line by the generated portion of the separating surface,

Fig. 2a-c show a concrete embodiment of a first part and Fig. 3a-c, a concrete embodiment of a corresponding second part of a screw according to the invention. FIGS . 2a and 3a are a side view normal to the axis, FIGS . 2b and 3b are a top view normal to the axis and FIGS . 2c and 3c are a front view in the axial direction.

In Fig. 1, the outer surface of the screw with 1 and its axis with 2 be distinguished. It consists of two parts, a first part 3 and a second part 4 . It is assumed that the area in which the screw was cut is created by axially parallel stretches, so that the image does not change when the cutting plane is moved a little forwards or backwards along axis 2 . The two parts 3 and 4 touch each other along two sections 5 and 6 , which are only visible as dots in FIG. 1 and run normal to the plane of the drawing. The first part 3 is convex in the region of the contact distances, the second part 4 is flat.

One of the two contact paths, namely 6 , is close to the outer surface 1 of the screw, and also the flat surface of the part 4 is close to the point of contact 6 normal to the outer surface 1 of the screw, ie the angle α is 90 °. The normal 8 on this flat surface, which lies in the drawing plane, that is to say runs normal to the screw axis, therefore intersects the outer surface of the screw at a very acute angle β . If the first part 3 of the screw is rotated counterclockwise, the force is transmitted to the second part 4 along the contact path 6 in the direction of the paint 8 , ie essentially in the circumferential direction. The second part 4 of the screw therefore rotates with it.

The normal to the flat surface of the second part 4 in the area of the other contact section 5 is designated by 7 . This normal 7 , which is also in the plane of the drawing, that is to say normal to the axis 2 of the screw, intersects the outer surface 1 at an angle γ which differs only slightly from 90 °. If the first part 3 is turned clockwise, the force is therefore transmitted to the second part 4 in the direction of this normal 7 , ie essentially radially. As a result, the second part 4 is only pressed outwards, but it cannot rotate with it. It is important that the normal 7 does not intersect axis 2 ; otherwise the convex area of the first part 3 could move parallel to the flat area of the second part 4 .

From the second contact section 5 , a gap 9 extends to the outer surface of the screw. If you turn the first part 3 clockwise (whereby, as described above, the second part 4 cannot rotate), the two parts 3 and 4 tilt against each other by the contact distance 5 , the width of the gap 9 decreasing until press both parts 3 and 4 firmly against the nut. The gap 9 must therefore be sufficiently wide to enable tilting which is sufficient to achieve an increase in diameter which is greater than the play between the screw and the nut. This prevents the first part 3 from rotating clockwise.

With reference to FIGS. 2a-c and 3a-c is described a simple concrete execution example.

The screw consists of two parts, a first part 11 and a second part 21 . The separating surface between the two parts each has three sections: two flat surfaces perpendicular to the screw axis, namely 12 and 13 or 22 and 23 and a section 14 a and 14 b or 24 , which is generated by axially parallel paths . Both parts 11 and 21 are thus stepped at their end.

The section 24 of the second part 21 produced by axially parallel paths is flat and runs through the screw axis. The section 14 a and 14 b of the first part 11 produced by axially parallel paths consists of two flat partial surfaces 14 a and 14 b , one partial surface, namely 14 a, extending through the screw axis. The two partial surfaces 14 a and 14 b merge into one another at a bend 15 , the angle δ between these two partial surfaces 14 a and 14 b being 15 °. In one partial area 14 a , the ratio a: b of the widths on both sides of the screw axis is 1: 5. (The drawings are not to scale.) These dimensions have proven to be very reliable with screws with an M10 thread.

The screw described can be turned if you turn the first or second part 11 or 21 clockwise. So it can - if you assume a right-hand thread - screw in when you turn the screw head 16 of the first part 11 , and unscrew when you turn the second part 21 .

Claims (8)

1. Self-locking screw, characterized in that it consists of two parts ( 3 , 4 ), that the two parts can be assembled into a screw with a circular cylindrical outer surface ( 1 ), in this position the two parts at least three points apart ( 5 , 6 ), of which two points ( 5 ) lie on an axially parallel straight line and the third point ( 6 ) lies near the outer surface ( 1 ) of the screw, the surroundings of these contact points ( 5 , 6 ) on one of the Parts ( 4 ) are flat or concave and on the other part ( 3 ) are flat or convex and the normals ( 7 , 8 ) run approximately normal to the screw axis ( 2 ) in each of these surroundings, so that the axis parallel straight line is off-center and away from this a gap ( 9 ) to the outer surface ( 1 ) of the screw, so that the two parts ( 3 , 4 ) can be tilted against each other around the axis parallel straight line by increasing the diameter of the screw and that the tangentia live the concave or flat environment of the third point ( 6 ) intersects the outer surface ( 1 ) of the screw at approximately a right angle ( α ) and that the normals ( 7 ) on the concave or flat surroundings of the first and second points ( 5 ) die Cut the outer surface ( 1 ) of the screw at approximately a right angle ( γ ), but pass the screw axis ( 2 ) sideways. ( Fig. 1) 2. Self-locking screw according to claim 1, characterized in that the two parts ( 11 , 21 ) have a separating surface which has a section ( 14 a and 14 b or 24 ) which is produced by axially parallel paths, so that the two Parts ( 11 , 21 ) in the position in which they together form a cylindrical screw, touch each other at least in two axially parallel distances. 3. Self-locking screw according to claim 2, characterized in that the section ( 24 ) of the separating surface of a part ( 21 ) is a flat and axially parallel. 4. Self-locking screw according to claim 3, characterized in that the flat and axially parallel section ( 24 ) goes through the screw axis. 5. Self-locking screw according to claim 3 or 4, characterized in that the section ( 14 a and 14 b ) of the separating surface of the other part ( 11 ) consists of two flat and axially parallel partial surfaces ( 14 a and 14 b ), which have a convex bend ( 15 ) are interconnected. 6. Self-locking screw according to claim 4 and 5, characterized in that a partial surface ( 14 a ) of the section ( 14 a and 14 b ) of the other part ( 11 ) passes through the screw axis and contains that the angle ( δ ) between the partial surfaces ( 14 a , 14 b ) is approximately 15 ° and that in the one partial surface ( 14 a ) the ratio of the widths on both sides of the screw axis (a: b) is approximately 1: 5. 7. Self-locking screw according to one of claims 2 to 6, characterized in that the separating surface of the two parts ( 11 , 21 ) except for the section produced by axially parallel sections ( 14 a and 14 b and 24 ) at each of their two ends have flat, preferably normal to the screw axis section ( 12 , 13 or 22 , 23 ), so that the separating surface is stepped. 8. Self-locking screw according to claim 7, characterized in that one of the parts ( 11 ) has a conventional screw head ( 16 ) at its end, but the other part at its end a slot, cross recess or hexagon or a hexagonal outer contour, the maximum diameter is less than the core diameter of the screw.