DE8611120U1 - Screw connection - Google Patents

Description

Description

The invention relates to a screw connection in which the screw passes through two parts in order to fix them to one another, with inner members arranged on both sides of one of the parts, which are flat on their respective surface that comes into contact with one part, while the surfaces of the parts facing away from the flat surface are curved and interact with oppositely curved surfaces of adjacent, outer members, whereby the screw passes through the members and the bore diameter of the inner members and of the part arranged between the inner members is larger than the outer diameter of the screw.

A screw connection of this kind is known from US-PS 3,220,289. Due to the design of the inner and outer links, a tension-free connection of the two parts is ensured even if the two parts do not fit together parallel. The screw connection has an inner and an outer link on each side of one of the parts, whereby the curved surface of the respective inner link is convex and the curved surface of the respective outer link is concave. The bore diameter of the relevant part surrounded by the links and that of the individual parts is larger than the outer diameter of the screw, which is to be understood as meaning that the inner diameter is larger than the outer diameter of the screw by such an amount that the screw can be pivoted within the relevant inner diameter in order to compensate for the lack of parallelism between the two parts to be fastened. The disadvantage of the known screw connection is that all four links have a larger inner diameter and

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Thus, when the two parts are clamped together, the axial offset of the links increases with the increasing non-parallelism of the parts, which reduces the size of the contact surfaces between the respective links. Apart from that, it is considered disadvantageous with the known screw connection that the screw bolt is not precisely guided in the relevant outer link, since the inner diameter of this outer link is also larger than the screw diameter.

10 Due to the lack of guidance of the links with respect to the

screw, the assembly of the screw connection is complicated. On the other hand, between the two

-., clamping parts an unfavourable force connection, for example

wise in the area of the head of the screw, which with its

-.: 15 the contact surface facing the outer member is not on a

_; defined circular ring surface of the outer member,

but rather on a ring surface of different thickness, which unnecessarily subjects the screw head to bending stress.

It is the object of the present invention to avoid the described disadvantages of the known screw connection.

The problem is solved in that one of the inner links has a concave and the other of the inner links has a convex curved surface, which interact with corresponding convex or concave curved surfaces of the outer links, whereby the contact surfaces between the respective inner and outer links run parallel to each other and the through hole widens conically from the concave surface of one inner link to the convex surface of the other inner link.

The screw connection according to the invention enables a

Safe clamping of parts that do not fit together in parallel, while simultaneously maintaining longitudinal and transverse tolerances between

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the two parts can be balanced. By designing the inner links with oppositely curved surfaces, these links describe a pivoting movement around a common pivot point when the two parts are clamped together, regardless of the position of the two parts relative to one another, whereby the respective contact area between the inner and outer links remains approximately the same* By designing the surfaces of the inner and outer links according to the invention, an inner diameter of the outer links can be selected that is as large as the outer diameter of the screw, i.e. the screw can be pushed straight through the outer links. The latter enables optimized guidance of the screw while simultaneously allowing the two parts to move relative to one another when not clamped.

The screw connection according to the invention is structurally much simpler if the outer member, which interacts with the convex inner member, forms a unit with one of the parts. In contrast to the prior art mentioned, the fourth member can thus be dispensed with, and the screw connection therefore only consists of two inner and one outer member.

Advantageously, the bore diameter of the part arranged between the inner links is larger than the bore diameter of these links in the area of the part. The increase in the diameter of the part results in an increased longitudinal and transverse displacement of this part in relation to the other part.

The angular mobility of the parts relative to each other can be influenced by the design of the contact surfaces. If only angular mobility around one axis is to be possible

/ it is advisable to design the curved surfaces of the inner links in the shape of barrel segments / in the case of mobility around several axes, the curved surfaces of the inner links have the shape of spherical segments.

In addition to the longitudinal and transverse tolerances, depth tolerances can also be compensated if the part arranged between the inner links is designed as an angle part, with one leg of the part being penetrated by the screw connection and an elongated hole running in the longitudinal direction of the other leg through which a screw passes.

Further details, features and advantages of the invention emerge from the following description of an embodiment based on the drawing. The figure shows a section of the mounting of the engine of a motor vehicle in the front frame of the vehicle's body. A holder is attached to the side of the engine 1 by means of a screw 2. The holder has a eJbwa horizontally running flange 4 on its underside, which is connected by means of the screw connection 5 according to the invention to a damping block 7 arranged in the front frame 6 of the body. The damping block 7 has an upper, concave, spherical segment-shaped receiving surface 8 with a threaded hole 9 arranged centrally in it. The flange 4 has a flat, upper surface 10 and a flat lower surface 11, an upper inner member, which is also flat on the underside, comes into contact with the upper surface 10, and a lower inner member 13, which is flat on the top, comes into contact with the lower surface. The lower surface 14 of the lower member 13 is convex and spherical segment-shaped, the spherical radii of surface 14 and receiving surface 8 correspond to one another. The upper surface 15 of the upper member 12 is concave and spherical segment-shaped, the surfaces 14 and 15 run

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parallel to each other, i.e. the spherical radii 16 and 17 of the surfaces 15 and 14 have the same spherical center 18» In contact with the upper inner member 12 there is an upper outer member 19, the lower surface 20 of which is convex and shaped like a spherical segment, whereby here too the spherical radii of surface 20 and surface 15 match. The upper surface 21 of the member 19 is flat. The member 19 is provided with a hole 22 through which a screw 23 passes, whereby the hole diameter 22 is so much larger than the screw diameter 23 that it can be pushed straight through the member 19. The screw head 24 comes into contact with the upper surface 21 with its underside. The links 12 and 13 are also provided with holes 25 and 26, the hole 25 widens conically from surface 15 to surface, the hole 26 widens conically from surface 11 to surface 14. In the area of surface 15, the hole diameter is already significantly larger than the diameter of the screw, for example twice as large. The holes 25 and 26 widen continuously from surface 15 to surface 14. The flange 4 accommodated between the links 12 and 13 has a hole 27 that is larger than the hole 26 in the area of surface 14.

The design of the screw connection 5 enables the holder 3 to be screwed to the damping block 7 without stress, despite large positional tolerances. Longitudinal and transverse tolerances can be compensated for by the design of the hole 27 in the flange 4, and angular tolerances are eliminated by the ability of the holder 3 to pivot relative to the damping block 7. The conical design of the holes 25 and 26 enables the holder 3 to pivot from the spherical perpendicular by an angle of approximately 5°. In the event that the curved surfaces 8, 14 and 15, 20 are not spherical segment-shaped, but rather barrel segment-shaped, pivoting is possible.

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I of Malters 3 exclusively around the perpendicular to the

I _I Drawing plane passing through point 18

*f axis possible. In order to avoid angular formation of the halves ¹ -

&iacgr; ters 3 also to compensate for a depth tolerance, i 5 the holder 3 has a countersunk hole in the area of the screw 2.

s long hole 28 running right to flange 4.

Claims (6)

li-ßTvfcüf nsprüche 1. Screw connection in which the screw passes through two parts in order to fix them together, with inner members arranged on both sides of one of the parts, which are flat on their respective surfaces that come into contact with one part, while the surfaces of the parts facing away from the flat surface are curved and interact with oppositely curved surfaces of adjacent, outer members, the screw passing through the members and the bore diameter of the inner members and of the part arranged between the inner members being larger than the outer diameter of the screw, characterized in that one of the inner members (12) has a concave (15) and the other of the inner members (13) has a convex curved surface (14), which interact with correspondingly convex (20) or concave curved surfaces (8) of the outer members (7, 19), wherein the contact surfaces between the respective inner and outer members (7, 13; 12, 19) run parallel to one another and the through-bore (25, 26) widens conically from the concave surface (19) of one inner member (12) to the inonvex surface (14) of the other inner member (13). i I 4 · I » 2. Screw connection according to claim 1, characterized in that the outer member (7) cooperating with the convex inner member (13) forms a unit with one of the parts (7). 3. Screw connection according to claim 1 or 3, characterized in that the bore diameter (27) of the part (4) arranged between the inner members (12, 13) is larger than the bore diameter (25, 26) of these members (12, 13) in the region of the part (4). 4. Screw connection according to one of claims 1 to 3, characterized in that the curved surfaces (8, 14, 15, 20) of the inner members (12, 13) are designed in the shape of a ball segment. 5. Screw connection according to one of claims 1 to 3, characterized in that the curved surfaces of the inner links are barrel-segment-shaped. 6. Screw connection according to one of claims 1 to 5, characterized in that the part (3) arranged between the inner members (12, 13) is designed as an angled part, wherein one leg (4) of the part (3) is penetrated by the screw connection (5) and an elongated hole (28) is provided running in the longitudinal direction of the other leg, through which a screw (2) passes.