SE468225B - DEVICE TO ATTACH A ELEMENT WITH A BODY - Google Patents

Description

468 225 2 prevents axial movement of the cylindrical part in the hole in at least one direction, while the screw turns, after tilting to the side by turning the cylindrical part, fit almost completely in the annular groove and thereby allow axial movement of the cylindrical part in the hole.

The invention will be described in more detail in the following with reference to the accompanying drawings, in which some exemplary embodiments of the device according to the invention are shown.

Fig. 1 is a side view, partly in section, showing the principle of the invention; Figs. 2 and 3 are side views, partly in section, showing variants of the inventive principle illustrated in Fig. 1; Figs. 4 and 5 show in section two alternative embodiments of a fastening device for engine heaters; Figs. 6 - 11 and 12a - 12c show examples of different practical embodiments of fastening devices according to the principle of the invention.

Fig. 1 of the drawing shows an arbitrarily selected element 10, which has at least one cylindrical part 11 and is attached to a body 12, which has a hole 13, in which the cylindrical part 11 is at least partially insertable. The cylindrical part 11 is provided with a circumferential annular groove 14, in which a toroidal helical spring 15 is inserted. The cylindrical part 11 has a diameter which is only slightly below the diameter of the hole 13.

The groove 14 has such dimensions that the toroidal helical spring 15 in all. substantially fills the groove 14 and projects radially, outside the cylindrical part 11, sufficiently to lock the cylindrical part 11 against extraction from the body 12 in the direction indicated by the arrow A in Fig. 1 after insertion. It will be appreciated that the insertion of the cylindrical member 11 into and through the hole 13 can only take place during tilting of the individual coil springs in such a direction that the outer diameter of the toroidal coil spring is reduced to less than the diameter of the hole 13. The insertion of the cylindrical part 11 into the hole 13 takes place in such a way that the part 11 with its end is inserted purely axially in the hole 13, 3 until the spring 15 abuts the first edge 17 of the hole in the insertion direction 17. Then the element 10 is rotated slightly. so that the screw turns are tilted laterally, as just described, and allows further axial insertion of the cylindrical part 11, until the spring 15 has passed the neck 13 in the insertion direction other edge 18, whereby the overturning of the spring turns normally ceases, so that the spring 15 returns to its original position. In this position the spring 15 will thus abut against the hollow edge 18, or at least assume such a position that the spring 15, by abutment against the hollow edge 18, effectively prevents axial movement in the extending direction of the element 10.

To loosen the element 10, proceed in the opposite way, ie apply some axial pulling force, so that the spring 15 will abut against the hole edge 18, and then the element 10 is turned slightly, so that the screw turns will be tilted over so that the spring 15 fits completely in the groove 14 and thus allows the cylindrical part 11 of the element 10 to be pulled out of the hole 13.

Among the parameters which affect the safety of the anchorage, mention must be made of the thread dimension of the helical spring element 15, the helical pitch of the helical spring element (the mutual distance between the helical turns) and the inner resp. outer diameter relative to the groove 14 resp. mounting hole 13 diameter.

In general, it can be stated that under otherwise equal conditions a tight winding, ie small pitch, gives better locking and simplified assembly / disassembly, as the screw turns can be more easily tilted to the side when turned, while a sparse winding, ie large pitch, gives poorer locking when the screw turns form a larger angle relative to the groove edge and with added traction is more easily tilted to the side, and of course the number of adjacent turns is less.

It is irrelevant whether the screw turns are left-handed or right-handed, as this only affects the function with regard to the screw turns being more easily tilted in one or the other direction during assembly resp. dismantling.

CO PO lx) 0 | The embodiment in Fig. 2 differs from that shown in Fig. 1 only in that in Fig. 2 the toroidal helical spring 15 is designed as a tension spring and is arranged to lie in an outer ring groove 14 in the cylindrical part 11 for reading interacts with an internal ring groove 16 in the body 12.

The embodiment in Fig. 3 differs from that shown in Fig. 1 only in that in Fig. 3 the toroidal helical spring 15 is designed as a compression spring and is arranged to lie in an inner ring groove in the body 12 for reading interaction with an outer ring groove 14 in the cylindrical part 11.

As shown in Fig. 1, the element 10 may have a shoulder 19, which prevents the cylindrical part 11 of the element from being inserted longer than a predetermined piece in the body 12.

In the embodiment of Figs. 4 and 5, the device according to the invention is used for attaching an electric motor heater 20. In this example, the above-mentioned body 12 corresponds to a wall 21 of an engine block and the above-mentioned element 10 corresponds to an element shell generally designated 22. , which has a cylindrical part 23. The cylindrical part 23 is anchored in the engine block wall 21 by means of a toroidal helical spring 15 arranged in an annular groove 14 in the manner described above and the recesses 22 are held in position with the spring supporting the inside of the engine block wall 21 with by means of a compression spring 24, which with one end abuts against the outside of the engine block wall 21 and with its other end supports against a shoulder 25 on the cylindrical part 23.

The embodiment in Fig. 5 differs from that shown in Fig. 4 only in that the element recesses 22 in Fig. 5 have a special lid 26 welded into the cylindrical part 23.

Figs. 6 and 7 show in simple cross-sections two types of cable or cable glands 27, 28, fastened according to the principles stated by the present invention. Both penetrations are penetratable, ie initially completely closed by means of lid 29 resp. But arranged so that they can be penetrated fairly easily by means of a suitable tool or even by means of the cable or wire which is to pass through them. The bushing 28 is provided with a relief device 31 for relieving axial tensile stresses in the cable or cable.

Figs. 8 and 9 show in side view resp. on average, a bushing for passing an element, of any kind, through a plate. The bushing is anchored to an axial hob in the manner specified according to the invention and is anchored to movement in the opposite axial direction by means of a so-called flange nut 33.

Figs. 10 and 11 show bushings 34, 35 for e.g. a car radio antenna. Both bushings are anchored in an axial direction in the manner specified according to the invention and are anchored against movement in the opposite axial direction by means of their respective flange nuts. According to Fig. 10, both the antenna rod 36 and the antenna socket line 37 are anchored to the bushing 34 in the manner indicated according to the invention, while according to Fig. 11 an antenna rod 38 is simply screwed onto the bushing 35 by means of a dome nut-like element 39.

The bushing 35 in this case only serves as a fastener for the mounting of the car radio antenna in a hole in the car plate.

Figs. 12a - 12c show the attachment of a suspension loop 40 of a per se arbitrary design to plates or walls with different designs and thicknesses in the manner specified according to the invention. It should be added that it is of course conceivable to place different kinds of sealing elements and the like between the walls or the like, where fastening is to take place, and the fastening element, also at other places in the anchoring. However, the arrangements in this regard must be adapted to the needs of each case.

Claims (4)

225 6 PATENT REQUIREMENTS Device for attaching an element (10:22), having at least one cylindrical part (11:23), to a body (12:21) with a hole (13), in which the cylindrical part is at least insertable in axial direction, wherein either the cylindrical part (11:23) or said body (12:21) in adjacent portions has a ring groove (14), in which a toroidal helical spring (15) is arranged, which is set up atn; prevent axial movement of the cylindrical part (11, 23) in the hole (13) in at least one direction, characterized in that the dimensions of the toroidal helical spring (15) are such that the individual helical turns in the rest position project outside the groove (14), in which the helical spring (15) is arranged, to such an extent that they prevent axial movement of the cylindrical part (11,23) in the hole (13) in at least one direction, while the helical turns, after tilting to the side by rotation on the cylindrical part (11:23), fits almost completely in the ring groove (14) and thereby allows axial movement of the cylindrical part (11, 23) in the hole (13). Device according to Claim 1, characterized in that the toroidal helical spring (15) consists of a toroidal helical spring (15) of a tension spring type (15) arranged in a ring groove (14) near the end of the cylindrical part (11), arranged to co-read with a neck edge (18) at the end of the neck (13) (Fig. 1). - Device according to Claim 1, characterized in that the toroidal coil spring (15) consists of a toroidal coil spring (15) of the tension spring type arranged in a ring groove (14) in the cylindrical part (11), which is arranged reading cooperating with at least one hole edge (18) at a ring groove (16) in the wall (13) of the hole (Fig. _2). Device according to Claim 1, characterized in that the toroidal coil spring (15) consists of a toroidal coil spring (15) of the compression spring type arranged in a ring groove (16) in the wall (13) of the sleeve (13), which is * 1 468 225 arranged to read cooperate with at least one edge of a ring groove (14) in the cylindrical part (11), (Fig. 3). 7