DE29508866U1 - Telescopic rod with eccentric locking - Google Patents

Description

DESCRIPTION

The invention relates to a telescopic rod with eccentric locking with the features specified in the preamble of claim 1,

Telescopic rods that are adjustable in length are known as legs of photo tripods from DBGM 18 18 900 and GB 11 27 497. The inner tube of the telescope is provided with a bearing pin that is offset parallel to its central axis, around which an eccentric disk can be rotated with the same eccentricity of its hole. When this eccentric disk is in alignment with the inner tube, the inner and outer tubes can be easily moved against each other. If you then rotate the two tubes against each other, the outer tube takes the eccentric disk with it, which rotates slightly around the bearing pin and clamps itself inside the outer tube. The two telescopic tubes are then locked against each other in their respective positions. To unlock them, you only need to turn them in the opposite direction until the eccentric disk releases the outer tube again. In order to prevent the two tubes from being twisted in the wrong direction when unlocking, and thus locking them even more tightly against each other, the eccentric disc is provided in the known cases with a sector-shaped edge cutout into which a pin extends parallel to the bearing pin, which, like the bearing pin, is seated on a plug that closes off the end of the inner tube. In this way, the angle of rotation of the eccentric disc is limited so that it cannot be twisted any further beyond a clamping angle sufficient to fix the two tubes against each other. The telescopic tubes fixed against each other can therefore only be twisted against each other in the direction of loosening their fixation.

The invention is based on the object of creating a telescopic rod with an eccentric locking mechanism which can be manufactured inexpensively and easily assembled without the use of tools.

This object is achieved by the features specified in claim 1. Further developments of the invention are characterized in the subclaims.

The cutout, which according to the invention extends to the hole in the eccentric disc, allows the eccentric disc to be easily pressed onto the bearing pin from the side, which can easily be done by hand. In the known telescopic locks, however, the eccentric disc is either placed axially on the bearing pin and then secured by a stop pin, as in the case of the DBGM 18 18 900, or a screw with a suitably wide head or a washer must then be screwed into the bearing pin, or the bearing pin itself is formed by a screw, onto which the eccentric disc is placed and which is then screwed into the inner tube or an end plug for it, as in the case of the GB 11 27 497. In any case, several individual parts are required in these cases to attach the eccentric disc to the plug or the inner tube, which makes both the manufacture of the parts of the eccentric mechanism and its assembly complicated and more expensive.

It is advisable to make the transition point between the recess and the hole slightly smaller than the diameter of the hole so that the eccentric disk pressed onto the pin does not accidentally come off the pin. By preferably rounding the transition areas between the recess and the circumference of the eccentric disk, the pin can be inserted into the recess more easily, thus making assembly easier.

Preferably, the eccentric disc is made of rubber-like plastic material so that it not only has a certain elasticity for application to the bearing pin, but also results in a firm fixation due to a good coefficient of friction without excessive tensioning movement of the two telescopic tubes against each other.

When using plastic or cardboard tubes for the inner and outer tubes of the telescopic rod, it is advisable to provide a plug that is tightly inserted into the inner tube. This plug can be manufactured as a plastic injection-molded part in one piece with the bearing pin and an end plate provided at the end of the bearing pin, which prevents the eccentric disc from slipping.

The invention will now be explained in detail using an embodiment shown in the attached single figure.

In the right part of the drawing, the upper part of an inner tube 2 can be seen, in the end of which a plug 4 is inserted, which rests against the end of the tube with an upper collar 6. The collar 6 represents the edge limit of an end plate 8 of the plug, from which a bearing pin 10 protrudes outwards, which is offset by an eccentricity e from the center line 12 of the inner tube. The length of the bearing pin corresponds to the thickness of the eccentric disk 14 shown in the left part of the drawing. At the end of the bearing pin 10 there is a limiting disk 16, which holds the eccentric disk 14 on the bearing pin 10.

In the left part of the drawing, an outer tube 18 of the telescopic rod is also indicated, which fits over the inner tube 2 and can be moved along it.

Inside this outer tube, the eccentric disc 14 is shown, which is provided with an eccentric bore 20, the diameter of which is slightly larger than the diameter of the

Bearing pin 10 so that the eccentric disk can rotate around the bearing pin. This hole 20 merges with an approximately sector-shaped recess 22 into the circumference of the eccentric disk 14 so that it can be easily pressed onto the bearing pin 10 from the side, whereby the narrowing of the transition point 24 from the hole 20 to the recess 22 expands somewhat elastically so that the eccentric disk 14 snaps with its hole 20 around the bearing pin 10 and then no longer falls down easily. As the figure shows, the recess 22 merges with the circumference of the eccentric disk 14 in a rounded manner so that the pin 10 slides more easily into the recess 22 during assembly. In addition, these rounded areas prevent the eccentric disk from accidentally getting stuck in the outer tube.

The recess 22 of the eccentric disk 14 is expediently located at the narrowest point between the bore 20 and ^the circumference of the disk, as the material on the opposite part of the disk is then not weakened, which benefits the strength and durability of the disk. The bore 20 is offset from the center line 28 of the outer tube 18 by the same eccentricity e as the pin 10 is offset from the center line 2, so that the eccentric disk 14 can be brought into a precisely concentric position with the end disk 8 of the plug 4. The outer tube 18 can then be easily pushed over the inner tube 2 and adjusted axially relative to it. By turning the two tubes against each other, the eccentric disk 14 is turned against the plug 4 and its circumference clamps itself against the inner surface of the outer tube 18, allowing both tubes to be locked against each other. You can also see a small bead 26 on the circumference of the disc , which serves as a driver for the eccentric disc 14 when the two telescopic tubes 2 and 18 are rotated against each other for safer locking and unlocking. You can also see two chamfers 30, 32, which make it easier to join the inner and outer tubes. So that when the eccentric disc 14 is pressed on from the side,

the pin 10 does not have to be on a specific side of the disk, the disk is chamfered on both sides so that one phase is on the outside in each case.

Claims (6)

EXPECTATIONS 1. Telescopic rod with eccentric locking, in which the inner tube is provided with a bearing pin that is offset parallel to the central axis and widens at the free end, and an eccentric disk with a bore that is eccentric by the amount of the parallel offset is rotatably mounted on the bearing pin, which eccentric disk clamps against the outer tube when rotated relative to the inner tube and which has a recess over part of its circumference, characterized in that the recess (22) merges into the bore (20). 2. Telescopic rod according to claim 1, characterized in that that the recess (22) is narrower than the bore diameter at its transition point (24) to the bore (20). 3. Telescopic rod according to claim 1 or 2, characterized in that the transition region (transition point 24) of the recess (22) to the circumference of the eccentric disc (14) is rounded. 4. Telescopic rod according to claim 1, 2 or 3, characterized in that the eccentric disc (14) consists of elastic material. 5. Telescopic rod according to one of the preceding claims, characterized in that the bearing pin (10) is formed on a plug (4) that can be inserted into the inner tube (2). 6. Telescopic rod according to claim 5, characterized in that the plug (4) is an injection-molded part.