DE19602472A1 - Telescopic rod with eccentric lock - Google Patents

Abstract

The inner tube of the telescopic rod is fitted with a bearing peg, widening at its free end and offset w.r.t. the centre axis. The peg carries a rotary eccentric drive (14) with a base (20), eccentric by the amount of the parallel offset, which clamps against the outer tube, on rotation, w.r.t. the inner tube. Over part of its periphery the drive comprises a recess (22) which merges into the bore. Pref. the recess is narrower, at the transition point (24) to the bore, than the latter dia. The transition point may be rounded towards the periphery of the drive.

Description

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

Telescopic poles adjustable in length are called legs of Photo tripods from the DBGM 18 18 900 and GB 11 27 497 be knows. The inner tube of the telescope is here with one against its central axis staggered parallel to the one eccentric disc with the same eccentricity of its hole is rotatable. In the position aligned with the inner tube This eccentric disc allows the inner and outer tubes to be easily move against each other. Then you twist the two pipes against each other, the outer tube takes the eccentric disc with it, which rotates somewhat around the bearing journal and turns on the inside Outer tube jammed. The two telescopic tubes are then in the locked each position against each other. To unlock you only need to move them in the opposite direction turn until the eccentric disc releases the outer tube. To prevent you from unlocking the two tubes in tries to twist in the wrong direction, and thus the eccentric disc is even more firmly locked against each other in the known cases with a sector-shaped edge cut provided, in which a parallel to the bearing journal The pin protrudes from the stopper, just like the bearing journal sits, which closes the end of the inner tube. In this way the angle of rotation of the eccentric disc is limited so that it each other to fix the two pipes together does not allow sufficient clamping angle to be rotated further. The telescopic tubes fixed against each other can only be used in Direction of releasing their fixation twisted against each other will.

The invention has for its object a telescopic rod to create with an eccentric locking mechanism that can be produced inexpensively and easily, without the aid of tools, can be assembled.

This object is achieved by the features specified in claim 1 solved. Further developments of the invention are in the dependent claims Chen marked.

Through the invention up to the bore of the eccentric disc the eccentric disc is easy to reach Press on the side of the bearing journal, which is easy with can be made by hand. In the well-known telescope The eccentric disc, on the other hand, either locks axially the bearing journal and then by a stop pin secured as in the case of DBGM 18 18 900, or in the warehouse must then tap a screw with a correspondingly wide Screwed head or washer, or but the bearing journal itself is formed by a screw, on which the eccentric disc is placed and which on closing in the inner tube or an end plug for this is screwed in, as in the case of GB 11 27 497. In each In this case, several individual parts are to be attached the eccentric disc on the plug or the inner tube derlich what both the manufacture of the parts of the eccentric Mechanism and its assembly complicated and expensive.

The transition point of the recess expediently becomes Hole made slightly smaller than the hole diameter, see above that the eccentric disc pressed onto the pin does not move unintentionally releases from the spigot. By preferably Ab Rounding the transition areas of the recess to the extent of the Eccentric disc, the pin can be more easily in the recess insert and thus facilitate assembly.  

The eccentric disc is preferably made of rubber-like art fabric material, so that they are not just a certain Has elasticity for application to the bearing journal, but also due to a good coefficient of friction without excessive Clamping movement of the two telescopic tubes against each other a fixed Fixation results.

When using plastic or cardboard tubes for indoor and outer tube of the telescopic rod, it is appropriate to one in to provide the inner tube tight plug to be used as Plastic injection part in one piece with the bearing journal and one the end of which provided an end plate that slipped off the eccentric prevented from being produced.

The invention is now based on one in the accompanying single Figure illustrated embodiment explained in detail.

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

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

Inside this outer tube, the eccentric disc 14 is drawn, which is provided with an eccentric bore 20 , the diameter of which is slightly larger than the diameter of the journal 10 , so that the eccentric disc can rotate about the journal. This bore 20 merges with an approximately sector-shaped recess 22 in the circumference of the eccentric disc 14 , so that it can simply be pressed from the side onto the bearing journal 10 , the narrowing of the transition point 24 from the bore 20 to the recess 22 being somewhat elastic expanded, so that the eccentric 14 with its bore 20 snaps around the pivot pin 10, and then no longer falls down readily. As the figure shows, the recess 22 is rounded in the circumference of the eccentric disc 14 , so that the pin 10 slides more easily into the recess 22 during assembly. In addition, these roundings prevent unwanted jamming of the eccentric disc in the outer tube.

The recess 22 of the eccentric disc 14 suitably sits at the narrowest point between the bore 20 and the periphery of the disc, since then the material is not weakened on the opposite part of the disc, which benefits the strength or durability of the disc. The bore 20 is offset against the center line 28 of the outer tube 18 by the same eccentricity e as the pin 10 against the center line 2 , so that the eccentric disc 14 can be brought into a precisely concentric position with the end plate 8 of the stopper 4 . Then the outer tube 18 can be easily pushed over the inner tube 2 and adjusted axially relative to it. By rotating both tubes against each other, the Exzen tersscheibe 14 is rotated against the plug 4 and clamps there with its circumference to the inner surface of the outer tube 18 , where both tubes can be locked against each other. A small bead 26 can also be seen on the circumference of the disk, which serves as a driver for the eccentric disk 14 when the two telescopic tubes 2 and 18 are rotated relative to one another for more secure locking and unlocking. You can also see two chamfers 30 , 32 , which facilitate the joining of the inner and outer tubes. So that one does not have to fit onto a specific side of the disk when the eccentric disk 14 is pressed onto the pin 10 laterally, the disk is chamfered on both sides, so that in each case one phase lies outside.

Claims (6)

1.Telescope with eccentric locking, in which the inner tube is provided with a bearing journal which is offset parallel to the central axis and widens at the free end, and an eccentric disk with an eccentric bore which is eccentric by the amount of parallel displacement and rotates on the bearing journal and which is rotated relative to the Inner tube clamped against the outer 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 the recess ( 22 ) at its transition point ( 24 ) to the bore ( 20 ) is narrower than the bore diameter. 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 ) on a in the inner tube ( 2 ) insertable plug ( 4 ) is formed. 6. Telescopic rod according to claim 5, characterized in that the plug ( 4 ) is an injection molded part.