DE7134020U - Device for clamping two telescopic tubes - Google Patents

Description

PATENT ADVERTISEMENT DlPL.-ING. ULRICH KLMKELIN >' _r

7032 Sindelfingen - Auf dem Goldberg- Weimarer Str. 32/34 - Telephone 07031/86501

August 27, 1971 U 167

Mr. Heini Hannweber, 7032 Sindelfingen, Obere Vorstadt 85

DEVICE FOR CLAMPING TWO TELESCOPIC TUBES

Never invention relates to a device for clamping two Teieskoprume with one certain extended position, which have a circular ring cross-section and which represent one telescopic tube with a larger inner diameter the other telescopic tube with a smaller one Outside diameter leads, with the help of a clamping device.

The awning or canopy of a caravan is both supported in front of a pole and excited. For example, in this construction there is one ridge pole, the two Includes telescopic tubes. One of the telescopic tubes wildly with its single end into the dome holder hung on the caravan to which a> cn acr edge of the awning is attached. The other telescopic tube has an upward-pointing pin at its outer end, which crosses an eyelet of a badger when in use. In the manufacture of such telescopic tubes So far, the outer telescopic tube has been drilled through at its inner end, a nut soldered or welded on there and a handle screw inserted into this nut.

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screwed in, which got stuck when tightening the inner telescopic tube. Attaching; - ripr mother kc:! et additional work steps and with Versana nar iicn often gcz.ciyi, doß

in spite of all care, the nut comes loose from the telescopic tube. The screw can also be lost go and deliver a share of the cost. When clarifying one must also pay attention to that the Stifi, which crosses the Ö'e, points to one side, and the mother with it The opening and screw point to the other side, because the tent fabric has to be just rest on the frame.

V r all has I jed made the establishment of such tents or sun canopies, as must the one to push apart the Teieskoprohre, ef ^ ririf of-ZcItstoff the right tension,) w to ^you: ν '^ its two hands are needed in all exploded. state of T .eskoprohre 'you have to tighten the screw, which include a dnt ^l s hand is necessary. One person alone can therefore hardly richtfj the no. .vendige Xraft apply for generating the train and even turn the screw.

In addition, in daily life there are a variety of cases in which telescopic tubes must be locked in any extended position, be it for parasols in the base, with the legs of photo tripods, with the length-adjustable tracks of tables etc. Sc-fem screws are used for clamping, the strength of the pipe is convenient always too small to accommodate the necessary threads. There are Therefore, reinforcement rings are always necessary to take the strain off the ear. So much for clamping devices used, these are complicated and can usually only be achieved with one

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adjust loud clicks and the clamping mechanism is opposite thickness swings

acs / viuieriuis cuipi inui i. juitnc UMttscriituYvunrwiiyGii rourmcit Vuii r-vniviiiy um uuii.il iv satchels arise as well as through signs of wear and tear during use.

The object of the invention is e. To provide a clamping device that has all of these disadvantages eliminated, which allows a real two-hand adjustment and two-hand locking, ohnu that one hand has to let go of a telescopic tube, c "s is very cheap and with which one comes into the area of self-locking practically without attempts, whereby the The forces that occur are in practice easily controllable hoop stress forces.

According to the invention, this object is achieved in that the clamping device comprises a disk, dip with ^f ice of a rigid pin is axially essentially immovable, but freely rotatable about the geometric longitudinal axis of the pin at the inner end of the inner telescopic tube, that the disk is irr contour in is essentially the same as the outline of the inner telescopic tube and that the first geometric longitudinal axis is opposite to the geometric longitudinal axis of the inner telescopic tube .; υπ is offset by an amount that allows at least a fifth of a turn of the telescopic tubes, after which the disk has come into driving engagement with the outer telescopic tube.

Further advantages and features of the invention emerge from the following description ^ ines preferred embodiment. In the drawing show: Fig. 1 is a perspective view of a caravan with attached linkage

and sun canopy,

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Fig. 2 shows the first bar of the sun canopy in side view, broken off and

simplified with regard to their connection with the rest of the boom,

3 shows a section through the two telescopic tubes in an enlarged representation

in an overlapping area in a non-fixed clamped position,

FIG. 4 shows a representation similar to FIG. 3, but in the clamped position,

5 shows the side view of a disk in a second embodiment.

6 shows the front view of a disk with flattening.

A caravan 11 has three dome brackets 13 on its upper, front i \ and 12. The linkage includes a ridge pole 14, two eaves poles Ιό, 17, two gable poles 18, as well as three post bars 21, 22, 23. is decent and is therefore not described in detail.

As can be seen from Fig. 2, the ridge pole has two telescopic tubes 24, 26 circular ring-shaped Cross-sectional. The telescopic tube 24 has an inner diameter which is larger than the outer diameter of the telascopic tube 26, so that the telescopic tube 26 is slightly in the Telescopic tube 24, but without unnecessary play, can be moved. At the front end the telescopic tube 24 has an upwardly projecting Siift 27, which is through an eyelet in the front upper gable area of the roof 28 carried and tensioned by the rods is inserted. In the front area, the telescopic tube 24 is also not shown Articulated to the gable poles 18, 19 and the post bar 22 "

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In the rear end of the telescopic tube 26, an insert 29 is pressed in, which is a coaxial Bohrun'q has, in the rotatable, but axially essentially non-displaceable, a The dome 31 is mounted, the end angled downwards in the dome holder 13 • stretches. As already described above, the pin 27 protrudes through a C ^ e in the Daqh 23. On the other hand is the roof 28 on its wagon-side edge on, not shown, known Orphan connected to the caravan 11 in a tensile manner in the area of its edge 12.

In order to tension the roof 28 in the region of the First Range 1 4, one must take one hand the telescope tube 24 and with the other Hanc ¹ the telescopic tube 2 <5 bt.de, possibly far aussinanderziehen and av; incndergezogenen state along immovably determine .

For this purpose, an insert 32 is pressed into the front end of the telescopic tube 26, the circular cylindrical body 33 of which fits into the telescopic tube 26 with a prefabricated seat. The body 33 is therefore connected to the telescopic tube 26 in a rotationally fixed and longitudinally non-displaceable manner. In the left end area of the body 33, a circular collar 34 is provided, the diameter of which is equal to the outer diameter of the telescopic tube 26, which there closes the telescopic tube 26 in a defined manner and at the same time serves to limit the insertion of the body. 33 result: _o As you can see, the collar 34 lies on the left end face of the telescopic tube 26. The collar 34, the body 33 and the telescopic tube 26 s * ~ id coaxially of said longitudinal axis 36 offset from a geometric County ~ ^r axis 36. Opposite by an amount X - in the drawing c \. Sake \ clarity in \ "eitem is exaggerated -

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; <a rigid pin 3 / is non-rotatably connected to the body 33. The body 33 is on the left

ij 'a flat face 38. Body 33 of this type can be with the necessary tolerance

pour _t They can even be faded out in such a way that the pin 37 is also poured on and

\ is not a separate piece. Freely rotatable on the pin 37 is a circular cylindrical

J d.ische disk 39, which has a through hole 41, the center of which is also around the

Amount X is offset with respect to the geometric longitudinal axis 36 of the disk 39. To the To stress pin 37 as little as possible in bending, the disc 39 follows immediately

; i on the end face 38. The distance is exaggerated in FIGS. 3 and 4 for the sake of clarity

drawn big. Beyond the washer 39, the pin 37 carries a washer 42 and a rivet head 43 so that the washer 39 cannot move axially substantially. The diameter d ^ ^r disk 39 is slightly smaller than the inner diameter of the telescopic tube 24 and is preferably equal to the outside diameter of the. Telescopic tube 26,

Because of the eccentricity X, the disk 39 can move in the direction of the geometrical longitudinal axis 36 seen coincide with the outline of the collar 34 and the telescopic tube 26 or - with free rotation outside the telescopic tube ^ 24 - the maximum eccentric Assume a position in which:> it protrudes far beyond the outline of the collar 34 or any other Take an intermediate layer. According to FIG. 3, the disk 39 is in alignment Position and this is also the position in which the telescopic tube 26 is displaced in the telescopic tube 24 can be. To fix it, the telescopic tube 26 is now rotated relative to the telescopic tube 24 about its geometric longitudinal axis 36, which is achieved by the rotatable mounting of the cathedral 31 is possible. The circumference 44 of the disk 39 then comes into frictional engagement

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with the inner wall 46 of the telescopic tube 24 and the disc 39 then makes the Drehbe movement no longer or only partially mii. As a result, the disk 39 is around the Pin 37 rotated and comes into even more frictional engagement with the innervation 46. This • st an increasing effect. The disc 39 stops completely and pushes itself 4 in the lower region of the inner wall 46, the telescopic tube 26 and the collar 34 pressed up against the inner wall 46 - / ground. You then get into the Area of self-locking in which the friction surfaces of the inner wall 46 of the circumference

Through-44, the bore 41 and the sound 34 and the telescopic tube 26 wedge so that they can no longer get out of this position without the action of external forces. With practically executed Linkage has shown that this very simple connection is also vibration-proof isi · and easily withstands vibrations. As you can see, the pressing takes place in any case much larger than when clamping with screws, where the danger would exist that the telescopic tube 26 is indented.

The amount of eccentricity X can be found by experiment. In an embodiment with an outer diameter of the ι telescopic tube 26 of about 25 mm, this had Measure.X the size of 1, 5 mm, whereby one very good proportions after a little more than a quarter turn. The dimension X must in no case be less than the difference between the inside diameter of the telescopic tube 24 and the outside diameter of the telescopic tube 26 sink because danr go: there is no deadlock. But it must be X too high - in the execution example e.g. 2.5 mm - then you cannot get into the area the self-locking and the telescopic tubes 24, 26 can be too small

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twist ¹ η. This applies to rigid metal designs, such as those used in tentous guides, rotosianven, Donnenscnirmsranaem oa.aqi. uDiicn sina. However, if the elements involved are given a certain elasticity, a higher degree of eccentricity is also possible. During the Metal! Performance of the Austu ^! In the example, the optimum holding position was 3/8 original rotation.

According to the exemplary embodiment according to FIG. 5, a circumferential groove 47 is provided so that only two narrow areas 48 of the circumference 44 of the first exemplary embodiment remain, v / <xi is increased by the specific surface pressure. That way you can

also establish self-locking better and faster. You could also have multiple Bell . . . ... .....

Provide rich AU , which, for example, have the height of metal plate rings or one could

also knurl the circumference 44 so that small peaks arise.

The disks 39 described so far are all circular on the circumference. However, this is not absolutely necessary. In the embodiment according to FIG. 6, a flattening is shown. The telescopic tubes 24, 26 are rotated here until the disk 39 grips and comes into the self-locking area and then a little further until the disk 39 rests on both sides of the flattening 49 on the inner wall 46 the inner wall 46 has been drawn with an exaggerated large diameter for the sake of it.

7?

Claims (8)

167 9-i i <! 1 I tgjn Proverbs: 1. Device for clamping two telescopic tubes in a certain extension! ! unc, which have a circular ring cross-section and which have a telescopic tube the other telescopic tube with a smaller one with a larger inner diameter Outer diameter leads, with the help of a clamping device, thereby gekennzeichn et that the clamping device comprises a disc (39), which can be essentially displaced axially by means of an itar pin (37), however, it is freely rotatable about the geometrical longitudinal axis (51) of the pin (37) on the inner end of the inner telescopic tube (26) so that the disc (39) is essentially the same in outline as the outline of the inner telescopic tube (26) and that the first geometrical longitudinal axis (51) is opposite to the geometrical one Longitudinal axis (36) of the inner telescopic tube (26) around a Betran (X) is offset, which allows at least a fifth turn of the telescopic tubes (24,26), nor the disk (39) in driving engagement with the outer Telescopic tube (24) has come. 2. Apparatus according to claim 1 , characterized in that the disc (39) \ has an exactly circular outline. 3. Apparatus according to claim 1, characterized in that the disc (39) on its circular outline has a tendon-shaped abplattuna (49). 13 ^ 0203011.72 167 -2- 8/27/71 4. Apparatus according to claim 1, characterized in that the disc (39) on its periphery has protruding areas (48) and recessed areas (47) that the area of the ü; back replaces en areas (47) is substantially larger than the area of the projecting areas (48) and that the projecting areas (48) form the outline of the disc (39). 5. Apparatus according to claim 4, characterized in that the recessed areas {. j are at least one circumferential flute and that the projecting areas (48) are circular cylindrical surfaces. 6. Device according to claim 1, characterized gekennzeichne ⁴ -, that the amount of displacement (X) equal to or less than one tenth the diameter of the Washer (39) ISt ₇ . _un d that the amount is always much greater than the play between the telescopic tubes ir 7. Apparatus according to claim 1, characterized in that the disc (39) is a massive metal plate. 8. Apparatus according to claim 1 _/ characterized in that in the hollow interior Telescopic tube (26) in the end of which is a cylindrical, pxial unverschics! Icher, with the Telescopic tube (26) non-rotatable insert (32) is inserted, which anchors the pin (37) and has a flat end face (38) on the outside, and that the disc (39) immediately follows this end face (38). 713402Ü30.H.72 167 - 3 - ? 7. H. 7 \ // -. r-r! / -1-ifi mn r-> n / -U Ariwiriirli A rlnrl l j rr. 11th <it - l · C nn Ze I C hn et. that the m riot ": (32) a collar (34) which glides through π, with the in'T'-n telescopic tube (26) iv and bündic; r: m iXcskoprohr C? 6) . 71340203011.72