DE9001987U1 - Tripod for optical devices - Google Patents

Description

29.047/70-Rl

Cull &pgr;&ngr;&rgr;&igr;&pgr;&pgr; Trading company for consumer goods Waldetraase 12. 8506 Lanoenzenn

Tripod for ootical devices

The invention relates to a tripod for optical devices, with a center column that can be moved and locked in a bearing sleeve of the tripod and with a locking device provided on the bearing sleeve, which can be adjusted between a locking position in which the center column is fixed in relation to the bearing sleeve and a release position in which the center column is movable in relation to the bearing sleeve.

Such a tripod is described, for example, in DB 37 33 956 Al. There, the locking device is equipped with a

The rotation axis aligned with the central longitudinal axis of the center column can be rotated between the locking position and the release position.

A tripod for optical devices with a tripod _head connected to tripod legs, each tripod leg consisting of a

An inner telescopic tube and an outer telescopic tube, which can be moved into one another and locked against one another by means of a locking device, is known, for example, from DE 34 30 C2. There, the inner telescopic tube is arranged on the tripod head and the outer telescopic tube is arranged on the lower side of the tripod leg opposite the tripod head. The locking device has an actuating part, a connecting rod which is operatively connected to the actuating part and a clamping element which is provided with at least one clamping cone on the connecting rod. The actuating part can be pivoted between a normal position, a locking position and a release position, whereby the clamping element is in a sliding friction connection between the inner and outer telescopic tubes in the normal position of the actuating part, while in the locking position it creates a mechanically strong static friction connection between the inner and outer telescopic tubes and in the release position the friction connection between the inner and outer telescopic tubes is eliminated, so that the outer telescopic tube can be easily moved in relation to the inner telescopic tube.

The invention is based on the object of creating a stand of the type mentioned at the beginning, in which the coat column can be adjusted as desired in relation to the storage case or can be fixed as desired with the help of the locking device, whereby the locking device is designed in a simple manner.

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This object is achieved according to the invention in that the locking device has a pin element and a spring element, the pin element facing the center column with a fastening end section, the pin element with its fastening end section is forced against the center column in the locking position with a static friction force, in the release position with the fastening end section is removed from the center column and in the normal operating position between the locking and release positions, the spring element with the fastening end section is pressed against the center column with a sliding friction force.

In the tripod according to the invention, the locking device is therefore intended to create a sliding friction connection between the center column and the bearing necks in the normal operating position of the tripod, so that in the normal operating position of the tripod it is possible to adjust the center column as desired in relation to the bearing sleeve with a certain amount of force that overcomes the sliding friction force. This prevents the center column from being accidentally moved out of the bearing sleeve, i.e. falling out of the bearing sleeve. At the same time, the static friction connection provided in the normal operating position between the center column and the bearing sleeve with the aid of the locking device enables a very precise adjustment of the center column in relation to the bearing sleeve. In order to be able to adjust the center column in relation to the bearing sleeve very quickly and without any effort using the tripod according to the invention, it is possible to adjust the locking device to its release position in which the pin element with its fastening end section is moved away from the center column. In the release position of the locking device, the spring element is simultaneously

mechanically pre-tensioned so that the locking device is automatically returned to the normal operating position after it is released and the spring element is simultaneously mechanically relaxed, in which sliding friction contact is established between the center column and the bearing sleeve. If the locking device is moved from the normal operating position to the locking position, the spring element of the locking device is simultaneously mechanically relaxed even further, which in turn advantageously supports the return of the locking device from the locking position to the normal operating position at the appropriate time. Overall, the result is a tripod with a locking device that is simple and easy to handle.

It has proven to be useful if, in the case of the stand according to the invention or its locking device, the pin element has an external thread section which is screwed into a threaded hole provided in the bearing sleeve. The external thread section of the pin element and the internal thread of the threaded hole provided in the bearing sleeve are designed in such a way that self-locking is avoided, or that with the help of the spring element interacting with the pin element, it is possible to automatically and immediately return the pin element from the release position of the locking device to the normal operating position of the locking device when the locking device is released. This means that the pin element with its external thread section is screwed into the threaded hole by the spring element which is mechanically pre-tensioned in the release position of the locking device, so that the pin element with its fastening end section has a sliding friction

is pressed against the center column by the force acting when the locking device is released in the release position.

The pin element can have a footrest section for a rotary handle, which is remote from the center column. With such a design of the tripod, the firing element can be provided between the rotary handle and the bearing sleeve. The rotary handle is preferably designed in such a way that it simultaneously forms a contact protection for the spring element.

The fixing section of the pin element can have a cross-sectional shape that differs from the circular shape and the rotary handle can have a recess with a cross-sectional shape that corresponds to the fixing section of the pin element. This can be a cylindrical fixing section with a spring and a circular recess with a groove. However, it is also possible, for example, to make the fixing section polygonal, i.e. with a polygonal cross-section, and the recess with a corresponding polygonal cross-section. This results in a twist-proof connection between the pin element and the rotary handle of the locking device.

In order to fix the rotary handle to the pin element so that it cannot move axially, the fixing section of the pin element can have a groove and the rotary handle can have a projection that engages in the groove. Such a groove and projection are easy to produce. The groove can run around the fixing section of the pin element and the projection provided on the rotary handle can be, for example, at least one small knob.

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The pin element can have a receiving section for the spring element and the spring element can be designed as a helical spring which is movably arranged on the receiving section of the pin element provided for this purpose. The receiving section of the pin element is preferably simply cylindrical when using a helical spring, the outer diameter of the cylindrical receiving section being slightly smaller than the clear inner diameter of the spring element in the form of a helical spring.

The coil spring preferably has two fastening end sections, of which one fastening end section is fixed to the bearing sleeve of the tripod and the second fastening end section is fixed to the rotary handle. In this way, a rotation of the rotary handle of the locking device about the central longitudinal axis of the associated pin element leads to a corresponding rotation of the second fastening end section of the coil spring in relation to the first fastening end section of the coil spring, which is fixed to the bearing sleeve of the tripod, and thus to a mechanical tension of the coil spring when the rotary handle is rotated from the normal operating position of the locking device, e.g. into the release position. If the rotary handle is released in the release position, the coil spring is automatically relaxed, as a result of which the pin element connected to the rotary handle with its fastening end section comes back into contact with the center column with a static friction force. If the rotary handle is turned from the normal operating position to the locking position, a mechanical tension of the coil spring occurs in the opposite direction, which causes the adjustment from the locking position to the normal operating position of the locking device in

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is advantageously supported. However, this does not result in an automatic return from the locking position to the normal operating position of the locking device.

Further details, features and advantages emerge from the following description of an embodiment of the stand for optical devices according to the invention, shown schematically in the drawing. It shows:

Fig. 1 is a side view of the tripod, the legs of which are only partially indicated, and

Fig. 2 shows a half-side longitudinal section through the most important parts of the tripod or its locking device, whereby the center column and one of the legs of the tripod are only shown in sections.

Fig. 1 shows a tripod 10 for an optical device, with a bearing sleeve 12, to which legs shown in sections are hinged. The reference number 16 designates a connecting axis with which one of the legs 14 is hingedly connected to the bearing sleeve 12 of the tripod 10. A central column 18 is arranged in the bearing sleeve 12, which is designed with a fastening device 20 for an optical device. A locking device 22 is provided on the bearing sleeve 12, which can be adjusted between a normal operating position, a release position and a locking position. In the normal operating position, the locking device 22 serves to establish a sliding friction connection between the bearing sleeve 12 and the central column 18, so that 9β in the

In the normal operating position of the tripod 10 or its locking device 22, it is possible to adjust the center column 18 relative to the bearing sleeve 12 as required with a certain amount of force which overcomes the sliding friction force between the center column 18 and the bearing sleeve 12. In the normal operating position of the locking device 22, it is possible to adjust the ^center column 18 relative to the bearing sleeve 12 without any effort, ie force-free. In the locking device 22, the center column 18 is fixed relative to the bearing sleeve 12, ie relative to the tripod 10.

A preferred embodiment of the locking device 22 of the tripod 10 is shown in half section in Fig. 2. This figure shows the bearing sleeve 12, a support leg 14 hinged to the bearing sleeve 12 and the center column 18. The reference number 16 in this figure also designates the connecting axis with which the support leg 14 of the tripod 10, shown in sections, is hinged to the bearing sleeve 12. The bearing sleeve 12 is formed with a threaded bore 24 through which a pin element 26 with its external thread section 28 is screwed. The pin element 26 has a fastening end section 30 which faces the center column 18. The pin element 26 is also designed with a receiving section 32 for a spring element 34, which adjoins the external thread section 28, and with a fixing section 36 for a rotary handle 38, which is axially adjacent to the receiving section 32. The receiving section 32 of the pin element 26 is simply cylindrical, while the fixing section 36 is a polygonal section. The rotary handle 38 is designed with a recess 40, the cross section of which is dimensionally adapted to the cross-sectional profile of the fixing section 36 of the pin element 26. This results in a torsion-proof connection.

between the pin element 26 Tin and the rotary handle 38 of the locking device 22. In order to fasten the rotary handle 38 of the locking device 22 to the pin element 26 or its fixing section 36 in an axially immovable manner, the fixing section 36 of the pin element 26 is designed with a circumferential groove 42 and the rotary handle 38 has at least one projection 44 on its recess 40 which fits into the groove 42 of the fixing section 36 of the pin element 26 when the rotary handle 38 is arranged to fit on the pin element 6 of the locking device 22.

The rotary handle M is provided in a central space 4S which serves to accommodate the spring element 34. The spring element 34, which is designed as a helical spring, has a first end section 48 and a second loading section 50, the spring element 34 being secured with its first end section 48 in the bearing sleeve 12 and with its second collar section 50 in the rotary handle 38. The spring element 34 is secured to the bearing sleeve 12 and to the rotary handle 38 with its two end sections 48 and 50 in such a way that in the normal rest position of the locking device 22 the fastening end section 30 of the pin element 26 presses against the center column 18 with a static friction force, the spring element 34 being mechanically relaxed. If the rotary handle is turned from this normal operating position into the release position of the locking device 22, the pin element 26 with its external thread section 28 or with its fastening end section 30 is moved away from the center column 18 by a small distance, whereby the spring element 34 is simultaneously mechanically tensioned. If the rotary handle 38 is released in the release position, the spring element 34 is relaxed, which causes a rotational movement in the direction opposite to the release adjustment, whereby the pin element 26 automatically returns to the

Threaded hole 24 of the bearing sleeve 12 is screwed in so that the locking device 22 or its rotary handle 38 is automatically returned from the release position to the normal operating position, in which a frictional connection is again established between the central column 18 and the pin element 26 of the locking device 22. If the locking device 22 is adjusted from the normal operating position to the locking position, which is done by a corresponding rotation of the rotary handle 38 in the direction of rotation opposite to the release adjustment, a mechanical tension of the spring element 34 results in the opposite direction, without this tension of the spring element 34 causing an automatic adjustment of the locking device 22 from the fixing position to the normal operating position after the rotary handle 38 is released. In the fixing position, there is a static friction contact between the pin element 26 or its fastening end section 30 and the center column 18 with such a force that the tension of the spring element 34 is smaller than this static friction force. On the other hand, this tension of the spring element 34 in the locking position of the locking device 22 results in a reduction in the amount of force required to return the locking device 22 or the rotary handle 38 from the locking position to the normal operating position.

Claims (8)

, ■ _&igr;1 , 29.047/70-R1 Cullmann Handelsgesellschaft für Verbrauchersüter mbH, WaldBtraase 12. 8506 Lanqenzenn Tripod for optical devices, with a central column (18) that can be moved and locked in a bearing sleeve (12) of the tripod (10), and with a locking device (22) provided on the bearing sleeve (12) that can be adjusted between a locking position in which the central column (18) is fixed in relation to the bearing sleeve (12) and a release position in which the central column (18) is movable in relation to the bearing sleeve (12), characterized in that \/ &Lgr;2, that the locking device (22) has a pin element (26) and a spring element (34), wherein the pin element (26) is forced against the center column (18) with a static friction force in the locking position, is removed from the center column (18) with a fastening end section (30) in the release position and is pressed against the center column (18) with a sliding friction force by means of the spring element (34) with the fastening end section (30) in the normal operating position lying between the locking and the release position. 2. Tripod according to claim 1, characterized in that the pin element (26) has an external thread section (28) which is screwed into a threaded bore (24) provided in the bearing sleeve (12). 3. Tripod according to claim 1 or 2, characterized in that the pin element (26) has a fixing section (36) for a rotary handle (38) remote from the central column (18). 4. Tripod according to claim 3, characterized in that the spring element (34) is provided between the rotary handle (38) and the bearing sleeve (12). 5. Tripod according to claim 3 or 4, characterized in that the fixing section (36) of the pin element (26) with a cross-sectional shape deviating from the circular shape and that the rotary handle (38) has a recess (40) with a cross-sectional shape corresponding to the fixing section (36) of the pin element (26). 6. Tripod according to claim 5, characterized, that the fixing section (36) of the pin element (26) has a groove (42) and the rotary handle (29) has a projection (44) which engages in the groove (42). 7. Tripod according to one of the preceding claims, characterized in that the pin element (26) has a receiving section (32) for the spring element (34), and that the spring element (34) is designed as a helical spring which is movably arranged on the receiving section (32) of the pin element (26) provided for this purpose. 8. Tripod according to claim 7, characterized, that the coil spring (34) has two Has fastening end sections (48, 50), of which one fastening end section (48) is fixed to the bearing sleeve (12) of the tripod (10) and the second fastening end section (50) is fixed to the rotary handle (38).