DE4013331C1 - Clamp for telescopic column in gymnasium - incorporates collar with levers engaging holes in hollow column - Google Patents

Abstract

The clamp consists of a collar which is fitted to the column and whose wing bearing limits a clamping slot and mounts a swivel lever. The lever swings between down clamping and raised release settings and an arrester swivels parallel to the lever between an arrest setting in which it locks into a slot on the inner leg of the column and a release setting raised clear of the slot. The arrester is held in the arrest position by a lug fitted on the lever when the lever is in its clamping position. The arrseter lever (36) should consist of a two arm drop lever arranged above the swivel lever (23). The lever (36) arm (47) facing away from the telescopic column should grasp round the nose (35) of the lever radially inwards from the arm. USE/ADVANTAGE - Gym equipment, e.g. parallel bars. Lever clamp and arrest system provides easy access without wearing parts.

Description

The invention relates to a clamping device for detachable Determining the movable column parts of a telescopic column a gymnastics device, in particular a bar, with a clamp cuff on the outer column part, which be a clamping slot has adjacent wing, on which a pivot lever as Clamping element is mounted between a downward ge pivoted clamping position and a pivoted release position is pivotable, and with a reference to the outer column part fixed locking, which is parallel to the Swivel lever between one in a recess of the inner Column-engaging locking position and one from the Recess raised position is pivotable, wherein the locking a safety projection on the swivel lever is assigned to the in the clamping position of the pivot lever Holds in its locking position.

Clamping devices of this type are used for gymnastics equipment turns, two mutually displaceable in the vertical direction  Column parts of a telescopic column can be detached in certain positions to be determined. The preferred application is for bars, the four telescopic columns in pairs, each carrying a spar have. In the release position of the one that forms the clamping element Swivel levers can be used with the clamping device adjust the connected column parts in the height direction, to adjust the device height and / or opposite each other turn to set the device width.

The respective swivel lever is located during gymnastics in its clamped position, the two pillar parts being powerful are firmly clamped together. Soon the locking takes its locking position at an early stage, in which, for security reasons, an additional positive Establishes connection between the two column parts. Thereby is an accidental one even with decreasing clamping force Lowering of the device height excluded.

The gymnasts are increasingly winding individual gymnastic exercises on the protruding bar ends of the ingot. In doing so the column parts of the opposite telescopic columns are very strong in the sense of pulling apart. Thereby be there is always the risk that if the clamping decreases force an unwanted lifting of the upper, inserted pillars partly takes place, which leads to the fall and injuries of the gymnast can lead.

This danger is also present in the state of the art DE-PS 4 93 010 given a clamping device with the input  described features. With this well-known before direction is locked by a leaf spring, which are located below the clamping collar on the outer column part extends along from bottom to top and at its upper end a locking lug carries through the outer column part engages in the respective recess of the inner column part. The pivot lever is based on the leaf spring in the radial direction in front and presses in its clamped position against the molded protrusion on it from the outside the locking nose. Now has an effect on the inner column part force directed upwards, the locking lug can be pushed outwards and the pivot lever is pivoted into its release position be so that the inner column part can be pulled up.

Another disadvantage of the known device is that that the swivel lever, so that the locking Leaf spring can be accommodated, a corresponding Ab stood facing the telescopic column. Bring protruding parts with gymnastics, however, there is a risk of injury for the gymnast with yourself. There is therefore a correspondingly increased risk of injury in front.

Furthermore, the sheet is in the release position of the pivot lever spring difficult to access when lowering the interior Column part must be operated by hand.

After all, the leaf spring can become lame over time and break.  

The present invention is therefore based on the object to create a clamping device of the type mentioned at the outset, which with better accessibility of the lock in place saves one without the use of wearing parts effective protection against pulling apart which forms the column parts.

This object is achieved in that the Locking one above the swivel lever two arm-like drop lever is the one facing away from the telescopic column Lever arm the fuse located radially on the inside projection of the swivel lever engages behind.

Since the drop lever forming the lock is above the Swivel lever is located, this can be ignored Locking lever fully moved to the telescopic column and the Risk of injury can thus be reduced. Also disabled the pivot lever does not give access to the drop lever. Especially but matches the top arrangement of the drop lever with its two arms and reaching behind the fuse projection with itself that next to that by means of the pivot lever caused a secure locking in both directions exists when the drop lever is in its locking position and the swivel lever is in its clamped position.

Another advantage is that the latch is located opposite him a recess of the inner column part, due to its weight automatically reaches the locking position, whereby a spring or the like is omitted.  

From DE-GM 17 66 942 it is known per se, one to use two-armed locking lever when pulling on the inner column part strikes upwards on the swivel lever. However, this locking lever extends between the Telescopic column and the pivot lever, so that the pivot lever protrudes relatively far from the telescopic column and the Be end of the locking lever. Furthermore, again a spring pushing the locking lever into the locking position available.

Appropriate embodiments of the invention are in the Unteran sayings.

If there is a stop according to claim 2, the is in the inner column part engaging lever arm of the locking lever supported downwards and thus also larger when it occurs Forces secured against swiveling downwards.

The realization of the attack according to claim 3 requires no additional part or the like. So that this measure manufacturing is technically particularly cheap.

In the embodiment according to claim 4, the locking lever sits on bearings separate from the bearing wings of the swivel lever to bake. In this way, a reduction in the Ab did not get up between the bearing wings during the clamping process the bearing jaws, so that the free pivotability of the Locking lever is not affected.  

The invention is described below with reference to the attached Drawing illustrated embodiment explained in more detail. The individual shows:

Fig. 1 is a equipped with the inventive clamp bars in a schematic view,

Fig. 2 shows a preferred embodiment of the clamping device in longitudinal section, wherein the two column parts are shown only in part and the clamping element in the clamping position and the locking element in the blocking position are located,

Fig. 3, the clamping device as in Fig. 2, partially broken, with the clamping element in the release position and the locking element in the release position and

Fig. 4, partly in section, the same clamping device in rotated by 90 °, on the section line IV-IV in Fig. 2.

The clamping device 1 is used in gymnastics equipment.

In Fig. 1 such is shown in the form of an ingot, which has a bottom 2 , four telescopic columns 3 protrude vertically in the use position. Two of these telescopic columns 3 carry a bar beam 4 connecting them at the top. Each telescopic column 3 has an outer tubular column part 6 , which protrudes from the bottom 2 . An inner column part 5 , which is preferably also designed as a tube, is inserted into this from the high end. The respective parallel bar 4 is attached to its upwardly projecting end.

The two column parts 5 , 6 of a respective telescopic column 3 can be adjusted relative to one another in the direction of their longitudinal axis 8 and thus in the vertical direction of the ingot according to "double arrow 7 ". By means of the clamping device 1 , the column parts 5 , 6 can be releasably fixed relative to one another in order to set a desired device height. Under certain circumstances, when the clamping device 1 is released , the upper inner column part 5 can also be rotated relative to the lower outer column part 6 in order to vary the width of the devices available between the bars 4 . In this case there is a suitable joint in the transition area between the telescopic columns 3 and a respective parallel bar 4 .

One of the clamping devices 1 is enlarged in FIGS. 2-4 and shown in detail. Advantageously, all clamping devices 1 of a respective gymnastics device are constructed in a corresponding manner. For the sake of clarity, the column parts 5 , 6 are not shown in FIG. 4.

The clamping device 1 has a clamping area 9 , which in the exemplary embodiment is formed by a clamping collar 10 . With this, the clamping device 1 is placed axially on the free end of the outer column part 6 . The corresponding passage 14 has a ring step 15 which limits the attachment path. In this way, the clamping device 1 sits like a head on the towering lower column part 6 , it can therefore also be referred to as a clamping head. The column part 6 is slotted at least in the end region arranged within the clamping region 9 . A corresponding longitudinal slot that is open on the end face of the tube can be seen at 16 .

The clamping device 1 sits on the column part 6 with the clamping collar 10 so that it cannot move in the direction of the longitudinal axis 8 . For this purpose, a press connection or a connection with conventional connecting elements can be provided. However, since it is expedient if the clamping device 1 is arranged on the column part 6 such that it can be rotated about the longitudinal axis 8 , the fixation takes place in such a way that only the axial movement is largely excluded. In the embodiment, the clamping collar 10 carries for this purpose at the lower end of the passage 14 an at least partially circumferential collar 17 , which sits in a corresponding annular groove 17 'on the outer circumference of the column part 6 .

The clamping collar 10 is longitudinally slotted at one point on its circumference and carries in the region of the two slot edges in each case a bearing wing 18 projecting laterally away from the telescopic column 3 . Both bearing wings 18 run in mutually parallel planes, which are also expediently aligned parallel to a column plane containing the longitudinal axis 8 and extending radially and axially. If the two bearing flaps 18 are moved towards or towards one another, then the diameter of the adjoining region of the clamping collar 10 also changes , so that the encompassing section of the column part 6 is compressed radially. After releasing the corresponding clamping force, there is an elastic return to the initial state. This effect is adopted in the present case for clamping the two column parts 5 , 6 together .

The required clamping force is generated via a clamping element 19 which is movably arranged on the clamping collar 10 and can be shifted between a clamping position shown in FIG. 2 and a release position shown in FIG. 3. In the clamped position, it causes a clamping connection between the outer column part 6 and the inner column part 5 pushed into it by means of the clamping sleeve 10 .

It acts on the clamping collar 10 in the sense of reducing its cross-section in the area of the slotted area of the column part 6 , whereby the latter is pressed radially clamping against the outer circumference of the inner column part 5 . In the free position, the clamping is released and the contact pressure reduced so that the inner column part 5 can be moved and / or rotated in the direction of the longitudinal axis 8 .

In the exemplary embodiment, the clamping element 19 has a clamping axis 20 which extends between the two bearing wings 18 at right angles to the longitudinal axis 8 . It is arranged at a radial distance from the circumference of the column part 6 and wings 18 in both bearings about its longitudinal axis 21 rotatably mounted. An actuating element 22 designed as a pivot lever 23 is arranged on the clamping axis section spanning the space between the two bearing wings 18 . There is a twist-proof connection, for which purpose the middle section of the clamping axis 20 can have a polygonal cross-section, onto which the pivot lever 23 is positively fitted with a corresponding opening 24 .

The two end sections 28 , 28 'of the clamping axis 20 each carry a thread. The direction of the turns is opposite, so that there is a left-hand and a right-hand thread. Corresponding counter-thread 29, 29 'are provided in the bearing wings 18, wherein the mating threads 29, 29' preferably in separate sleeve members 30 od nuts. Like. Are formed. The sleeve elements 30 are attached to the associated bearing wing 18 so as to be freely rotatable from the opposite outer sides and possibly at least partially let into recesses 31 of the bearing wing 18 . By means of fixing elements 32 , the rotational position of the two sleeve parts 30 can be fixed immovably releasably relative to the respective bearing wing 18 .

If the clamping element 19 is now rotated from its release position ( FIG. 3) into the clamping position ( FIG. 2) about the axis 21 with the aid of the downwardly pivoting lever 23 , then the thread sections of the clamping axis 20 screw into the counter threads 29 , 29 'On the wing 18 on both sides, whereby the wing 18 are contracted.

The setting of the clamping force and the actuation path of the clamping element 19 can be made after loosening one or both fixing elements 32 by screwing one or both sleeve parts 30 relative to the clamping axis 20 .

So that the inner column part 5 does not fall down in the release position of the clamping element 19 , a locking element 33 is additionally provided, which is arranged on the outer column part 6 . For this purpose, it forms part of the clamping head and is in fixed connection with the clamping region 9 of the clamping collar 10 via a holding region 34 . Holding area 34 and clamping area 9 are in particular formed in one piece with one another.

The locking element 33 can assume a locking position shown in FIG. 2, in which it releasably connects the two pillar parts 5, 6 which assume a certain relative axial position to one another. Several such relative positions are possible, in which the inner column part 5 projects into the outer column part 6 with different immersion depths.

It is essential that the locking element 33 cannot leave its locking position as long as the clamping element 19 is in its clamping position. Because in the clamping position of the clamping member 19 the locking member 33 is approximately projection 3 release position shown locked by means of a Siche 35 in its locking position against a movement to its in Fig. Or blocked.

The locking element 33 can only be shifted into its release position when the clamping element 19 is in its release position or is about to take one. In the release position of the locking element 33 , the positive connection between the two column parts 5, 6 is canceled, and these parts can be axially displaced relative to one another.

The securing projection 35 will automatically and automatically be moved between its locking ( Fig. 2) and the non-locking ( Fig. 3) position when the clamping element 19 is actuated. For this purpose, the securing projection 35 is arranged on the clamping element 19 so that it can be pivoted with it.

The locking element 33 is rocker-like in the manner of a trap. It is a two-armed locking lever 36 , which, pivotably suspended on a bearing axis 37 , can be moved between its two possible positions as part of a pivoting movement. The bearing axis 37 extends between two bearing jaws 38 , which are part of the holding area 34 and, corresponding to the bearing wings 18, protrude from the telescopic column 3 immediately above them. The locking lever 36 is freely rotatably received in the space between the two bearing jaws 38 , the bearing axis 37 penetrating it being anchored in the two bearing jaws 38 . The bearing axis 37 runs parallel to the longitudinal axis 21 at a distance above the clamping axis 20 .

In this way, the locking element 33 and the clamping element 19 are also part of the clamping head.

The locking element 33 is fixed in the locking position in such a way that the two column parts 5 , 6 are prevented from being pushed together due to a positive connection.

The locking lever 36 forming the locking element 33 is axially immovable relative to the outer column part 6 via the clamping device 1 or its clamping area 9 . On the other hand, it is pivotable about the bearing axis 37 . If it assumes the locked position shown in Fig. 2, is to be a lever arm 39 positively connected with arranged thereon means 40 to the inner pillar part 5 or latched. In the exemplary embodiment, a projection 44 is provided as a means 40 for connection, which in the locking position can engage in one of several recesses 45 arranged on the inner column part 5 . The recesses 45 are arranged on the inner column part 5 in the axial direction 8 at a distance from one another in a row of holes.

The lever arm 39 projects in the locking position from the bearing axis 37 essentially radially with respect to the longitudinal axis 8 in the direction of the inner column part 5 , the projection 44 located at the free end of the lever arm 39 engaging in one of the recesses 45 . In the locking position, the lever arm 39 is secured against swiveling downward by resting on a stop 46 . In the exemplary embodiment, the stop 46 is formed by the upper edge region of the outer column part 6 , but it could also be part of the clamping device.

Even if the clamping action should now decrease in the clamping position of the clamping element 19 , the inner column part 5 cannot slide downward because it is firmly secured by the locking lever 36 .

To adjust the height of the device, the locking element 33 is in particular manually brought into the release position shown in FIG. 3. If the clamping element 19 is in the release position and the inner column part 5 is pulled up out of the outer column part 6 , the locking element 33 can assume the release position automatically. The locking lever 36 pivots with its lever arm 39 carrying the projection 44 simultaneously with the displacement movement of the inner column part 5 upwards.

So that this locking lever pivoting movement is excluded in the clamping position of the clamping element 19 , the safety lock 35 ensures a corresponding blocking. The securing projection 35 projects in the clamping position of the clamping element 19 into the pivoting path of the locking lever 36 located in the locking position, so that it is fixed.

The securing projection 35 is arranged on the actuating element 22 of the clamping element 19 formed as a pivot lever 23 and is in particular formed by an integrally formed, nose-shaped projection on the circumferential region of the pivot lever part surrounding the bearing axis 37 . With the pivot lever 23 projecting essentially axially downward from the bearing axis 37 , the securing projection 35 is located in the region above the bearing axis 37 .

The locking lever 36 has a second lever arm 47 opposite the first lever arm 39 . This works together with the locking projection 35 to fix the locking lever 36 . In the exemplary embodiment, it is shaped for this purpose in such a way that, starting from the bearing axis 37, it projects radially away from the telescopic column 3 and at the same time projects downwards. In the locking position, its end area 48 therefore engages behind the securing projection 35 , which lies opposite the end area 48 radially on the inside. The securing projection 35 is thus arranged radially closer to the column parts 5 , 6 than the end region 48 of the locking lever 36 which cooperates with it when locking.

If now the two column parts 5, 6 in the sense of their load pulling apart, then the locking lever 36 is acted upon in the sense of its movement into the release position. Since he can still be supported on the securing projection 35 , the relative position between the two column parts 5 , 6 remains unchanged even when the clamping force decreases.

In order to be able to move the two column parts 5 , 6 relative to one another, only the clamping element 19 is to be brought into the release position indicated in FIG. 3, as a result of which the securing projection 35 is moved out of the pivoting path of the second lever arm 47 or its end region 48 . Now the locking lever 36 can be pivoted into the release position.

Claims (4)

1. Clamping device ( 1 ) for releasably fixing the displaceable column parts ( 5 , 6 ) of a telescopic column ( 3 ) of a gymnastics device, in particular a bar, with a clamping collar ( 10 ) on the outer column part ( 6 ), the bearing wing ( 18 ), on which a pivot lever ( 23 ) is mounted as a clamping element ( 19 ) which can be pivoted between a clamp position pivoted downwards ( FIG. 2) and a pivoted release position ( FIG. 3), and with one with reference to the outside Column part ( 6 ) fixed locking, which parallel to the pivot lever ( 23 ) between a recess ( 45 ) of the inner column part ( 5 ) engaging locking position ( Fig. 2) and a lifted out of the recess ( 45 ) release position ( Fig. 3rd ) is pivotable, with the locking being associated with a locking projection ( 35 ) on the pivoting lever ( 23 ) which, in the clamping position ( FIG. 2) of the pivoting lever ( 23 ), the locking ng in their locking position ( Fig. 2) holds, characterized in that the locking (locking lever ( 36 )) is a two-armed drop lever arranged above the pivoting lever ( 23 ), the lever ( 47 ) facing away from the telescopic column ( 3 ) which is radial to it the safety projection ( 35 ) on the inside of the pivot lever ( 23 ) engages behind. 2. Clamping device according to claim 1, characterized in that the telescopic column ( 3 ) facing lever arm ( 39 ) of the locking lever ( 36 ) in the locking position rests against a stop securing it against pivoting downwards ( 46 ). 3. Clamping device according to claim 2, characterized in that the stop ( 46 ) from the upper edge region of the outer column part ( 6 ) is formed. 4. Clamping device according to one of claims 1 to 3, characterized in that the locking lever ( 36 ) on a the clamping sleeve ( 10 ) and the pivot lever ( 23 ) containing, on the outer column part ( 6 ) attachable clamping head on above the bearing wing ( 18 ) for the pivot lever ( 23 ) from the telescopic column ( 3 ) projecting bearing jaws ( 38 ) is arranged.