DE202013000692U1 - Window pivot device - Google Patents

Abstract

A disk pivoting device with at least one stationary base element (1) and a pivotally mounted disk holder (3) for holding a disk (2), and a force accumulator (4), wherein a first connection of the energy accumulator (4) is fixedly secured to the base element (1) characterized in that a second connection of the energy accumulator (4) is articulated via a lever element (5) on the base element (1) and the disc receptacle (3) is non-rotatably connected to a pivot shaft (6) for torque transmission, wherein the energy accumulator (4) via the lever member (5) causes a torque which is transmitted to the pivot shaft (6).

Description

The present invention relates to a disk pivoting device for assisting the pivoting movement of a disk. The pivoting movement is supported by a force storage. Disc swivels or lifting hardware are usually used at sales counters or counters. The disk pivot devices facilitate the lifting and closing of the front glasses.

Such devices are known in the art. For example, in the publication DE 90 04 215 U1 is shown a support for a sales counter for mounting a hinged front window. One end of the gas spring is fixedly attached via the fork end to a bolt. The second end of the gas spring is attached to an articulated arm. The longitudinal axis of the gas spring is oriented orthogonal to the axis of rotation which passes through the hinge pin.

In the DE 19 88 255 U a folding window for rail-bound passenger cars and buses is shown. As well as from the 1 and 2 to refer to the document, the strut is hinged on the one hand articulated to a crossbar and on the other hand to the buck. When you open the window, the strut is compressed. The axis of rotation is in this construction at the bottom of the window, which is located on the bottom and a stop block which limits the opening of the window.

In the EP 02 63 957 A2 a sales counter with a pivoting windshield is shown. The energy accumulator is mounted on the one hand to the fixed articulation point and on the other hand attached to the articulation point. The longitudinal axis of the energy accumulator is arranged orthogonal to the axis of rotation.

In the DE 44 02 727 C1 a device for pivoting a disc is shown. In this device, the force accumulator used are attached directly to the hinge part.

One object is to design a generic disk pivoting device such that a space-saving installation of the disk pivoting device at a counter or sales counter is made possible. A further object of the present invention is to reinforce the force of the force accumulator so that the disc pivoting device can be realized with only one force accumulator. These objects are achieved by the features of the independent claim. The dependent claims relate to advantageous embodiments of the invention.

The disk pivoting device may comprise at least one stationary base element, a pivotally mounted disk holder for holding a disk, and a force accumulator. A first connection of the energy accumulator can be fixedly attached to the base element. The basic element can be made in one or more parts. A second connection of the energy accumulator can be articulated via a lever element on the base element. The lever element used can increase the force of the energy accumulator. In this case, the force of the energy accumulator acts on the lever element on the pivoting movement of the pivotally mounted disc holder and thus supports the pivoting movement.

The disc holder may be rotatably connected to a pivot shaft for torque transmission. The energy accumulator can cause a torque on the lever element which is transmitted to the pivot shaft. The conversion of the force of the force accumulator via the lever element into a torque which acts on the pivot shaft, allows a compact design of the disc pivoting device. By providing a pivot shaft via which the torque is transmitted, it is possible to make the disc holder largely independent of the energy storage and other components.

The energy accumulator can cause a torque on the lever element, which can be transmitted via a transmission to the pivot shaft. The use of a transmission allows a variety of advantageous design options. On the one hand, the torque generated via the lever element can be changed, and on the other hand, a more variable arrangement of the energy accumulator is made possible. Through the use of a lever element and a gearbox, the movement plane required for the force generation of the force accumulator can be reduced, so that the required installation space for the disc pivoting device can be advantageously reduced.

The disk pivoting device may also comprise a deflection gear or a propeller shaft. Through a deflection gear or a propeller shaft, the force of the energy accumulator can be deflected so that the energy storage independently can be arranged from the axis of rotation of the disc holder. The plane of movement spanned by the force accumulator can be arranged parallel to the axis of rotation of the disc holder in order to further reduce the required installation space. About the propeller shaft, the torque generated can be deflected in the direction of movement required for the pivoting movement. As a result, the energy accumulator and the lever element can be arranged independently of the axis of rotation of the disc holder.

The energy accumulator can be arranged on one side of the base element and the disc holder on another side of the base element. This allows a more flexible arrangement of the energy storage and the disc holder. The required installation space of the energy storage is not in conflict with the required installation space of the disc holder.

The torque can be transmitted via a transmission bearing shaft from one side of the base member to the other side of the base member, wherein the transmission bearing shaft can be rotatably supported and can pass through the base member. The transmission bearing shaft can be designed on the one hand as part of the transmission and on the other hand used for the storage of the lever and / or the energy storage. As a result, the installation space of the disk pivoting device is reduced.

The lever element may have an eccentric end, which may be in communication with the second connection of the energy accumulator. The torque acting in the second connection of the energy accumulator, in conjunction with the lever arm of the lever element, generates the torque. The lever element can be mounted at a central end.

The disk pivoting device may comprise a lever element which is non-rotatably connected to a transmission bearing shaft, which may be mounted on the base member. Via the gearbox shaft, the torque can be transmitted through the gearbox. Since the lever member is rotatably connected to the transmission bearing shaft, the torque generated via the lever element can be passed directly into the Getriebelagerwelle and in the transmission.

The disk pivoting device may comprise a bevel gear, which may be fixedly connected to the transmission bearing shaft. The bevel gear may be in communication with a second bevel gear which may be fixedly connected to the pivot shaft. Through the use of the bevel gears on the Getriebelagerwelle and the pivot shaft, a simple diversion of torque from the transmission bearing shaft on the bevel gears in the pivot shaft is made possible. In addition, the installation space of the disk pivoting device can be kept to a minimum by the use of two bevel gears.

The pivot shaft which is non-rotatably connected to the disc holder in connection may be formed as part of the transmission. By forming the pivot shaft as part of the transmission, the installation space of the disk pivoting device can be reduced.

The disc holder may be suitable for picking up a glass pane. The inclusion of a glass pane requires a careful fixation of the disc. Unlike metal, plastic or wood discs, drilling or excessive clamping forces can cause the glass to fail. Also discs made of Plexiglas or various plastics can be fixed in the receptacle.

The energy storage of Scheibenschwenkvorrichtung- may be a gas pressure accumulator. The slender cylinder-like shape of the gas pressure accumulator can have a positive effect on the reduction of the installation space of the disk pivoting device. The energy accumulator can also be configured via a spring, gas spring, torsion spring, or generally pneumatic spring or as a coil spring, torsion spring, bending spring or air spring.

The disk pivoting device may comprise a rack instead of the lever. By the movement of the rack can be generated via an associated gear torque. The energy accumulator moves the rack along a guide attached to the base element. As a result, a one-dimensional movement of the energy accumulator can be converted into a torque and the required installation space of the disk pivoting device is reduced to a minimum. The disc pivoting device with the rack may allow the force of the force accumulator in the direction sense does not change during the pivotal movement of the disc holder. As a result, a compact arrangement of the energy storage is guaranteed regardless of the opening angle of the disc holder. The energy accumulator can be arranged parallel to the axis of rotation of the disc holder in order to make the disc pivoting device even more compact.

The disc pivoting device may be installed in a counter, wherein the base member may be fixedly connected to the ceiling and the disc holder can receive the front window of the counter.

Advantageous embodiments and further details of the present invention will be described below with reference to various embodiments with reference to schematic figures. In the schematic drawings, the connection is explained in detail.

1 : shows a first view of the disk pivoting device.

2 : shows a plan view of the disk pivoting device.

3 : shows a side view of the disk pivoting device on the axis of rotation.

4 : shows a side view of the disk pivoting device in the open position.

5 Fig. 1 shows a side view of the disk pivoting device in the closed position.

6 : shows a side view of the disc pivoting device with built-in disc and cover elements.

7 : shows an oblique view of the disk pivoting device.

8th : shows the power flow at the disk pivoting device

9a : shows the movement plane of the energy store in parallel arrangement.

9b : shows a plan view of the disk pivoting device with the energy storage device in a parallel arrangement.

10 Fig. 1 shows a plan view of the disk pivoting device for a further embodiment with rack.

11a Figure 1 shows another embodiment of the invention with the disc in the open position.

11b Figure 11 shows a further embodiment of the invention with the disc in the middle position.

11c Figure 1 shows a further embodiment of the invention, with the disc being shown in the closed position.

12a : shows a further view of the embodiment of the invention.

12b Fig. 3 shows another view of the embodiment of the invention with the abutment in contact with the base member.

In 1 a first view is shown on the disc pivoting device. The components required for the realization of the disk pivoting device are on a basic element 1 attached. The basic element 1 can also be designed as a housing. Another possibility is that primitive 1 as part of a profile used for the bar. The basic element 1 has different attachment points 101 . 102 . 103 on. The profile part of the basic element 1 in 1 has an elongated shape with a quadrangular profile. The execution of the primitive 1 however, it does not conform to the square shape 1 limited. The basic element 1 may also be an L-profile, U-profile or the like. The choice of profile shape depends on the particular application of the basic element 1 , The basic element 1 can in addition to receiving the disc pivoting device also supporting functions of the counter 11 in which the disc pivoting device is installed, take over. Depending on the particular application, the basic element 1 also be made of metal or plastic.

On the back of the in 1 shown basic element 1 is the energy storage 4 above the attachment point 103 at the basic element 1 fixed in place. The energy storage 4 For example, it can be a gas pressure accumulator. The energy storage 4 can make a first connection 41 of the energy store 4 exhibit. This first connection 41 of the energy storage is designed as a joint, which over the attachment point 103 with the primitive 1 communicates. The cylindrical energy storage 4 has a second port 42 of the energy store. The first connection 41 of the energy storage and the second connection 42 of the energy storage are as the entire energy storage 4 , on the back of the basic element 1 ,

The first connection 41 of the energy accumulator and the second connection of the energy accumulator 41 can also be designed as a joint or ball joint. These joints are possible with a two or three degrees of freedom. About the energy storage 4 Forces are in the first port 41 of the energy storage and the second connection 42 directed the energy storage.

The second connection 42 the energy accumulator is connected to an eccentric end of the lever element 5 in connection. The connection can be made via bolts or pins via the joint of the second connection 42 of the energy storage done. Also a direct storage of the second connection 42 the energy accumulator at the eccentric end of the lever member 5 is possible. This would be the eccentric end of the lever element 5 directly a part of the joint which with the second connection 42 of the energy accumulator is related. This would be a pin or bolt for the connection of the energy storage 4 not necessary. The length of the pen 51 in 1 can be designed depending on the joint used.

A centric part of the lever element 5 is fixed to a transmission bearing shaft 8th connected. The transmission bearing shaft penetrates 8th the basic element 1 and is stored in this. The transmission bearing shaft 8th is in the basic element 1 rotatably mounted. About the eccentric end of the lever element 5 and the power storage device connected therewith 4 The force of the energy storage is converted into a moment, which in the transmission bearing shaft 1 is led. About the length of the lever element 5 The size of the torque can be influenced.

The gear shaft suitable for torque transmission 8th which in the basic element 1 is stored, directs the torque in the transmission 7 further. The diameter of the transmission bearing shaft 8th can be designed depending on the maximum torque occurring. When used in a refrigerated counter, the material of the gear shaft 8th of the lever element 5 and the primitive 1 be coordinated so that jamming is avoided by temperature fluctuations and the associated thermal expansion coefficient of the various materials.

At the front of the basic element 1 , as in 1 shown is the other end of the transmission bearing shaft 8th , which is opposite to the lever element 5 firmly connected end of the transmission bearing shaft 8th located. On the other end of the transmission bearing shaft 8th is a bevel gear 9 appropriate. The bevel gear 8th is fixed to the transmission bearing shaft 8th in conjunction, so that the torque generated by the lever element in the bevel gear 9 can be forwarded. The use of bevel gears like in 1 is shown to represent only one of many possibilities of torque transmission. The bevel gear 9 stands with a second bevel gear 10 so in connection that the torque can be transmitted.

The transmission of torque from the transmission bearing shaft 8th on the pivot shaft 6 can also be realized with a reversing gear or a cardan shaft. On the pivot shaft 6 , which on the axis of rotation of the disc holder 3 is arranged, there is the second bevel gear 10 , The second bevel gear 10 is rotatably with the pivot shaft 6 connected. The torque is transmitted through the pivot shaft 6 in the disc holder 3 forwarded.

The disc holder 3 performs the pivoting movement. In this case, the disc mount is designed such that a recording of glass panes is easily possible. As an alternative to glass panes, however, panes made of metal, plastic or other materials are also conceivable. The disc holder 3 is pivotable in the stationary base element 1 stored. The disc holder 3 However, it can also be stored in an element which firmly in connection with the stationary base element 1 stands.

At the basic element 1 are also a first primitive fixation 101 and a second primitive fixation 102 , These fixings can be used for fixing the disc pivoting device at the respective counter.

In 2 a plan view of the disc pivoting device is shown. The gear 7 consists of two bevel gears which are arranged rotated by 90 ° to each other. The second bevel gear 10 is along the axis of rotation of the disc holder 3 arranged with the bevel gear 9 on the transmission bearing shaft 8th is arranged along the transmission bearing shaft rotation axis. In the present embodiment are the axis of rotation of the disc holder 3 and the rotation axis of the transmission bearing shaft 8th orthogonal to each other.

The energy storage 4 in 2 has an opening angle with respect to the axis of rotation of the disc holder 3 on. About the displacement of the second connection 42 of the energy storage is the lever element 5 emotional. The forces generated by the force accumulator 4 be on the one hand in a torque to the Getriebelagerwelle 8th converted and on the other hand in transverse forces which about the bearing of the Getriebelagerwelle 8th in the basic element 1 be recorded. On the side of the first connection 41 of the energy storage are the forces and moments occurring via a hinged storage at the attachment point 103 in the basic element 1 initiated. By the arrangement of the energy storage 4 on the back of the basic element 1 and the arrangement of the disc holder 3 on the front of the basic element 1 a reduction of the required installation space of the disk pivoting device is possible.

The telescopic movement of the energy storage 4 which in a rotational movement of the lever element 5 The result is the transmission 7 in a pivoting movement of the disc holder 3 diverted. This allows a flexible connection of the disc device to the counter. The energy storage 4 which is on the back of the basic element 1 However, it can also be located on an upper side or a lower side of the basic element 1 , depending on the basic element used, be appropriate. This is the power storage 4 on one side of the primitive 1 and the disc holder 1 on another side of the primitive 1 ,

In 3 is a side view in the direction of the axis of rotation of the disc holder 3 shown. The disc holder 3 has a pen 32 , a disc clamping element 31 and a deposit 33 on. In the deposit 33 a disc is inserted. This disc is over the disc clamping element 31 and the pen 32 in the disc holder 3 fixed. By the arrangement of the energy storage 4 , based on the disc holder 3 , the largest possible tilt angle of the disc is possible. Depending on the gearbox used 7 can thereby at constant movement distance of the energy storage 4 an individual tilt angle of the disc holder 3 be set. About the transmission 7 and / or the bevel gears used 9 and 10 as well as depending on the energy storage 4 and / or the length of the lever element 5 , Can be an adjustment of the optimal manual force to open and / or close, as well as the pressure in the closed position of the disc holder 3 to be discontinued.

The disc holder 3 can take a variety of glasses or front glasses. By appropriate adaptations, the disc holder 3 easily adapted. The disc which is in the insert 33 is located over the disc clamping element 31 clamped so that the disc is firmly attached to the disc holder 3 connected is. About the pen 32 the disc clamping force can be adjusted. The disc holder 3 has a root piece on which is circularly curved, so that the disc in the insert 33 opposite the axis of rotation of the disc holder 3 additionally spaced.

In 4 is a side view of the disk pivoting device shown in the open position. At the basic element 1 and at the storage of the disc holder 3 is a cover 104 appropriate. The cover 104 is at the respective maximum positions in the open and the closed position of the disc holder 3 customized. The disc holder 3 in 4 is executed in several parts. A lower part of the picture 34 and a top of the receptacle 35 clamp over the recording 33 the disc 2 one. The top of the picture 34 and the lower part of the receptacle 34 have grooves 351 on, in which the deposit 33 intervenes. The deposit 33 is in direct contact with the disc 2 , The grooves 351 The recording serve to fix the insert 33 and for even force distribution. This will secure the disc 2 , especially with glass panes. The top of the picture 35 has in addition to the clamping function of the disc 2 also a cover function. The top of the picture 35 is about hook-like elements 352 with the lower part of the recording 34 tightly clamped with respect to the recorded disc 2 an attack 353 between the shell 35 and the lower part of the receptacle 34 is present. The lower part of the picture 34 is in a leadership 341 the disc holder 3 guided and fixed. The fixation can be carried out for example via screws or bolts. The leadership 341 of the lower part of the picture 34 and the top part of the recording 35 allows a quick removal and installation of the disc and a quick disassembly of the disc holder 3 and the lower part of the picture 34 ,

In 5 the disk pivoting device is shown in the closed position. The disc holder 3 has a stop 36 the receptacle on which in the closed position of the disc pivoting device in contact with a part of the basic element 1 communicates. The stop 36 The recording allows by its variability an individual adjustment of the position of the disc 2 in the closed position, so that the pressure in the closed position of the counter 11 can be customized according to the respective user requirements.

The lower part of the picture 34 has a linear guide over which the connection to the disc holder 3 will be produced. This guide 341 may be, for example, a sliding guide or rail guide. The arrangement of the slide can be the lower part of the recording 34 when loosening the attachment from the guide 341 the disc holder 3 for faster replacement.

In 6 is the disc pivoting device when installed at a counter 11 shown. The one- or multi-part basic element 1 is about a counter fixation 105 stuck with the counter 11 in connection. At the counter fixation 105 can also be simultaneously recordings for a possible counter lighting. The disk pivoting device can via holding elements 1051 and fasteners 1052 at the counter fixing 105 to be appropriate. The fasteners 1052 For example, screws can be. These screws are for attachment through the first primitive fixation 101 and / or the second primitive fixation 102 guided.

In 7 is shown an oblique view of the disc pivoting device. The disc holder is about screws in the fixing holes 31 . 32 with the pivot shaft 6 connected. The pivot shaft 6 can be executed in one or more parts. In the present embodiment, the pivot shaft 6 through the disc holder 3 passed. The screws in the fixing holes 31 . 32 ensure the non-rotatable connection of the disc holder 3 with the pivot shaft 6 , Alternatively, a keyway could also be provided.

In 8th the power flow plan of the disk swing device is shown. The force F4 of the energy accumulator 4 generated via the connection and the lever element 5 the moment M8 which over the transmission bearing shaft 8th is transmitted. This moment M8 is about the transmission 7 in the pivot shaft 6 redirected in which the moment M6 occurs. The force flow diagram illustrates the conversion of force F4 of the energy storage device 4 in the respective moments and the deflection of these moments, so that a pivoting movement of the disc holder 3 by the force F4 of the energy storage 4 is supported. When installing an electronically or electrically activated energy accumulator 4 In addition, an autonomous pivoting of the disk pivoting device is possible. The force F4 here has only a small angle with respect to the axis of rotation. A parallel arrangement of the force F4 brings the advantages of facilitated connection of the energy storage 4 , the connection joints could be parallel arrangement of the energy storage 4 be provided with only one degree of freedom. The reduction of two degrees of freedom to one degree of freedom results in a simpler joint design.

In 9a is the plane of movement E of the energy storage 4 shown, wherein the energy storage 4 parallel to the axis of rotation of the disc holder 3 is arranged. With parallel arrangement of the energy storage 4 to the axis of rotation of the disc holder 3 is also the movement plane 1 of the energy store 4 parallel to the axis of rotation of the disc holder 3 , The lever element 5 turns around the rotation angle α. In 9b is the top view of the disk pivoting device with parallel energy storage 4 shown.

In 10 a further embodiment of the disc pivoting device is shown. In this version is the lever 5 through a rack 52 replaced. The rack 52 is about a storage 53 firmly on the basic element 1 stored. This is the rack 52 only a longitudinal movement parallel to the axis of rotation of the disc holder 3 possible. The rack 52 is in contact with the gear 91 which rotates on the base element 1 is stored. The longitudinal force of the energy storage 4 gets over the rack 52 in a rotational movement or a torque on the gear 91 transformed. The gear 91 is in connection with a second gear 92 and this is related to the second bevel gear 10 or with a third gear. About the second bevel gear 10 or the third gear, the torque is in the pivot shaft 6 and subsequently into the disc holder 3 directed. In the present arrangement, the energy storage leads 4 only a telescopic linear movement, a rotational movement of the energy storage 4 is no longer needed here. This arrangement also makes it possible that the power losses of the energy storage 4 be reduced to frictional losses. The power of the energy storage 4 acts over the rack 52 directly on the generated torque, which is thus only dependent on the force of the energy storage. A version with only one gear instead of the gears 91 and 92 is possible, too.

In 11a another embodiment of the present invention is shown. In this embodiment, the basic element 1 on a square bar fixation 105 appropriate. In the embodiment shown, the disc 2 in the closed position inclined by about 8 ° to 10 ° relative to the vertical position.

11a shows the disc 2 in open position, in 11b is the disc 2 in focus and in 11c is the disc 2 in closed position. The disc 2 is in this embodiment punctually with the disc holder 3 connected. This connection can be realized for example by means of a screw. The energy storage 4 acts in this embodiment only when extending the piston rod 43 ,

In 11b the disk is shown in center of gravity. This is the focus of the disc 2 so above the disc holder 3 in that the lever element 5 aligned along the disc pivot axis. The moments occurring cancel each other, so that the energy storage 4 is relieved. The stop 36 The recording, for example, be made of plastic.

In 11c is the disc 2 shown in closed position. The eccentric end of the lever element 5 is deflected in the opposite direction than in the position in the open state of the disc 2 , in 11a , The first connection 41 and the second connection 42 of the energy store 4 are designed as hinges in the illustrated embodiment. This type of connection of the energy storage 4 reduces the movement of the energy storage device 4 Required degrees of freedom and increases the efficiency of the stored energy storage 4 ,

12a is another view of the above-mentioned embodiment. Here is the disc 2 in the disc holder 3 attached. Part of the primitive 1 is about fasteners 1053 at the counter fixing 105 fixed. The illustrated counter fixation 105 consists of a tube with a square profile and is firmly connected to the counter. The disc 2 may be inclined in the closed position, for example by 10 °, based on the vertical position of the disc 2 ,

In 12b is the stop 36 in contact with the primitive 1 shown. By the stop 36 is a limitation of the maximum movement of the disc 2 possible. The stop 36 For example, it can be made of rubber or plastic.

Present features, components and specific details may be interchanged and / or combined to create further embodiments depending on the required use. Any modifications that are within the skill of those in the art are implicitly disclosed with the present specification.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 9004215 U1 [0002]
• DE 1988255 U [0003]
• EP 0263957 A2 [0004]
• DE 4402727 C1 [0005]

Claims (13)

A disk pivoting device with at least one fixed base element ( 1 ) and a pivotally mounted disc holder ( 3 ) for holding a disc ( 2 ), and an energy store ( 4 ), wherein a first connection of the energy store ( 4 ) fixed to the basic element ( 1 ) is characterized in that a second connection of the energy storage device ( 4 ) via a lever element ( 5 ) at the basic element ( 1 ) is hinged and the disc mount ( 3 ) rotatably with a pivot shaft ( 6 ) is connected to the torque transmission, wherein the energy storage ( 4 ) via the lever element ( 5 ) causes a torque on the pivot shaft ( 6 ) is transmitted. The disk pivoting device according to claim 1, characterized in that the energy accumulator ( 4 ) via the lever element ( 5 ) causes a torque which via a transmission ( 7 ) on the pivot shaft ( 6 ) is transmitted. The disc pivoting device according to claim 2, characterized in that the transmission ( 7 ) comprises a reversing gear or a propeller shaft. The disk pivoting device according to one of claims 1 to 3, characterized in that the energy accumulator ( 4 ) on one side of the primitive ( 1 ) and the disc holder ( 3 ) on another side of the primitive ( 1 ) is mounted, and the torque via a transmission bearing shaft ( 8th ), wherein the transmission bearing shaft ( 8th ) is rotatably mounted and the basic element ( 1 ) interspersed. The disk pivoting device according to one of claims 1 to 4, characterized in that the lever element ( 5 ) has an eccentric end with the second connection of the energy store ( 4 ) The disk pivoting device according to claim 2 or 3, characterized in that the lever element ( 5 ) rotatably with a Getriebelagerwelle ( 8th ), which at the basic element ( 1 ) is mounted, via which the torque in the transmission ( 7 ). The disk pivoting device according to claim 6, characterized in that a bevel gear ( 9 ) fixed to the transmission bearing shaft ( 8th ) and the bevel gear with a second bevel gear ( 10 ), which fixed to the pivot shaft ( 6 ) is connected. The disc pivoting device according to one of claims 2 to 5, characterized in that the pivot shaft ( 6 ) as part of the transmission ( 7 ) is trained. The disk pivoting device according to one of claims 1 to 7, characterized in that the disk holder ( 3 ) for receiving a disc ( 2 ) made of glass is suitable. The disk pivoting device according to one of claims 1 to 8, characterized in that the energy accumulator ( 4 ) is a gas pressure accumulator. The disk pivoting device according to any one of claims 2, characterized in that instead of the lever ( 5 ) The gear ( 7 ) comprises a rack. The disk pivoting device according to claim 11, characterized in that the force-acting direction of the energy accumulator ( 4 ) does not change during the pivoting movement. A counter with the disk pivoting device according to one of claims 1 to 12, characterized in that the basic element ( 1 ) fixed to a counter ( 11 ) and the disc mount ( 3 ) receives the front window of the counter.

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