DE19858350A1 - Slip clutch in particular for driving a winding storage device and winding storage device equipped with it - Google Patents

Abstract

The invention relates to a winding storage mechanism for storing individual sheets such as bank notes between the windings of a storage reel (24) that is characterized by a friction clutch (82) having a coupling lining support (84) lined with a clutch lining (86) on one side and a clutch disk (88) that can be pressed against the clutch lining (86) with a normal force (Fn), wherein said normal force (Fn) is modified inversely proportional to the transmitted torque (M) depending on a change ( DELTA M) of said torque, the supply reel (12) is rigidly fixed to the clutch lining support (84) and the shaft (16) of the supply reel (12) is coupled to a reversible reel drive (59, 60, 62, 64, 66) by means of a free-running wheel (67) in such a way that the supply reel (12) is rotated in the direction of winding (D) when the shaft is rotated and is secured when the reversible reel drive (59, 60, 62, 64, 66) rotates in the opposite direction.

Description

The invention relates in particular to a slip clutch for the drive of a winding storage and a wic kel memory for storing single sheets such. B. Banknotes between the turns of a tape wrap, around a housing with a transfer conveyor for the Single sheets and a storage spool, a storage spool and a reversible coil drive to at least one Storage tape from the supply reel to the storage reel and vice versa, with both coils in the Ge housing rotatably mounted around a shaft fixed to the housing are.

If such a winding memory, for example in egg an ATM is installed, it is connected to a trans port device connected, which banknotes with a predetermined constant speed to the winding chip cher transported or removed from the winding storage. It is therefore essential that the banknotes with constant Speed stored in the winding memory or be spent out of it. Since the banknotes are each in the outermost layer of the winding formed or are delivered from this position, this means that the peripheral speed of the tape winding of the memory coil must be constant.

In a memory known from EP 0 290 731 B1 Direction of the type mentioned are the storage track le and the supply spool are each floating and lie on stationary drive rollers, of which too at least one always at a constant speed can be driven. The drive rollers grip on Extent of the storage coil or the supply coil, so that there is a constant belt speed. This to  Order is relatively complex, since the storage of Storage spool and the supply spool carefully on it care must be taken that the floating coils change in the diameter of the tape roll do not tilt.

From US 3 222 057 A is one after the winding storage principle working memory device known in the the shafts of the storage spool and the supply spool are housed are stable and driven by a motor. The Motor is always in the winding direction of the storage reel operated while the shaft of the supply spool over a electromagnetically reversible gearbox in up and down Unwinding direction is drivable. The storage coil and the supply spool are each via an electromagnetic Coupling can be coupled with its shaft, the storage track le is also equipped with an electromagnetic brake allowed. For storing a banknote in the memory chereinrichtung the clutch of the storage coil be flows while the supply spool over to their output the reversing gear operated in the winding direction, the Coupling of the supply coil energized and the brake of the Storage coil must be operated. This arrangement is mechanically and technically very complex.

The object of the invention is to work purely mechanically slipping clutch with a tightly tolerated torque give as well as a winding memory that with such Slip clutch is equipped.

The first part of the task is characterized by the characteristics of the Claim 1 and the second part of the task by Features of claim 7 solved.

In general, the following results for a clutch disc Problem: The disc is countered with a normal force Fn an annular clutch lining with a Reibungskoef efficient µ and medium radius r pressed. That about  portable torque is M = Fn.µ.r. The friction coefficient efficient µ is subject to fluctuations (temperature, air humidity te, long-term changes). With constant normal force the effective torque is proportional to the changes subject to the coefficient of friction µ.

The invention is based on the consideration that with changes change in the coefficient of friction µ a constant torque ment can be obtained if the normal force is reversed per is changed proportionally.

According to the invention, the normal for the slip clutch force with increasing torque by increasing the Ab between the clutch lining and the clutch slice reduced until there is a balance between the transmitted torque and a counter torque ment. The normal force changes from the maximum (Idle state) down to 0 when the clutch disc is completely is lifted off the coupling material.

In Fig. 3 the basic structure of a slip clutch development is shown in a schematic side view. It shows a clutch lining carrier 1 with a clutch lining 2 fixed to it. This is a clutch disc 3 in a coaxial orientation with an Ab stood S opposite.

Fig. 4 shows a torque characteristic of the slip clutch shown in Fig. 3. If, due to a change in the coefficient of friction µ, the distance S of the clutch disc 3 from the clutch lining 2 is changed by a value ΔS ge against a defined counter torque, the working point of the slip clutch adjusts to this counter torque. If the coefficient of friction µ (µ1 ... µ3) changes, a counter torque GM equipped with a flat pitch captures the working point of the slip clutch with a narrow tolerance of ΔM.

Moving the clutch disc and clutch apart lungsbelag z. B. by a lever linkage, a win arrangement or by elastic material deformation rea be lized. The counter moment can be structurally simple by at least one preloaded mechanical spring be fathered.

In a preferred embodiment of the invention, the Counter moment generated by a spring, which a magnification the distance between the clutch lining and the Counteracts clutch disc.

A winding memory for storing single sheets like e.g. B. banknotes between the turns of a memory wic kels includes a housing with a transfer conveyor for the single sheets and a storage spool, a supply spool and a reversible spool drive to min at least one imaging plate from the supply reel to the Storage coil and vice versa to wind, both Spu len in the housing around a housing-fixed shaft are rotatably mounted. This winding storage is with the Slip clutch according to the invention according to one of the preceding existing claims, the supply spool is firmly connected to the clutch lining carrier and the Shaft via a freewheel in such a way with the reversible Coil drive is coupled so that when it rotates is rotated in the winding direction of the supply reel and in the opposite direction of rotation of the reversible Coil drive is held. This results in a particularly simple construction of the winding storage drive esp.

The reversible coil drive then comprises a single one gene motor, in particular a stepper motor, the egg a toothed belt, the shaft of the supply spool and the spokes cherspule drives.  

According to a preferred embodiment of the invention Winding storage is the transport speed of the Scan the imaging plate over a speed kept the tachometer at a constant value. There through is a bump and train-free handover of the individual sheets between the winding memory and one with a predetermined transport speed working trans port system possible without any problems.

An embodiment of the invention is described below Hand explained in the accompanying drawings. It shows:

Fig. 1 is a schematic side view of the contemporary storage roller fiction, in the direction of the SpeI cherspule of the storage winding with a small diameter,

Fig. 2 shows one of Fig. 1 view corresponding with ma ximalem diameter of the storage coil,

Fig. 3 shows the basic structure of a slip clutch in a schematic side view,

Fig. 4 is a torque characteristic curve of the set in Fig. 3 Darge slip clutch,

Fig. 5 shows the concrete structure of a slip clutch in a partially sectioned side view.

The roll storage shown in Figs. 1 and 2 comprises a housing 10 in which a supply reel 12 and a storage reel are rotatably mounted to housing-fixed shafts 16 and 18 14. An imaging plate 20 is connected to both the supply spool 12 and the storage spool 14 and can be wound back and forth between these two spools to form a supply reel 22 or a storage wiper 24 . For this purpose, the coils 12 and 14 are connected to a drive device 59 , 60 , 62 , 64 , 66 , which will be described further below. The imaging plate is guided between the supply reel 12 and the storage reel 14 via stationary deflection rollers 26 , 28 , 30 and a movable deflection roller 32 , which is mounted on a conveyor table generally designated 34 , which will now be explained in more detail below.

The conveyor table 34 has a frame 36 which , when the conveyor table 34 is in the position between the positions shown in FIGS . 1 and 2, simultaneously carries out a pivoting movement about a shaft 38 fixed to the housing and a translatory movement in the direction of the double arrow B, ie parallel to the direction of conveyance . For this purpose, the frame 36 laterally protruding front and rear Fort sets 40 , 42 , the slots in the fixed curved slots 44 , 46 engage, as shown in FIGS . 1 and 2.

Furthermore, the conveyor table 34 comprises a transfer conveyor 48 for transferring banknotes to the storage roll 24 or for removing banknotes from the storage roll 24 . The transfer conveyor comprises a belt conveyor 50 with an endless belt 52 . This is guided over two on the pivot shaft 38 at an axial distance from each other rotatably mounted first rollers 54 and second rollers 56 , which are rotatably mounted together with the movable deflection roller 32 on a shaft 58 which is held in the frame men 36 of the conveyor table 34 .

With the upper run of the endless belt 52 , roller pairs work together, each consisting of a support roller 68 supporting the endless belt and one of these respectively assigned pressure roller 70 , the rollers 68 and 70 being rotatably mounted on the frame 36 about axes 72 and 74, respectively.

In the state of the roll memory shown in FIG. 1, the imaging plate 20 is completely wound onto the supply reel 12 . The storage coil 24 thus has its smallest diameter. In this position, the conveyor table 34 receives under the action of a tension spring 76, on the one hand engages a housing-fixed point 78 and on the other hand on an extension 80 of the frame 36 at its topmost position a, in which the feed table 34 on the surface of the storage winding 24 lies on. In this position, the shafts 38 and 58 of the belt conveyor 50 have their greatest distance from one another.

Fig. 2 shows the roll storage in a state in which the storage roll 24 has its largest diameter. Due to the growing storage roll 24 , the conveyor table 34 resting on its surface is pressed down against the force of the tension spring 76 . During this pivoting movement downward, the frame 36 is moved by the sliding of the extensions 40 and 42 in the scenes 44 , 46 in Rich direction on the pivot shaft 38 .

The supply spool 12 and the storage spool 14 are driven by a motor 59 , preferably a stepper motor, via an endless toothed belt 62 . This is a motor toothed belt wheel 60 , a deflection roller 64 , a with the shaft 16 of the supply spool 12 connected via a freewheel 67 toothed belt wheel 66 and the storage spool 14 leads GE. The freewheel 67 couples the shaft 16 with the toothed belt wheel 66 when the motor 59 rotates in the winding direction of the supply spool 12 , while it blocks the shaft 16 when the motor 59 rotates in the winding direction of the storage spool 14 . The shaft 16 is coupled to the council spool 12 via a slip clutch 82 . A constant feed rate of the imaging plate 20 is achieved by a tachometer 61 which is in contact with the imaging plate 20 and regulates the speed of the motor 59 .

Fig. 5 shows the structure of the slip clutch 82 in partially cut side view. The supply spool 12 is provided with a clutch lining carrier 84 . On the latter, a clutch lining 86 is attached. This is opposed by a clutch disc 88 in a coaxial orientation. The clutch plate 88 has on its side facing away from the clutch lining carrier 84 a threaded projection 90 with an internal thread. The supply spool 12 is freely rotatable on the shaft 16 via ball bearings 92 so that it can absorb axial forces from the clutch lining 86 . In the area on the right in FIG. 5, the shaft 16 has a thread 94 , onto which the clutch disk 88 is screwed with its threaded attachment 90 up to the clutch lining 86 . On the shaft 16 , a leg spring 96 is arranged coaxially, one leg 98 of which is inserted into a bore 100 running in the threaded shoulder 90 and running parallel to the shaft 16 . The other leg 102 of the leg spring 96 engages in a second bore 104 which is introduced into a spring receiving nut 106 which is also screwed onto the thread 94 of the shaft 16 and is oriented parallel to the shaft 16 . The spring receiving nut 106 can be fi xed in any position on the shaft 16 by a lock nut 108 . The leg spring 96 is biased by screwing the spring receiving nut 106 onto the thread 94 in the direction of the clutch disc 88 with a desired torque and mounted between the clutch disc 88 and a fixed point given by the position of the - countered - spring nut 106 . Before the voltage is directed so that the clutch plate 88 is rotated against the clutch lining 86 .

The mode of operation of the slip clutch 82 in connection with the winding storage device is described below, it being expressly pointed out that its use is not restricted to such a winding storage device. Applications in which clutches with tightly tolerated torque in one direction of rotation are required are e.g. B. winding spools in weaving mills, paper roll processing, transformers and wire winding.

Here, the imaging plate 20 is to be wound onto the supply reel 12 with a constant torque or unwound from the latter. When unwinding, the shaft 16 is blocked, and by pulling on the imaging plate 20 , the spool 12 is rotated before; when winding the Wel le 16 rotates faster than the supply spool 12 , since the storage film 20 runs slowly from the storage spool 14 .

A) Unwinding the imaging plate

For storing bank notes in the storage reel, the shaft of the supply spool 12 fixed by the freewheel 67 and 16 pulling the aufgewic around the supply reel 12 kelten memory film 20th As the tensile force increases, the supply spool 12 rotates in the direction of the arrow C. The clutch disc 88 is carried along on the thread 94 until the "turning" moment of the leg leg 96 reaches a balance with the braking torque between the clutch disc 88 and the clutch lining 86 . The slip clutch 82 then works as a brake for the before reel 12 with this moment.

B) winding up the imaging plate

The shaft 16 is rotated in the direction of arrow D in order to withdraw banknotes from the winding store. With the storage film 14 retained by the storage film 20 , the clutch disk 88 is held over the frictional engagement with the clutch lining carrier 84 until it detaches itself from the clutch lining 86 by the spool 12 which rotates slower than the shaft 16 . Then there is an equilibrium of the torques between the prestressed leg spring 96 (rotating) and the slip clutch 82 (releasing). With slow release of the Speicherfo lie 20 this is now wound onto the supply spool 12 with constant torque.

From the rest position, in which the clutch disc 84 is coupled to the clutch lining 86 without slippage, until the slip clutch operation, the rotation of the clutch disc 88 on the thread 94 of the shaft 16 is only a few degrees, so that the bias of the leg spring 96 results in the resulting torque certainly. The ease of movement of the thread 94 is decisive for the constancy of the resulting moment.

Environmental influences such as temperature or humidity, changes in the coefficient of friction over the service life and friction differences over 360 degrees of rotation of the slip clutch 82 are compensated for via the linear spring characteristic of the leg spring 96 . The higher the torsion angle of the leg spring until the desired torque is reached, the smaller the control deviation from the desired torque.

The pitch of the thread 96 and the stiffness of the clutch plate 88 and clutch lining carrier 84 are suitable for the angle of rotation when regulating the above-mentioned influences.

The wear of the clutch lining 86 is linear in the change in torque. This is why a low-wear covering is used. In the exemplary embodiment described, the torque is reduced by 5% with a thread pitch of 2 mm and a pretension of the leg spring of two turns by 5% when the clutch lining 86 wears out by 0.2 mm.

If a constant tensile force of the material to be wound or unwound is required over the winding circumference, the torque of the slip clutch 82 can be easily adjusted by scanning the wic keldameter and derived adjustment of the bias of the leg spring 96 by the lock nut 108 by a the winding circumference following actuator is replaced.

The danger of "sticking" to a slip clutch Heating through continuous operation or after a long standstill is counteracted by actively separating the friction partners works. That is why this coupling structure is special for use in safety and overload protection Suitable applications.

Claims (9)

1. Slip clutch ( 82 ), comprising a on one side with a clutch lining ( 86 ) occupied clutch carrier ( 84 ) and against the clutch lining ( 86 ) with a normal force (Fn) pressable clutch disc ( 88 ), which are coaxial with each other are aimed, the normal force (Fn) depending on a change (ΔM) of a transmitted torque (M) is changed inversely proportional to this. 2. Slip clutch according to claim 1, wherein the normal force (Fn) with increasing torque (M) by Ver increasing the distance (S) between the clutch lining ( 86 ) and the clutch disc ( 88 ) is reduced until there is a balance between the transmitted torque (M) and a counter torque. 3. Slip clutch according to claim 2, wherein the counter moment is generated by a spring ( 96 ) which counteracts an increase in the distance (S). 4. Slipping clutch according to one of the preceding claims, in which

• - The clutch lining carrier ( 84 ) is freely rotatable on a shaft ( 16 ),
• - The end of the shaft ( 16 ) projecting beyond the clutch lining carrier ( 84 ) on the clutch lining side is provided with a thread ( 94 ),
• - The clutch disc ( 88 ) is provided with an internal thread with which it is screwed onto the thread ( 94 ) so far that it lies against the clutch ( 86 ),
• a leg spring ( 96 ) is arranged coaxially to the shaft ( 16 ), one leg ( 98 ) of which engages the clutch disc ( 88 ) and the other leg ( 102 ) is held at a fixed point ( 104 ),
• - The leg spring ( 96 ) with a clutch disc ( 88 ) against the clutch lining ( 86 ) rotate the bias is applied.

5. Slipping clutch according to claim 4, wherein the fixed point ( 104 ) on a spring receiving nut ( 104 ) is formed, the purpose of generating the bias in the leg spring ( 96 ) by a predetermined number of rotations in the direction of the clutch lining carrier ( 84 ) is screwed onto the thread ( 94 ) and then fixed in the adjusted position by a lock nut ( 108 ). 6. Slipping clutch according to claim 4, wherein the fixed point is formed on a lever which scans the circumference of a storage coil ( 24 ) on a storage spool ( 14 ). 7. winding memory for storing single sheets such. B. banknotes between the turns of a storage winding ( 24 ), comprising a housing ( 10 ) with a transfer conveyor ( 48 ) for the single sheets and a storage spool ( 14 ), a storage spool ( 12 ) and a reversible spool drive ( 59 , 60 , 62 , 64 , 66 ) to wind at least one imaging plate ( 20 ) from the pre-reel ( 12 ) onto the storage reel ( 14 ) and vice versa, both coils ( 12 ; 14 ) in the housing ( 10 ) each around a housing-fixed Shaft ( 16 ; 18 ) are rotatably mounted, with a slip clutch ( 82 ) according to one of the preceding claims, wherein the supply spool ( 12 ) is fixedly connected to the clutch carrier ( 84 ) and the shaft ( 16 ) via a freewheel ( 67 ) is coupled to the reversible spool drive ( 59 , 60 , 62 , 64 , 66 ) in such a way that when it rotates in the winding direction (D) the supply spool ( 12 ) is rotated and in the opposite direction of rotation of the reversible spool drive ( 5 9 , 60 , 62 , 64 , 66 ) is held. 8. Winding memory according to claim 7, wherein the rever sizable coil drive comprises a single motor ( 59 ), in particular a stepper motor, which drives the shaft ( 16 ) of the supply spool ( 12 ) and the storage spool ( 14 ) via a toothed belt ( 62 ) . 9. Winding memory according to claim 7 or 8, in which the reversible coil drive ( 59 , 60 , 62 , 64 , 66 ) is kept at a constant value via a tachometer ( 61 ) scanning the speed of the imaging plate ( 20 ).