DE1117371B - Drive and tensioning device for a tape serving as a display carrier - Google Patents

Description

Drive and tensioning device for a serving as a display carrier Belt The invention relates to a drive and tensioning device for a Tape serving as a display carrier, which is supported by two storage rollers that take up the tape ends can be moved past a reading window via guide rollers. Such drive and clamping devices are mainly known for such display carriers that are used for Display of train directions and departure times at stations, from stops Trams that use stock exchange prices in banks, but also on billboards will. These bands, which serve as an advertisement carrier, are marked with numbers, letters, Words or symbols can be used either by hand or by motor, often also remotely controllable, in the respectively desired position to a reading window to be brought. It is generally desirable that the setting of the various dispatch the messages scheduled on the tape as quickly, securely and accurately as possible goes and the tape while avoiding excessive stress on the Observation or reading point is pulled past taut.

There are already tape drive devices known in which only one of the storage rollers for the tape is driven. As far as tension pulleys are provided, they are attached to the tape guide. The Driven storage roll, which acts as a take-up reel.

There are also drive and tensioning devices for display tapes became known, in which both storage rollers are driven. The storage roles are coupled to one another via a differential gear. This clutch, which represents a non-rigid drive connection between the shafts of the storage rollers, is the speed difference that these shafts due to the fluctuating angular diameter of roles have, balance. Rigid drive connections between two storage shafts, which are connected to their storage rollers via spiral springs and the springs Tension and relax when rolling the display tape are also already known. They make it possible for the driving shaft to move at a constant speed Adjust the speeds of the storage rolls to the respective roll diameters. The length of the path of the display tape between the two storage rollers remains essentially constant. A particular disadvantage of the last-mentioned solution is that only a significant tensioning movement must be given to the spring before the tape masses set in motion. Likewise, when the drive is at a standstill, there are strong pendulum movements of the band to be set to calculate the target position. The invention has set the task of a drive and tensioning device for a display carrier To create serving tape, with the rigid drive connection of the storage rollers resulting winding path differences are to be compensated. This is according to the invention achieved in that both storage rollers by rigid drive connection of their Shafts are driven at the same angular speed and in the tape guide one or more under the action of a spring or weight, parallel with itself self-moving tensioning rollers to adjust the length of the belt the changing up and down tape lengths during winding and unwinding are provided are.

This solution creates a tape drive with the advantage that the storage rolls and thus suddenly stopping the display tape as such from the drive side and are set in motion much faster when the drive is switched on can: This means that the setting of the respective display values is faster and more precise possible. Pendulum movements when starting up and braking the belt avoided, because despite the necessary mechanical coupling of the two storage rollers the winding differences can be moved parallel to itself by means of the flexible balanced tensioning rollers.

The formation of the spring-pretensioned tape rollers and their Insertion into the tape run can be carried out in various ways and is essentially dependent on how much space for the Tape storage is available in each case. A particularly space-saving embodiment of the Invention is shown diagrammatically in Fig. 1 of the drawing and in Fig. 2 in side view, each shown schematically. 3 and 4 of the drawing show schematically two further exemplary embodiments in which the compensating rollers are prestressed by springs suffer relatively large displacement distances and therefore a lot of space for tape storage is required.

In the embodiment according to FIGS. 1 and 2, a total of six rollers are provided, namely the two storage rollers A and B, the two guide rollers C and D provided above and below the reading window indicated by the hatched area in FIG. 1, and a pair of smaller guide rollers E. and F, the shafts e and f of which are mounted on both sides in a carrier T which is partially indicated by dashed lines in FIG. The latter is kept floating freely between the stationary rollers A, B, C, D by the belt H. The band H consists of a smooth and flexible material that is as free of stretch as possible, preferably made of a polyvinyl-based plastic that is on the market under the trade name "Luvitherm"; it is perforated on both edges. The teeth z of two gears provided on the shaft c of the guide roller C mesh with the perforation. The shafts a to f of all roles are parallel to each other. However, only the shafts a, b, c are driven by the belt drive motor M. In order to maintain the clarity of FIG. 1, the transmission itself is not shown; however, the arrows p indicate the force profile of the rigid transmission connection existing between the three shafts a, b, c. In the illustrated embodiment, the three shafts a, b, c should be coupled to one another in a transmission ratio of 1: 1. The rotation of the motor M is introduced into the transmission via a slip clutch K, also shown schematically. It is thought in the embodiment of a remote control of the tape drive in such a way that a remote-controlled relay electromagnetically actuates the bolt r, which is normally in the slot of a clutch disc located on the shaft c of the guide roller C and actuates a switch when it moves upwards, whereby the motor M is switched on. As soon as the said electromagnet is de-energized, the bolt r rests on the edge of the disk s, and it falls into the groove of the disk s exactly at the point in time when the desired image is correctly in front of the reading window. Immediately thereafter, the motor M is de-energized; it can then run out via the slip clutch K. The shafts a, b, c and thus also the rollers C and D stand still when the bolt R engages.

Each storage roll has a drum a1 or b, which is loosely pushed onto the shaft a or b the associated shaft a or b connected. The two helical springs S have opposite winding directions according to FIG. 2 and should have an equally strong pretension in the position shown, where both drums a1 and b1 of the storage rollers are wound equally strong. If there are n display fields on the tape H, the diameter d becomes the with Display fields wound storage drums selected so that it is equal to the diameter of the drum of the guide roller C. The pair of rollers E, F, which enable force compensation, is initially in the center position shown. The band H is stretched taut by the pretensioned springs S. The clamping force P may have approximately the size indicated by arrows on the rollers E and F. All tensile forces P of the band H are in equilibrium in the starting position shown. It can be seen that the forces P directed to the two guide rollers C and D cancel each other out so that the belt H is completely relieved at the perforation. This is extremely important for the life of the belt.

If the tape drive is now switched on in such a way that it drives the rollers A, B, C in the sense of the arrows indicated on the circumference, it runs over the guide roller C until the point in time when the storage roller A is completely wound and then the diameter d " assumes a band of length if n is the number of display fields and the number of revolutions required for a display change is 1.

Since the peripheral speed of the storage rolls A and B is the same only at the point in time when the effective diameter is equal to d, the winding drum a1 must lag behind the shaft a with increasing winding diameter, while the unwinding drum b1 leads the associated shaft b. The two springs S are further tensioned in the direction of the arrows drawn approximately up to the new position of the outer spring end indicated by dotted lines, which means that the forces P acting on the pair of rollers E, F are increased. It is now important that the increase in spring preload is not the same for both rollers. The spring S of the unwinding drum b1 is more tensioned than the spring of the winding drum a1, since with the drum A the tape is wound from a smaller diameter to a larger diameter and thus more revolutions are required for the unwinding on the drum B than for the winding on the drum A. The circumferential force on the unwinding storage roll B is also greater than that on the winding storage roll A because it increases with decreasing diameter (lever arm <d), while the circumferential force required for compensation on the winding storage drum A decreases with increasing winding diameter (lever arm> d). The difference between the two forces pulls the pair of rollers E, F downwards, until the bias of the spring of the unwinding roller B is reduced so much and that of the. winding roll was increased by so much that the tensile forces of the outgoing tapes are the same again and thus the forces acting on the pair of rollers E, F are balanced again. This compensation takes place continuously during the entire rewinding process, so that the belts leading from the rollers E and F to the deflection rollers C and D are practically evenly tensioned and the perforation on the teeth of the drum C is relieved. When the desired hinge position is reached, the bolt r falls into the locking disk s, as a result of which the roller C comes to an instant standstill. Because of the rigid gear connection between shaft c and shafts a and b , the latter are also stopped immediately. The motor M can still coast via the slip clutch. The drums a, and b1 of the storage reel, together with the tape reels located on them, still have a considerable torsional momentum that can swing out on the helical springs S. This torsional force counteracts the helical spring in the unwinding drum B and is intercepted by it, while the spring of the winding drum A maintains the belt tension and dampens the return oscillation of the rollers E, F to their central position after the torsional balance has been destroyed. During this run-out process, the same forces prevail in all belt parts converging at the force transmitter E, F, so that the belt is relieved of the perforation during this run-out process.

If the direction of rotation of the motor is changed, the tape is rewound from drum A to drum B. The springs S initially relax to their original tension until they tension again after the position shown has the same winding diameter d and the tape sequence described is repeated. The described arrangement is extremely space-saving, even with the greatest lengths of tape. It is therefore attached wherever it is important to accommodate the display device, which can optionally also consist of several strips to be arranged parallel to one another or one above the other, in the smallest possible space.

In contrast, the embodiments shown schematically in FIGS. 3 and 4 can only be used where sufficient space is available. In these arrangements, in addition to the two storage rollers A and B, only one of the guide rollers, namely roller C, is driven by the motor 1YI, again via a slip clutch K, the shafts of the three rollers mentioned being rigid again, namely through gears with a Gear ratio of 1: 1, are coupled together. In addition to the roller C, a total of four further guide rollers D ', D ", E' and F 'are provided here. The rollers D' and D" together with the roller C guide the tape towards the reading point, with one or more reading windows can be arranged between the rollers D 'and D ″ and the roller C. The rollers E' and F 'are mounted parallel to themselves in a horizontal direction in a manner not shown and by means of springs S, and S2, which are unilaterally localized or are held fixed to the device, biased by a certain amount.

In the initial state, both storage rolls A and B are wound to the same diameter d. In the arrangement according to FIG. 3, the drum diameter d of the storage rollers is selected to be equal to the drum diameter d of the roller C that engages with a toothing in a perforation of the belt. In the starting position, the compensating rollers E 'and F' tension storage loops of approximately the same length, the tensioning forces exerted by the springs S and S2 being equal to one another. If the belt is set in motion as indicated by the arrows on the drums, then the storage rolls A and B have a greater peripheral speed than - the guide roll C for all winding diameters that are larger than d Wind up the tape as it passes the reading window and thus shorten the upper storage loop while tensioning the spring S. The unwinding storage roll B will unwind more tape than passes the reading window, so that the lower storage loop is lengthened when the helical spring S2 relaxes. When reaching the winding diameter d. the roles E1 and F may have reached the position indicated by dotted lines in FIG. In Fig.3a, the spring characteristic (spring force as a function of the spring travel) is plotted. It can be seen that in the end position mentioned, a greater force (P 1) acts on the upper loop than on the lower loop (force P2). Accordingly, in this embodiment, in the end positions of the belt, the toothing provided on the guide roller C will load the belt perforation with the force P, - P2.

This stress can very easily lead to the destruction of the belt and is avoided in the arrangement according to FIG. 4 in that the drum diameter dl of the storage rollers so much smaller than the drum diameter of the guide roller C can be selected so that the effective winding diameter of the storage drum only then corresponds to the drum diameter of the guide roller C when the storage drums are half wound. Then tension springs S, and S2, in contrast, tighten to the arrangement according to FIG. 3 always evenly, so that in both belt loops the same tensile forces are effective and thus the band perforation on the teeth the guide roller C is always relieved.

Claims (9)

PATENT CLAIMS: 1. Drive and tensioning device for a tape serving as a display carrier, which can be moved past a reading window or the like by two storage rollers receiving the tape ends via guide rollers, characterized in that both storage rollers (A, B) by rigid drive connection of their shafts be driven at the same angular speed and in the tape guide one or more tensioning rollers (E, F or E ', F'), which are under the action of a spring or weight and are mounted so that they can move in parallel with themselves, to adapt the path lengths of the tape to the and unwinding changing up and down running lengths of tape are provided. 2. Apparatus according to claim 1, characterized in that with the two storage rollers also at least one of the guide rollers (C, D) rigidly coupled is that - seen in the direction of travel of the tape - in front of or behind the reading window Od. The like. and by means of an engaging in a perforation of the tape Toothing a position of the belt that is precisely defined for the position of the drive with respect to the reading window or the like. 3. Apparatus according to claim 1 or 2, characterized in that the tape of the - seen in its running direction - lying in front of or behind the reading window two guide rollers (C, D) each over a roller (E, F) one in a freely hanging Carrier-mounted tension roller pair is guided to one or the other storage drum (A, B) , which are each connected to their associated shaft (a, b) by screws or spiral springs (S). 4. Apparatus according to claim 2 or 3, characterized characterized in that the storage rollers have the same drum diameter and an average Have the winding diameter equal to the drum diameter of the driven guide rollers is, or that the translation is determined so that the peripheral speeds the same on the half-wound storage drums and the driven guide rollers are. 5. Apparatus according to claim 3 and 4, characterized in that the two Storage rollers and the two guide rollers are axially parallel and at approximately the same distance are arranged to one another and in between the two tensioning rollers coupled to one another hang freely and also axially parallel to the aforementioned rollers. 6. Device according to claim 2, characterized in that in the tape guide paths between the Storage rollers on the one hand and those driven together with these storage rollers Guide rollers, on the other hand, a spring-loaded pulley parallel to itself is arranged displaceably (Fig. 3 and 4). 7. Apparatus according to claim 6, characterized characterized in that the storage rollers have the same drum diameter as the leadership role rigidly coupled with them. B. Device according to claim 6, characterized characterized in that the storage rollers have the same drum diameter and an average Have the winding diameter equal to the drum diameter of the driven guide rollers is. 9. Apparatus according to claim 2 or the following, characterized in that the shaft of the storage rollers and the rigidly coupled guide rollers are driven by a common motor via a slip clutch and the belt is stopped by a preferably remotely controllable pawl lock connected to the driven guide roller. Considered publications: German Patent Nos. 822 447, 817 533, 620 981, 542 117; German patent application G 6646 IXa / 54 h (published on December 24, 1952); Swiss patents No. 157 203, 230 518, British patent No. 368 001; French Patent No. 688,696; Dissertation by Dr.-Ing. Heinrich Voigt, "Critique of the Known Devices for Maintaining a Constant Film Train", 1940.