DE1091495B - Electrically driven clock with step-by-step switchable electromagnetic rotating armature mechanism - Google Patents

Description

Electrically driven clock with step-by-step adjustable electromagnetic Rotating armature drive mechanism The invention relates to an electrically driven clock with step-by-step switchable electromagnetic rotating armature drive, its incremental pulse generator by an aisle folder oscillator, inhibited in its process, by means of one of the Swivel armature drive intermittently wound storage spring driven in time is, where possibly existing other energy consumers, such as time display devices or pulse generator for slave clock lines, directly, d. H. without using this Storage spring, can be driven by the rotating armature drive; such a watch, preferably fed from a battery or other local voltage source, finds Can be used as a single clock or as a master clock for a slave clock system.

Electric clocks are already known, mainly for use as master clocks, in which the energy loss caused by the operation of the clock is replaced by, for example, impulses that repeat every minute. The energy content of the energy storage device - be it a weight or a storage spring - oscillates around a certain value, which makes the clocks with relatively great constancy are driven. Here, the storage spring drives once over a multi-stage Lay down the display device, and at the same time its expiration, in turn, is over a multi-stage transmission, controlled by a gear folder. These two tasks together require a relatively large torque, which is correspondingly large dimensioned storage spring must deliver. Because of that and because of the different Tooth play in the multi-level mat at different temperatures, as well as arise because of the different oil viscosity for different temperatures large, uncontrollable friction losses and thus cause considerable path differences. But also for the individual movements with each other arise because of the the necessary spring strengths unavoidable large manufacturing tolerances path differences, which cannot be fully compensated even with great effort.

In other known devices, fluctuations in the driving force, which are unavoidable as soon as you have a large reserve of power from a tension spring wants to have, on the one hand, to obtain a longer running time without a minute lift and on the other hand to operate a slave mechanism, compensated by that although the actual driving force of the main spring from the escapement directly or is intercepted indirectly, but not itself directly to drive the gear regulator serves. Rather, the main spring gives a small auxiliary spring a precisely defined one Preload, and this determines the torque to be transmitted to the regulator. The small auxiliary spring therefore only stores such a large force pulse at a time, to drive the regulator once, and the spring tension and thus that of the Auxiliary spring exerted torque fluctuate between a maximum and a Minimum. This conversion of the main drive spring inherent constant acting Driving force in individual force pulses of the auxiliary spring requires a considerable technical effort and great precision of the individual components. But still must the inhibition when notching resulting from the possible differences in tension of the Overcome the different frictional forces resulting from the main spring. Because the forces to notch but ultimately have to be applied by the unrest, but only the impulses of restlessness to maintain its course by switching between them the small auxiliary spring is kept constant, is the rate of the clock here too still strongly dependent on the spring tension.

There is also the interposition of a small spring with little storage capacity of power reserve between the aisle folder oscillator and the energy for the steady one Gear of the same delivering, trained as a continuously rotating motor and directly, d. H. without the spring, the drive mechanism driving the movement of clocks already known to have an action of the mass of the drive device through this elastic coupling to prevent or at least reduce the aisle folder oscillator. Through this namely, the alternating acceleration and deceleration of the gear folder oscillator only transferred to this flexible coupling, while the great Mass of the drive device almost not to be decelerated or accelerated needs and therefore their feedback on the aisle folder oscillator remains small; the Gear folder influences the engine speed practically only when this deviates from the target speed corresponding to the gear folder frequency. Apart from that of the not inconsiderable power consumption of a continuously running motor, the a battery would run out relatively soon, has the inevitable high speed the motor has the disadvantage of considerable gear ratios to the pointer mechanism.

The invention has set itself the task of one by an electromagnetic Rotating armature drive to create driven clock, its incremental pulse generator and a co-operating speed regulator by means of one of the rotating armature drive intermittently wound accumulator spring is actuated, with frictional inaccuracies as a result different gear expansion and different oil viscosity with different Temperatures despite the simple mechanical structure and path differences as a result different tension of the mainspring by a constant on the gear regulator Acting, always the same torque of the accumulator spring can be avoided; simultaneously is due to the use of a rotating armature drive mechanism that is only periodically driven by pulses compared to continuously running motors, the power consumption is reduced and the production both for the drive system and for the translation to the pointer mechanism be simplified.

In the case of watches of the type mentioned at the outset, this is done according to the invention achieved in that a rotary switch as a stepping pulse generator and as a storage spring a practically reserve-free spring, e.g. B. with a slightly larger than for that Pause between two pulses required power reserve, used and the spring, preferably directly between the rotating armature drive mechanism and the rotatable part of the rotary switch is arranged, the latter, preferably positively over a single-stage back gear, controllably connected to the escapement part of the gear folder is. Advantageously, those generated by the rotary switch can then be used at the same time Pulses have such an energy content that they are used simultaneously as drive pulses can be used for a slave clock line. An advantageous further development of the invention provides a leaf spring with a triangular leaf surface as a storage spring in order to thereby to achieve a much larger spring deflection at a certain force. In further Embodiment of the invention, this spring can interact with a band for tensioning, referring to one on the drive shaft of the electromagnetic rotating armature drive provided, eccentrically designed cam disc, in order to thereby achieve a constant, to generate the rotary switch driving torque.

Further details of the invention and expedient developments the same result from the following description of one shown in the drawing Embodiment. It shows Fig. 1 the structure of the clock with electromagnetic Rotating armature drive, storage spring, rotary switch and gear folder, Fig. 2 in individual parts a schematic representation of the electromagnetic rotating armature mechanism, the tension spring, the rotary switch and the gear folder.

As FIG. 1 shows, the individual components are on circuit boards 1 and 2 for the clock driven by an electromagnetic rotating armature drive. Among other things, this consists of a drive coil 3, which by means of the rotary switch 4, which is designed as a pole reversing switch and consists of the contacts 5 and the cams 6 consists, electrical impulses from the battery 7 receives.

The drive coil 3 is pushed over the core 8. The magnetic one Flux is passed through the two pole pieces 9 and drives the armature 10 of the electromagnetic Rotating armature drive. The cams 6 of the rotary switch 4 are fixed with the gear 11 connected and free on the shaft 12 of the electromagnetic rotating armature drive rotatably arranged. To get the clock going, it has to be started. In addition is the fixed on the shaft 12 of the electromagnetic rotating armature drive Turn knob 13 to the left and the storage spring, which is designed here as a band spring 14 to tension. By providing a stop, not shown here, it is achieved that the rotating armature drive shaft 12 rotated at most 180 °, the storage spring 14 can therefore only be stretched to a certain extent. Because one end of the memory spring 14 is attached to the shaft 12 and the other end via a bolt 15 on the gear 11 attacks, this will be counterclockwise under the force of the spring 14 turn. In the gear 11, the pinion 16 meshes, and this is over an escapement 17 and corresponding intermediate components with the balance 18 of a gear regulator 19 in Link. This results in a time-constant sequence of the gear 11 and thus at the same time a constant sequence of the cams 6 of the rotary switch 4 is guaranteed, so that these pulses of alternating polarity from the Battery? to the drive coil3. In the present case, the rotary switch 4, the memory spring 14 and the gear folder 19 be dimensioned so that each every minute a pulse of alternating polarity rotates the armature 10 by 180 ° and thereby the accumulator spring 14 is tensioned again. The accumulator spring 14, in turn, is dimensioned in such a way that that it stores a power reserve of about 1 minute, so that its Voltage can only change within small limits.

In Fig. 2 the circuit of the battery 7, the contacts 5, the coil 3 and the magnetic circuit from the core 8 and the pole pieces 9 to drive the Armature 10 shown schematically. Furthermore, the gear folder 19, the cogwheel 11 with the cams 6, the rotating armature drive shaft 12 including armature 10 and storage spring 14 drawn out in individual parts. With the rotating armature drive shaft 12 is still a pinion 20 firmly connected, which sets the clock hands via the gear mechanism 21.

The attachment of the accumulator spring 14 is solved somewhat differently in FIG. 2 than in FIG. 1. It is in turn attached to the bolt 15 and designed as a leaf spring. However, your blade surface now has a triangular shape in order to achieve a large spring deflection with a given spring tension. The end of the leaf spring, which is designed as a triangular tip, is not directly connected to the rotating armature drive shaft 12 , but a completely flexible band 22 tensions the spring, while this band 22 rests on an eccentric cam disk 23, which is firmly connected to the shaft 12, when it is turned to the left the shaft 12 winds on it. The storage spring 14 formed in the form of a band and the eccentrically formed cam disk 23 are dimensioned in such a way that the distance of the flexible band 22 from the axis of the shaft 12 decreases as the tension of the storage spring 14 increases. The torque formed from the center distance of the flexible band 22 and the spring tension therefore remains almost constant over the entire spring travel.

In the present case, only the weak storage tank serves as an energy store 14, which has a power reserve of just over a minute to accommodate and directly only via a single-stage intermediate gear with the escapement shaft of the gear folder 19 communicates. As a result of the measures already specified to achieve constant torque and the low power reserve absorbed by the spring and because the accumulator spring 14 only actuates one rotary switch 7, no Errors like the uneven tension of a normal clock spring arise. Because otherwise the clock drive spring not only has to hold the gear folder, but also that Drive the pointer mechanism, continues to point the spring to achieve a sufficient Power reserve of a few hours once the voltage state »zero« when it has expired and the other time the maximum tension with the spring wound up. Also are Several single-stage countershafts are provided between the accumulator spring and the escapement shaft, and even through these occur as a result of thermal expansion defects and different 01 viscosity at different temperatures shows large time differences. But even the errors occurring in the exemplary embodiment only extend over the duration a spring winding, so at most over 1 minute, so that the errors, provided they are only within the tolerance limits of the aisle folder, are fully compensated can. Even different voltages of the power source 7 cannot cause errors, as long as the tension is only sufficient to turn the rotating armature running gear fully through 180 °, because with each half turn the storage spring 14 is only tensioned as far as it will go can.

Claims (4)

PATENT CLAIM: 1. Electrically driven clock with step-by-step switchable electromagnetic rotating armature drive, its incremental pulse generator, by a Aisle folder oscillator inhibited in its process by means of one of the rotating armature drive intermittently wound storage spring is timely driven, where appropriate existing other energy consumers, such as time display devices or pulse generators for slave clock lines, immediate, d. H. without stressing this storage spring, are driven by the rotating armature drive, characterized in that as an incremental pulse generator a rotary switch and, as a storage spring, a practically power reserve spring, e.g. B. with an only slightly larger than required for the pause between two pulses Power reserve, used and the spring, preferably directly, between the rotating armature drive and the rotatable part of the rotary switch is arranged, the latter, preferably form-fitting via a single-stage intermediate gear with the escapement part of the aisle folder is controllably connected. 2. Clock according to claim 1, characterized in that the Drive pulses for the electromagnetic rotating armature drive such an energy content have that they can be used at the same time as drive pulses for a slave clock line are. 3. Clock according to claim 1 or 2, characterized in that a leaf spring Forms the storage spring (14) with a preferably triangular leaf surface. 4. Clock according to claim 3, characterized in that the leaf spring and a band (22) which winds up for tensioning the spring on an eccentrically formed cam disc (23) provided on the drive shaft (12) of the electromagnetic rotating armature drive, in the sense of achieving a constant torque driving the rotary switch (4). Publications considered: French Patent Nos. 1,136,278, 1162765.