DE1095212B - Electromagnetic clock drive - Google Patents

Description

Electromagnetic clock drive So that for precision clocks the necessary high accuracy can be maintained, the transducer, d. H. that at such clocks mostly provided pendulum, practically no fluctuations in its Have amplitude. To keep the oscillator amplitude as even as possible, It has long been known to provide stop contacts or the like actuated by the pendulum, which briefly switch on electromagnets when the pendulum amplitude drops, which in turn, an acceleration impulse is given to the pendulum via a soft iron part provided on the pendulum grant, which subsequently brings an increase in the pendulum amplitude with it (Hippsches pendulum). With these designs, the pendulum amplitude fluctuates - seen as a whole - around a predetermined mean value. To decrease the time impulses from the oscillator are usually also closed mechanically by the pendulum Contacts used. As a result of the mechanical points of contact are in the pendulum external influences are effective, so that the pendulum is no longer a freely swinging pendulum can be addressed and there are deviations in the individual pendulum oscillation times result from each other, which in their totality result in a certain average gear fluctuation run the clock.

In order to reduce the external influences that act on the pendulum as much as possible On the lye side, an attempt has already been made, both the time pulses and the drive pulses for the clock pendulum to be controlled via so-called photo contacts. When arranging a Photo contact becomes an optical control on the freely swinging pendulum, such as a Aperture, a mirror or the like. Provided which steering at a certain pendulum position directs a directed light beam to a photocell or also continuously the photocell interrupts the directed light beam, so that then in the photocell current Fluctuations occur that control the time display or the drive device can be used for the clock pendulum. As a drive device for the Pendulums are again electromagnets that act on a soft iron core provided on the pendulum intended. In a known drive control working according to this principle the pendulum receives a drive impulse with each pendulum passage through the middle position. Theoretically, this solution appears to be particularly favorable, as the pendulum moves with every oscillation is exposed to similar influences. In practice, however, it turns out that is not possible, the work impulse given to the pendulum with every oscillation to dose precisely so that it absorbs the energy losses caused by friction, air resistance, etc. of the pendulum. As a result, however, larger amplitude fluctuations result of the pendulum and thus also considerable average rate fluctuations of the pendulum Controlled clockwork or the like. Receives, for example, the pendulum with each pass If a drive impulse is too strong even by very small values, then his Amplitude from oscillation to oscillation by an amount corresponding to the energy excess Increase value until it is finally remedied or the pendulum somewhere strikes. If, on the other hand, the drive impulses are too weak, it comes to a steady decrease in the amplitude of the pendulum, which in turn leads to a Fluctuation of the clock brings with it. So the mentioned drive control to some extent works accurately, it is necessary to use stabilized voltages for the drive the electromagnet to work, since voltage fluctuations are inherently considerable Would cause amplitude changes. Need drive controls of the type mentioned therefore a considerable technical effort and are moreover prone to failure.

It is therefore also the suggestion known, although the pointer mechanism through to switch a relay connected downstream of the photocell for each pendulum oscillation, but only after a large number of increments by the movement itself to operate the pendulum drive relay. The assumption on which this arrangement is based, that the pendulum amplitude is always the same after a constant time interval permissible minimum has fallen, but is erroneous, since the influences of the changeable Friction conditions, temperature, etc. are not taken into account. All these disadvantages are eliminated by the invention. This refers to one electromagnetic clock drive, the drive magnet of which is driven by the oscillator photoelectric element that can be influenced with optical guidance of a light beam, preferably with a downstream relay, can be controlled so that only after lowering the oscillator amplitude to a minimum value that is considered to be permissible, a drive pulse he follows. But while with a known electromagnetic clock drive this Kind, who again uses the pendulum oscillation itself as a measure of the drive control, a complicated system of two nested pendulums is provided to to influence the light cell control as soon as the two pendulums are synchronized is disturbed, the vibration of a simple vibrator is according to the invention itself used as a measure of control so that the photoelectric member so is arranged to the oscillator that it is at the smallest permitted oscillation amplitude by the optical steering means on the transducer when reversing the transducer oscillation is influenced longer, z. B. by stringing together two flashes of light, as, for. B. by two separate short flashes of light, with larger amplitudes, and that between the photoelectric member and the drive magnet or between the photoelectric member Link downstream relay and the drive magnet delay means so switched on are that only when the photoelectric element is influenced for a long time is a drive pulse he follows. The drive impulses given to the oscillator, preferably a pendulum are kept small so that they do not cause a sudden speed increase. and thus the amplitude of the pendulum can change. Practical by the invention Drive order achieves that the oscillator amplitude is within very small limits is kept constant. Only relatively simple control organs are necessary for this. Since the oscillator amplitude is kept practically constant, the rate fluctuations also remain of the clock within minimal limits.

In the practical version, that of the photocell is preferred downstream relays - to ensure a high level of readiness to respond - polarized and closes its contact or contacts in the rhythm of the photocell pulses received when the transducer passes through the light beam. The contacts is another delayed relay that switches the drive magnet on and off downstream, which is controlled by them. With a normal, sufficiently large pendulum swing the photocell receives two short light impulses with each pendulum swing through which the polarized relay is made to respond for the duration of the pulses however, it is not sufficient to also delay the delayed downstream of your polarized relay To bring the relay to respond, so that in this case the drive magnet is switched off remain. However, as soon as the oscillator's reversal point after the oscillator amplitude has dropped coincides with the setting of the photo contact, the photocell receives because the Schwinger is known to remain in the reversal point for a longer period of time, a longer one Light pulse, which is then transmitted via the photocell and the polarized relay also brings the delayed relay to speak, so that now the drive magnet is switched on and the transducer receives an acceleration pulse. Through this the oscillator amplitude increases again, so that after one or more subsequent oscillations of the oscillator an amplitude value that is so great that the turning point is reached again of the transducer is outside the setting of the photo contact, so that then the Drive is no longer switched on.

When using electromagnets to give the acceleration impulses Attention must be paid to the pendulum that the electromagnets only operate at that time are effective, in which the magnetic force acts in the direction of the pendulum oscillation, so mostly in the time in which the pendulum swings towards the magnet. According to a This becomes an expedient further development of the drive control according to the invention achieves that the relay switching on the drive magnet (s) also has one Has changeover contact, which is preferably adjustable in the rest position Capacitor with a power source, but in the working position this capacitor connects to the relay winding, so that the relay after its response for a by the time constant of the relay winding, the capacitor and, if applicable an additionally switched-on resistor existing RC element for a certain period of time remains in the working position, this time by appropriate choice of the individual members of the RC element kept less than the duration of a quarter oscillation of the pendulum is. The adjustability of the capacitor makes it possible to adapt the circuit to different Adjust conditions.

The subject matter of the invention is illustrated, for example, in the drawing. 1 shows a basic circuit diagram of a drive control device according to the invention, 2 and 3 schematically two different possible arrangements of photocell, light source and optical steering on the pendulum.

In Figs. 2 and 3, the pendulum is only indicated by a line 1 and his Middle position indicated by a dash-dotted line 2. The pendulum suspension is denoted by 3. In the pendulum t there is a soft iron anchor (not shown) housed, arranged on the below the pendulum and via the control device Switchable electromagnets 4 act. On the pendulum 1 sits a carrier 5, which at the The embodiment according to FIG. 2 as a slit diaphragm, in the case of that according to FIG. 3, on the other hand, as a carrier is designed for a mirror 6. A Lainpe 7 is required for drive control with upstream aperture 8 as well as a photocell 9, which also has an aperture 10 is upstream, provided. The aperture 11 and the mirror 6 are so arranged so that they correspond to the smallest desired deflection of the pendulum Pendulum position a light beam 12 from the light source 7 to the photocell 9 permit. It is clear that it is not only a question of what is visible, but also of infrared or ultraviolet as well as polarized light can act.

As can be seen from Fig. 1, is for the entire control device a common power source 13 is provided to which the lamp 7 is permanently connected is. As soon as a light beam 12 falls on the photocell 9 from the lamp 7, over this, a not shown, possibly downstream amplifier, a downstream measuring instrument 14, a control resistor 15 and a polarized relay P a current flow, so that the relay P is its normally open contact p closes in the rhythm of the light impulses. The contact switches in the closed position p via a series resistor 16 a relay h into the circuit. This relay is connected by a parallel Capacitor C "in its readiness to respond delayed and therefore only responds when the light impulses and thus also the The current pulses given to the relay via contact p have a predetermined duration. By choosing the capacitance of the capacitor C ,, this delay is chosen so that it is the case with the short pulses that occur when the pendulum swing is sufficiently large not, but with longer pulse duration (which occurs when the reversal point of the pendulum is in the area in which a light beam from the light source 7 to Photocell 9) to a response of the relay Ir 'comes, which then his Normally open contact z- closes and a changeover contact v "flips over. Contact v switches in the working position the electromagnet 4 in the circuit, so that the pendulum receives an acceleration pulse. The contact v, 1 connects in its in the drawing shown rest position a capacitor C large capacitance with the power source, so that this capacitor is charged. When relay h responds, the Contact v "and now connects the capacitor C to the winding of the relay l 'through which the capacitor discharges, so this relay for the duration the unloading is held in the working position. The capacitor C is preferable designed as an adjustable capacitor, so that the discharge time constant the respective conditions can be adapted.

In a modification of the arrangement described, a closed-circuit current could also be used be provided, in which the relay P instead of the normally open contact is an im Circuit of an additional capacitor that is equivalent to capacitor C. od. The like delayed auxiliary relay has normally closed contact and the auxiliary relay Via a break contact lying in the circuit of the relay 1 'this and thus the or the 'magnets 4 controls. The auxiliary relay is in the \ normal state in the working position and holds the circuit of the relay via its normally closed contact V open. The short interruptions that occur when the pendulum swing is sufficiently large of the circuit of the auxiliary relay through the normally closed contact of the relay P can be according to the delay does not affect. Only when the interruption is smaller Pendulum amplitude is sufficiently long, the auxiliary relay drops out and then closes the circuit of the relay via its normally closed contact h. The rest of the function is the same that of the previous circuit.

So that when the lamp 7 burns out, the pendulum stops is reliably prevented, a lamp turret can be provided, which in the event of an interruption of the lamp current automatically od via an electromagnet. The like. By one step - advances to the next ready-to-use lamp. In this version a joint operated with the lamp turret is preferably on the outside of the control unit Indicator provided that indicates the failure of a lamp that has occurred this can then be replaced in good time. For the decrease of the time impulses can also use photocell arrangements, which are preferably equipped with phototransistors are to be provided.

Claims (5)

PATENT CLAIMS: 1. Electromagnetic clock pendulum drive, its drive magnet by one that can be influenced by the pendulum with optical steering of a light beam photoelectric element, preferably with a downstream relay, can be controlled so that only after the pendulum amplitude has dropped to a minimum value that is regarded as permissible a drive pulse occurs, characterized by the use of pendulum oscillation itself as a measure of control, but modified so that the photoelectric Link (9) is arranged in relation to the pendulum in such a way that it is permitted for the smallest Oscillation amplitude due to the optical steering means on the pendulum when the pendulum oscillation is reversed is influenced longer, z. B. by stringing together two flashes of light, as, for. B. by two separate short flashes of light, with larger amplitudes, and that between the photoelectric member (9) and the drive magnet or between the photoelectric Link downstream relay (P) and the drive magnet delay means so switched on are that only in the longer influencing of the photoelectric member (9) a Drive pulse takes place. 2. Drive control according to claim 1, characterized by a polarized relay which can be switched in this way by the photoelectric contact (9) (P) that it has its contact (p) in the rhythm of the photoelectric contact when the pendulum passes through the beam of light activated, and by another controllable from the relay contact (p), the drive magnet (4) delayed switching on and off relay (h). 3. Drive control according to claim 1 and 2, characterized in that the contact or contacts of the downstream photocell Relays are designed as normally closed contacts so that they delay the circuit of a Control auxiliary relays, which in turn have a control relay for the Drive magnet actuated. 4. Drive control according to one of claims 1 to 3, characterized in that the relay (V) switching the drive magnet (4) is additionally a changeover contact (v ") arranged in such a way that it has a preferably adjustable capacitor (C) with a power source (13), in the working position however, this capacitor connects to the relay winding in such a way that the relay (h) after its response for one of the time constant of the relay winding, the capacitor and, if necessary, an additionally switched-on resistor RC element remains in the working position for a certain period of time, this time through corresponding choice of the individual members of the RC member less than the duration of a Quarter oscillation of the pendulum is held. 5. Drive control according to one of the Claims 1 to 4, characterized in that the light source for generating the Control light beam a lamp sitting on a turret carrying several lamps is provided, the circuit of which a revolver when the lamp current is interrupted to the next lamp switching device, z. B. an electromagnet, controls. Documents considered: French Patent No. 567 334; U.S. Patent Nos. 1971086, 2820338.