DE825978C - Electromagnetically operated pendulum - Google Patents

Description

Electromagnetically operated pendulum Among the pendulum clocks are those with electromagnetic .drive of the pendulum the purely mechanically operated ones superior in accuracy because of the irregularities in the gear train The main source of error for the gait of mechanically operated pendulums and on the other hand the electric drive can be kept very constant. Works very special This superiority is evident when the pendulum is not for mechanical actuation a pointer mechanism and not used to actuate mechanical contacts will. Precision clocks built according to such principles are, however, by a considerable effort for the generation and amplification of the necessary control pulses marked. For a good utility watch, it seems best if that Pendulum actuates mechanical contacts through which both the Pendelatitriel> and (read Anreigewerk is controlled. One difficulty here is the fact that a symmetrical arrangement of magnet system and contacts braking and driving forces of the same size results. This is taken into account through a wide variety of constructions worn, such as switching off or reversing the polarity of the back oscillation pulses by a special Relay or indirect actuation of the switch via a gear train or by displacement the switching times by means of an auxiliary pendulum or by means of a friction clutch switching elements coupled to the pendulum.

According to the invention, the following arrangement is used for this purpose, which is superior to the known devices both in terms of simplicity and in terms of the absence of uncontrollable friction losses which can adversely affect the pendulum movement. The pendulum i is equipped with an armature 2 which faces the poles 3 of a fixed electromagnet 4. Either these poles or the armature are duplicated and placed in such a way that in the rest position of the pendulum the armature is in the middle O 'O between the poles of the electromagnet or the poles in the middle between the two armatures (see Fig . i and 2). If the magnet is excited, the pendulum is pulled to one side or the other, so that the armature and the magnetic poles face each other. If the power is turned on at pendulous oscillating, as long as the armature between the poles or the poles between the anchors 'are, as found on the way to the middle of A'A O' O a brake, on the way from the middle 0'0 to shutdown B 'B instead of a driving effect (see. fig. 3). As a result of the coil inductance, the current increases only gradually after switching on, while it suddenly drops after switching off. The distance between the magnetic poles or armature, the speed of the pendulum and the self-induction of the magnet coil can be coordinated in such a way that the current in the coil increases at a time in which the pendulum has approached the rest position or has even exceeded it, so that the braking pulse is only weak , but the drive impulse is developed almost completely. Since the time which the pendulum consumes to traverse the distance A'A to B'B decreases with increasing pendulum amplitude, it can be set up so that the drive pulse also decreases, so that the pendulum regulates itself to a certain amplitude. Also allows the described arrangement to make the pendulum self-starting, ie so that the pendulum swings without mechanical intervention after switching on the current. The magnetic pole arrangement described is therefore suitable in connection with switching contacts that interrupt the coil current as soon as the armature leaves the area between the poles or the magnetic poles the area between the armatures A ' AB' B to drive the pendulum.

This type of circuit can be extremely simple and perform only a little disruptive way for the pendulum movement.

In Fig. 4 the head of a pendulum 5 is shown, which by means of a Leaf spring 7 is suspended in carrier 6. The pendulum rod extended upwards is when the pendulum is in its rest position O 'O, with play between the very light springs 8 and 9, which are attached to the support 6 in an isolated manner and by their mutual contact the passage of current through the drive coil 4 of the Enable pendulum. When the pendulum swings, the pendulum rod becomes one of the springs z. B. 8, touch. Both springs are due to the bias between them follow the pendulum movement until the other spring 9 touches the stop io. In this Position which coincides with position B'B in Figs. I to 3, the current is interrupted. If the pendulum reverses, the current is switched on again in the same position and according to the position A'A by touching the spring 8 and the stop io interrupted. The pendulum swings freely between positions A'A and B'B, beyond it, however, in such a way that one or the other of the two springs sets the pendulum influenced in the sense of an increase in the straightening force. When you lift the spring occurs moreover, there is always a loss of impact, but this can be achieved through a suitable design the feathers can be made extremely small. All of these interactions between Pendulums and springs are extremely precisely reproducible processes that are do not need to change even in long periods of time.

Of course, the coil 4 can have one or more synchronous motors or Stepping mechanisms are connected in parallel, each driving a display mechanism, which can also be done with the interposition of a relay.

Fig. 5 shows a switching mechanism in which the pendulum ii is supported by the intermediary of the intermediate piece 13 on two cutting edges 16 and 17 secured to the carrier 12 in an isolated manner. If the pendulum swings, it takes the intermediate piece 13 with it by pressing one of the two adjusting screws 14, 15, and both then swing together around one of the cutting edges 16, 17 until the intermediate piece 13 approaches the rest position 0'O by reaching the second cutting edge 17 or 16 comes to rest and turns on the power. The pendulum continues to oscillate and, by impact, takes the spacer 13 along with the opposing set screw 15 or i4 while the current is switched off. The Stromein or. Switch-off positions are adjusted to the positions A 'A and B' B by means of the adjusting screws 14, 15.

Here, too, the processes of movement are of such a nature that an exact Repetition can be achieved over long periods of time.

The arrangement according to Fig. 6, in which the intermediate piece has been replaced by a leaf spring 23 with as little inertia as possible, on which the Pendulum 21 is at rest. The leaf spring 23 connects again within the area A'A-B'B two cutting edges 24, 25 secured in isolation on the support 22, while the pendulum outside this area around one of these cutting edges oscillates, the current as a result Lifting the spring 23 from the other cutting edge is interrupted. When going through of the pendulum through the area A'A-B'B occurs in this case a gradual increase the load on one cutting edge and a corresponding decrease in the load the other edge. As a result, shock losses are largely eliminated in this construction avoided. An exact repetition of the processes within long periods of time allows reach each other here too.

Claims (4)

PATENT CLAIMS: i. Pendulum driven by an anchor and a mechanical one is driven by the pendulum-switched electromagnet, characterized in that that either the poles (3) of the electrical Inagnets (, 4) or the armature (2) are duplicated and the self-induction of the magnet coil (4) is dimensioned accordingly is that the braking impulse acting on the oscillating pendulum is opposite to the drive impulse through <read delayed growth of the current as a result of this self-induction is decreased when the power is turned on in the area (A'A-B'B) in the armature (2) between the magnetic poles (3) or the magnetic poles between the anchors. 2. Pendulum according to claim r, characterized in that the switching of the drive magnet by two contact springs (8, 9) takes place in the area (A ' AB' B) in which the armature of the pendulum is between the poles of the magnet or the poles of the magnet are located between the armatures of the pendulum, make contact by direct or indirect mutual contact and are alternately lifted by the swinging pendulum. 3. Pendulum according to claim r, characterized in that the pendulum (i I) oscillates alternately using an intermediate piece (i3) on two cutting edges (i6, 17) that are electrically isolated from one another, wherein! the intermediate piece bridges both cutting edges as long as the pendulum is in the middle area (A'A-B'B). . 4. Pendulum according to claim t, characterized in that the pendulum is made using a spring (23) two electrically isolated cutting edges (24, 25) oscillate alternately, the spring bridging both cutting edges as long as the pendulum is in the middle area (A'A-B'B).