DE1009537B - DC alarm clock or bell mechanism - Google Patents

Description

Direct current alarm clock or chime The invention relates to a direct current alarm clock or a DC bell with a movable one connected to the clapper The stored armature is attracted by a DC magnet system and after it has been switched off the direct current excitation of the magnet system by a special restoring force is withdrawn to the rest position.

In the previously known alarm clocks or chimes of this type takes place the return of the armature by means of a mechanical spring. This pen exercises in. the rest position of the anchor, d. H. when the magnet system is not excited, only a very small one or no force at all on the anchor while it is in the tightening position of the anchor, d. H. when the magnet system is excited, the armature with a relatively high force pulls or pushes away from the poles of the magnet system. The force of the spring changed usually linearly between these two limit positions of their work area.

Such a drive is simpler for single-shell direct current alarm clocks Design suitable; it can be adjusted by setting the break contact operated by the armature set the magnet system to resonance, with an additional special suspension of the clapper is used.

With two-shell alarm clocks as well as with long-term alarm clocks or impact alarm clocks However, such a known system does not work satisfactorily because the suspension the entire vibrating system does not emit individual, clear bell tones allowed.

The invention is based on the consideration that for double-shell alarm clock, Einschlugwecker and Slowschläger a system is particularly suitable in which the Restoring force does not have a linear, but an approximately quadratic curve and acts in such a way that the restoring force is its in the rest position of the armature Maximum value, but reached its minimum value in the tightened position of the armature.

It is well known that the attraction force of the magnet system as a function of the Pull a quadratic curve, since the magnetic force between the poles of the system and the armature changes with the square of the induction. Through this is in the tightening position of the anchor, i.e. H. with a very small air gap between the armature and the poles of the magnet, a very large holding force is available. if the restoring force can now also be changed according to a similar law leaves, the anchor and thus the oscillating system is also in the rest position held in great force.

The invention consists in having this particular characteristic the restoring force by using a permanent magnet that constantly acts on the armature reaches the armature after switching off the excitation of the DC magnet system moves to its rest position.

In principle, it would be possible to use the magnetic attraction force of the permanent magnet at any part of this system that is firmly connected to the vibrating system to be attacked; However, thorough experiments led to the finding that it It is advantageous to place the permanent magnet directly on the armature of the oscillating system to let it act itself, at a point at which also that of the direct current magnet system resulting work flow flows through the armature.

In itself it is no longer new, the movable armature of a magnetic one Drive system through the interaction of a permanent magnetic flux - that of one Dauermagnetsysdem arises - with a working magnetic flux - that of an arbitrary excited magnetic system is generated - to influence. So one has z. B. at Telegraph relay polarized or the movable relay armature by permanent magnets a basic magnetic field generated by such permanent magnets, in the air gap of which the Armature is movably mounted. This anchor then leads to additional action of the controlled work flow from certain movers. In these telegraph relays however, the fields of the polarized permanent magnets act in the same way as the controlled ones Working magnetic fluxes together that is always the sum or the difference of the two Flows occur in the same working air gap and as a sum or difference on the Anchors act, whereby they flow together through a certain piece of the anchor.

In the drive system of the direct current alarm clock or direct current bell according to the invention neither a polarization nor an immediate one Cooperation of the two magnetic fluxes intended in a common working air gap; on the contrary, the two rivers should act separately on the anchor, where -the permanent magnetic flux only has the task of bringing the armature into its rest position to pull. The two iliagnet rivers have only a limited part inside Hall> of the magnetically conductive armature the same way, with only a slight mutual Influencing the two rivers can take place.

When using a permanent magnet with a relatively small coercive force it proves to be expedient for the permanent magnet to act on the armature in this way to let the flux coming from the permanent magnet be the same in the anchor Has the same direction as that generated by the magnet system in the armature excited by direct current Workflow.

On the other hand, it is occasional with permanent magnets with high coercive force advantageous if one arfordnet the permanent magnet so that it creates a flux in the Armature is generated which is opposite to the working flow of the DC magnet system is.

In this way, it is also possible to have a single unit Däuermagnet system for generating the reset force on DC alarm clocks of different sizes or chimes by using the Lets rivers pass through the anchor in the same direction and with a light propulsion system the opposite direction of the rivers preferred.

The simplest arrangement of the permanent magnet system that supplies the restoring force arises when the DC magnet system and the permanent magnet system each symmetrical. face each other and the anchor between the two Magnet systems is oscillating.

If the DC alarm clock according to the invention as a simple alarm clock is to be used, the armature must have a break contact in a manner known per se periodically control the power supply line to the DC magnet system lies. For this control of the break contact a special one turns out Control lever as advantageous, which is firmly connected to your anchor.

In the case of double-shell alarm clocks, the permanent magnet system can be used according to the invention or use its pole pieces directly as a stop for the rest position of the armature. To limit the forces of attraction between the anchor and the The permanent magnet system is the anchor with an adhesive sheet made of non-magnetic material provided, preferably as a sleeve drawn or pressed onto the armature is trained.

The invention is particularly suitable for impact alarm clocks or slow beaters, since the proper definition of the anchor in its two end positions is a very exact one The stop of the clapper is guaranteed when the oscillating one consisting of the anchor and the clapper System executed relatively rigid and the movement of the clapper through the Attacks of the armature on the two magnet systems is limited in such a way that the Clapper braked sharply by the stop shortly before reaching the bell shell is sprung and only a very small way to strike the bell shell. The great forces exerted on the armature shortly before it reaches its end position cause the clapper to strike vigorously, which, however, subsequently is immediately withdrawn from the bell shell at the strike. This creates a cushioning of the sound by the clapper resting against the bowl or a multiple "trembling" Impact prevented.

This advantage can also be seen in slow racers, where the DC excited magnet system through a corresponding electrical delay circuit is excited in larger time intervals. Tests have shown that the new Drive according to the invention a greater sound power with lower power consumption results than the previously known drives.

In the drawing, the invention is shown by way of example; it Fig. 1 shows a drive for a double shell alarm clock, Fig. 2 a drive for a single-shell alarm clock, FIG. 3 shows a partial section along the section line A-B of Fi.g. 1.

The alarm clock consists of the base plate 1 (Fig. 3), the DC drive magnet system 2 (Fig. 1), the oscillating armature system 3, the reset magnet system 4 and the interrupter 5. The clapper 6 is rigidly connected to the oscillating armature system 3, which strikes alternately on the two bell shells 7 (see. Fig. 1).

The drive magnet system 2 is by means of the sheet metal bracket 8 (Fig. 3) screwed tightly to the base plate 1 by the screws 9. In the longer leg of the angle plate 8, the cores 10 of the two magnet coils 11 and 11 'are riveted. The armature 12 lies opposite the two poles of the drive magnet system 2; he is designed as a large flat anchor. A glue stick 13. (Fi, g. 1), the prevents tight application of the armature 12 to the poles of the magnet system, forms the Stop for the working position of the anchor.

The anchor 12 is fastened to the base plate with a pin 14 Mount 15 stored and on the one hand with the rod of the clapper 6 and on the other hand rigidly connected to a short additional lever arm 16.

On the side of the armature opposite the drive magnet system is the restoring magnet system 4. The permanent magnet 17 (Fig. 3) is in mounting plates 18 and 18 'held and by means of a screw 19 on a support 20 on the base plate 1 set. The two pole plates 21 and 22 (Fig. 1) of the Deue @ rmagnetlen are on their ends bent at right angles. In its rest position, the anchor lies with the formed as a sleeve made of non-magnetic material adhesive sheet 23 (Fig. 3) on the pole pieces of the reset magnet system 4.

The one consisting of the two contact springs 24 and 25 (FIGS. 1 and 2) The interrupter is connected to the contact spring 24 by the lever arm 16 Insulating piece 26 controlled. The two springs sit in the insulating socket 27, which in turn is attached to an angle lever 28. The angle lever 28 can around the screw 29, which acts as a fulcrum and is drawn into the base plate 1 pivot in order to precisely set the point in time of the interruption of the contacts 24, 25. For this setting, an adjusting screw with knurled nut 30 is used, the one between the vertical leg of the sheet metal angle 8 and the free arm of the angle lever 28 lying angle spring 31 compresses.

The system shown in FIG. 2 is basically constructed in the same way. With him, however, is only a solenoid il used whose both poles 10 'are attached to the base plate 1. The setting of the breaker contacts 24, 25 takes place in the same way with this drive; the attachment the adjustment screw is made here on a special one attached to the base plate 1 Angle plate 32.

In the drive according to FIG. 1, the magnetic fluxes which penetrate the armature 12 within the adhesive sheet 23 are in the same direction (cf. arrows 33 and 34, from which the arrow 33 comes from the drive system and the arrow 34 comes from the reset magnet 17 River).

In the embodiment according to Figure 2, the same reset system is used; However, here the rivers 33 and 34 are directed in opposite directions, so that when Switching on the DC excitation weakened the flux 34 and thus the holding force of the permanent magnet 17 is reduced.

Should the drive according to the invention be used as an impact wheel or as a If slow-moving bearings are used, the breaker 5 is not required As an alarm clock, the breaker is activated by a simple on / off switch replaced; with a Lan.g; amschläger is a known timing element that z. B. off Capacitor, resistor and rectifier can be used to drive the magnet system To feed in larger time intervals with sawtooth-like pulses.

Claims (7)

PATEN TANSFRI; CIIE: 1. DC alarm clock or bell, in which a movably mounted armature connected to the clapper is attracted by a DC excited magnet system and, after switching off the DC excitation of the magnet system, is pulled back into the rest position by a special restoring force, characterized in that the restoring force is generated by a permanent magnet acting on the armature. 2. DC alarm clock according to claim 1, characterized in that the Permanent magnet acts directly on the armature. 3. DC alarm clock according to claim 1 or 2, characterized in that the magnetic flux pulling the armature into its rest position of the permanent magnet acts on the armature at a point where that of the The work flow resulting from the DC magnet system flows through the armature. 4. DC alarm clock according to claim 3, characterized in that the magnetic flux of the permanent magnet and the working flow resulting from the magnet system excited by direct current is separated enter the armature via special air gaps and only within the armature the have the same direction. 5. DC alarm clock according to claim 3, characterized in that that the separately entering the anchor through special air gaps flows of the Permanent magnets and the magnet system excited by direct current within the armature run opposite to each other. 6. DC alarm clock according to claim 1 or one of the following claims, characterized in that the DC excited The magnet system and the permanent magnet system are each symmetrically opposite one another and the armature is oscillating between the two magnet systems. 7. DC alarm clock according to claim 6, characterized in that the armature has a special control lever for the actuation of an interrupter contact that switches the DC excitation of the magnet system is firmly connected. B. DC alarm clock according to claim 1 or one of the following Claims, characterized in that the rest position of the armature by firm contact of the armature covered with an adhesive sheet on the pole pieces of the permanent magnet system given is. 9. DC alarm clock according to claim 8, characterized in that the Adhesive sheet as a sleeve made of non-magnetic material that is pulled or pressed onto the armature Material is formed. Publications considered: German patent specification No. 22,204; French Patent No. 455,484; Schiweck: »Teletype technology«, C. F. Winter'sche Verlagsbuchhandlung Leipzig, 2nd edition, 1944, p. 172.