DE712298C - Time switch mechanism, in particular with an electromagnetic drive, in which switching processes are triggered immediately by an oscillation of a flywheel mass - Google Patents

Description

Timer, especially with electromagnetic drive, at the switching process is triggered directly by an oscillation of a flywheel The invention relates to a timer for series and individual tripping of switching operations, in particular with an electromagnetic drive, during the switching operations directly through one oscillation each one through a short drive pulse electrically or mechanically driven, stationary mounted and under - the action of a Restoring force standing centrifugal mass are triggered.

With such timers for series or individual tripping exact tripping times are required, which must be controllable within wide limits. The previously known arrangements fail after a certain time, because you have the drive and the release part connected to the process only depending on the actuator size and can calibrate the process translation to the individual time values. The drive is designed electrically or mechanically and consists of an oscillating Anchor or a flywheel. As a rule, one was content with the speed of the process of such devices by a restoring force within a once defined limit to keep. If major procedural errors occurred from time to time, then found one Recalibration by changing the restoring force with the help of a correction device instead of.

The subject matter of the invention makes the field of application more such Time switches have been significantly expanded, since it is possible to produce trigger pulses that are precisely timed to generate, which are continuously adjustable within wide limits. This is achieved by that the restoring force of the flywheel mass for the timely adjustable sequence of the vibrations regardless of the short drive pulse, already deviating with zero or only slightly begins to increase linearly from zero near the center of oscillation of the centrifugal mass and the linear increase within wide limits at a transmission between the flywheel and restoring force is adjustable.

Exemplary embodiments of the subject matter of the invention are shown in the drawing partly shown schematically.

In all figures, r denotes the flywheel mass, which at a is rotatably mounted. The flywheel carries a pinion 3 with a toothed segment q. is engaged. The segment q. is rotatably mounted at 5 and is supported against an adjustable stop 6 from. The flywheel i receives a drive pulse by any arrangement.

In the embodiment according to FIG. I, an impact magnet 7 issues the flywheel the required drive pulse. If the flywheel is driven in the direction of arrow 8, so the firmly connected R: tzel 3 takes the tooth segment q. in the direction of the arrow 9 with, and when the centrifugal mass returns to its starting position, this segment runs again against the adjustable stop 6. At this segment d. are the adjustment means intended for the various times of the flywheel i. These exist For example, according to Fig. i from a lever approach to on the segment 4 and one opposite mounted lever 12. This approach to is via a role ri with the lever 12 through a restoring force 13 positively connected. The lever 12 is at i.1. rotatable stored, and outside its pivot point at 15, the restoring force 13 is in the form a spring attached to this. The roller i r is mounted in a threaded nut 16, which is adjustable by a spindle 17 via a rotary knob 18. For the side Evasive movement of the roller i i a longitudinal slot r9 is provided in the threaded nut 16, in which the role r i of the lateral evasive movement of the two levers to and 1a can follow. In the housing wall 2o a scale 21 is provided, which is guided by a cable 22 is connected to the threaded nut 16 and depending on the position of the threaded nut indicates the selected gear ratio of the segment with levers to and 12. If the flywheel i is in the direction of arrow 8, for example, by the impact magnet 7 driven, the segment q. taken in the direction of arrow 9 by the pinion 3, and that until through the selected translation according to the position the roller 1 r the restoring force 13 via the levers to and 12 the drive movement reverses. At the segment q. can in any form this executed movement of the Segments for triggering the individual switching processes are removed, as these Movement takes place precisely in time. For this purpose, special contacts can be made through the Connections or drains that are used for triggering the switching processes Find.

In Fig. 2 and 3 an arrangement according to Fig. I is shown, wherein the setting means for the reset device have been omitted. In this figure a magnet 23 is provided as a drive for the flywheel i. its yoke 24 the flywheel grasps and strives to provide one on the flywheel segment-shaped armature 25 between the two poles 26 and 27 to be tightened. D: e flywheel i consists of a non-magnetic material.

With this arrangement, care must be taken that the excitation of the magnetic field only takes place as long as it is drivingly acting on the armature 25, ie that the magnet 23 is switched off at the moment when the armature 25 is completely between the two POIs 26 and 27 of the yoke 24 is drawn in and this no longer acts as a driving force on the armature 25. To switch off the magnet 23, the movement of the segment d., Which is driven by the pinion 3 in the direction of the arrow, is expediently used. For this purpose, a contact 28 is provided on this segment, to which a contact 29 is assigned. This contact sits on a resiliently pretensioned bracket 30 which is fastened at 31 in the housing. A stop 32, which is expediently adjustable, takes care of this. that the contact 29 with its resilient bracket can only follow the direction of movement of the segment as far as the armature 2; is drivingly attracted by the two poles 26 and -27. If the armature 25 is about to leave the poles 26 and 27, the spring 3o rests against the stop 32, and the current is interrupted at the contacts 28 and 29, since the moving flywheel i the segment. continues to drive. This continues in the direction of arrow 33 and returns to the initial position drawn after a certain time. The segment-1 then runs against the adjustable stop 3: 1. This adjustable stop 34 is resiliently arranged in a sleeve 35. A rotary knob 36 is used to adjust this stop. The switch 37 closes the circuit of the element 38, whereupon a corresponding oscillation of the segment d, depending on the set translation of the resetting device. he follows. At any point in the circuit, the individual devices that are to be controlled by switching operations can be earthed, e.g. B. at 39, can be connected.

If series release is desired, namely a certain number of Switching operations, for example ten, must then after one-time activation of the Switch 37, a switching process takes place ten times in the once set time interval. For this purpose, an adjustable circuit (not shown) is added to the circuit Step-by-step or distribution plant switched on, through which the trigger pulses also can go through. Through this distributor, after ten trigger pulses, the set on this were, the circuit was broken. One can at such a distributor there are special number discs or counters that Provide a control over the tripping processes that have taken place at any time. At the switches to be actuated by the release device can have feedback devices be provided, which indicate that the switching operation has been carried out. For the impulse one is not bound to the drawn magnetic arrangements, but rather you can also provide mechanical energy storage for the pulse distribution. At which Where the impulses are given to the flywheel is also irrelevant. Man is not bound to give the impulses to the flywheel itself, but rather you can also the toothed segment 4 connected to the flywheel, the individual drive pulses To give. The translation of the restoring force of the segment 4 is, if one is the mutual I do not want to use stored levers io and 12, likewise by other means reach. For example, cam lever guides can also be used for this.

In Fig. 4 one possibility is shown, the flywheel i directly to be provided on the armature of an electric motor 40. The electric motor 40 is through special contact means de-energized at the moment in which the reset device is set the drive movement reverses. For the shutdown of the engine is a through friction Drag contact 42 held on shaft 41 is selected, which is against contact 43 is present when the motor 4o drives the flywheel i in the direction of the arrow. At the turning point the drag contact 42 is immediately torn from the contact 43, so that the armature immediately becomes de-energized. In this figure is another adjustment device for the Levers io and i2 shown. A rotary knob 44 is provided here to which a scale 45 assigned. This rotary knob carries a lever 46 with a longitudinal slot 47. The roller i i is slidably mounted in this longitudinal slot. depending on the setting of the rotary knob, the role changes its position on the levers io and 12 and thus the transmission ratio: A switch 48 is actuated by segment 4, the affects the circuit 39 for the individual switching operations. Segment 4 is running against the adjustable stop 34 already described.

Should the flywheel i, in contrast to the arrangements described so far carry out a full oscillation, if a tooth segment 4 is retained will not let this run against a stop 34, but the segment swings out fully over the previous approach 35 and when passing through the center of oscillation (formerly the stop 35) is one in a suitable manner the individual to be switched Reduce processes through special contacts. At the same time you will be at this point (earlier stop 35) the next drive pulse of the flywheel directly or via grant segment 4.

In Fig. 5 and 6 are two other possible embodiments for the adjustable restoring force shown. Here is the stationary flywheel i connected to the pinion 3 with the toothed segment 4 rotatable at 5. The tooth segment 4 is provided with a rolling curve So into which the free end of a leaf spring 51 intervenes. The free end of this leaf spring 51 has a small roller 52 for Avoidance of frictional losses. The shape of the rolling curve can be according to kinematic Develop principles. The free length of the leaf spring 51 is adjustable, namely in the embodiment shown by a threaded nut 55, which has a slot 56, in which the leaf spring slides easily. The other end the leaf spring is attached at 53 to the frame 2o. The nut 55 is by means of a. Spindle 54 adjusted and lengthened or shortened by the rotary knob i8 the leaf spring according to its position.

In the embodiment shown in FIG. 6, the sequence curve Thus, the segment 4 dispenses and firmly carries the leaf spring 51, which is in the threaded nut 55 is mounted between two rollers or balls 57, so d.aß according to the position the threaded nut 55, the free length of the spring 51 is also adjustable. at Such an arrangement of the adjustable restoring force is widely obtained Limits an adjustable control range, with the favorable characteristic of a leaf spring shows no deviations that are unfavorable even after a longer period of operation Affect measurement errors.

Claims (13)

PATENT CLAIMS i. Timer,. especially with electromagnetic Drive in which switching operations are carried out directly by one oscillation each a short drive pulse electrically or mechanically driven, stationary and the flywheel, which is under the action of a restoring force, is triggered, characterized in that for the precisely adjustable sequence of the oscillations The restoring force of the flywheel is included regardless of the short drive pulse Zero or only slightly different from zero in the vicinity the center of vibration the centrifugal mass begins to increase linearly and the steepness of the linear increase within wide limits operationally on a translation between the flywheel and restoring force, expedient on the basis of a scale, is adjustable. 2. Time switch according to claim i, characterized in that a rotatable, under the action of a restoring force standing positioning segment, e.g. B. toothed segment, with the flywheel in drive connection and between the segment and the reset device the adjustable transfer or reduction is provided. 3. Time switch according to claim i and 2, characterized characterized in that a lever approach for the step-up or step-down on the toothed segment is provided, which has an adjustable roller with an oppositely mounted Lever cooperates on which the restoring force acts (Fig. I). 4 .. timer according to claims i to 3, characterized in that the roller on the threaded nut a spindle in a slot provided for the lateral evasive movement is. 5. Time switch according to claim i to 3, characterized in that the adjustable Role guided in the slot of a lever and over this lever with an adjustment knob is connected to which a scale is assigned (Fig. 4). 6. Time switch according to claim i and 2, characterized in that a vibrating = lowing spring, z. B. a leaf spring, as a restoring force by a threaded nut adjustable on a spindle in its effective length is adjustable, the free end of which, for. B. via a rolling curve, is connected to the segment (Fig. 5). 7. Time switch according to claim 1, 2 and 6, characterized in that the oscillating spring is firmly connected to the segment is and its free end as smoothly as possible, z. B. between roles in which by a spindle adjustable threaded nut is mounted (Fig. 6). B. Timer according to claim 1, 4, 6 and 7, characterized in that the adjustable threaded nut A scale (21) is assigned via a cable guide (22) (FIG. i). 9. Time switch according to claims i to ä, characterized in that on the non-magnetic Material existing flywheel is made of magnetizable material Segment is provided on the circumference of the flywheel so that. this from a stationary stored magnetic field receives its drive pulse. ok Time switch according to claim t to 9, characterized in that drag contacts are used for switching find, in such a way that at the reversal point the current path for the electromagnetic Drive is interrupted and remains interrupted until it coasts, whereupon it is switched on again he follows. i i. Time switch according to claims i to io, characterized in that, for the excitation of the magnetic field (23), a resilient contact (29, 30 in Fig. 2) touched by the toothed segment closes the circuit and this stationary contact rests against an adjustable stop (32) after he has followed the movement of the toothed segment for so long that he closes the circuit for the excitation of the magnetic field (23) for the required period of time. 12. Time switch according to Claims i to i i, characterized in that the switching times, if the flywheel performs a full oscillation, mechanically when passing through the center of the oscillation or be removed electrically from the flywheel. 13. Time switch according to Claim i to 12, characterized in that by means of the flywheel or the segment of controlled contacts exactly when passing through the center of the oscillation the triggering impulses are given to special control lines and earthed on this Place the next drive pulse is given to the flywheel or the segment. 14 .. time switch according to claim i to 4, characterized in that when working together of the timer with a step-by-step or distributor mechanism known per se mechanical or electrical locking means are provided through which the initiation or The timer is switched off from the step-by-step or distribution unit.