DE6949596U - ELECTROMAGNETIC STEP-BY-STEP CONTROL UNIT, IN PARTICULAR FOR TIME SWITCHES IN MOTOR VEHICLES. - Google Patents

Description

Electromagnetic stepping mechanism, in particular for time switches in motor vehicles

The invention relates to an electromagnetic stepping mechanism in which a switching drum is advanced from switching position to switching position via the armature of an electromagnet especially for time switches in motor vehicles.

Such stepping mechanisms with a correspondingly large number of switching positions are used for so-called long-term sensors used. The stepping mechanism is controlled by a pulse generator switched from switching position to switching position. the Switching drum controls a set of contacts, which maintains its switching status for a full cycle of the switching mechanism. The contact itself can be used as a resting or working contact be designed so that a pulse or a pause of great duration is obtained as an output signal.

The construction of such a stepping mechanism requires a large number of complicated parts, since the drive elements of the shift drum coupled to the armature are unique Advance movement must be transferred to the shift drum so that it really only shifts in one direction of rotation will. One direction of movement of the armature does not lead to any further switching of the shift drum.

It is the object of the invention to provide an indexing mechanism in which a shift drum over the armature of an electromagnet of So holding position is advanced to switching position, to be set up as simply as possible. The number of parts required should be significantly reduced and still be one unambiguous switching of the switching mechanisms must be ensured.

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The electromagnetic stepping mechanism with a switching drum is advanced from switching position to switching position via the armature of an electromagnet, in particular for time switches in motor vehicles, is characterized according to the invention that designed as a plunger armature of the electromagnet carries a switch pin that is directly in a circular shift gate ^ the shift drum is guided, their bilateral boundaries an equal number of against each other bear offset locking recesses, each one The guide surface that determines the direction of rotation of the shift drum opposite the other limit. With separated The return spring holds the switch pin in place using an electromagnet the locking recess of the inner shift gate limitation and when the electromagnet is energized, the shift pin rotates the shift drum over the guide surface of the outer shift gate limitation in a locking recess of the outer Shift gate limitation on. When switching off the electromagnet the return spring guides the switch pin out of the locking recess of the outer valve gate limitation and ' while rotating the shift drum over the guide surface of the inner shift gate limit in a locking recess of the inner shift gate limitation. Since the end positions of the armature are clearly defined by the shift gate, does not need to be set with the new stepper mechanism Ankerweges to be made more, as it is with known Shift gate is the case. The armature stroke is therefore based on the difference in the distances between the locking recesses on both sides Shift gate limits limited to the pivot point of the shift drum.

A return spring takes over the resetting of the plunger, their free ends attack on both sides of the plunger on the switching pin and those on the mounting bracket of the stepping mechanism is fixed.

The number of parts required and the assembly effort thereby further reduced that the shift drum with the

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Shift gate and the bearing shaft is injection-molded in one piece from plastic. Also the bobbin for the excitation coil and the support plate with the side windings for receiving and mounting the school roller is injection-molded in one piece from plastic .

The derivation of an output signal at the stepping mechanism can take place in different ways. The shift drum can have a shift bead that only opens a contact when the shift drum is in one switch position. However, the shift drum can also wore a switch cam that only in a scarf Is lun el, ^"r of the shift drum for a close contact closed hi It.

Since the shift drum both when tightening and when the Armature is advanced, is the number of stable switching positions of the step fastener through half the number of locking recesses of the shift gate limits given.

The invention is illustrated by means of one in the drawings Execution example JKlher explained. ! s show :::

1 shows the longitudinal section along the line I - 1 of FIG. 2 by a consultation work according to the founding, ",

Fig. 2 is a plan view of the stepping mechanism and

Fig. 3 enlarges the side view of the switching cylinder with the shift gate.

On a carrier 20 with the side walls 21, the shift drum 23 is rotatably mounted with the scarf t-uulisse. The bearing roll lh is produced in one piece with the shift drum 23 and inserted into the side winds 21 of the carrier 20. This carrier 20 merges directly into a coil former 19 for the excitation winding 10 on one end face. This electromagnet with the cup-like yoke 11, which is connected to the coil receptacle via the element 18, controls a plunger 12. This plunger 12 is guided displaceably in the bore of the coil body 19 axii.1. The free end of the anchor 12, dae

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that protrudes from the bobbin 19, carries a transversely directed Sonic pen 17, on one side in the circular one See I tkulisse according to Fig. 3 of the shift drum 23 directly and also is guided in a guide groove in the side wall 21.

^; ..i <: from » Viii. 1, the two free I HiI (Mi of a return spring 13 are supported on both sides of the armature 12 on the switching pin 17. This return spring 13 can, as can be seen from Ti;:. 2, together with the carrier plate 2 'i for the I. (Mitakt springs 15 to be fixed on the door 20. The rivets Io carry out this connection. In the Ausoliul is Le 1 luii · the bead 22 of the switching drum 23 releases the contact i ^r ) As soon as the shift drum 23 is rotated further on this switch, it is closed and held by the shift drum 23 over a full passage.

Using the Vi;:. 3 is never explained in more detail stepping-up of the shift drum 23 when the armature approaches and drops. The scarf gate embedded in the scarf 23 extends over the entire length of the scarf 23 and has an inner boundary 21 and an outer boundary 26, preferably 25 and 2 (j trucon an equal number of Rastausnohnungen 2? And 29 for the switching pin 17 of the armature 12.

In the Ausscii ;. 11 s tel lun :; The very thing is that puts the back to Il spring 13 dm switch pin 17 in a latching recess 27 of the inner ochal tf.ul issenbegrenzung 25. If the electromagnet is backed up .. ¹ ! 1 te t, then the armature 12 is in the coil = Körperaufnalii'K! moved in. During this armature stroke, the switching pin 17 ″ is guided out into the latching recess 27 until it finally strikes the opposite guide surface 28 of the outer shift gate limit 26. The armature 12 and thus the switching pin 17 are adjusted further to the right, the switching pin 17 sliding counterclockwise along the guide surface 28 into the opening 29 of the outer switching gate limitation 26 while the switching drum is turned counterclockwise. ; / he armature stroke wire ¹ thereby limited and ended in this direction.

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If the electromagnet is switched off again, then the Return spring 13 the armature 12 back. The switch pin 17 from the load recess 29 of the outer shift gate limiter 26 led out until it is on the guide surface 30 the inner shift gate limit 25 abuts. The switching pin 17 is moved further to the left, whereby it is rotating the shift drum 23 counterclockwise along the guide surface 30 into the following locking recess of the inner shift gate limitation 25 slides and reaches its stable switching position again.

These two partial rotations of the shift drum 23 are each The control pulse supplied to the electromagnet is carried out. X'aeli the switching pin 17 and the safety gate adopts the assignment shown for each control pulse. The stepping mechanism according to the invention has a number of stable switching positions by half the number of locking recesses 27 on the inner shift gate limit 25 or the Itastausnehmungen 29 given on the outer shift gate limit 26 is. The throttling direction of the shift drum 23 is determined by the inclination of the guide surfaces 28 and 30. These guide surfaces 28 and 30 are the locking recesses 27 and 29 so on the other hand, that the desired direction of rotation of the shift drum 23 is reached with the further movement of the shift pin 17 will.

Claims (1)

Il 111 SWF special factory for car accessories Gustav [lau GmbH., 712 Bietigheim - 6 - A 11 707 December 15, 1969 PAT j / Vo / nö "Claims 1. Electromagnetic stepping mechanism with a switching drum via the armature of an electromagnet from open position is advanced to interlocking, especially for time switches in motor vehicles, characterized in that the armature (12) of the electromagnet, designed as a plunger (10, 11, 19) carries a switch pin (l?) That directly is guided in a circular shift gate of the shift drum (23), the two-sided boundaries (25, 26) a wear the same number of mutually offset Rastausnehraungen (27, 29), each of which shows the direction of rotation of the Sohaltwalze (? -3) defining guide surface (28, 30) of the other Limit opposite. 2. Stepping mechanism according to claim 1, characterized in that the switching pin (17) of the plunger (12) additionally in a guide groove in a side wall (21) of the body support (20) performed 1st. 3. Stepping mechanism according to claims 1 and 2, characterized in that that the armature stroke of the plunger (12) is based on the difference in the distances between the locking recesses (27, 29) of the Shifting gate limits (25, 26) on both sides to the pivot point of the shift drum (23) is limited. k. Step-by-step switching mechanism according to Claims 1 to 3, characterized in that the free ends of a return spring (13) which is fixed to the superstructure support (20) act on the switching pin (17) on both sides of the plunger (12). - 7 - A 11 707 5. Stepping mechanism according to claims i to 4, characterized characterized in that the shift drum (23) with tier shift gate (25, 26) and the bearing shaft (14) of the snap drum (23) is injection-molded in one piece from plastic. 6. Stepping mechanism according to claims 1 to 5, characterized characterized in that the coil body (19) and the carrier plate (20) with the side walls (21) are made in one piece from plastic are injected. 7. Stepping mechanism according to claim 1 to 6, characterized in that the shoulder roller (23) carries a switch bead (22) which opens an adjacent contact (15) only in one switching position of the switch drum. 8. Stepping mechanism according to claims 1 to 6, characterized characterized in that the switching drum (23) carries a switching cam which is only in one switching position of the switching drum keeps an applied contact closed. 9. Stepping mechanism according to claims 1 to 8, characterized in that that the number of switching positions of the step switch mechanism by half the number of locking recesses (27, 29) of the switching gate limits (25, 26) is given. 10. Step-by-step mechanism according to claims 1 to 9, characterized in that when the electromagnet is switched off (lO, ίί, 19) the return spring (l3) holds the switching pin (17) in the latching recess (27) of the inner shift gate limitation (25) and that at the electromagnet is excited (ic, 11, 19) of the switching pin (17) of the outer shift gate limitation (26) (29) of the outer shift gate limitation (26) enters with rotation of the ^above chaltwalze (23) over the guide surface (28) in a latching recess. - 8 - A 11 707 11. Step-by-step mechanism according to claim 10, characterized in that when the electromagnet (10, 11, 19) is again shut off, the return spring (13) leads the ächaltstift (L7) out of the latching recess (29) of the outer shift gate limit (26) and rotates the Shift drum (23) leads over the guide surface (30) of the inner shift gate limit (25) into a latching recess (27) of the inner shift gate limit.