DE6917376U - REAR CONTROL, ESPECIALLY FOR OPERATION - Google Patents

Description

8 Munich Ά · L owekystr. 1Ö j.

Tel. 778956 J.

Our reference: k-fr-5 Date: April 28, 1969

ALFX. FRIEDHANN KOMMANDIT-GESELLS CHAPT in Vienna

Rear derailleur

The invention relates to a rear derailleur, in particular for actuating control flaps of a KlinaanlafC, with from an electromagnetic drive device is the switching pulse output shaft switchable by the same angle of rotation.

Various designs of switching mechanisms are known in which the back and forth movement of the armature an electromagnet excited by successive switching pulses or the coil core of a stop pulse beauf = When solenoids hit, they are transferred to the output shaft, e.g. via a lever system and a pawl that engages in a gear will. Such step switches are for example for driving slave clocks controlled by pulses from a central time switch, for step-by-step port switching of

6? 1? 376m. 72

Shift drums, used for rotary dials in telephone systems and the like. Purposes.

A major disadvantage of these known stepper mechanisms consists in the fact that they only allow a switching movement of the working shaft in one rotation. It follows a relatively limited area of application of these known derailleurs. In addition, some of them give quite a bit complicated switching mechanisms of these devices often cause to malfunctions, in particular due to inadequate engagement of the pawl * in the retaining gear. Especially with stepper mechanisms, where the pawl is in the switch-off end position If their own weight should fall into the corresponding tooth gap of the ratchet wheel, incorrect shifting often occurs by skipping a tooth or advancing the indexing gear3 by more than one tooth. Besides, they are enough relatively low switching forces of these known stepping mechanisms not for all purposes.

The invention is based on the object of creating a switching mechanism which can be used for both directions of rotation and which is characterized by particular operational reliability and at the same time provides relatively large switching forces. This switching mechanism should be particularly suitable for driving thermostatically controlled air flaps for air conditioning systems. Fiction $ emäß this goal is achieved in that the elektromagneUj-specific arrival ü

M drive device from a known per se, from a reverse j tension spring in the Aussehalt-Enälegο retractable. Rotary solenoids.

is formed with a limited angle of rotation, and that the working shaft of the switching mechanism with the output shaft of the rotary magnet over an electromagnetic clutch can be coupled non-positively and / or positively.

In addition to the main advantage of working in both directions of rotation, the inventive design of the switching mechanism also has the advantage that the most favorable torque range is achieved by restricting the angle of rotation accordingly of the rotary solenoid can be fully utilized and, moreover, due to the small switching steps, a finely graduated, one continuous rotary motion almost equivalent rotation of the working shaft is obtained. This is the preferred one Use of the switching mechanism according to the invention for driving thermostatically controlled air flaps of particular importance, as a result, a sensitive, the respective existing Heizbzw. Cooling air requirement closely adapted regulation of the free passage cross-sections for the heating or cooling air supply becomes possible. With the previously known, rotating magnet controlled air flaps on the other hand, there were only two positions of the air flap corresponding to the switch-on and switch-off end positions of the rotary magnet possible, whereby there was also the disadvantage that the magnetic coil of the rotary magnet is constantly under tension in one position was standing.

For the actuation of the switching mechanism according to the invention in one direction of rotation, a switching pulse is simultaneously on to give the rotary magnet and the magnet winding of the clutch.

The rotary magnet then returns due to the action of the return spring back to the switch-off end position, whereas the uncoupled Working shaft remains in the corresponding holding position. To move the switching mechanism backwards, a pulse is first given to the rotary magnet, closer to the switch-on end position achieved. A switching pulse is then given to the electromagnetic clutch and the rotary magnet is switched off. This then returns to the switch-off end position, taking the working shaft with it, due to the force of the return spring. These Switching operations can be performed according to the respective purpose of the switching mechanism can be carried out manually or automatically.

Advantageously, however, it is provided according to the invention that there is a rotary magnet and the electromagnetic clutch switching pulses can optionally be applied simultaneously or alternately via an upstream control unit. With help of the control unit, which is equipped, for example, with a control relay or as an electronic control device contactless semiconductor elements can be implemented, the operation of the switchgear can be fully automated.

According to a preferred embodiment of the invention, there is the electromagnetic clutch from one having the magnetic coil, attached to the output shaft of the rotary magnet Armature and one on the working shaft fixed against rotation, axially displaceable against the force of a clutch pressure spring

Anchor plate. The coupling part carrying the solenoid requires There is no separate storage and the entire facility can be housed in a very compact design in a common housing be accommodated.

In special applications that require precise compliance with the angle of rotation corresponding to each switching step require on the output shaft, it is recommended, according to a further feature of the invention on the anchor plate in to arrange drivers, e.g. radial ribs, at an angular spacing that corresponds to the switching steps of the rotary solenoid, wherein the armature has at least one shoulder which engages positively in the retainer when the clutch is engaged. This version has the advantage, among other things, that the

The clutch solenoid is not on the force-locking t
i Transmission of the torque required magnetic force

must be measured but only on the one to engage

the clutch against the force of the clutch pressure spring

j required magnetic force is to be interpreted.

<The invention is described below in an embodiment

. example explained in more detail with reference to the drawing. It show 'Pig. 1 an axial section of a preferred application

• Example of the invention in a schematic representation, Fig * a section along the line II-II in Γig. 1 and 3 a further section along the line III-III in Fig. 1. Fig.4 1 to 6 show representations corresponding to FIGS. 1 to 3

• the same embodiment in a different switching position.

In a hollow cylindrical housing 1 with bottom 2 is housed a rotary magnet 3, which consists of a magnet winding 4 supporting iron core 5 with four pole pieces 6 consists. The pole pieces 6 are arranged on the inner jacket of the housing 1 and opposite magnetic poles 7 short-circuited to the core 5 via the housing 1.

The output shaft 8 of the rotary magnet, which carries the four-pole armature 9 of the rotary magnet 3, is mounted in a central bore in the core 5. A return spring 10 acts on one pole of the armature 9, the other end of which is attached to one of the magnetic poles 7 of the housing 1. A stop 11 on one of the magnetic poles 7 limits the angle of rotation of the armature 9, which is shown in FIG. 2 in the switch-off end position. On the output shaft 8 of the rotary magnet, provided with a magnetic winding 12 anchor 13 is attached to an electromagnetic clutch. The armature 13 is opposite an armature plate 14 at a distance , which is arranged on a working shaft 15, which is coaxial to the shaft 8 and mounted in the base 2 of the housing 1, so as to be non-rotatable but displaceable in the axial direction. Between the armature 13 and the armature plate 14 there is a clutch compression spring 16 which keeps these parts of the electromagnetic clutch at a distance from one another.

The housing 1 is with the Βοίβι 2 on the only partially shown housing 17 of the control device of a Luftheizbzw. Cooling system attached. On the cylindrical jacket 18 of the housing 17, an air outlet opening 19 is provided which

- Ί -

controlled by a control flap 20, which rests resiliently on the inner surface of the jacket 18 and is curved towards a cylinder surface is.

The control flap 20 engages with a radial pin 21 in a corresponding blind bore 22 of a radial arm 23 that is firmly connected to the working shaft 15. One between the end face of the arm 23 and the control flap 20 arranged compression spring 24 provides the required contact pressure the control flap 20 on the housing shell 18. The interior of the housing 17 is in a manner not shown to a Luftheizbzw. Cooling system connected.

In the rest position of the switching mechanism (Fig. 1 to 3) the two magnet windings 4 and 12 are switched off. The poles of the rotary magnet armature 9 are offset by approximately 45 degrees with respect to the pole pairs 6, 7 of the rotary magnet 3. The electromagnet! Ser Coupling 13, 14 is open and the control flap 20 keeps the air outlet opening 19 of the housing 17 closed.

Is now, for example by the switching pulse of a thermostat, which is in the air outlet opening 19 with hot air heated room is located, the winding 4 of the rotary magnet 3 and at the same time the winding 12 of the magnetic ^: The clutch is switched on, as shown in FIG Poles of the rotating magnet armature 9 between the pole pairs 6, 7 of the rotating magnet 3 until the armature 9 hits the stop 11. The rotary magnet 3 emits its greatest torque in this adjustment range. The rotation of the armature 9 is via the output

shaft 8, the armature 13 and the anchor plate sucked in by this 14 transferred to the output shaft 15. The arm 23 fixedly connected to the output shaft 15 is thereby around a the rotation angle of the rotary magnet 3 corresponding switching step rotated, so that the control flap 20 is part of the Cross section of the air outlet opening 19 releases.

When the power supply to the windings 4 and 12 is interrupted, the parts 13 and 14 of the electromagnetic Clutch separated by the clutch pressure spring 16 and the armature 9 of the Djpehmagneten returns together with the armature 13 of the Coupling back into the switch-off end position (Pig. 2) through the action of the return spring 10. The control flap 20 remains in place on the other hand in the one from Pig. 6 visible switch position.

As long as the air cross-section exposed by the control flap 20 is not sufficient to heat the room, the room thermostat emits another switching impulse through which the control flap 20 is rotated by a further switching step and the free cross section of the air outlet opening 19 accordingly is enlarged.

In order to operate the switching mechanism in the opposite direction of rotation, an alternating output of switching pulses is required on the rotary magnet and the electromagnetic clutch. The rotary magnet is switched on first and when the rotary magnet armature is still in the switch-on end position, the clutch is switched on. Then the current supply to the rotary magnet interrupted. The return spring 10 leads

the "moving magnet armature back into the rest position, whereby the Working shaft 15 via the closed clutch and thus the control flap 20 iLit moved and thereby by one switching step is shifted back.

The corresponding switching operations are advantageously carried out by a control device shown in the drawing triggered, which is provided, for example, with control relays or electronic switching elements.

The invention is not limited to the illustrated and described application example. So in particular, too instead of the frictional! working magnetic coupling Coupling design can be provided with the driver on the two coupling halves for positive transmission of the torque of the rotary magnet.

Claims;

Claims (3)

k-fr-5 J 12.11.71 File number: G 69 17 37 ^ .8 Applicant: ALEX. FRIEDMAN !! KOI-PLAN) ITGESELLSGHAPT. Vienna protection claims: 1. Switching mechanism, in particular for the actuation of control flaps of an air conditioning system, with an electromagnetic drive device via an electromagnetic clutch step-by-step by the same angle of rotation work shaft, the electromagnetic drive device having a return spring for the return to the switch-off end position, and the electromagnetic clutch from one Its magnet body having a magnet coil and an armature plate which is axially displaceable and rotationally fixed on the working shaft and is axially loaded by a clutch compression spring, characterized in that the electromagnetic drive device is designed as a rotary magnet (3) coaxial with the clutch (12,13,14) and the The magnet body (13) of the coupling is rigidly connected to the coupling-side free end of the drive shaft (8) of the rotary magnet (3) carrying the rotary magnet armature (9). 2. Switching mechanism according to claim 1, characterized in that on the anchor plate in one of the switching steps of the rotary magnet corresponding angular spacing, e.g. radial ribs, are arranged and the Armature has at least one approach which engages positively in the driver when the clutch is engaged. 3.Π.7Ι Kr / W / Wa