DE805286C - Selector for telecommunication systems with a common drive for the lifting and turning movement of its switch arms - Google Patents

Description

Selector for telecommunication systems with a common drive for the lifting and turning movement its switching arms The invention relates to a lever-operated rotary selector for telecommunications systems, especially for telephone or teleprinter systems, the two in mutually perpendicular Carries out setting movements that run in planes and one in both directions of movement owns jointly assigned stepper motor.

It is known to design rotary dials so that a common stepping motor can be used for the two directions of movement. The previous voters of this type, as described, for example, in patents 678 077 and 69o 052, however, require mechanical clutches which are actuated by an electromagnet and bring about the switchover from one direction of movement to the other. Apart from the fact that the electrically controlled clutch means additional expenditure, the clutches cause noise and are subject to great wear.

With the invention, a clutchless lever-operated rotary selector is now to be included common drive fier both directions of movement are created, the in itself combines the advantages of the three common types of dialers, namely lever-operated dials, Motor selectors and crossbar selectors, are peculiar. Each of these three known Voter types used on a larger scale has characteristic features for each type Advantages, which, however, are offset by disadvantages caused by the structural design.

The lever rotary selector has the advantage over the motor selector of an advantageous one Adjustment movement of the switching arm (square movement), which it allowed the desired contact lamella by a short distance, d. H. with a maximum of 2o setting steps for ioo contacts. This movement is mostly separated by two Magnetic stepping mechanism causes the strong vibrations, room and contact noises and reduce the setting speed to a maximum of 35 steps per second limit. The usual rotary dial has only one in the speech path Frictional contact, because the power supply through the returning square movement can be done to the switching arm via a flexible cord, but the cord becomes prone to failure after prolonged use, and base frictional contacts are common the cause of unpleasant noises when conducting the conversation about the built up Connection path. By using a silver pressure contact bank, it would be possible to eliminate the disadvantage mentioned. The previous rotary dial with pressure contact bank however, require a special lifting magnet to keep the switch arms moving along the contact bank only in the working position of the selected contact with this are engaged.

The motor selector has the advantage of the drive due to the fast, Low-vibration and low-noise selector motor. The great walking pace however only partially affects the speed of the setting process, because the hundredth contact lamella through the direction of the rotary movement of the switching arm contact lamellas arranged one behind the other is only reached after 100 steps. With the long grinding path, there is a correspondingly large amount of wear and tear on the scanning elements tied together. The circumferential, non-returning movement of the switch arms forces for the power supply in the speech path in series with the actual lamellar contact to arrange a second frictional contact. Here, too, requires what is in itself possible Training the lamellar contact as a silver pressure contact requires a special effort Lifting magnets.

The crossbar selector has the advantage that contact is made through a precious metal contact takes place, which is operated like a relay contact. This advantage is, however, with a hundred-part voter with (learning effort of 2o magnet systems and correspondingly large space requirements bought without the direct working voter systems made use of the possibility of multiple occupancy can be.

In summary it can be said that for a direct worker Selector for the setting movement the coordinate movement, for the drive the selector motor and represent the best solutions for making contact with the precious metal pressure contact.

The invention now enables the means that the Advantages of the three types of voters mentioned. The voter according to the invention is characterized by a completely vibration-free run and very simple Construction from.

This is achieved according to the invention in that the longitudinal and rotatably arranged on the voter axis with the help of a adjusted by a stepping motor in the same direction in rotation offset screw drive is, whose axially displaceable element has a disengageable linear guide and is under the action of a restoring force (weight, spring). After another The feature of the invention is the switch arm support that has a pressure contact bank operating switch arms is equipped, a molded part designed so that it is with a second molded part moved by a magnet, the disengageable linear guide and provides a guide in rotating the selector.

The use of a screw drive in conjunction with the disengageable Straight guidance enables the desired lifting and turning movement (coordinate movement) of the Shift arms without the aid of a clutch by rotating one in the same direction Stepper motor of the usual embodiment for motor selectors and allows the Return of the switching arms to the starting position without Um-control organs, there the switching arms after leaving the contact bank under the influence of the restoring force further rotated by the screw drives in the same direction as during the adjustment movement so that the switching arms reach their starting position after a full revolution. The self-contained circuit of the switch arms suggests that the switch arms do not to make it live, but to work with a pressure contact bank. Training of the screw drive can be done in various ways, such as those described below Show embodiments.

The drawing shows only the parts of the Voter shown.

Fig. I shows a perspective view of the selector from which the For the sake of simplicity, only one switching arm is shown with a row of contacts; Fig. 2 to 4 are different versions of the screw drive; Fig. 5 is a perspective view of a selector in which the switching arm is only in its working position is brought into engagement with the selected contact.

As Fig. I can be seen, is attached to the in the voter frame i Axis 2 of the tubular switch arm support 3 with its pressure contact bank 4 serving Switching arm 5 arranged to be longitudinally and rotationally displaceable. From the pressure contact bank only one row of contacts is shown, ufhd on the representation of the remaining ones Switching arms with the associated contact banks is dispensed with. The adjustment of the Switching arm support 3 against the return spring 6 is carried out by the not shown Voter motor, the pinion 7 of which rotates the voter drive wheel 8 in the direction of arrow P1 offset.

The screw drive 9, io, is used to convert the rotary movement of the selector drive wheel 8 into the lifting rotary movement of the switching arm carrier 3. As will be explained in more detail with reference to FIGS. 2 to 4, the screw drive can be designed in various ways. As is known, a screw connection consists of two dividers, namely the screw bolt and the screw nut. When the screw bolt is stationary, the nut moves axially on the screw bolt when it rotates and, conversely, when the screw bolt is stationary, it moves in its axial direction when the screw bolt is rotated. If the screw bolt is prevented from moving longitudinally during its rotation and the nut can move freely, it will rotate at the same speed as the screw bolt. As soon as the nut cannot rotate due to a stop, it must move axially on the rotating screw bolt. After explaining the movement processes between screw and nut, the operation of the screw drive for the intended purpose of converting the rotary movement of the drive wheel into the lifting and turning movement of the switch arm carrier is readily understandable. In the arrangement according to FIG. I, the nut thread forms a part 9 of the drive wheel 8, which is rotatable about the axis 2 and cannot move axially. The screw bolt thread io is cut into the switch arm support 3 so that when the nut part 9 rotates, the screw bolt io, ie the switch arm support, is carried along by friction and rotates at the same angular speed as the drive wheel 8. However, as soon as the rotation of the switching arm support 3 is inhibited, it must move axially in the direction of arrow P2. In order to bring about the desired stroke adjustment of the switching arm support 3, it is firmly connected to the molded part ii, which has a comb-like toothing 12. The circular guide plate 13 attached to the selector frame can come into engagement with the cutouts of the toothing 12. The number of recesses in the molded part ii corresponds to the number of height steps, and the distance between the individual recesses is selected according to the distance between the individual rows of contacts in the contact bank 4. The part ii serves in connection with the stop 15 controlled by the magnet 14 as a straight line guide during the axial displacement of the switch arm carrier, which occurs when the guide surface 16 of the part ii rests against the stop 15 when the drive wheel 8 rotates and the switch arm carrier 3 rotates inhibits. The rotary steps given by the selector motor via the pinion 7 to the selector drive wheel 8 are therefore first converted into the corresponding number of height steps by the screw drive 9, io in connection with the part ii and the stop 15. In the following selection process, the rotary steps given to the voter drive wheel 8 must act as rotary selection steps. In the second selection gear, the magnet 14 is energized at the beginning, so that the stop 15 disengages from the guide track 16 of the molded part ii. The stop 15 is shaped at its free end 17 so that it can grip through the cutouts of the comb-like toothing 12. In this way, it is possible to work with a relatively small armature stroke of the magnet. To secure the screwing in when the last height step is reached, the cutout 18 assigned to this height step is cut deeper so that the leading end 17 can penetrate this cutout even when the magnet 14 is de-energized and the straight-line guidance becomes ineffective when the last height step is reached. The selector is turned in as soon as the end 17 of the stop 15 is no longer in contact with the guide track 16. By pivoting the molded part ii, the circular guide rail 13 attached to the selector frame comes into engagement with a section of the comb-like toothing and ensures that the switching arms are turned in the plane reached during the stroke adjustment. Depending on whether the selector is used as a group selector or as a line selector, the switching arms 5 are stopped on the contact determined in free choice or by dialing pulses.

When the selector is triggered, the drive wheel 8 is set in rotation again by the stepping motor and the rotary movement of the switch arm carrier initially takes place until the switch arms have left the contact bank. Correspondingly, the molded part ii serving as a guide comb has also disengaged from the guide rail 13. From this point on, two movements are superimposed, namely one movement is brought about by the restoring force (spring 6), which tries to move the switch arm carrier 3 against the direction of arrow P2, while the other movement is caused by the rotating drive wheel. If the nut thread 9 is considered to be stationary, the screw bolt io would not only move axially in the event of an axial movement against the direction P2, but would also rotate in the direction P1 at the same time. Since the nut thread 9 now rotates at the same angular speed as the drive wheel 8 in the direction of arrow P1, the two rotational movements that are given to the switching arm carrier by the drive wheel 8 and by the return spring 6 add up. For a better understanding, the movement path of the switch arm end is shown in a dash-dotted line. The switching arm 5 is first lifted from its starting position a into the dashed position b. Then it is screwed in to position c. When the selector is triggered, the switching arm then moves from c to the end of the contact bank in position d. Then the switching arm descends into the starting level. By superimposing the axial movement with the two rotary movements, an inclined movement path is created from position d to position e . From position e, the switching arm is rotated by the stepper motor until it has reached the starting position a, in which the guide plane 16 of part ii again rests against the extension 17 of the armature 15 and the stepper motor is stopped by a suitable contact .

As already mentioned, the screw drive for the lifting and turning movement of the voter can be carried out in various ways. Fig. 2 shows a screw drive corresponding to the arrangement according to FIG. The voter axis is with 2 and the switch arm support with 3 designated. The nut thread 9 is firmly connected to the drive wheel 8, and the screw bolt io forms a unit with the switch arm support. In the arrangement According to Fig. 3, the switch arm support 3 with the nut thread 9 and the screw bolt io firmly connected to the drive wheel 8. In the screw drive according to FIG instead of a nut thread and a screw bolt, two helical gears i9 and 2o used, of which the helical gear i9 with the drive gear 8 and the helical gear 20 are firmly connected to the switch arm support 3. It is of course conceivable that the axes of the helical gears are not perpendicular, as in the example in FIG. 4 Must be to each other, but also arranged to run parallel, for example could be.

In Fig. 5 a further embodiment of the invention is shown in which the magnet 14 used to control the straight line is used to control a pressing and lifting movement of the switching arms so that the switching arms pass through the contact rows without contact and only in their working position with the corresponding contact of the selected row of contacts come into engagement. For this purpose, the guide comb 21 is moved by the armature of the magnet 14 in a plane inclined to the voter axis, ie the direction of movement of the guide comb 21 has a component directed radially and a component directed longitudinally to the voter axis. When the armature has fallen off, the sector-like molded part 22 leans with its end face against the guideway of the comb body 21. The sector-like extension 22, which is rigidly connected to the switch arm support 3 in a plane perpendicular to the voter axis, has a nose 23 which, when the armature of the magnet has fallen, has a nose 14 cannot penetrate into the cutouts of the toothing 12 of the comb body 21. In the same way as in the arrangement according to FIG is converted into the corresponding lifting movement. The screw drive consists of a thread 9 cut into a hollow cylinder, in which engages a driving pin io firmly connected to the shift arm support 3, which is expediently designed as a roller so that the least possible friction forces must be overcome when sliding in the screw thread. The pitch of the thread is chosen to be about 45 '. When the magnet 14 responds, the selector is turned in, since after the guide comb 21 has been displaced, the nose 23 can penetrate into the cutout which corresponds to the selected height increment. The sector-like extension 22 is used to guide the switch arm support during the screwing. As soon as the switching arm 5 has selected the specific contact, the magnet 14 falls off, and the downward component of the movement of the comb body 21 opposite to the direction P2 is transmitted via the sector-like projection 22 to the switching arm support. Since the shift arm support is determined in its movement at the same time by the screw drive 9, io, the contact arm 5 is placed on the contact in the same way in a movement path which corresponds to the distance de of FIG. When the selector is triggered, the magnet 14 is temporarily energized again, so that the contact arms are lifted from the contacts. The movement processes of the voter are controlled via contact arms, which are used to check whether lines are free or occupied and are therefore constantly in engagement with the corresponding contacts while the voter is being pulled in. These test contacts can be simple friction contacts, while the contacts in the speech lines are designed as noble metal pressure contacts. After the movement processes described with reference to FIG.

To the switch arm support 3 when it is reset to the initial position to intercept, a buffer spring 24 is provided.

It should be mentioned that the control of the pressing and lifting movement of the Switching arms also carried out in "a different way as in the arrangement according to FIG could be. For example, the sector-like guide plate 22 of the switching arm support are provided in its scope with teeth, the cutouts of the width of the guide comb 21 correspond. This would have the effect that after pivoting the guide comb 21 the comb of the part 21 actuated by the magnet 14 is again in front of a tooth of the guide segment 22 places, so that in the following rotating step of the drive wheel 8 a renewed longitudinal displacement of the switching arm support 3 and thus a pressing of the selected contact of the contact bank 4 is reached. The comb 21 @ nut then however, be designed so that it allows a small longitudinal movement of the segment 22. The easiest way to achieve this is when the cutouts and teeth are in their Dimensions to be matched accordingly.

Claims (13)

PATENT CLAIMS: i. Selector for telecommunication systems with a common drive for the lifting and rotating movement of its switching arms, characterized in that the longitudinally and rotationally displaceable switching arm support (3) is adjusted with the aid of a screw drive (9, io) which is rotated in the same direction by a stepper motor, the axially displaceable of which Element has a disengageable linear guide and is under the action of a restoring force (weight, spring). 2. Voters according to claim i, characterized in that the screw drive consists of two elements, of which one is longitudinally and rotationally displaceable and with the switch arm carrier in a rigid manner Connection is, while the other only rotatable element with the drive wheel (8) of the stepper motor is connected. 3. Voters according to claim i and 2, characterized marked, that the screw drive consists of a thread and a sliding in the thread There is driver and that the element of the screw drive having the thread with the drive wheel of the stepper motor and the driver with the switch arm support or the element having the thread with the switching arm support and the driver are rigidly connected to the drive wheel. 4. Voters according to claim i to 3, characterized characterized in that the thread consists of a machined in a hollow cylinder Slot (9 Fig.5) consists in which as a role or as a pin or as a prismatic Shaped body trained driver (io) moves. 5. Voters according to claim i and 2, characterized in that the screw drive consists of two screw gears (19, 20 Fig. 4) is formed, one of which is a helical gear (2o) with the switch arm carrier (3) and the other helical gear (i9) with the drive gear (8) of the stepper motor rigid connected is. 6. Voter according to claim i to 5, characterized in that the with the axially displaceable element of the screw drive firmly connected switch arm support has a molding serving as a guide (ii Fig. i), which with a second, of a magnet moving molded part (15) the disengageable linear guide and the guide when turning the selector forms. 7. Voter according to claim 6, characterized in that that the guide serving molded part (ii) of the switching arm support (3) is a radially positioned, is a comb-like body extending in the axial direction of the switch arm, whose cutouts (12) correspond to the height steps and when turning the selector with a circular guide rail (13) attached to the voter frame (i) in Engage come while the side surface (16) of the comb-like body as a guide for the stop (15) moved by the magnet (14). B. Voters according to claim 7, characterized in that in the attracted state of the magnet (14) the stop (15) is out of engagement with the guide surface (16) of the molded part (ii). 9. Voters according to claim 8, characterized in that the stop (15) and the last Height step corresponding cutout (18) are shaped so that when reaching the the last height step the straight line becomes ineffective and the turning of the selector he follows. ok Selector according to Claim 6, characterized in that the switch arm support (3) attached molded part (22 Fig. 5) a sector-shaped, in a to the voter axis vertical plane extending, flat body (22) and that of the magnet (14) moving molded part (21) is a comb-like body. ii. Voters according to claim io, thereby characterized in that the shaped part (21) moved by the magnet (14) is a comb-like, body placed radially to the voter axis (2) with one on the switch arm support (3) Sector disk (22) fastened in a plane perpendicular to the voter axis in this way cooperates that the one end face of the sector disk moved with that of the magnet comb-like body the straight line and with radial displacement of the comb body the magnet forms the guide when screwing in. 12. Voters according to claim ii, characterized in that the magnet used to control the linear guide (14 Fig. 5) at the same time the control of the pressing and lifting movement of the contact arms (5) causes. 13. Voter according to claim ii, characterized in that the radial movement of the comb body (21) by the magnet (14) in an inclined to the voter axis (2) Level and the cutouts of the comb are shaped so that they are parallel to the Run level of the sector disk (22) and after turning in the selector the return movement of the magnet causes an axial displacement of the switch arm support (3) causes the control of the pressing and lifting movement of the switching arms serves.