DE895923C - Switching mechanism for storing series of current impulses - Google Patents

Description

Switching mechanism for storing series of current impulses The invention relates on a switching mechanism for storing series of current impulses in Fearnmel @ de-, in particular Telephone systems. It; are already: Memory known where by setting an electrically testing tap on mechanically moved storage elements that The end of the series of impulses is determined. The aim of the invention is to use simple means mechanically moved storage elements in connection with an electrically testing one To unite grippers in one structural unit. This is achieved by that: as a storage member a contact lamella set. radial and rotatable around the axis of the memory is arranged and the contact blades for unsaved digits on the one hand a ring disk fixedly mounted in the context of the memory, while the contact lamellas in the storage layer are on the other side of the ring disc, in which d i, ea contact lamellas. get through a cutout of the washer and only in this memory layer, a lamella a metallic connection between Lamella and pick-up for the test current to terminate the series of impulses produced will.

In. the drawing shows an embodiment of the invention. It. is the switching mechanism for a pulse repeater, with the electrically recorded series of impulses stored and from one of the storage independent point in time to be sent out again, the number of times to be sent out A series of surges from the electrical test of a tap to the in Storage location brought storage members is determined. The fig. r shows the switching mechanism of the pulse repeater from the tap side.

2 shows a section in the direction A-B according to FIG. For the purpose of a clear setting in Fig. 2, the magnet A is with his Armature arrangement 16 not in the inclined position according to FIG. I, but clockwise by 15d ° shown rotated. The contact spring set i5 from FIG. I is not shown in FIG. 2 either Drawn in its natural incline, but rotated by 30 ° clockwise.

3 shows the switching mechanism from the memory side. The one in this Fig. 3 shown in an inclined position drive magnet D is also not in Fig. 2 in his original incline drawn, but in a position in which the drive magnet D 'is rotated 3: 0 ° in the counterclockwise direction.

FIG. 4 shows part of the pulse repeater in plan view which the mechanical control of the memory elements 3 by the magnet M with. Its Anchor 4 can be seen.

Fig. 5 shows a second embodiment of the mechanically moved Memory elements.

The switching mechanism consists of an injection-molded frame 6. In this injection-molded frame 6 an axis 2 is fixedly mounted. On a circular part of the frame 6 is an washer 0 5 insulated in such a way that no metallic connection between the washer 5 and the frame 6 consists. The annular disk 5 has the two Cutouts 5 'and 5 "(see Figs. I and 3).

A sleeve 32 is rotatably mounted on the axis 2. Stuck with this Sleeve 32 are connected to the gear 9, the storage member disk i with the radial arranged storage lamellae 3. These storage lamellae 3 consist of spring-loaded Material. Furthermore, a gear 13a is firmly connected to the socket 32.

In the gear 9 (see. Fig. 3) engages a pawl 8, .de with the armature 7 of a magnet D is connected. The pawl 3: 1, the, on the housing 6 is attached, prevents backward movement of the gear g.

For the mechanical movement of the memory lamedlem 3 (see Fig. 2) of the rest position in the storage position is a magnet M with its anchor 4 (Fig. 1, 3 and 4).

One end of the spring 19 is firmly connected to the axis: 2. The other end of the spring ig is mounted in the spring housing. This housing is in a fixed connection with the socket 13 which is rotatably mounted on the axis 2. With the socket 13, a switching arm carrier 1a is also firmly coupled, on which the gripper 2o-ii and the Stromzuführungs.arm 21 are attached and a double-armed lever 14 with glue actuating lever 17 is rotatably mounted. The Strornzüführungsarm 21 slides on a Stromzufüh: approximately element 22, which is connected to the frame 6 of the switching mechanism. firmly connected: is.

The lifting part 14, as shown in FIG. 1, is at both ends designed ratchet-like for the rapid grip in the gear wheel 13 ". The operating lever 17 is controlled by an armature 16 of the magnet A. The anchor 16 is on his free end funnel-shaped. The funnel-shaped anchor end overlaps the sleeve 13 rotatably mounted on the axis 2, as shown in particular in FIG. 2 can be seen.

The switch arm support 12 also has a switch pin 23, the actuates the spring set 15 in the rest position of the switching mechanism.

One end of the spiral spring 18 is on the Schadta arm support 12 (FinG. I) attached. The other end of the spring 18 is in the operating lever 17 hooked and causes a torque about its axis clockwise.

The mechanism of operation of the switching mechanism is as follows: In the rest position of the switching mechanism, the Magnat M is de-energized and the armature 4 is in the Rest position. The, spoke member 3 "in the cutout 5 'of the annular disk 5 is through the Armature 4 of the magnet Min brought the storage layer, as can be seen from FIGS is.

The rotary magnet D in Fig. 2 and 3 takes the current surges to be stored on. The armature 7 with its ratchet pawl is corresponding to the current surge tooth recorded 8 actuated and thereby the gear 9 in the direction of the arrow shown in Fig. 3 turned. Due to the rigid connection between gear 9, spoke disk i with the storage lamellae 3 and the gear wheel 13 ″ (FIGS. i and 2) are also followed by these parts the rotary motion. The first step is the storage disk i, the storage lamella 3 'from the end of the armature 4: -slide and on the storage side of the annular disc 5 slide along. With the first current impulse in the series of current impulses, the magnet also becomes M turned on and brings the armature 4 into working position, so that initially more storage lamellae are not actuated by the armature 4 of the magnet M. According to the recorded Current impulse number is then a certain storage lamella 3 'in front of the cutout 5' the annular disk 5 (Fig. 1, 3 and 4). After the series of current impulses has ended, the Magneit M is de-energized, and the armature 4 is brought into the rest position by spring force. Through this the Speiche @ rlamellei is through the cutout 5 'on the .Speicherseite of the ring disc 5 turned.

If the rotary magnet D now receives the second series of current impulses, then the gear 9 with the storage disk i in a .the second current impulse number corresponding Position rotated. With the first turning step of the second series of impulses, the Storage lamella 3 ', through which the number of current impulses of the first current impulse series is marked, from the anchor end 4 of the Magnerten to the storage side. the washer 5 slide. The magnet M receives electricity again, so that the armature 4 attracted does not touch the storage lamellae sliding past the cutout 5 '. Only when the second series of current impulses has ended and then the magnet M is de-energized, the armature 4, which teaches back into the rest position, presses that of the second current impulse number corresponding storage lamella through the cutout 5 'into the storage position. The inclusion of further series of current impulses takes place in the same manner as described above and way.

The F'ig. i shows a storage lamella o in storage position on the the pickup i i is also set. With V, IV, IX, II, V, IX, I are more Speicheirlamellen referred to, which are located in the storage layer. By .the Number of storage elements between two storage elements brought into storage are present, the number of power surges in a series is determined. According to Fig. I has So, the rear derailleur first the number 5, then the number 4, then further the digits g, 2, 5, 9 and i have been added.

Tapping; stored digits can be any Point in time. The gear wheel i3d is, as already stated, with the storage disk i and the gear g rigidly connected. That of the gear wheel g and the memory disk i when the series of current impulses are recorded, the rotary movement will also be Executed by the gear wheel 13 ". Through the coupling between gear wheel 13" and the lever 14 (Fig. I), the switching arm support i2 with pick-up 2o-i i is the rotary movement execute, and the switching arm i i remains on the storage lamella o. By the rotary movement of the Sch.altarmträgers, 1a also leads the housing of the spring ig a Rotational movement is lousy, and this tensions the spring ig.

The return of the tap i i is as follows: With the Magnet A receives current impulses as an incentive for the process. The magnet A can be in any Controlled manner, either by a special relay breaker or in a known manner, not shown, in a self-interrupting circuit. Everyone Current impulse acting on the magnet A will also be of any kind and Way on the tax b @ betw. Link devices transmitted by the pulse repeater are to be set.

The armature 16 of magnet A is attracted by the first current surge, and the funnel-shaped end of armature 16 according to FIG. 2 moves from right to left about the armature axis. This movement of the funnel-shaped end moves the actuating lever 17 (Fig. I) about its axis of three axes. The actuating lever 17 will move away from the center of the axis 2. As a result of the movement of the lever 17, the right pawl of the lever 14 disengages from the gear wheel 13. As a result of the pulled-up spring ig (FIG. 2), the switching arm support 12 with the pawl 14 according to FIG. so far until the left pawl of the lever 14 rests against the next tooth of the wheel i3a: If the magnet A is de-energized, the armature 16 goes into the rest position. The retraction spring 18 (Fig. I) pulls the lever 17 in the direction of the center of the axis 2. The left pawl of the lever 14 leaves the tooth base of the wheel 13a. The right handle! of the lever 14 pivots into the next tooth. During this movement of the lever 14, the switching arm support i2 again rotates to the left until the right pawl of the lever 14 rests on the flank of the next tooth of the wheel i3a.

By tightening and falling of the armature 16, the Miagneten A thus becomes the Switching arm support 12 rotated back by one step in two switching times. The one with the switch arm support i2 firmly connected, the gripper i i has the storage lamella o left and is one step to the left, i.e. H. counter clockwise been rotated.

If the magnet A receives power again, the above-described processes are repeated. The Ab -greifer ii carries out the second step. lErreicht the tapper ii .the in Fig. i denoted by V fin, and that is after the fifth, latching the case, which acts on the magnet A, then comes through the washer 5, memory lamella V, tapper ii, switch arm 21 of the power supply and Seigment 22 of the power supply creates a current path through which a relay arrangement is controlled, which interrupts the actuation of the magnet A for a certain time in any arbitrary manner and at the same time the control of the magnet A ve: ranla.ß.te Power surge, broadcast ended.

If magnet A receives the incentive to emit the second series of impulses, so with the current impulse confirmation of the magnet A, the pick-up i i in Execute a left turn as long as shown in FIG. i in the manner described above until the pickup i i has reached the storage lamella labeled IV. Through the Switching from lamella V to lamella IV, magnet A is excited four times and it is the emission of an impulse series of four impulses at the same time been initiated.

After further switching back the Abgrei: feirs i i and the transmission of the other stored series of current impulses (digits g, 2, 5, g, i) the tap has i i the memory lamella marked I: reached, and at the same time the switch pin has 23 (Fig. 2) put the spring set 15 in the working position. With the cold spring set 15 is given the indicator that .that all series of current impulses that the memory has received, have also been sent out again. The return, the storage lamellae from their storage position (the storage lamella is located on the right according to Fig. 2: Side of the ring disk 5) is brought about in the following way: As already is described, when a series of current impulses is received by the magnet D, the gearwheel g and the storage disk I according to FIG. 3 rotate to the left. In the representation According to FIG. i, the storage disk I then makes a clockwise rotation, and it becomes here after each series of current impulses the corresponding storage lamellae 3 in the storage layer brought. During this movement, a lamella in the storage position rotates in front of the Cutout 5 ", then the storage lamella is due to its natural resilience through the cutout Spring back 5 "and after a further turning step behind the washer 5 to lie down. The position of such a lamella is denoted by 3 ″ in FIG. The storage lamella has thus reached the legend from which it only then comes back can be brought into the storage position if they are at the end of a series of current impulses in front of: the cutout 5 'stands and the anchor q. of the magnet M the storage lamella switches to the memory position.

In Fig. 5 is a further embodiment of the storage lamellae and @d iren control shown. In the case of the in Fi, g. 2 arrangement is between the Storage lamella 3 in its rest position (to the left of the annular disk 5) still a distance from the annular disk 5 present, and the lamella 3 'brought into storage position slides with the pock-like end on the storage side of the annular disk 5 along. In Fig. 5, however, the spoke disk i lies in the plane of the annular disk 5, in which is also the contact lamella 3 ″. The storage lamellae not stored Numbers slide, here on the upper side of the ring disk 5. Reaches the lamella 3 at: the rotation of the storage disk the cutout 5 ', so the lamella of slide off the left run-off surface on the washer 5 and the position below: des Ankeiranmes q. from the magnetic case M. If the storage lamella is 3 "through the anchor arm q. not brought into storage position, this storage lamella slides on the right: contact surface on the upper side, the ring disk 5. Will oppose it the lamella 3 "pressed by the anchor arm in di.eSpeicherlage, so, this is at the subsequent step of rotating the storage disk i on the lower one. Side of the washer Slide along 5 (storage position).

The embodiment shown in Fig. 5 has your: Advantage because, ß the storage disk i with smooth storage lamellae and the annular disk 5 not be unilaterally burdened.

Claims (3)

PATENT CLAIMS: i. Switching mechanism for storing current impulses: rows, in the case of the mechanically moved by setting an electrically testing tap Storage elements the end of each series of current impulses is determined, thereby marked, that as storage elements a contact lamella: ensatz raidiial: and rotatable around the axis of the memory is arranged and the contact blades (3 ") for unsaved Digits. on the one hand, one that is firmly fixed within the framework of the transmitter. Washer (5), while the contact lamellas (3 ') in the storage layer on the other side the annular disc (5) are in which the contact blades (3 ") through a cutout (5 ') of the annular disc (5) and only in this, storage position of a lamella (3 ') a metallic connection between LamOlle (3') and Ab: gripper (i i) for the test current is established to terminate the series of impulses. 2. Derailleur for storing series of current impulses. according to claim i, characterized in that the storage elements arranged radially and rotatably about the axis of the storage unit (3) by a magnet (D) controlled by current surges into one of the. Digits, corresponding position can be rotated. 3. Switching mechanism for storing Current impulse series! according to claim i, characterized in that the storage lamellae (3) be brought into the storage position (3 ') by the armature (q.) Of a magnet (M). - q .. switching mechanism for storing series of current impulses according to claim i and 3, characterized characterized, d @ ate the storage lamellae (3 in Fig. 5) from the side of the annular disk (5) for unsaved digits over a drainage area of the washer (5) in slide the cutout (5 ') and over a run-up surface of the annular disc (5) the same side of the washer can be returned. -5. Switching mechanism for storage of current surge: rows according to claim 4, characterized in that the in the cutout (5 ') standing storage lamellas (3 ") through the armature (q.) Of the magnet (M) in the Be pressed. 6. Switching mechanism for storing current impulse series according to claim i, characterized in that after the tap (i i) on a lamella (3 ') brought into storage division a connection with the Washer (5) is made, over the, the test circuit of a relay arrangement to end the series of impulses. 7. Switching mechanism for storing series of current @ impulses according to claim 6, characterized in that the gripper (i i) has a switching arm (ei) and switching segment (22) existing power supply is connected. B. Derailleur for storing series of current impulses according to claim i, characterized in that the returning from maturing (ii) only the lamellas (3 ') brought into storage position touched.