DE918515C - Switching mechanism for storing series of current impulses - Google Patents

Description

The invention relates to a switching mechanism for storing series of current impulses, in which as Storage members, a contact blade set is arranged radially and rotatably about the axis of the memory and the Kantakt lamellae for unsaved digits on one side of one of the Memory firmly mounted washer, while the contact lamellas in the memory layer on the other Side of the washer are in which the contact lamellas through a cutout of the washer get, according to patent 895 923.

The invention represents a further development of the arrangement according to the main patent and exists in that a rotatably mounted lever arrangement by pressing the key of a certain number .. Digit determined.

With the invention, the switching mechanism for storing series of current impulses with simple mechanically controlled memory elements used as a key selector switch for each telephone station will.

In the drawings, an embodiment of the invention is shown.

Fig. Ι shows the side view of a push button selector switch; in

Fig. 2 is a view of the tap side of the switch shown;

Fig. 3 is a section in the direction AB of Fig. Ι; in

Fig. 4 is the activation of the drive magnet for the gripper in a subscriber circuit shown; in

Fig. 5 shows details of a set of springs controlled by the rear derailleur;

6 shows a plan view of the drive magnet for controlling the tap; in

Fig. 7 is shown in vertical form, the annular disc, in which above the annular disc the contact lamellas on the rest side of the washer and the contact lamellae below the washer are located on the storage side of the ring disc; that shown below FIG Fig. 8 identifies the power interruptions that are generated when the tap is running.

The push-button selector switch consists of a main support made of flat material with a base plate 12 and the two side walls 13 and 14. A cover plate 15 in connection with the intermediate web 16 is used to guide the resiliently mounted keys Ti to Tu. Between the two side walls 13 and 14 a lever arrangement is rotatably mounted. This lever arrangement has two U-shaped curved rails 17-18, its jointly guided Leg ends are rotatable about the axis 19. The two levers 17-18 are on the side wall 13 mounted on a shoulder screw 20. A bushing 21 is inserted into the side wall 14. On this Bushing 21, the other two leg ends of the rails 17-18 are rotatably mounted. The bridge of the U-shaped rail 17 has a vertical position in the rest position (Fig. 3), and it act on this web the approaches of the keys T1 to T 5. The The web of the U-shaped rail 18 is inclined. The keys T 6 to T10 act on this bar. The keys T1 to T 5 are provided with shoulders, which have a different distance from the upper edge of the web of the rail 17. Likewise are the keys T6 to T10 with approaches which have a different distance from the inclined web of the rail 18.

The U-shaped rails 17 and 18 are in fixed connection with a lever 22, which at its outer end in the horizontal direction (Fig. 1) is angled. The shape of the angled Area 23 can be seen from FIG. 7. The edge 24 serves as a ramp for the Lamellae 25. The lamellae 25 are the radially arranged storage elements of the lamella set 26. The angled part 23 of the lever 22 also has a bearing surface 27. This bearing surface 27 is dimensioned in length so that three individual slats can lie next to each other. That Angled part 23 of the lever 22 protrudes through an incision 28 in the side wall 14. This incision 28 is guided around the axis of rotation 19 in the shape of a circular arc. The intermediate web 16 is also provided with an incision so that the lever 22 is unimpeded can perform a rotary movement according to FIG. 1 backwards. On the side wall 14 is one off Insulating material existing ring disk 29 attached. This annular disk 29 has a cutout 30 (Fig. 2) provided, which extends over sixteen slats.

The rails 17-18 (Figs. 1 and 3) are through a spring 31 suspended from the side wall 13 is pulled up. The bushing 21 fixedly mounted in the side wall 14 serves as a bearing of the carrier 32 for the plate set 26. This carrier 32 is on its left side (according to FIG. 1) designed as a gear 33. This gear 33 forms in connection with a not shown Lock spring a reverse rotation lock. Due to this lock, the lamella set 26 according to FIG. 2 can only one Turn to the left. The plate set 26 is fixed on the carrier 32 between insulating rings stored. Furthermore, a gear 34 is permanently connected to the carrier 32.

A carrier 35 with the gripper 36 is also rotatably mounted on the bearing bush 21.

A pawl bearing 37 is placed on the gripper carrier 35, around the axis 47 of which the pawl is 38 can be moved. The pawl 38 is at the free end with two offset pawl parts 50 and 51 designed in such a way that in the event of a rotary movement from right to left the tappet carrier 35 is rotated by half a tooth pitch of the wheel 34. The latch is then used 38 moves from left to right, the Tap carrier 35 rotated by a further half lamella pitch.

A switching pin 39 is guided through the bore of the bearing bushing 21, which rests with its right end on the pawl 38 and with its left end touches the armature 40 of the magnet M (see FIG. 6). The magnet M is attached to the part 41 bent from the base plate 12. The magnet M is provided with a contact spring set 42. The contact spring set 42 consists of a normally closed contact ab and the normally open contact bc.

A contact spring set 43, the contact structure of which can be seen from FIG. 5, is fastened to the side wall 14. The sliding spring k lies with the free end against the sliding path of the contact blade set 26. The contact springs g and h form a working contact. The contact springs ed are a normally closed contact, while e and / act as a normally open contact. The slide spring Z is provided with a metal pimple 44 which protrudes into a cutout 45 of the pick-up support 35 in the rest position of the switching mechanism. In the working position of the switching mechanism, the metal pimple 44 slides on a slideway of the ring-shaped central part of the tap 36. As a result, the contact spring set 43 is placed in its working position around. The contacts ef and gh are then closed and the contact ed opened.

A conical disk 46 is attached to the switching pin 39. This conical disk is below one inclined mounting surface of button T11. At the "5 Pressing the Tu button therefore causes the conical disk 46 to be connected to the switching pin 39 moved in the axial direction to the right and thereby rotated the pawl 38 about the pivot point 47, until the pawl part 50 of the pawl 38 is no longer generally in engagement with the toothing of the wheel 34 stands.

A spring 48 is inserted within the bearing bushing 21. This spring 48 is with the left end inserted into a bore of the bearing bushing 21, while the right end through a bore of the

Pawl 38 is inserted. The only purpose of the spring 48 is to act as a mainspring and to provide the force to generate for the return of the tap 36. By a spring 49, the pawl 38 is easy Pressure printed against the switch pin 39.

The springs of the contact sets 42 and 43 are shown with the same designation in the circuit of FIG. The magnet M is in the upper wire of the subscriber loop.

The mode of operation of the key selector switch is as follows: As an example, it is assumed that the digits 3, 4, o, 3, ο and 1 are to be saved and then sent out. The participant of the intercom must first press key T 3. The button T 3 is now designed so that at the lowest position by the approach of this button, the web of the rail 17 is rotated so far about the axis 19 that the lever 22 with the angled part 23 is rotated over six slats.

The movement of the lever 22 can be seen from FIG. 7. The position SJ shown in dashed lines is the rest position and S II is the position when the T button 3 is pressed. In this case, three slats remain on the storage side is slid and are located on the resting side RS. the three fins ΙΙΓ lying on the support surface 27, and that is the right-hand lamella of the three lamellae III 'against the shoulder between ramp surface 24 and contact surface 27.

If the button T 3 is released, the rails 17-18 are turned back to the rest position ^{with the lever 22-23 m with the support of the spring 31.} With the rotation of the lever 22-23, the lamella set 26 is now also rotated, namely this makes a left-hand rotation as shown in FIG. The three lamellae marked ο are rotated further on the storage side ^ "5 *, while the three lamellae III slide along the rest side of the annular disk 29. After the rotation of the lamella set 26, the three contact lamellae ΙΙΓ now take the position of the contact lamellae ο.

With the rotation of the lamella set 26 , the carrier 35 with the gripper 36 will also execute the same rotary movement via the pawl 38 which is in engagement with the gearwheel 34. When the switching mechanism is set, the gripper 36 remains on the right contact lamella o (Fig. 7). During the rotary movement of the carrier 35 and the indexing pawl 38, the spring 48 is tensioned.

To store the next digit 4, key T 4 is pressed. The approach of the button T 4 is so far removed from the web of the rail 17 that in the end position of the button T 4, the rail 17 is rotated with the lever 22 by seven slats. Of these seven lamellae, the lamellae ΙΙΓ remain on the storage side SS of the annular disk 29, while the four lamellae marked IV slide onto the rest side RS of the storage disk 29. The three contact lamellas IV are in the lowest position of the button T 4 on the support surface 27 of the lever 22-23.

If the button T4 is released, the rail 17 rotates back into the rest position with the lever 22-23. The lamella set 26 is taken along. As a result, the four lamellae IV reach the rest side RS of the annular disk 29, while the three lamellae IV remain on the storage side 6 * 5 ". With the rotation of the lamella set 26, the pawl 38 with the carrier 35 and the gripper 36 become the same In this case, too, the pick-up remains on the same lamella ο.

The other digits o, 3, ο and ι are stored in the manner described above. When the ο button is pressed, the lever 22-23 ^is rotated by thirteen slats. Of these thirteen lamellae, the ten lamellae X reach the rest side RS of the annular disk 29, while the three lamellae X ′ run onto the storage side SS of the annular disk 29. By pressing the next button 3, the lever 22-23 slides over six slats. From these, when the lever 22-23 returns, the three lamellae III reach the rest side RS and the three lamellae III 'reach the storage side SS of the annular disks 29.

To store the fifth digit, the lever 22-23 glides over thirteen slats by pressing the T το button, so that when you return the ten slats X to the RS side and the three slats X 'to the 5 ¹ JT side of the disk 29 accumulate. To store the last digit 1, the lever 22-23 slides over four slats when the T1 button is pressed. Of these four lamellas, the lamella I is brought to the RS side of the disk 29, while the three lamellae Γ come to rest on the bearing surface 27 of the lever surface 23. This end position of the lever 22-23 is shown by the lever shown on the right in FIG. 7. The position of the lamellae after the numbers 3, 4, o, 3, ο, ι have been stored in FIG. 2. The pickup 36 is not in the position shown in FIG. 2, but is during the storage of the aforementioned number stopped on the lowest of the slats marked with ο. The switching mechanism is now ready for tapping the stored digits.

The reproduction of the stored digits is as follows: The subscriber of the intercom gives the incentive for the switch to run according to the present exemplary embodiment by lifting the receiver. The handset hook switch in Fig. 4 has a sliding contact HU2, which is only temporarily closed during the movement of the hook switch. During the temporary closure of contact HU2 , the following loop circuit is closed: from the α-wire of the speech line relay R, hook switch HU 2, contact de, contact off, hook switch contact HUi, loop of the intercom, & -wire.

Relay R responds temporarily in this loop circuit. The contact r is closed and thus the magnet M during the

Drop-out delay time of relay R in the following! Circuit switched on:

α-wire of the speech line, magnet M, contacts from contact , hook switch HU i, loop of the call station, ib-wire of the speech line.

The magnet M places the armature 40 (Fig. 1 and 6) in the working position. The switching pin 39 follows the movement of the armature, and the pawl 38 will therefore also rotate to the left about the axis 47 due to the force of the spring 49. The rear side of the pawl part 50 of the pawl 38 slides along the tooth flank of the wheel 34. If only the cutout between part 50 and part 51 is in the area of gear 34, the tensioned spring 48 rotates pawl 38 backwards until the pawl part 51, which is advanced by half a tooth pitch, rests against the tooth surface left by part 50 . When the armature M is tightened, the pawl 38 turns clockwise by half a tooth of the wheel 34, and that corresponds to half a pitch between two adjacent lamellae 25 of the lamellar disk 26 , the gripper 36 also rotates to the right when the armature M is tightened. It slides into the space between the lowest lamella ο and the first lamella III. When the carrier 35 is rotated, the pimple 44 (FIGS. 2 and s) leaves the cutout 45 in the carrier 35. The contact spring set 43 is brought into the working position. Contacts gh and ef are closed and contact ed is opened. There is a connection between the sliding spring k via the lamellar disk 26, contact lamella o, pick-up 36, contact pimple 44, sliding spring b.

According to FIG. 4, the following switching state now exists: The contact de is open and the contact ef is closed. The contact from ab is interrupted and a connection is established via bc . Furthermore, the contacts gh are closed and the above-described connection is established via the gripper via lk. There is the following loop circuit:

α-wire of the speech line, resistance Wi, contact lk, contact cb, hook switch HUi, contact gh, & -wire of the speech line.

The interruption at contact ab causes magnet M to be de-energized. The armature 40 (FIGS. 1 and 6) returns to the rest position.

Here, the switching pin 39 executes a movement from left to right according to FIG. 1. The pawl 38 is rotated about the axis 47. The back of the pawl part 51 slides along the vertical tooth flank. If part 51 leaves the right side of gear 34, then as a result of the tensioned spring 48, pawl 38 with carrier 35 and gripper 36 will perform a rotary movement backward as shown in FIG. 1 until the back of pawl surface 50 is on the vertical tooth flank of the next The tooth. As a result of this movement of the tap 36, it has been rotated by a further half division of the lamella set 26. The lowermost contact lamella o according to FIG. 2 has finally been left by the gripper 36 and is now on the first of the three lamellae labeled III. By the fall of the armature M and the contacts are open bc and closed the contacts from. When the tap 3.6 slides off the lamella 0, the connection between the contact springs k and I according to FIG. 5 is interrupted. According to the circuit diagram in FIG. 4, the contact lk is therefore open. The magnet M receives power again via the α-wire of the speech line, magnet M ₁ contact fe, contact ab, hook switch HU 1, contact gh, δ-wire of the speech line. The contacts of the spring set 42 from the magnet M (FIG. 6) are brought into the working position again. First contact bc is closed and then contact ab is opened. Closing contact bc has no effect. By opening the contact ab , the loop of the intercom ab is opened, and the first power interruption ■ for setting the voters is sent via the intercom line ab .

In Fig. 7, the set of contact lamellae with annular disk 29 and gripper 36 is shown in an extended form. Has the gripper 36 after leaving the right contact lamella o through the first response and falling of the magnet M has reached the first lamella labeled III, separated by the insulating washer 29, and the magnet M is made to respond again, so is the next switching of the tap 36 on the second of the lamella labeled III generates the first interruption via the voice line. This interruption can be seen in the surge current diagram shown in FIG. ,

As a result of the interruption at the contact from the speech loop in FIG. 4, the magnet M is de-energized. This falls back into the rest position. The gripper 36 (FIGS. 2 and 7) is hereby rotated by a further half step (clockwise rotation according to FIG. 2) in the manner already described. The gripper 36 then faces the middle lamella of the lamellae labeled III. If, after the fall of the magnet M from the contact is closed again (Fig. 4), including the magnet M is again turned on and thus, the tapper 36 is rotated back by another half a step. The magnet in turn causes the contact to open . The second interruption of the speech loop is generated (see Fig. 8). With the interruption of the speech loop, the magnet M of the current is withdrawn. The magnet M returns to the rest position. The gripper 36 carries out a further half step and then faces the third lamella of the lamellae labeled III. The falling magnet M causes the contact to close again, so that the second current surge via the voice lines is ended. The magnet M is then switched on again. The gripper 36 takes another half step. The speech loop is opened again via contact from. M falls off. From the-

gripper again carries out half a step and, after the third current surge, reaches the first lamella of the lamellae marked III 'via the speech line. This lamella is located on the storage side 5 * vS * of the annular disk 29 (Fig. 2 and 7). The connection already described between the sliding contact springs k and / according to FIG. 5 is thus established. The contact lk shown in FIG. 4 is thus closed. The switching on and off of the magnet M continues to be carried out in the same manner as described. During the next three current surge interruptions, the control of the magnet M takes place at the contact from. However, the interruptions cannot affect the a- and ö-wire of the speech line, since the impulse contact ab is bridged via the sliding contact arrangement kl and resistor Wi. Only when, after energizing the magnet M three times, the gripper 36 is validly opposite the first lamella of the lamellae labeled IV, is the connection between the slip springs kl interrupted again and thus the bridging of the impulse contact ab (Fig. 4) is canceled. The next four interruptions generated by the magnet M at the contact ab are transmitted via the voice wire from the voice line. When the gripper 36 reaches the three lamellae labeled IV and located in the storage position, the current surge transmission is interrupted. If these storage lamellas IV are left and the tap of the first lamella is opposite the lamella marked X, then when the magnet M responds again, the current surge transmission via the voice line begins. Ten power pulses are sent out in a row. The current surge transmission is then interrupted again, specifically when the tap 36 overflows over the lamellae marked X '.

In the manner described above, a further three series of current impulses are sent out, namely the first series consisting of three interruptions, then the second series consisting of ten interruptions and then the series consisting of one current surge. If the gripper 36 then reaches the first of the three storage lamellae numbered with I ', the gripper 36 will carry out two further steps until it has reached the last lamella. In this position of the tap, which is shown in FIG. 2, the contact spring set 43 reaches the rest position as a result of the metal pimple 44 falling into the cutout 45 of the contact carrier 35 (FIGS. 2 and 5). The contacts gh and ef are interrupted here. The magnet M (Fig. 4) can no longer be switched on. The speech loop consists of α-wire, resistor Wx, contact de, contact ab, hook switch HU i, loop of the call station, & -wire of the speech line. The surge transmission is thus ended.

If the participant of the intercom has saved a wrong number, the participant has the ability to delete all storage. For this purpose he presses a so-called Error key T11.

This key Tu (Fig. 1) is when moving moves down through the cone 46 of the switching pin 39 from left to right. The latch 38 makes a rotation about the axis 47, until the pawl part 50 the toothing of the wheel 34 has left. The gripper 36 becomes so long as a result of the tensioned spring 48 perform a clockwise rotation until the pawl holder 37 rests against the stop 52 (FIG. 2) and thus the gripper 36 is held in its rest position. The participant of the intercom must start again with storing the individual digits. With the renewed storage of a Digit, all the storage lamellae are automatically returned from the storage position to the rest position, which reach the cutout 30 of the storage disk 29 during the new storage.

According to the embodiment shown, only the time between the closure of the loop via the hook switch HU 2 and the transmission of the first current impulse, that is, until the second response of the magnet M, remains for the setting of the preselection element before the emission of the first series of current impulses. can be determined by response conditions of relay R. To extend this time, however, a changed position of the tap 36 can be used for its rest position, in that the tap 36 does not find its rest position on the third lamella of the lamellae designated V , but rather on the first lamella of this row. In this case, the gripper 36 then first has to perform three steps. During this time the impulse contact ab is bridged via the contacts kl. Only the fourth drop of the magnet M then generates the first current surge via the speech lines .

Claims (27)

Patent claims: 1. Switching mechanism for storing series of current impulses, in which a set of contact lamellas is used as storage elements is arranged radially and rotatably around the axis of the memory and the contact blades for non-saved digits on one side a fixed no within the scope of the memory mounted washer, while the contact lamellas in the storage layer on the other Side of the washer are in which the contact lamellas through a cutout of the washer get, according to patent 895 923, characterized in that a rotatably mounted Lever arrangement by pressing the key of a certain number a 'certain rotary movement executes and determines the contact lamellas according to the digit to be saved. iao 2. Switching mechanism according to claim 1, characterized in that that the linearly moved keys (T ι to T10) are provided with an actuating surface are used to control the rotational movement of a lever assembly (17, 18, 22, 23) by one Serve axis (19). 3. Switching mechanism according to claim 2, characterized in that that the lever arrangement (17,18,22, 23) controlled by the keys (T 1 to T10) acts directly on the contact blades (25) and the contact blades for identification the number determined. 4. Switching mechanism according to claim 3, characterized in that that the lever arrangement (17, 18, 22, 23) the contact blades (25) for identification \ o nation of the number in the memory position (SS) . 5. Switching mechanism according to claim 2, characterized in that the lever arrangement (17, 18, 22, 23) has a U-shaped curved rail (17 or 18) with a lever (22, 23) for Control of the contact blades (25) is provided, and the rails (17,18) with control arm (22, 23) Rotate the two ends of the leg when pressing a key. 6. Switching mechanism according to claim 5, characterized in that the buttons (T 1 and T10) with Approaches are provided that act on the web of the U-shaped rail (17 1> between 18). 7. Switching mechanism according to claim, characterized in that the approaches of the different Keys (Ti to T10) have a different spacing from their counterpart. 8. Switching mechanism according to claim 7, characterized in that that the approaches of the different keys (Ti to T10) have a different spacing from the web of the U-shaped rail (17 or 18). 9. Switching mechanism according to claim 2, characterized in that the buttons (Ti to T10) in two rows (Ti to T5 and T6 to T10) arranged are, of which each row on one at a different distance from the axis (19) arranged counter-support of the lever arrangement acts. 10. Switching mechanism according to claim 5, characterized ge-4.0 indicates that the lever (22, 23) has a ramp surface (24) for the contact blades (25) through which the contact blades (25) from one side (RS) of the annular disc (29) on the other side (SS) of the ring disc (29) are bent. 11. Switching mechanism according to claim 10, characterized in that that the lever (22, 23) following the run-up surface (24) for a certain Number (three) of contact blades (25) provided with a straight support surface (27) is. 12. Switching mechanism according to claim 11, characterized in that the lever (22, 23) is rotated by a certain angle by pressing the button of a certain number and a corresponding number of contact blades from the straight bearing surface (27) of the lever (22, 23) ) slide off and spring back onto the resting side (RS) of the annular disc (29). 13. Switching mechanism according to claim 12, characterized in that that by pressing the key a certain number also a certain number (three) of contact lamellas (25) on the bearing surface (27) of the lever (22, 23) and through this number (three) of contact lamellas (25), the impulse pause between two series of impulses is determined. 14. Switching mechanism according to claim 12, characterized in that that by releasing the button in the end position the returning to the rest position Lever (22, 23) causes a rotary movement of the contact blade set (26). 15. Switching mechanism according to claim 14, characterized in that the lever (22, 23) returning to the rest position has a number of contact blades (25) corresponding to the specific digit on the rest side (RS) of the annular disc (29) and on the straight bearing surface (27) of the control arm (22,23) located number (three) of contact blades (25) on the storage side (SS) of the annular disc (29) rotates. 16. Switching mechanism according to claim 15, characterized in that the current surge transmission is interrupted via the contact lamellas (z. B. III ') and a pick-up (36) brought into the storage position (SS). 17. Switching mechanism according to claim 16, characterized in that the impulse contact (from the magnet M) is bridged via the contact lamellas (ΙΙΓ) brought into the storage position (SS) and the pick-up (36). 18. Switching mechanism according to claim 17, characterized in that the current impact contact (& -b ) is controlled by the control magnet (M) of the pickup (36). 19. Switching mechanism make claim i8, characterized in that the control magnet (M) is in the loop circuit of a call station and works in self-interrupter circuit with the impulse contact (from) . 20. Switching mechanism according to claim 19, characterized in that the control magnet (M) is switched on by loop closure over the receiver hook (HU) . 21. Switching mechanism according to claim 17 and 19, characterized in that the contact lamellas (ζ. Β. ΙΙΓ) and the pickup (36) of the impulse contact (cir-b) and the control magnet (Ii) of the pickup are brought into the storage position (SS) (36) can be bridged. no 22. Switching mechanism according to claim 21, characterized in that the bridging of the impulse contact (ab) and the magnet (M) takes place via the normally open contact (bc) of the magnet (M) . 23. Switching mechanism according to claim 1 and 14, characterized in that the tapping of the contact lamellas (25) placed on the storage side (SS) of the annular disk (29) is prevented by pressing a special button (Tu). 24. Switching mechanism according to claim 23, characterized in that the special key (T 11) the backstop of the tap (36) cancels. 25. Schälwerk according to claim 24, characterized characterized in that the special key (Tu) has an axially arranged to the contact lamella set shift pin (39) in the horizontal direction and the progression pins (38, 50, 51) for the gripper (36) removed from the toothing of a ratchet wheel (34). 26. Switching mechanism according to claim 25, characterized in that the gripper (36) is returned to the rest position after the release by pressing the button (Tu) by spring force (spring 48). 27. Switching mechanism according to claim 8 and 25, characterized in that the control magnet (M) and the special button (Γ11) act on the same Scha'ltstift (39) to control the tap (36). 1 sheet of drawings © 9550 9.54