DE891998C - Circuit arrangement for checking the operational readiness of a hot cathode tube in telecommunication systems, in particular telephone systems with dialer operation - Google Patents

Description

Circuit arrangement for checking the operational readiness of a hot cathode tube in telecommunications systems, in particular telephone systems with dialer operation. The invention refers to telecommunication systems in which glow cathode tubes are used to control switching processes be used. In such arrangements, if the tube is disturbed, incorrect Switching operations occur. For example, in systems with capacitor storage, in which the evaluation of the stored .Switching orders by a hot cathode tube takes place which, if disrupted, result in an unlimited emission of power surges and thus a wrong connection can be made.

To check the operational readiness of incandescent cathode reddeners Various arrangements have already become known, which, however, involve considerable additional effort make necessary. The object of the invention is to test the operability to bring about a hot cathode tube when it is used with the simplest means, this is achieved by adding a relay in the anode circuit of the tube their commissioning (switching on the heating circuit) which is to be controlled by the tube Circuits prepared, the preparation of which prevents, however, if the tube is disturbed is. The arrangement according to the invention has the advantage of an absolutely reliable test the operational readiness of a tube with those required in the circuit itself Means while at the same time preventing incorrect switching when the Tube.

In the drawing, a numerical transmitter is shown as an exemplary embodiment of the invention for telephone systems with dialer operation shown in which the through a keyboard marked switching orders can be saved in capacitors. the evaluation the stored switching orders are carried out by a hot cathode tube GR, in which A relay P is arranged in the anode circuit, which indicates the operational readiness of the tube checks when they are commissioned and at the same time for evaluating the capacitors stored switching orders is used. However, the invention is not limited to that shown Embodiment is limited, but can be used analogously in all systems find, in which glow'kathodenröhren to control any switching processes to serve.

The numeric transmitter shown in the drawing is suitable for the transmission of six series of current impulses. It has six storage capacitors C i -C 6, each of which is used to identify a series of current impulses. The number of current impulses to be emitted in each case is identified by the set of keys with the keys T i -T o , in that a certain potential is applied to the relevant storage capacitor via the pressed key. The contacts of the keys T i -T o are at the branch points of a voltage divider formed from the resistors Wi i-Wi io. Assuming a battery voltage of 6o V, a partial voltage of 6V is applied to each of the resistors Wi i -Wi ro, which are identical to one another. The successive connection of the storage capacitors Ci-C6 to the button set is carried out by the control switch D i with the switching arms dz Id i III, while the individual capacitors for sending the marked series of current impulses via the switching arm d2I of the tap D 2 to the control grid of a hot cathode tube GR and via the switching arm d2II can be connected to the contacts of the control relay IV.

If both selectors have assumed the rest position shown in the drawing, the following circuit is closed: + -pole of the battery, switch arm d 2III of the tap D: 2 in position o, switch arm di III in position i, contact iy, winding of the relay hi, --Pole of the battery. The relay V i has responded and interrupted the circuit for the drive magnet D 2 at its contact 2 vi. If, for example, key T 3- is pressed to store the first digit, the following circuit is initially established for relay T: --Pol of the battery, resistors Wz4-Wi io @, contact of key T3, contacts 3 t, 4s, Winding I of relay T, + pole of the battery. The relay T responds and closes a holding circuit for its winding II, which runs via the relay S, via its contact 5 t. At contact 3 t the winding I of the relay T is separated from the identification key T 3 and the voltage divider is switched on via contact 17 t. A partial voltage of 1'8.V is now applied to the upper assignment of the capacitor Ci via the contact of the button T3 and the switching arm di I. The other assignment of the capacitor C i is via the switching arm di II directly to the + pole Battery connected. When relay T responded, relay Y was also switched on via its contact 6 t and held via its contact 71 y . After energizing the relay S , a circuit for the drive magnet D i of the control switch came about via the contacts 7 t and 8 s, so that its switching arms di Id i III execute a step. The occupancy of the capacitor C i is thus galvanically switched off, so that the capacitor cannot self-discharge and it retains the full storage energy until the switching order is evaluated. The relay Y closes the heating circuit of the hot cathode tube GR via its contact gy and via the resistors Wi ii and Wi i2. Since the control grid io of the tube is de-energized at this point in time, the relay P located in the anode circuit responds and closes a circuit for the starting relay via its contact iip and via contact 12 y. If, on the other hand, the tube should be disturbed, the relay P cannot respond and the circuit for the relay ON remains open, so that the processes described below cannot be initiated. This state can be displayed in a manner not shown, for example by a lamp.

If the tube GR is ready for operation and consequently the relay An responds, the circuit for the relay Vi at the contact 14an that has remained after the relay Y has been energized via the contacts 13y and 14an is opened. The drop in relay V i is delayed by the simultaneous charging current of capacitor C 7. When relay S responded, winding II of relay T was short-circuited via contacts 15s and 16s , so that after a short drop-out time it releases its armature and interrupts contact 7 t in the circuit of drive magnet D i. At the same time, the contact 3 t is closed and thus the relay S is kept energized via the contact 15 s until the button T 3 has been released. When the next button is pressed, for example T7, the winding I of the relay T is re-energized via the resistors Wi8-Wiio and via the contacts 3 t and 4 s, which triggers the same switching processes as previously described. ' After the contact 3 t has been opened and the contact 17 t has closed, a voltage of 42 V is applied to the upper occupancy of the capacitor C2, which is now connected via the switching arm di I, via button T 7. the magnet D i of the control switch is t-8s via the contacts and 7 energized and the latter indexed by one step, so that for the next storage capacitor C3 is switched on. The other switching orders are stored in the same way, depending on the actuation of one of the Ti-To buttons. If the switching arm di I of the control switch reaches the B. position after the last switching order has been saved, the relay T is energized again via the high-ohmic resistor Wi 23, via which the relay S cannot hold, and switches over 5 t the relay S on. The control switch takes a further step, whereupon the relay T responds again after the relay S has dropped out. These processes continue until the switching arms of the control switch D r reach the position shown in the drawing.

The switching processes initiated when the relay <37a responds to the transmission of the series of current impulses corresponding to the stored switching order will now be described. As soon as the relay Vi has dropped out, as explained above, the drive magnet D: 2 of the tap is switched on via its contact 2 vi, which brings the switching arms d2I-d2II @ I into contact with the next contact in their rows of contacts. Thus, the upper assignment of the capacitor C i is connected via the switching arm d21 and the resistor Wi 13 to the control grid io of the @ hot cathode tube GR, while the lower assignment of the capacitor via the switching arm d2,11 and via the resistor Wi 14 with the contact chain of the Control relay 1-V and above is connected to the voltage conductor formed from the resistors Wi 16-Wi22. The resistors IYi 16-Wi 2o are the same size, e.g. B. ioo ohms, while the resistors Wi2i and Wi22 have five times the value, i.e. 500 ohms; since there is now a negative bias voltage on the grid io of the tube GR, the relay P drops out.

The relay An had closed a holding circuit for itself when it responded via its contact i8an and now switches on the delay relay h via the contacts i9 p and 2oaza. ; This causes the relay hi to respond via its contact 2iv and places the impulse relay J parallel to its winding via contact 23v and contact ' 24h. The relay J sends in a known manner a current impulse for setting the selector via a contact (not shown) and switches on an auxiliary relay H via the contact 25i, which connects the capacitor C8, which is charged in its rest position via the contact 26h and resistor Wi i 5, via the normally open contact 271a as well as via contact 2,8f to the winding a of the relay I so that it responds and closes a holding circuit for its winding b via the contacts 29y, 3o d 2, 3111, 32I. With contact 361 the winding I of the relay E is energized, .that is maintained via the contacts 71f and 72, V and via its winding II. By closing the contact 391 , the lower assignment of the capacitor C i is applied via the switching arm d2II and via the resistor Wi 14 to the connection point between the resistors Wi 16 and Wi 17 of the voltage divider, which is switched on via the contacts 66 and 65 v i . In addition, when relay H responded via its contact 33h, the winding of relay J was short-circuited so that it drops out with a slight delay and interrupts the circuit of relay H by opening contact 25i. The capacitor C 8 is recharged via the normally closed contact 261a and the relay T is switched on again via the contact 24h. It closes the circuit for relay H at contact 25i, so that capacitor C 8 is now discharged via contacts 27 h, 34 f, 35 1 and via winding a of relay II. The relay II interrupts the holding circuit for the winding b of the relay I at contact 31 11 and holds itself via the contacts 37111 and 3811. At the same time, the lower assignment of the capacitor C i via the switching arm d211, contacts 411, 4211 and the resistors Wi 16 and Wi 17 to a voltage - of 12 V applied to the filament of the tube GR. The next time the relays J and H respond again, the winding a of the relay III is traversed by the discharge current of the capacitor ü8.-through the contacts q.311, 441, 34f and 27h. It responds, interrupts the holding circuit for winding b of relay II at its contact 37111 and holds itself via contacts 45 IV and 4611I. The lower assignment of the capacitor C i now has a voltage of 18 V across the contacts 411, 471I and q: 8111 compared to the filament of the tube GR i compensates for the applied voltage and thereby de-energizes the control grid ro of the hot cathode tube GR. In the anode circuit of the tube, the relay P responds and interrupts the circuit for the relay J at its contact igp, so that the further emission of current surges does not occur. At the same time, the circuit for relay V is interrupted, which drops out after a short delay time and switches off relay hi at contact 2iv. This closes the circuit for the drive magnet D2 of the tap at its contact 2 vi, so that its switching arms d 2 I and d 2 I1 switch on the capacitor C 2. At the contact 3o d 2 the holding circuits for the relays F and III are interrupted, so that these also drop out and thus the control relays for the current impulse are returned to the idle state.

Since there is a potential of -42 V at the top of the capacitor C 2, which is pressed onto the control grid io of the hot cathode tube GR via the switching arm d: 21 and resistor Wi i 3, the relay P in the anode circuit of the same drops out. It closes the circuit for the relay h via its contact igp and via the contact 2o , which switches the relay Vi on again via contact 21v, so that the drive magnet D 2 drops out and its contact 3o d 2 closes again. Relay J is switched on again via contacts 23v2 and 241a, which closes the circuit for relay H at contact 25i. When it responds, the capacitor C 8 discharges through the contacts 27h and 28f into the winding a of the relay I, whereupon the same switching processes occur as described above for the emission of the first series of impulses. When the relay H responds for the fourth time, the winding a of the relay IV is placed in the discharge circuit of the capacitor C via the contacts 4911 and 5oIII. It responds and closes a holding circuit for its winding b via contacts 29y, 30-d2, 51V and 52 IV. The lower assignment of the capacitor C2 is now on the contacts 411, q.711, 5311I and 5 [IV] at a voltage of 24 V with respect to the filament of the tube GR. The next time the relay H responds, the winding a of the relay V is excited via the contacts 5511I and 56 IV, which is held via the contacts 57I or 58 k and 59 V and, by opening the contacts 5 i V and 72V, the holding circuits for the Winding b of relay IV and for winding II of relay F are interrupted. The lower assignment of capacitor C: 2 is thus connected to a voltage of 30V via contacts 60-1V and 61V. The next time relay H responds, winding a of relay I is switched on again via contacts 27h and 2.8f, which now excites windings I of relays F and K via contacts 3.6I and 62V in addition to the holding circuit for its winding b. The relay K responds, opens its contact qo, k and closes its contact 63k. The resistor Wi2i is short-circuited and the short-circuit via the resistor Wi 22 is canceled, so that a potential of 36 V is now applied to the lower assignment of the capacitor C2 via the contact 391: In addition, the relay K closes a holding circuit for its via its contact 64k Winding II. The next time the relay H responds, the relay II is excited via your winding a in the discharge current circuit of the capacitor C 8, so that a voltage of 42 V is now applied to the lower assignment of the capacitor C2 via the contacts q.11 and q.211 opposite the filament of the tube GR prevails. The voltage applied to the upper assignment of the capacitor C via the identification key T 7 is thus compensated for; so that the relay P responds again and interrupts the further current impulse.

The transmission of the remaining series of current impulses according to the switching orders stored in capacitors C 3 to C, 6 takes place in the same way as described for the first two series of current impulses. If the relay P -in the anode circuit of the tube GR has responded after the last series of impulses has been sent out, further impulses are prevented at the contact 19p and the relay V is switched off. It opens the circuit of the relay V i at contact 2i v, which actuates the drive magnet D 2 of the pick-up via its contact 2 v i. Since there is no potential at the last contacts of the rows of contacts swept by the switching arms di I and di II, the relay P remains permanently activated, while the magnet D 2 creates a circuit for the relay Vi via its contact 67d2. This switches off the magnet D 2 at its contact 2 vi, so that the contact 67d2 is opened and the relay Vi is again brought to waste. The further switching of the tap D2 takes place via contact 2vi. The mutual switching on and off of the relay Vi and the magnet D2 continues until the switching arm d 2III reaches the rest position shown in the drawing. In this the relay Y is short-circuited via the switching arm dz III and the contacts 68 v, 6g y and 70-t. It drops out and interrupts the circuit for the relay An at its (contact i2y. In addition, the relay hi remains switched on via contact iy prepared a new connection.

Claims (3)

PATENT CLAIMS: i. Circuit arrangement for checking operational readiness a hot cathode tube in telecommunication systems, especially telephone systems Selector mode, characterized in that one located in the anode circuit of the tube (GR) Relay (P) when they are put into operation (switching on the heating circuit) the through the Tube prepared circuits to be controlled, but their preparation prevents when the tube is disturbed. 2. Circuit arrangement according to claim i, characterized in that that the relay (P) after determining the operational readiness of the tube (GR) again brought to waste and to control the switching processes to be monitored by the tube (GR) is used. 3. Circuit arrangement according to claim i, characterized in that the relay (P) located in the anode circuit of the tube (GR) switches on an auxiliary relay (An) when it responds, which initiates the switching operations to be controlled by the tube. q .. Circuit arrangement according to claim 3 for current surge storage, in which the switching orders are stored in capacitors, characterized in that the in the anode circuit of the tube evaluating the switching orders. (GR) lying relay (P) when it takes place after it has been determined that the tube is ready for operation. 5. Circuit arrangement according to claim 2 and q., Characterized in that the anode relay (P) of the tube (GR) responds again after sending a number of current surges corresponding to the number of current surges stored in the respective switched-on capacitor and the further emission of current surges up to the switchover to the next storage capacitor (C i - C 6) is prevented. Cited publications: German Patent Specifications No. 72,0 473, 733 569