DE1042662B - Circuit arrangement for actuating the bar and bridge magnets of crossbar selectors in telecommunications, in particular telephone systems - Google Patents

Description

GERMAN

The invention relates to a circuit arrangement for controlling the actuation of a bar magnet in self-connecting telephone systems with crossbar selectors or crossbar switches that are operated by one Marking device can be adjusted by adding DC circuits to actuate a bar magnet and thereafter to operate a switch or bridge magnet. In such telephone systems the marking element is expensive and it is of great importance to achieve fast switching operations, in order to reduce the occupancy time of the marking element when each selector is pressed. So far has been Each bar magnet was provided with a special contact that had to close before the switching magnet could attract, or an interval of a certain length was set between the closure of the circuit Rod magnet and the closure of the circuit of the holding magnet inserted. The first procedure incurs costs for a contact on each bar magnet and for lead wires between the contacts and the marking element and expenses for connecting these wires to the marking element. That The latter method causes a loss of time if the bar magnets are unequal to one another and when a margin of safety is required. You can't control the bar magnet draws his anchor.

According to the invention, the actuation of the bar magnet controlled without additional contacts and additional lead wires and without any loss of time. This is achieved by a switching device assigned to the marking device in which Electronic switching means, relays and a transformer are provided and the such with the marking device and the solenoid of the crossbar selector cooperates that the primary winding of the transformer connected in series with the winding of the bar magnet to be operated and the secondary winding of this transformer with the electronic switching means as well Relay is connected so that the electronic switching means through the in the winding of the bar magnet at its armature tightening and the resulting in the primary winding of the transformer Induction surge take effect to operate the relay, which in turn sets the circuit for the bridge magnet closes.

The invention is described in more detail in connection with the drawing.

1 to 3 show the current and voltage curves in the windings of the transformer;

Fig. 4 shows an embodiment of the invention using a discharge tube and a relay as indicators be used;

Circuit arrangement for actuation

the bar and bridge magnets

of crossbar voters in telecommunications, in particular telephone systems

Applicant:

Telefonaktiebolaget LM Ericsson,
Stockholm

Representative:

Dr.-Ing. H. Ruschke, Berlin-Friedenau, Lauterstr. 37 _t

and Dipl.-Ing. K. Grentzenberg, Munich 27,

Patent attorneys

Claimed priority:
Sweden 19 October 1955

Carl Gunnar Svala, Älvsjö,

and Karl Gunnar Brunberg, Segeltorp (Sweden),
have been named as inventors

Fig. 5 shows an embodiment of the invention in which a transistor and a relay are used as indicators will.

Fig. 1 shows how the current increases in a bar magnet. At point Q the armature of the bar magnet begins to move, and at point P the armature hits the magnet core. During the armature movement, the magnetic field in the core increases, creating a back EMF that reduces the current through the winding of the bar magnet and the primary winding of the transformer. The voltage produced in the secondary winding of the transformer shows the changes shown in FIG. The curve in Fig. 2 represents the course of the first differential quotient or the first derivative of the curve in Fig. 1. If a capacitor is connected in series with a suitable resistor to the secondary winding of the transformer, the current flowing through the resistor changes according to 3. The curve in FIG. 3 is the first derivative of the curve in FIG. 2 and thus the second derivative of the curve in FIG. 1. The peaks UA, UB or IA, IB can actuate a switch which indicates that the bar magnet has attracted its armature. The rush current IC in Fig. 3 is through

809.677 / 94

Eddy currents and charging currents of the winding capacities cause and occur at the time of connection. However, if the bar magnet has a large pole pin and small movement, the. Peaks UA and IA disappear, the circuits in FIG. 1 and the voltage curve in FIG. 2 having the form drawn in dashed lines. Therefore, a device according to FIG. 4 will first be described, which is based on the current pulse IB . Current pulses IB 3 arise when the armature of the bar magnet hits the core of the bar magnet The voltage induced in the secondary winding of the transformer in FIG. 2 changes from the value UA to the value UB over a very short period of time.

In Fig. 4, A is a telephone set and L is one with a line relay Li? and a switch rail or bridge for coordinate switches provided line, the switching or bridge magnet BR and its spring sets a, b, c are shown in the figure. The rod magnets of the crossbar are; with Ml, MZ ... M 10. In addition, a trunk circuit SN and an identification device D are provided. The identification device consists of the relays Dl ... DlO for marking the tens and the relays Ul ... UlO for marking the units and of relays Fl ... FlO for selecting an unoccupied connecting line circuit. A switching device consisting of the transformer T, the discharge tube GL and the relays Kl and K 2 is available to control the operation of the bar magnets Ml ... MIO. The discharge tube GL receives an initial ionization from a current source VF via a resistor r3 and has a bias voltage on the ignition electrode from a current source VG via the resistors r 1 and r2. As shown in the figure, no sets of springs are required on the bar magnets.

When calling from the apparatus ^ the line relay LR responds. Contacts 11 and 12 are actuated. The contacts 12 of the line relays, which belong to a tens number, are connected to one another. Relay D1 is excited via contacts 12 and 403 and picks up. Contacts 101 to 105 are actuated. Each contact 11 of the line triangle in the decimal number is connected to the contacts 104 and 105 of the decimal relay Dl . The relays DIl and FlO respond in the following circuits: From plus via contact 103, the winding of relay D 11 to minus or via contacts 395 ... 305, 424 ... 303, the winding of relay FlO, the contact 31 to minus. The contact 31 is closed when the connecting line circuit SN is unoccupied. Contacts 400 to 403 and 301 to 306 are actuated. The relay Dl is then kept energized via the contact 101. The relay JV 2 in the connecting line circuit SN pulls in one. Circle via contact ¹ at 306. Contact 32 is closed and relay N 3 picks up . Contact 33 is closed. The relays Ul to UlO form a relay chain in which only one relay can pick up at a time. The relay Ul works at the same time as the relay FlO in the following circuit: From plus via the contacts 201 ... 291, ... the contact 203, the upper and lower winding of the relay U1, the contacts 104 and U, the winding of the Shift solenoid BR to minus. The upper winding of the unity relays U1 to U 10 has such a high resistance that the switching magnet BR cannot pull in series with it.

Contact 301 closes before contact 302. The following two circuits are formed:

a) from plus via contact 301, the winding, relay K1 to minus and

b) from plus via contact 301, the lower winding of the "transformer T _1, contact 302, the bar magnet M 10 to minus.

The relay K1 picks up, and the contacts 411 and 412 are actuated, the discharge tube GL being interposed. During the actuation of the relay Kl , the current surge IC in FIG. 3 and possibly current surges caused by contact vibrations in the contacts 301 and 302 have time to pass through the contact .412 without actuating the discharge tube GL. The current through the lower coil of the transformer T decreases in accordance with Fig. 1 to, and the current through the upper coil of this transformer passes through the rectifier B ₁ charges the capacitor C. When the bar magnet M 10 attracts its armature M 10A , the increase in current ceases and is generally reversed into a decrease in the current IA (FIG. 3), whereupon there is a rapid change in a current surge IB , which runs through the resistor R and causes capacitor C to discharge. The voltage drop across the resistor R ignites the ignition path of the discharge tube GL, after which the main path is ignited and a circuit is formed through the upper winding of the relay K 2 and the contacts 400, 422 and 401. Contacts 421 to 424 are operated. The relay K2 is kept energized by its lower winding via contacts 411, 421 and 401. The bridge or switching magnet BR responds in the following circuit: From plus via contacts 423 and 204, the lower winding of relay U 1, which has a low resistance, contacts 104 and 11, the winding of switching magnet BR to minus. The contacts 21, 22 and a, b, c are actuated. The line relay LR drops its armature and the identifier D becomes free. The shift solenoid BR is kept energized; the relay Nl picks up in a circuit via the contacts 33 and c . The feed relay N2 is held in a circuit via the contacts a, b, the line L and the apparatus A.

The task of the resistor r4, which bridges the lower winding of the transformer T , is to effect the damping of the vibrations which easily arise when the contact 412 is actuated.

5 shows an embodiment of the invention in which the voltage peak UA in FIG. 2 actuates a switching device which consists of a transistor 6 ″ and a relay K2 and replaces the discharge tube GL and the relay K 2 in FIG 4, a battery VA is connected to the switching device through the contact 400 on the relay DIl. The selector relay FlO switches the bar magnet AfIO in series with the lower winding of the transformer T by means of the contacts 301 and 302. During the actuation of a relay Kl should If present, contact shocks are ended, the relay connecting the transistor 5 ″ to the upper winding of the transformer T. At rest, the emitter of the transistor receives a negative bias from a battery VF.

When the current through - the bar magnet MIO and the lower winding of the transformer T increases, a voltage is induced in the upper transformer winding. This tension causes

a current through the rectifier £ and therefore does not operate the transistor. When the bar magnet MIO attracts its armature, the direction of the voltage in the upper winding of the transformer T is changed. The rectifier E does not allow any current in this direction, but the voltage UA in Fig. 2 changes the bias voltage at the emitter of the transistor, so that a current through the contact 411 through the lower winding of the relay K 2 and through the emitter of the transistor arises. As a result, a circuit is closed from the battery VA via the contacts 400 and 422, the battery VF, the transistor VS "and the upper winding of the relay K 2. The current through the upper winding of the relay K 2 induces a voltage in the lower winding of relay K2, and this voltage increases the current in the emitter circuit and thus causes negative feedback. The current density through the transistor and the upper winding of relay K 2 increases rapidly, so that the armature of relay K 2 is attracted to 423 are actuated, the transistor being switched off and the relay i? 2 being kept energized via the contact 421. The switching magnet BR in the crossbar switch operates in a circuit, which is shown in FIG.

Claims (4)

Patent claims: 1. Circuit arrangement for actuating the bar and bridge magnets of crossbar selectors by a marking device in telecommunications, in particular telephone systems, characterized by a switching device assigned to the marking device (D; Fig. 4, 5) in which electronic switching means (GL, S) , Relay (K2) and a transformer (T) are provided and which interacts with the marking device and the switching magnet of the crossbar selector that the primary winding of the transformer is connected in series with the winding of the rod magnet (MIO) to be operated and the secondary winding of this transformer with the electronic switching means and relays is connected so that the electronic switching means are effective by the induction surge in the winding of the bar magnet when its armature pulls up (M 10 ^ 4) and the resulting induction surge in the primary winding of the transformer, in order to operate the relay (K2) , which in turn sets the circuit for the B back magnet (BR) closes. 2. Circuit arrangement according to claim 1, characterized by a capacitor and a Resistors connected in series and connected to the secondary winding of the transformer and through a discharge tube with an ignition gap parallel to the resistor and ignited by the voltage drop across the resistor during the induction surge and characterized in that the relay is in series with the main line of the discharge tube is switched. 3. Circuit arrangement according to claim 2, characterized by an auxiliary relay (Kl) which prevents the effect of the inrush current through the bar magnet on the discharge tube, and by a rectifier which is connected in parallel to the resistor and the ignition path and prevents the ignition of the ignition path, when the current decreases during armature pull of the bar magnet. 4. Circuit arrangement according to claim 1, characterized in that a transistor amplifier is provided, the input of which is connected to the secondary winding of the transformer, and that the relay with a first winding connected to the output of the amplifier and with a second winding contained in the input circuit of the transistor is provided, the Polarity of the second winding is changed so that an amplifying feedback from the Output to the input of the transistor amplifier is obtained when the current in the first relay winding is increased, and that finally a rectifier is provided which connected across the secondary winding of the transformer and the feedback current lets through, but blocks a current surge that is passed through the transformer to the input of the transistor occurs when this current surge occurs due to a current decrease in the primary winding of the transformer is produced. 1 sheet of drawings ©. TO 677/94 10.