DE1487940A1 - Circuit arrangement for telecommunications, in particular telephone systems for the optional actuation of switching means - Google Patents

Description

Circuit arrangement for telecommunications, in particular telephone systems for optional actuation of switching means.

-------------------------------------- The .Erfindung relates to a circuit arrangement for telecommunications, in particular telephone systems for the actuation of formwork elements with the help of the energy that can be stored in capacitors. Such arrangements are used zD when the ap location of the switching means maximum available power due to unavoidable resistances (eg the line resistance of a telecommunications line) is less than the power required to operate the switching means. It has already been proposed that the discharge circuits of the capacitors be under the. To provide switching influence, preferably electronic switching devices, which in turn can be controlled via the same connection terminals that are also used to charge the capacitors. The proposed arrangement also allows two groups of switching means, which are arranged in the discharge circuits of two capacitors, to be operated independently of one another via the same pair of connection terminals, viennäic charging circuits of the capacitors by means of current direction-dependent switching elements in such a way against one another. :: "are v-coupled so that they can be charged alternatively by different power lines. The invention has set itself the task of improving the proposed arrangements and reducing their complexity. It relates in particular to a circuit arrangement at the switching means arranged in the discharge circuits of capacitors can be activated optionally with the help of the energy that can be stored in these capacitors s = r_d, where the capacitors are mutually dependent on different current directions and / or through different current directions in switching elements that are dependent on the current direction Coupled circuits can be charged independently of one another and is characterized in that the said ?: discharge circuits are combined in a washing-like manner with the help of further current-direction-dependent decoupling means that they run over a branch that is always flowed through in the same direction and that in this branch a switching device is inserted, which can be controlled in their conductive state by lowering or increasing the voltage applied to the respective connection terminals and the charging current circuit @ of the respective capacitors. The invention therefore makes it possible to control the actuating circuits for a plurality of switching means with the aid of a single switching device. A further development of the invention proposes that the circuits, which run between two connection terminals and are decoupled from one another with the aid of current-direction-dependent switching elements, in which two capacitors can be charged independently of one another by different current directions, are combined in a mesh-like manner that two capacitor assignments that can be charged with the same charge are connected to one another. Such a combination of the two charging circuits means that the cost of decoupling means can be kept low: If - as another development of the invention suggests - an electrically bistable two-pole, i.e. a diode with ignition voltage characteristics, is used as the switching device to control the discharge circuits , the arrangement can be made so that each of the two capacitors, which are permanently interconnected with one of their assignments, have a uniform which is impermeable to the direction of its charging area. Richter is bridged that the connection point of the two capacitors is connected to one electrode of the electrically bistable two-pole and that its other electrode is connected to the other assignments of the two capacitors via a decoupling rectifier and the respective switching means to be operated. In order to operate the switching means arranged in the discharge circuit of a capacitor, the latter is charged by a DC voltage of suitable polarity, namely up to a value which is lower than the ignition voltage of the electrically bistable two-terminal network. This is then ignited with a voltage pulse of a suitable size, but in any direction, and thus switches on the discharge circuit running via the switching means to be actuated. It is also possible to connect the two capacitors one after the other by means of different polarized DC voltages or by a. Charging AC voltage at the same time and actuating the switching means assigned to them at the same time by means of a voltage pulse which causes the ignition of the electrically bistable two-terminal network. So that the mentioned voltage pulse can now reach the electrodes of the electrically bistable two-terminal network unhindered, another development of the invention recommends connecting a preferably inductive resistor to the charging circuit of at least one of the two capacitors. This prevents the impulse from being overturned by the capacitance of the capacitor in question. If the switching means to be operated in the discharge circuits are electromagnetic relays, it is also possible to connect their windings or part of them in series with the capacitors if the response value is greater than the maximum charging current of the capacitors or if the relays are polarized, that is, cannot be actuated by a current that has the direction of the charging current of the capacitor in question.

Another development of the invention is characterized in that that said switching device is a switching element equipped with a control input (e.g. a transistor or a relay), which becomes effective during charging one or more capacitors through the front one or more into the charging circuits Rectifiers inserted in these capacitors had a low-resistance bridging effect its control input or due to the voltage drop occurring at these rectifiers is prevented. Such an arrangement can be designed, for example, so that the two connecting clamps are provided with straw circles for independent charging two capacitors are combined in the manner of a bridge circuit., whose first bridge branch from the two. capacitors connected in series with each other, the second branch of the fruit consisting of two with opposite polarity. uucinander in Series connected rectifiers, each of these rectifiers for the charging current of the respectively adjacent capacitor is impermeable and its Diagonal branch one for the charging currents of the two capacitors in the forward direction Contains polarized rectifier. The voltage appearing on this rectifier can be used as a control variable for the * in the common branch of the discharge circuits of the Switching devices inserted in both capacitors are used: If as Switching device namely a triode a transistor or a thyristor) is used and its control electrode -with the electrode facing away from the two capacitors of the rectifier inserted in the DiagAal branch is connected, the Svoltage drop causes which occurs at this rectifier during the flow of the charging current Blocking the Tricde. If, however, after the capacitor has been charged, the external voltage is lowered, a reverse voltage occurs at the: rectifier on, which is polarized in such a way that the triode is controlled in its conductive state. If the DC voltage feeding the charging circuits of the capacitors does not is reduced but switched off, a suitable control current or a control voltage can be used via high-ohmic resistance. related to the charged capacitors will.

If a large number of bridge circuits of the beschriereger. Art provided is, in whose over different Anscl: luEskler..men two 'capacitors through different Strorrichtüngen charged independently of each other t ,, erdeil 'äcr: r_en, so russ be sure that the inserted into the common discharge branch Switching device is always blocked if at least one capacitor charged, d.lz. at least one of the rectifiers inserted in the individual diagoral branches is stressed in the forward direction. According to a development of the invention this through it. causes the rectifier with their co-naming electrodes Via decoupling means preloaded in the forward direction, each with a collecting line are connected and that these two manifolds - to the control input (e.g. the bitter-base path) of the switching device (e.g. a transistor). This ensures that the rectifiers stressed in the forward direction occurring voltage drop as reverse voltage to the switching device "z: eitergegebcn" will.

In the drawings are some embodiments of the invention shown, from which further details can be deduced. In the. Circuits According to FIGS. 1 to 3, two switching means S1 and S2 are shown as relays are and in the, .Discharge circuits of the capacitors C1 and 02, respectively, where the Condensate can be charged independently of one another via the pair of terminals a and b are.

Connects rn-an. in the scarf @ uung after rig. 1 the terminal a with the negative and the terminal b with the: positive pole of a DC voltage source, the capacitor C1 in the straw path a, 5, 112 017 2, b, in which the two rectifiers 5 and 2 are polarized in the forward direction, charged. Its discharge circuit, in which the switching means S1 is to be excited and which runs via the rectifier 3 and the four-layer diode YD, is switched on by a voltage pulse being fed to the connection terminals: raen a and b, the amplitude of which is sufficient to ignite the To effect four-layer diode. This voltage pulse can have any polarity; it always reaches the electrodes of the four-layer diode with the "correct" polarity, since this is in the diagonal line of a rectifier bridge circuit in relation to the two connection agents a and b. Causing the two capacitors 01 and 02 overall in series switched inductors eine'Phasenverschiebung between the terminals A and B applied voltage and the current flowing in the respective capacitor current and thereby allow the Srannungsippuls daso unhindered to the four-layer diode pass through can. If voltage pulses of the same polarity are always used to ignite the four-layer diode * -v: ground, it is of course sufficient to provide only one inductance (e.g._D2). The four-layer diode VD can then be ignited by a positive pulse applied to the connection terminal a in the current branch a, 1, S2, VD, 4, 6, b. If both switching means S1 and S2 are to be operated simultaneously, then both capacitors C1 and C2 must either be charged one after the other by differently polarized DC voltages that are lower than the ignition voltage of the four-layer diode or by an alternating voltage whose amplitude is also smaller than this ignition voltage . The two discharge circuits are then switched on simultaneously by a voltage pulse that causes the four-layer diode to ignite.

In the circuit shown in Fig. 2, the two capacitors 01 and C2 are in the Stronz @. "E: #gen (-), a, 5, Cl g 1, 2, b, (+) or, (+) 7 11 19 021 62 b2 (-) independently of one another. In a common branch of their discharge circuits, a four-layer diode VD is also provided as in the circuit according to Rectifier bridge consisting of rectifiers 1 to 6. The inductance 1 ensures that this voltage pulse is retained by the two capacitors C1 and C2 and can reach the electrodes of the four-layer diode VD without hindrance be bridged 7, the two capacitors is only permeable for the direction of Fntladestromes. In the circuit of Fig. 3 are the Entladestronkreise of the two capacitors 01 and 02 under the Schalteinf Flow of a transistor: T. As long as one of the two capacitors C1 or 02 is charged, is this transistor due to the voltage drop at the rectifier--? he 5, which is inserted into a common branch of the two charging toroidal circuits and bridges its emitter-basia route, is blocked. However, as soon as the charging voltage applied to the connecting terminals a and b is switched off, the base of the transistor is connected to the negative via the resistor R1 or R2. Occupancy of the capacitor, which has been charged in the meantime, in connection. It reaches its conductive state and thus switches on a discharge circuit for the respective capacitor. Curse with this circuit, the two shifters S1 and S2 can be operated at the same time, if. bothc. Capacitors are charged one after the other by different currents. However, you have to Care must be taken that with. the reverse polarity of Ia.de- the transistor T does not prematurely enter its voltage has reached a conductive state. This can be done in a simple manner e.g. through. a rectifier 5 connected in parallel the capacitor of a suitably dimensioned capacitance be prevented. The circuit according to Fig. 4 has a number of connections closing a1 to an over which the capacitors C1 to Cn charged independently of each other. can be with the counter potential of the contact line b. to be led. The discharge tower circuits of all capacitors are via the decoupling equation: jumper 11 to n1 sarr .: collected and run through the transistor T. So- long one or more of the capacitors C1 to ON charged and the equator in ricl: tion is claimed, the transistor is through the SFannun.csabfall blocked on this rectifier. To- successful charging, call the rectifier in his Locked state reached, ': poor of the positive assignments, of the loaded cords via the relevant resistances R1 to Rn S control torrent to the base of the sistors T fli, esser_. The circuit shown in Fig. 5 is similar to the circuit device according to Fig.A, but it contains four capacitors, C11, C12, C21 and 022, which can be charged independently of one another via the connection terminals a1., a2 and b. The discharge circuits of these capacitors, i3. which the individual switching means S11, S12, S21 and S22 are arranged, run across the four-layer diode VD. The charging voltage of the individual capacitors should again be lower than the ignition voltage of the four-layer diode and, after charging, it should be triggered by an arbitrarily polarized voltage pulse via one of the inputs a1 or a2. As in the circuit according to FIG. 2, the inductance 11 and 1.2 allow this voltage pulse to reach the electrodes of the four-layer diode unhindered, ie without being fed by the capacitors in question.

In the circuit according to FIG. G, the two capacitors 011 and C12 can be charged independently of one another by means of different current directions via the pair of terminals a1 and b1 and the capacitors C21 and C22 via the pair of terminals a2 and b2. A transistor i is inserted into a common Zihrer discharge circuit which is blocked while one of the capacitors is being charged by the voltage drop occurring at the rectifier 15 or 25. Nominally after charging, the voltage supplying the charging circuit is switched off, this rectifier goes into its blocking state and the transistor flows from the low-earthing of the charged capacitor to a suitable control current, through which it becomes conductive with low ears.

Finally, FIG. 7 shows a circuit which allows any number of capacitors to be charged independently in advance of one another and to control their charging circuits via a transistor which is assigned to them in common. In contrast to the circuit according to FIG. 6, in which each of the .Anschlussklei 4en a1 and a2 has a terminal b1. bz @@ r. b2 assigned to the supply of the counter potential iss - this arises from the need for the charging circuits of the individual capacitors - all of which with their. positive, assignments are firmly connected to each other, to be separated from each other - there is such a restriction in the. 7 do not hold: all connection terminals. a1, a2, ... is the terminal adhesive b for supplying the counter potential in common! assigned. The charging circuits for the individual capacitors are constructed in the same way as in the & circuit according to Frg. 3. * so ap 3 the capacitor C11 can be charged via the connection terminal a1 by a positive voltage, while the condenser Bator Cte via the same connection terminal from a negative ven voltage can be charged. As long as one of the Capacitors are charged, is located either the rectifier 15 or the rectifier 25 in his Pure cl: let alone. The electrodes on its electrodes emerging voltage is transmitted via the decoupling rectifier ter 16 and 17 or 26 and 27 and the veins se and ab the Fnitter-Easis path of the transistor T is supplied and locks it. For this it is necessary that the Decoupling rectifier 16 and 17 or. 26 and 27 in their on-state so that they can get to the Electrodes of rectifiers 15 and 25 prevailing potential tial tZw. a corresponding potential difference to the Veins sb or se z: pus yield ki:, rnen, d. H . During the Au'- charge a capacitor, the relevant discharge nopplungsgleichricl: ter, e.g. 16 and 17 in transparency tuug be biased. This happens, for example, in the following Strov circuits: If the capacitor Q11 via the connection klenme a1 charged t.rird, so runs from the positive i elegun g this capacitor a circuit over the Lntk cpplungsgleichr icnter 13, the switching means S11, the Resistor R and the decoupling rectifier 17 to be a negative evaluation. Another circuit runs also from the positive assignment of capacitor 0119 de .. Resistor R11, the decoupling rectifier 16 and the rectifier 12 to the connection block b. Hence, are found during the charging of the capacitor Cif the two P-coupling rectifiers 16 and 17 in their ". Through the state of the laser and can eire the voltage drop to the rectifier 15 corresponding potential difference als.back voltage to the control path of the transistor i pass on. Since the charging circuits for the condenser Sators G`12 and C11 in relation to the two connection hlenr-en a1 and b are completely symmetrical, the Decoupling rectifiers 16 and 17 in analog power ~ - circling biased, t-tenn the capacitor 012 open- will load. The discharge circuit for the charged charged capacitors will be turned on again when the rectifiers 15 bzt @ ;. 25 by sending or: switch the voltage supplying the charging circuit get into their., i lock state. Because can namely from the positive occupancies of the jevreils charged con capacitors. via the relevant: resistors R11 bis R22 control current flow to the base of transistor i, its middle via the decoupling gauges 17 bzu. 27 with the negative assignments of the relevant condensate are connected.

Claims (1)

P atent claims ----------------- ----------- 1. Circuit arrangement for Fernnelde- in particular telephone systems, in which switching means arranged in the Entladestronkreisen of capacitors : 2. with the help of the energy storable in these capacitors 1iahlireise can be actuated, whereby the capacitors can be charged independently of one another by different current directions via different connection terminals and / or in circuits decoupled from each other by current direction dependent switching elements st-omrici @ t @ ngsabLöngiger decoupling means are combined in such a mesh-like manner that they are connected via a discharge gate belonging to them ger_einaart. always run in the same direction traversed branch and that in this branch a switching device is inserted, which by lowering or increasing the to the respective. Terminal clamps applied and the charging circuits of the capacitors in question feeding voltage can be controlled in their conductive state. 2. Circuit arrangement according to claim 1, characterized in that the lit running between two connection terminals with the aid of current-direction-dependent switching elements decoupled from one another, in which two capacitors can be charged independently of one another by different current directions, are combined in such a way that two capacitors of the same name can be charged are firmly connected to each other. 3. Sclialtu. "" Gsanordrung according to claim 1 or 2, characterized in that said switching device is a Dicde with ignition voltage characteristics (eg a Glimnlanpe). . 4. Circuit arrangement according to claim 2 and 3, characterized in that each of the two with one of their assignments firmly together me2lgeschal te th Kendensa tones of one? rectifier impermeable for the direction of its charging current is bridged and that the connection point of the two capacitors is connected to an electrode of a diode with ignition voltage characteristics, the other electrode of which is connected via each. a decoupling rectifier and the switching means to be actuated is connected to the other assignments of the two capacitors. . 5. Circuit arrangement according to one of claims 3 and 4, marked by the fact that in the charging circuit at least one of the two capacitors is a preferred wise inductive resistance is inserted. 6. Circuit arrangement according to claim 1 or 2, characterized characterized in that said switching device a switching element equipped with a control input ment (e.g. a transistor or a relay) is whose kfirkamw'erdeii during the flow of charging Stron for one or more capacitors by the by one or more in the charging circuits of these Capacitors inserted rectifier caused low-resistance bridging of his regret or fear, due to the occurring on these rectifiers Voltage drop is prevented. 7. Circuit arrangement according to claim 6, characterized geken3.- shows that the two cynical connecting clergy ongoing. Circuits for independent. Charge two Ke_: capacitors form a bridge circuit, whose first bridges # - # @. tear off the two. with each other in he switched capacitors, 'desei = zr; eiter Brtickere- branch from zz .; egg with opposite folurgy in series connected rectifiers, what each of the Sch rectifier for the charging current of the jei-reils. adjacent capacitor is impermeable, and its diagonal pipe one. for the charging currents of the two condensers polarized in the flow direction th rectifier contains. Circuit arrangement according to claim 7, characterized in that shows that the connection point of the two - the capacitors formed one end of the diagonal branch with the cathode b-zw. deri emitter of a triode (4.E. cold cathode tube or a transistor) is connected, whose anode or collector via each a decoupling rectifier and each to actuating switching means with your other: assignments of the two capacitors and its control electrode with the aI: their end of the diagonal: ciges in verbis - dung steepens u @: d that the mentioned Tricde by the dctl in the diagonal section; cig inserted @leic: ^. richter t. when lowering the low voltage occurring reverse voltage i =: his leading state is controllable. 9. Circuit arrangement according to claim 7, characterized draws that one h1 such a bridge signal services provided: rather is in which ever üZ'ici Kender_satoren can be charged independently of one another by different directions of current, dasw those in the diagonal. rectifiers contained in these bridge circuits with their electrodes of the same name are each connected to a collecting line via decoupling means preloaded in the forward direction and that these two collecting lines to the control input (e.g. the emitter-base line) of the in the common branch of the% ntladestromkreise all capacitors inserted switching device JB of a transistor) lead. 10. Circuit arrangement according to. Claim or 9, characterized in that the capacitor assignments facing the respective connection terminals are connected via high-impedance resistors to the control electrode of the circuit switching device inserted in the common branch of their discharge current circuits.