DE2440765A1 - Current supply unit for subscriber station - with input in a subscriber line and output to deliver a constant voltage of a specifieeeeeiied polarity - Google Patents

Abstract

The unit generates from the voltage drop at its input, irrespective of its polarity, and delivers a steady voltage for operation of an additional unit, such as charge meters and quasi-key dialling equipment. It has two transistors, a transformer and a rectifier at the transformer output. At the input (2, 4) the two transistors (T1, T2) of opposite conduction types are connected in parallel. The junction point is between the two bases, and either collectors or emitters are connected to the transformer (U) primary winding (W1, W2) ends (B, C). A tapping (A) of the primary windings is connected to one input terminal (4) of the current supply unit, and the emitters or collectors are connected to the other input terminal (2). A capacitor (K) between input terminals (2, 4) shorts out oscillations or speech frequencies.

Description

Power supply device The invention relates to a power supply device according to the preamble of claim 1.

A power supply device of the type mentioned is largely known (see DT-OS 2 058 701 of June 15, 1972, German class 21 a3, 76/01). The known power supply device is in particular a polarity-independent one Circuit for telephone stations with charge indicator, with two voltage converters each with one bipolar transistor of the same conductivity type, one transformer with five windings, two diodes on the secondary side of the transformer and finally two resistors are provided.

In this known power supply device are in particular disadvantageous is the high number of windings of the transformer, and their direction of winding must be observed, as well as the two resistors including adjacent ones separate capacitors and the lack of stability of the power supply device, especially with large loop currents through the telephone set.

In particular, the large number of windings, resistors and capacitors complicates an extensive implementation of the power supply device as an integrated Circuit as it is especially for telephone subscriber stations from space and Maintenance reasons is desirable.

It is therefore the object of the invention to provide a power supply device of the type mentioned at the beginning, which have less discrete transformer windings, Resistors and capacitors gets by, also works more stably and finally generates a relatively small voltage drop at its input terminals, so that the live electrical line to which it is connected, if possible is little influenced.

According to the invention, this object is achieved by the teaching of the label of claim 1 solved.

In the power supply device according to the invention, the transformer only two windings, namely a primary and a secondary winding, are furthermore no resistors at all and only one capacitor is provided. The voltage drop at the input terminals is also particularly low, which is not least due to the omission of resistances is conditional. The inversely operated three-electrode semiconductor component exercises at different currents in the live line, e.g. B. when using for a telephone subscriber station of loop currents of 20-60 mA, a stabilizing Effect on the secondary voltage of the transformer, including the parallel connection of the two three-electrode semiconductor components and being the limiting factor Effect independent of the winding ratio of the transformer list, but more precise will be explained.

It goes without saying that the power supply device according to the invention not only for telephone subscriber stations, but generally for remote control systems is applicable, e.g. B. also for so-called prefix meter.

In addition, another use case is that of the invention Power supply device for solar cells conceivable, their output voltage with 0.4 V is also very small and, for example in mobile use, is independent of polarity should be connected (see e.g. DT-Zeitschrift Elektronik, 1969, issue 3, P. 73).

The three-electrode semiconductor components can, for. B. bipolar, but also be field effect transistors, in the latter case it is z. B. to one n- and a p-channel field effect transistor.

The capacitor provided according to the invention at the input terminals of the power supply device is just like the phase rotation by 1800 by the Base winding of the transformer is useful for operating the power supply unit. In contrast, there is still a single one in the DT-OS 2 o58 701 mentioned at the beginning capacitor present, but there it serves as a storage capacitor and is connected to the output of the power supply device. According to the DT-PS 1 291 797 dated November 20, 1969, German class 21a3, 76/01, is just one more Capacitor at the input of a non-polarity-independent circuit arrangement for as Roller counters trained fee counters at stations in Ferninelde-, in particular Telephone systems became known, but this capacitor is only used for bridging identified by voice frequencies.

The invention is advantageously further developed by the teaching of claim 2.

Anti-parallel diodes have already become known in this context, But not for overvoltage protection. According to DT-PS 1 291 797, the forward voltage dropping across one diode is processed further while the other diode takes on a protective function when the polarity is reversed. In the DT-OS 2 o58 701, on the other hand, is via the anti-parallel connection of the diodes, whereby depending on the polarity the voltage at the terminals one or the other diode in the forward direction is operated, the operating voltage for the transistor oscillator in one or other voltage converter removed.

The invention is explained in more detail with reference to the drawing.

1 shows an application example of the power supply device according to the invention in a telephone subscriber station; and FIG. 2 shows a detailed exemplary embodiment the power supply device according to the invention for the application of Fig. 1.

In telephone subscriber stations are more and more electronic Additional devices such as billing meters or quasi-touch dialing devices through the Loop current fed to the telephone subscriber station itself. For this purpose (cf.

Fig. 1) a power supply device in the form of a six-pole SP between the exchange line with wires a and b and the actual subscriber circuit TS looped in, whereby the six-pole SP is used for the operation of an additional device ZE provides the required supply voltage U, v. The polarity of the supply voltage Uv must always be the same and independent of the polarity of the wires a and b be the flowing loop current Is.

According to the invention, FIG. 2 shows a parallel connection of an npn transistor T1 and a pnp transistor T2, each with their collectors C, the bases B and the emitters E are connected in parallel. In addition, the primary winding is W1 a transformer Ü galvanically connected to the control winding W2 for the B bases. The winding tap A is located at one end 4 of the split a or b-wire, while the other end 2 is led to the emitter E. With the input terminals 4 and 2, a capacitor K is connected to the switching voltage peaks of the voltage converter short-circuit and create a low-resistance path for the alternating voice voltage. The voltage of the secondary winding W3 of the transformer Ü is made with a diode bridge rectifier G1 is rectified and represents the supply voltage Uv for the additional device (not shown in Fig. 2) available.

Depending on the direction of the loop current Is, the npn transistor is T1 or the pnp transistor T2 in use and forms with the transformer U a current-voltage converter.

The voltage U42, which occurs between the input terminals 4 and 2 at the current-voltage converter, depends on the base-emitter voltage UBE and the collector-emitter residual voltage UCE of the working transistor as well as the number of turns W1 and W2 of the primary or Control winding as follows: The inverse transistor has a stabilizing effect on the secondary voltage of the transformer U with different loop currents, which in practice can fluctuate between Is = (20 ... 60) mA. Because if UBE increases with higher loop currents, then in the blocking phase the voltage of the primary side UcB = UBE - UCE (2) r exceeds the forward voltage of the base-collector diode of the parallel-connected transistor, which then goes into inverse operation and loads the primary winding . As equation (2) shows, the use of the limitation is independent of the ratio of the number of turns.

From the largest base-emitter voltage UBEmax occurring in the forward phase and the voltage UBEmin required in the blocking phase to block the active transistor, the number of turns ratio is as follows: Between the input terminals 4 and 2 parallel to the capacitor K, an identification resistor (not shown) and the parallel connection of anti-parallel diodes (not shown) can be provided to protect the circuit from incoming high voltage pulses. According to equation (1), loop current Is 5 does not, or almost no, flow through these protective diodes.

The power supply of Fig. 2 operates in detail as follows follows: The loop current Is of the telephone subscriber station flows from the input terminal 4 to the center tap A of the transformer Ü and from there through the primary winding W1 to the connection point C of the collectors of the two transistors T1 and T2. at With the transistor T1 switched through, it is the path to the connection point E of the two emitters and for input terminal 2 free. The current Is flowing through the winding W1 is induced in the base winding W2 the voltage UBA, which for a given base-emitter voltage UBEmax of the switched-through transistor T1 determining which is at the input terminals 4 and 2 forming voltage U42 = UBEmax - UBA (4).

The switching process to block the transistor T1 is then initiated, when the transformer Ü approaches its magnetic saturation and therefore the Voltage UBA decreases. The transistor T1 changes from being overdriven to being active Range, and its residual voltage UCE increases. As this increases the tension on the Primary winding W decreases, the voltage UBA also decreases further.

Through this feedback process, the transistor T1 is quickly blocked, and all voltages on the windings of the transformer U oscillate because of stray capacitances to reverse polarity. The base-emitter voltage UBEmin according to UBEmin = U42 - UBA (5) is below the lock voltage of the base-emitter path of the Transistor T1. This means that it remains blocked. The voltage U42 at the input terminals 4 and 2 is during the blocking phase of the transistor T1 by the capacitor K approximately kept constant.

The bridge rectifier is on the secondary side of the transformer 8 Gl arranged to win the DC supply voltage Uv. Instead, could also a push-pull rectifier with two diodes and a secondary winding Center tap be provided. A bridge or push-pull rectification is required, as it depends on the direction of flow of the loop current through the primary winding W1 a bipolar voltage occurs across the secondary winding W3. In addition, energy can be fed into the secondary circuit during the flow and blocking phases of the converter be transmitted.

When the loop current reaches a certain size, it can be in the blocking phase of the transistor T1, the voltage UcB at the primary windings W1 and W2 of the transformer Ü is the forward voltage of the collector-base path of the transistor connected in parallel Exceed T2.

As a result, it goes into inverse operation, i.e. H.

The collector and emitter interchange their function. That also flows in the blocking phase a certain proportion of the loop current Is through the voltage transformer, while the rest of the capacitor K is taken up. Due to the inverse operation part of the magnetic energy stored in the core of the transformer U is dissipated, which is thus lost to the secondary side. As a result, the loop current increases Is the efficiency of the converter from, but since the connected to the secondary side Consumers normally have a constant power requirement, this means one approximately constant power output despite different loop currents Is dependent power consumption.

If the loop current Is has the reversed direction of flow, since the wires a and b were connected in reverse, the two transistors T1 and T2 their function.

Claims (4)

Claims 1. Power supply device, the input of which is in an external current-carrying electrical line, in particular a wire of a telecommunication line, in particular a telephone subscriber line, and that from the voltage drop at the input regardless of its sign a DC voltage of constant sign is generated, in particular for power supply an additional device such as charge meter, quasi-touch dialing device or the like a telecommunications system, in particular a subscriber station; with two three-electrode semiconductor components such as transistors, a transformer and one on its output side, unit of directional conductors connected to the output of the power supply device like diodes; characterized in that a parallel connection at the input (2, 4) of the two three-electrode semiconductor components (T1s T2) is located; that the three-electrode semiconductor components (T1, T2) have a different conductivity type; that the connection point of the second electrodes of the two three-electrode semiconductor components on the one hand and the first or third electrodes of the two three-electrode semiconductor components on the other hand with one or the other end (B; C) of the primary side (W1, W2) of the transformer (Ü) are connected; that a tap (A) of the Primary side (W1, W2) to one input terminal (4) of the power supply device and the first or third electrodes of the two not led to the primary side Three-electrode semiconductor components connected to the other input terminal (2) are; and that at the input terminals (2, 4) a capacitor (x) for short-circuiting of vibration and possibly speech frequency. 2. Power supply device according to claim 1, characterized in that that parallel to the input (2, 4) two anti-parallel diodes to protect the power supply against overvoltages and / or an identification resistor are connected or is. 3. Power supply device according to claim 1 or 2, characterized in that that the unit of directional conductors is a diode rectifier bridge (G1). 4. Power supply device according to claim 1 or 2, characterized in that that the unit of directional conductors is a push-pull circuit with two diodes, where the secondary winding of the transformer is provided with a center tap.