DE3333631A1 - Circuit arrangement for supplying an oscillating-armature motor - Google Patents

Abstract

The invention relates to a transistor switch for switching an inductive load, especially the inductance of an oscillating-armature motor, and consists of two transistors whose load paths are connected in series with the inductance and of two diodes, which are likewise connected in series with the inductance, in the opposite direction, and are connected in parallel with a supplying DC voltage source or a rectified AC voltage source. The transistors are driven directly or via an additional transistor or the load path of the other transistor from a pulse generator, preferably a square-wave generator, the energy which is stored in the inductance during the phases when the transistors are switched off flowing back into the supplying DC voltage source or an input capacitor which is connected in parallel with the supplying DC voltage source. The circuit arrangement makes it possible to dimension the active components to a blocking voltage which is slightly higher than the supplying DC voltage.

Description

Circuit arrangement for feeding a vibrating armature

motors Description The invention relates to a circuit arrangement for feeding a vibrating armature motor from a DC voltage source or rectified AC voltage source via a single-ended transistor converter with two transistors operated in the same mode and controlled by a pulse generator, their load paths are connected to one another via the inductance of the oscillating armature motor and are each connected to a terminal of the DC voltage source and with two cross-connected diodes, each anti-parallel to the series connection the load path of one of the two transistors and the inductance are connected.

For operating small electrical devices, especially electrical ones Vibrating armature motors used for dry shavers consist of one in one alternating magnetic field oscillating armature with a mechanical Energy storage, in particular a spring is connected. The alternating magnetic field is generated by inductances or coils connected to an alternating voltage, wherein the frequency of the oscillating armature depends on the frequency of the feeding AC voltage source depends.

Because of the dependence on a feeding AC voltage source is a network-independent operation of a vibrating armature motor or a supply off a DC voltage network or an accumulator with the known circuits is not possible.

There are transistor switches for inductive loads knows in which according to FIG. 1, the load path of a transistor 20 in series with a first Inductance 21 parallel to a DC voltage source or a parallel to DC voltage source switched capacitor 24 is connected. Also in parallel to the capacitor 24 is the series connection of a fixed to the first inductance 21 coupled second inductance 22 is connected to a diode 23. The base of the switching transistor 20 is controlled by a pulse generator, wherein different depending on the on or off state of the transistor Direction of current flow through the two inductors that are magnetically tightly coupled to one another 21 22 result. While in the on state of the transistor 20, the current from the DC voltage source via the first inductance 21 and the load path of the transistor 20 flows back to the DC voltage source, the current flow direction is when switched off Transistor 20 via the diode 23 and the second inductance 22 back into the battery given. This makes it possible that when the transistor is blocked, the inductance stored magnetic energy returned to the DC voltage source. Because of the energy-storing effect of the inductance is, however, the maximum am The reverse voltage occurring in the transistor or the diode is twice the operating DC voltage. The transistor or the diode must be dimensioned accordingly.

A second circuit arrangement for switching an inductive load by means of a transistor switch is shown in Fig. 2 and also exists from a load path of a transistor connected in series to form an inductance 25 20, which run parallel to a DC voltage voltage source or an input capacitor 24 are switched. The series connection of a diode is parallel to the inductance 25 26 with the parallel connection of a capacitor 27 and a resistor 28 is provided. When the transistor 20 is switched on, the current flows from the DC voltage source via the inductance and the load path of the transistor back to the DC voltage source, while in the blocked state of the transistor 20, the current through the inductance 25, the diode 26 and the resistor 28 flows.

This known circuit arrangement therefore requires a corresponding one Dimensioning of both the transistor 20 and the diode 26 to double DC voltage significant losses because the inductance 25 of the stored energy does not flow back into the battery but essentially in the resistor 28 is converted into heat.

From the reference "Siemens: Technical communication from the area Components - Switching Power Supplies 1, General Introduction, Basic Circuits ", pages 9 and 10, a single-ended converter with two transistors is known, both of which are the load paths two transistors of the same conductivity type with one between the two load paths of the transistors connected primary winding of a transformer to a feeding DC voltage source are connected. There are two crossed diodes on the cathode or anode side with one or the other connection of the primary winding of the transformer on the one hand and on the anode or cathode side with the one or connected to the other pole of the DC voltage source. The transistors are clocked in the same way controlled via another transformer, both of which Secondary windings are connected in parallel to the base-emitter path of the transistors.

The two cross-connected diodes of the known circuit arrangement cause the transistor blocking voltages to be retained at the level of the supply voltage, so that no higher reverse voltages on the transistors than those of the supply voltage may occur. Because of the switched between the load paths of the transistors The primary winding of the transformer cannot be essential when the transistors are switched on Cross currents flow so that the energy stored in the transformer is blocked Transistors essentially across the secondary winding of the transformer into the connected load can flow away. This known circuit arrangement, however, has the transformer not as the actual load but as a transmission link for the supply a load connected to the secondary winding of the transformer opens and closes in addition, the disadvantage that to avoid cross currents accordingly fast diodes must be used and the control of the transistors via a separate transformer must be used.

The object of the present invention is to provide a circuit arrangement to supply a vibrating armature motor from a DC voltage source, with no dimensioning of the active components on one opposite the feeding DC voltage much higher voltage is required, which no circuitry Includes conditional losses and in which a separate control of the active Components required via a transformer or transformer is.

According to the invention, this object is achieved in that two transistors different conductivity type are provided and the base of the first transistor directly and the base of the second transistor via a third transistor or is connected to the pulse generator via the load path of the first transistor.

The solution according to the invention enables a vibrating armature motor to be operated from a DC voltage source and thus a network-independent operation or

operation independent of the frequency of an alternating voltage network to be fed and ensures that the transistors or diodes used are not on one opposite the supply voltage source must be designed with a significantly higher operating voltage. In addition, no potential-separated control of the transistors is required, and no circuit-related losses have to be accepted.

The basic principle of the circuit arrangement according to the invention is true corresponds to the basic principle of the known single-ended transistor converter, but serves the known circuit arrangement not for feeding an inductance such as, for example the inductance of a vibrating armature motor or the like. but an alternating voltage consumer, via the output transformer depending on the clock frequency of the transistors is supplied.

An advantageous embodiment of the solution according to the invention is thereby characterized in that the load path of the third transistor in series with two resistors is connected in parallel to the DC voltage source and that the base of the second Transistor is connected to the junction of the two resistors or that the base of the second transistor is connected to the junction of two resistors is that in series with the load path of the first transistor parallel to the DC voltage source are switched.

These configurations of the solution according to the invention enable a direct, galvanic control of the control electrodes of the transistors without Interconnection of transformers with separate secondary windings, whereby a Saving of components is ensured and an absolutely uniform control of the two switching transistors takes place.

Based on an embodiment shown in the drawing the idea on which the invention is based are explained in more detail. They show: Fig. 1 and 2 known circuit arrangements for switching an inductive load; Fig. 3 shows a first exemplary embodiment for a transistor switch with two transistors different conductivity types and a control of one of the two transistors Via an additional transistor and FIG. 4, a second exemplary embodiment for Switching inductive loads with two transistors of different conductivity types without additional transistor and direct control by means of a square wave generator.

The circuit arrangement shown in Fig. 3 consists of a a track voltage source UB connected bridge circuit with two on opposite Diagonals of the bridge circuit arranged load paths of two transistors 1, 2 as well as two diodes 3, 4 arranged in the other bridge diagonals, which are polarized in this way are that they correspond to the direction of current flow of the load path in each case connected in series Transistor are opposite. In the bridge diagonal there is an inductive one Load 5 arranged, which in the preferred embodiments from the coil of a Oscillating armature motor exists. In the present exemplary embodiment, there is the first Transistor from an NPN transistor whose collector connects to the anode of the first diode 3 and its emitter with the negative pole or ground connection of the DC voltage source UB is connected. The second transistor 2 consists of a PNP transistor whose Emitter with the positive connection of the DC voltage source and its collector is connected to the cathode of the second diode 4, the anode of which in turn is connected to the negative Connection or ground connection of the DC voltage source UB is connected.

The base of the first transistor 1 is through a first resistor 13 with the output of a pulse generator, preferably a square wave generator tied together.

In parallel with the base-emitter path of the first transistor 1 is a third diode 11 with cathode-side connection to the base of the first transistor 1 switched.

The base of the second transistor 2 is connected to the connection of a second Resistance 9 with a third Resistor 10 connected that in series with the load path of a third transistor 7 in parallel with the feeding DC voltage source UB are switched. The base of the third transistor 7 is through a fourth resistor 14 also connected to the pulse generator 6. In addition, it is parallel to the base-emitter path of the third transistor 7, a fourth diode 12 with a cathode-side connection the base of the third transistor 7 is provided.

An input capacitor is parallel to the feeding DC voltage source UB 8 provided, in the case of a rectified AC voltage as a smoothing capacitor serves.

Since the transistors 1, 2 are operated in common mode, the switched on state of the transistors 1, 2 the current from the feeding direct voltage source UB or the input capacitor 8 via the load path of the second transistor 2, the inductance 5 and the load path of the first transistor 1 back into the DC voltage source UB or in the input capacitor 8. When the transistors 1, 2 are switched off the voltage across the inductance 5 changes so that the diodes 3, 4 become conductive and the current from the inductor 5 via the first diode 3, the input capacitor 8 or

the DC voltage source UB and the second diode 4 back into the Inductance 5 flows. This ensures that the in the inductance 5 stored energy in the feeding DC voltage source UB or

the input capacitor 8 flows back.

In the conductive state of the transistors 1, 2 only falls on them the collector-emitter saturation voltage voltage UCEsat so that the Voltage at the inductance 5 UL = UB - 2 (UCEsat), where UL is the voltage at the inductance 5 and UB is the voltage of the feeding direct voltage source.

If the transistors 1, 2 are blocked, the voltages are applied to them UCE = UB + Uf or UcE = 0 - Uf an, where Uf is the voltage drop across the diodes 3, 4 is in the conductive state.

This means that the voltage across the inductance is 5 UL = UB + 2 Uf Will the transistor switch according to the invention, for example, on a rectified 220 volt AC mains operated, so is a dimensioning of the transistors 1, 2 and the diodes 3, 4 to a maximum reverse voltage of 400 volts is completely sufficient, transistors and diodes with such a reverse voltage are commercially available and are available inexpensively.

A variant of the solution according to the invention shown in FIG. 4 consists analogously to the embodiment according to FIG. 3 from one to one feeding DC voltage.

source or an input capacitor connected bridge circuit with two load sections each arranged in opposite bridge branches two transit interfere 1, 2 of different conductivity types and two diodes 3, 4 arranged in the remaining bridge branches with one of the arrangement corresponding polarity according to FIG. 3.

In the bridge diagonal, there is also an inductance 8 as a load preferably a coil of a vibrating armature motor is arranged.

In a modification of the circuit arrangement according to FIG. 3, this Circuit arrangement, however, no additional transistor required, since the control of the second transistor 2 directly via the load path of the first transistor 1 takes place. For this purpose, the collector is designed as an NPN transistor first transistor 1, a fifth resistor 15 connected in series with the load path of the first transistor 1 and a sixth resistor 16 in parallel with the input capacitor 8 is switched. The base of the second transistor 2 is connected to the connection of the fifth and sixth resistor 15, 16 connected.

If the base of the first transistor 1 via a resistor 13 of a pulse generator 6 is driven, the collector of the first transistor 1 of the NPN type pulled to ground or reference potential, which is a corresponding control of the second transistor 2 of the PNP type via the fifth resistor 15. Through this Both transistors 1, 2 are controlled in the conductive state and a current flows through the inductance 5 serving as a load.

In the blocking state of the two transistors 1, 2 flows analogously to the previous one described embodiment of the in- follow the voltage reversal at the inductance 5 resulting current through the diodes 3, 4 into the feeding DC voltage source or the input capacitor 8 back.

The circuit arrangement according to FIG. 4 includes compliance with the the same advantages as the circuit arrangement according to FIG. 3, an additional saving of components, besides a saving of an additional transistor, whereby only one connected in parallel to the base-emitter path of the first transistor 1 Diode 11 is required.

Claims (5)

Claims Circuit arrangement for feeding a vibrating armature & circuit arrangement motors from a DC voltage source or rectified AC voltage source via a single-ended transistor transformer with two in common mode operated by one Pulse generator controlled transistors, their load paths through the inductance of the oscillating armature motor are connected to one another and to one connection each of the DC voltage source are connected and with two cross-connected diodes, each in antiparallel -for series connection of the load path of one of the two transistors and the inductance are switched, characterized in that two transistors (1, 2) different Conductivity type are provided and the base of the first transistor (1) directly and the base of the second transistor (2) via a third transistor (7) or connected to the pulse generator (6) via the load path of the first transistor (1) is. 2. Circuit arrangement according to claim 1, characterized in that the load path of the third transistor (7) in series with two resistors (9, 10) is connected in parallel to the DC voltage source (UB) and that the base of the second Transistor (2) is connected to the junction of the two resistors (9, 10). 3. Circuit arrangement according to claim 1, characterized in that the base of the second transistor (1) to the connection of two resistors (15, 16) is connected in series with the load path of the first transistor (1) in parallel are connected to the DC voltage source (UB). 4. Circuit arrangement according to one of claims 1 to 3, characterized in that that the first transistor (1) is an NPN type transistor and the second transistor (2) is a PNP type transistor. 5. Circuit arrangement according to claim 2 or 3, characterized in that that parallel to the base-emitter path of the first transistor (1) a third diode (11) and parallel to the base-emitter path of the third transistor (7) a fourth Diode (12) is switched.