DE1119387B - Contactless control device for bypass generators, especially for motor vehicles - Google Patents

Description

Contactless control device for bypass generators, in particular for motor vehicles The invention relates to a contactless control device for shunt generators, preferably for vehicle alternators, in the one switched on in the excitation circuit of the generator of a second transistor Transistor is controlled, the base of which is connected to the voltage to be regulated and whose Output power partly on its input circuit to generate self-excited Oscillations are fed back, according to patent 1095 923, for alternators, whose output terminals are connected to a battery via rectifiers.

According to the invention it is proposed in the connecting line an output terminal of the generator with its associated rectifier, the primary winding turn on a current transformer, its secondary winding with a first resistor is loaded, which is connected with its one end to one pole of the battery is, the first resistor with a voltage divider from a second resistor and a conductor with a strongly kinked current-voltage kink characteristic bridge and finally to the tap of the voltage divider one of the control electrodes of the second transistor to be connected.

In the drawing are the circuit diagrams of two exemplary embodiments of the subject matter of the invention.

The three-phase generator denoted by 10 in FIG. 1 serves as an alternator for a motor vehicle; it is driven by the motor vehicle engine, not shown. The output terminals of the generator 10 are connected to a rectifier arrangement 11 , the positive output terminal of which is connected to the positive terminal via the positive lead denoted by 12 and the negative output terminal of which is connected to the negative terminal of a battery 14 via the negative lead denoted by 13. The field winding 15 of the generator 10 is connected in series with the emitter-collector path of a power transistor 16 between the plus and minus lines. To regulate the excitation current flowing through the field winding 15, the base Bi of the power transistor 16 is controlled by a control transistor 17, which is switched so that it generates self-excited electrical oscillations as soon as the output voltage of the generator 10 or the current it delivers exceeds a permissible maximum value. As a result of these oscillations, the power transistor 16 is blocked for a shorter or longer period of time and the current flow through the field winding 15 is prevented.

To generate the electrical oscillations, a transformer with three windings 18, 19 and 20 designed in the same direction is switched on in the collector circuit of the control transistor 17. Of these windings, the winding 18 forms the primary side, the winding 19 the secondary side of the transformer, while the winding 20 serves as a feedback winding. One end of the primary winding 18 is connected to the collector K2 of the control transistor 17, and the other end is connected to the negative line 13 to which one end of the feedback winding 20 is also connected. The other end of the feedback winding 20 is connected to the base B2 of the control transistor 17 via a fixed resistor 21 and a potentiometer 22. The base B2 is also connected via a further potentiometer 23 to the tap of a voltage divider, which is formed from a resistor 24 and a diode 25 with a strongly kinked current-voltage characteristic. This voltage divider bridges a resistor 26, which represents the load on the secondary side of a current transformer 27. The primary side of this current transformer 27 is connected to the connecting line between an output terminal of the generator 10 and the rectifier arrangement 11.

One end of the resistor 26 is connected to the positive line 12. The resistor 24 of the voltage divider is also connected to this end. That the other free end of the resistor 26 is connected to the cathode of the diode 25. Of the Emitter E2 of the control transistor 17 is connected to a voltage divider which is between the positive line 12 and the negative line 13 is connected. This voltage divider consists of a diode 28, which has a strongly kinked characteristic curve and between the positive line 12 and the emitter E2, and a resistor 29 between the emitter E2 and the negative line 13. The voltage divider ensures a constant, independent of the fluctuations in the terminal voltage of the rectifier arrangement 11 negative emitter bias.

The secondary winding 19 of the transformer has a center tap on the positive line 12, while the two ends each lead via a diode 30 or 31 to the base Bi of the power transistor 16. The base Bi is also connected to the positive line 12 via a capacitor 32 and to the negative line 13 via a resistor 33.

The switching arm 34 of a relay 35 is switched on in the positive line 12. The winding of the relay 35, to which a capacitor 36 is connected in parallel, is connected to the output terminals of a rectifier-Graetz circuit 37, the input terminals of which are connected to two output terminals of the generator 10 . The switching arm 34 serves as a reverse current switch and is closed as soon as a certain minimum voltage is generated by the generator 10.

The mode of operation of the control device can easily be overlooked, if one assumes that the voltage U supplied by the generator is increasing is understood and the potentiometers 22 and 23 are set so that the resistor 24 and at the potentiometer 23 falling partial voltage when the target voltage is reached the base B2 at the same potential as the negatively biased emitter electrode E2 of transistor 17 brings. This makes the transistor 17 conductive, and it sets a collector current J2, which in the feedback winding 20 is indicated by the arrow Uz indicated voltage induced. This voltage U2 is directed so that it the Base Bz of transistor 17 is even more negative than emitter electrode E2 power. There is therefore a strongly increasing base current (the maximum value of which is due to the size of the induced voltage Uz and the size of the resistors 21 and 22 are given is) and consequently a rapidly increasing collector current 1 is generated. The ones from Collector current J2 during its rise induced voltage U2 only changes little. However, the collector current soon reaches its maximum value, which is caused by the Maximum value of the base current fb and the construction data of the transistor is fixed. When this maximum value has been set, the one in the feedback windings disappears induced voltage U2, and the potential of the base electrode B2 jumps to one higher value, so that the base current Jb is no longer at the previous level can be sustained. This also reduces the collector current fb. The inductance of the primary winding 18 acts on this change in the collector current against and and generates a voltage pulse, which in the drawing is marked with an in voltage arrow U2 is indicated by broken lines. Through this Voltage pulse, the transistor 17 is completely switched to the non-conductive state, in which it is held until the voltage pulse Uz has decayed. then the game described can start again until the voltage U is again Target value reached.

Since the voltages U2 and U2 generated in the feedback winding 20 as a result of the changes in the collector current J2 act on the potential of the base electrode B2 and thus on the input circuit of the transistor 17 in the sense of amplifying these changes, a self-excited electrical oscillation occurs in which the transistor 17 between an operating state with high and an operating state with low collector current J2 tilts back and forth in the manner of a monostable blocking oscillator, as often as the increasing generator voltage has risen to the setpoint set on potentiometers 22 and 23.

The same time with the voltage pulses U2 and U2 'in the secondary winding 19 generated voltage pulses U3 and U3 'are via the rectifiers 30 and 31 given to the capacitor 32, the size of the time constant of the alternator is adapted. Each of the voltage surges U3 and U3 causes the potential of the Base Bi is briefly raised and the transistor 16, the excitation current J, strong throttles, which lowers the alternator voltage. The drop in the alternator voltage below the setpoint has the consequence that the transistor 17 remains blocked for so long and therefore no alternator voltage lowering pulses on the transistor 16 is able to give until the alternator returns to its nominal voltage has excited. This process is repeated in quick succession in the one described Way, as long as the load current JL has the value zero (or a constant value).

To avoid overloading the alternator due to excessive consumer currents To avoid this, the circuit connected to the current transformer 27 is provided. At the resistor 26, which is kept low, creates a flow of current in the primary winding proportional and rectified in the full-wave rectifier 38 Voltage Ui. The polarity of the full-wave rectifier 38 is such that the potential of the free end of the resistor 26 negative with respect to the positive pole of the battery 14 will. The voltage Ui forms the input voltage for the resistor 24 and the diode 25 formed voltage divider. The voltage characteristic of this Diode 25 has a forward voltage drop of approximately 0.3 volts sharp kink. As long as the voltage drop across the diode 25 is less than the knee voltage remains, the base potential of the control transistor 17 is practically not of that Current transformer affected. In this case, namely, flows through the resistor 24 essentially only the current for the voltage divider formed from elements 20 to 23. If, however, the voltage drop across the diode 25 exceeds the knee voltage, then it is at the tap of the voltage divider practically all the voltage across the resistor 26 in the secondary circuit of the current transformer 27 drops. Because the voltage drop on the Even with relatively large currents, diode 25 is only insignificantly larger than the knee voltage. The base potential of the control transistor 17 is thereby lowered and the control transistor conductive. It thus in turn generates self-excited vibrations in the manner described above Art.

The embodiment according to FIG. 2 differs from the embodiment according to Fig. 1 only through the input circuit of the control transistor 17. The switching elements that remain the same are therefore identical in FIGS. 1 and 2 Reference numerals denoted.

The base Bz of the control transistor 17 is connected to the tap of a first Voltage divider connected, which consists of a resistor 40, a potentiometer 41 and the feedback winding 20 and via a Zener diode 42 with the Tap of a second voltage divider is connected. This second voltage divider is formed from resistors 43 and 44. Both voltage dividers are between the plus and minus lines switched. The emitter E2 of the control transistor 17 is connected at the tap of the voltage divider, which consists of the resistor 24 and the diode 25 is formed and the resistor 26 bridges. One end of the resistor 26 is connected in this circuit to the anode of the diode 25, and the full-wave rectifier 38 in the secondary circuit of the current transformer 27 is polarized such that the potential that end of the resistor 26 is positive with respect to the positive potential of the battery 14 will.

The mode of operation of the voltage regulation in this exemplary embodiment can be overlooked if one assumes that the switching arm 34 is held open, so that no consumer current can flow.

The potentiometer 41 of the first voltage divider is set in such a way that the base potential of the control transistor 17 remains more positive than the emitter potential even in the event that the output voltage of the generator exceeds the desired value. Under the assumption made above, the emitter potential is only determined by the voltage drop caused by the quiescent transistor current across resistor 24. The potentiometer 44 of the second voltage divider, on the other hand, is set in such a way that its Zener voltage drops across the Zener diode 42 when the output voltage of the generator reaches the setpoint. Then the Zener diode 42 becomes conductive and the base current of the control transistor 17 can flow through it. With this, however, the control transistor becomes conductive and generates self-excited blocking oscillations.

If, on the other hand, the switching arm 34 is closed so that a load current flows, the emitter potential is no longer determined by the voltage drop across the resistor 24, but rather by the voltage drop U across the resistor 26 in the secondary circuit of the current transformer 27.If it exceeds the quiescent current across the resistor 24 caused by the transistor caused voltage drop by more than the amount of the knee voltage of the diode 25, then this goes from its high-resistance to its low-resistance state. As a result, the emitter potential of the control transistor 17 is raised and can become more positive than the base potential established by the first voltage divider. As a result, the control transistor also becomes conductive and causes the self-excitation of the blocking oscillations.

Claims (5)

PATENT CLAIMS: 1. Contactless voltage regulating device for shunt generators, preferably for vehicle alternators, in which a in the excitation circuit of the Generator switched on transistor is controlled by a second transistor, the basis of which is the voltage to be regulated and its output power to the Part fed back to its input circuit to generate self-excited vibrations is, according to patent 1,095,923, for alternators whose output terminals are above Rectifiers are connected to a battery, characterized in that in the connection line of an output terminal of the generator with its associated Rectifier, the primary winding of a current transformer (27) is switched on, whose Secondary winding is loaded with a first resistor (26) with its one End is connected to one pole of the battery (14) that the first resistor (26) from a voltage divider made up of a second resistor (24) and a current conductor (25) is bridged with a strongly kinked current-voltage kink characteristic and that finally to the tap of the voltage divider one of the control electrodes of the second transistor (17) is connected. 2. Control device according to claim 1, characterized in that at least one rectifier in the secondary circuit of the current transformer (38) is arranged and that the first and second resistor each with one end are connected to the positive terminal of the battery. 3. Control device according to claim 2, characterized in that the positive end of the first resistor (26) with the The positive pole of the battery is connected and that the base of the second transistor (17) connected to the tap of the voltage divider via a further resistor (23) is. 4. Control device according to claim 2, characterized in that the negative The end of the first resistor (26) is connected to the positive terminal of the battery and that the emitter of the second transistor (17) to the tap of the voltage divider (24, 25) is connected. 5. Control device according to claim 4, characterized in that the base of the second transistor (17) is connected to the cathode of a Zener diode (42), the anode of which is at the tap of a second voltage divider (43, 44) which is connected between the plus and negative line is switched.