DE1538315B2 - SEMI-CONDUCTOR VOLTAGE REGULATOR FOR AN AC GENERATOR DRIVEN AT VARIABLE SPEED - Google Patents

Description

The invention relates to a variable speed semiconductor voltage regulator Drivable alternator that feeds a direct current network via a rectifier set, with one in series with the field winding of the alternator on its control electrode controllable rectifier that can be switched on and off, the control electrode of which is connected via a voltage divider a positive potential compared to its cathode and additionally with a switching arrangement is connected to generate the switch-off pulses.

From the Japanese patent specification 40-9170 (1965) such a regulator with a controllable semiconductor rectifier is known in which the semiconductor rectifier can be switched on by means of a DC voltage and can be switched off by means of a switching pulse on the control electrode. The switch-off pulse is in this known semiconductor voltage regulator, however, obtained via a transistor, which in turn is conductively controlled by the generator output voltage via a Zener diode. The control characteristic this arrangement is therefore not only strongly dependent on the temperature, but also on the Component tolerances; in addition, the regulation does not work very precisely. Such regulators are indeed Sufficient for many purposes, but sufficient to

3 4

requirements where there is a need for the constancy of the winding of the feedback transformer DC voltage higher requirements are placed Zener diode. It stabilizes the tension so that the. In particular, this applies in the event that the changing operating voltages have no effect DC network no backup battery is provided to have the behavior of the controller. In addition, the the voltage of the Zener diode as a comparison voltage in the event of load changes or load shutdowns. A particularly simple, non-linear network is grounded. It then has to be expensive to smooth out the temperature, because it is designed as a Zener diode fixed capacitors are used. From the japa- is whose input electrode is connected to one of the voltage of the Niche patent 40-4982 (1965) a regulator DC network proportional DC voltage is known, in which to switch off the excitation current io is closed, while its output electrode with a controllable rectifier is used. The cable is connected to the positive pole of the DC voltage source method of this controllable rectifier becomes a positive.

tive pulse supplied so that the control current is no longer a particular for generators with heavy loads can continue to flow. At the same time, the fluctuations on the direct current side also become suitable The anode potential of the controllable rectifier is negative made so that the working current of the thyristor is made by that it is designed as a second transistor, stors is interrupted. In this known arrangement, the input electrode is connected to one of the voltage of the voltage is a blocking oscillator for controlling the direct current network proportional direct voltage controllable Used rectifier; the non-conductor is closed while its output electrode is with A controllable rectifier has to be made at the other end of the second winding of the back yoke a high circuit complexity related to the coupling transformer. In Episode. From the British patent specification 967 539 a connection with the parallel to the series connection of Semiconductor voltage regulator with one across the emitter-collector path of the transistor and the Control electrode on and off switchable semiconductor one winding of the feedback transformer rectifier known. The switching off of the half-lying Zener diode works this arrangement as ladder rectifier is not done with the help of a switching non-linear network and is at the same time against overpulse, but protected by a connection with the voltages.

Ground line. This arrangement has a substantial decrease in the residual voltage drop between emitters lower control steepness than an arrangement with and collector of the second transistor to compensate-pulse control. 30 ren, is advantageously between the output electrode, the object of the invention is to create a simply constructed second transistor and the base of the first tranbauten, precisely working semiconductor voltage transistor a diode is arranged. She prevents that to show greed. Blocking oscillator already oscillates when the span according to the invention If there is an input on the direct current network, this is not yet set The semiconductor voltage regulator has reached the setpoint value as a result.

It is sufficient that the circuit arrangement for generating the circuit arrangement has several

Switch-off impulses have a blocking oscillator. Advantages, including the possibility of using

holds, the voltage to start above a certain target voltage and the possibility of the

on the direct current network with an increasing excitation current continuously from a maximum to

voltage oscillates with increasing frequency, and to be able to adjust its output 40 to the value zero, namely with

gear over a preferably two-way rectifier a very simply constructed arrangement that with

the rectifier designed in a mid-point circuit requires a small number of components,

on the one hand with the cathode and on the other hand with the

The control electrode of the controllable rectifier is insensitive to the gene and does not require an expensive tempe connection stands. 45 heat-resistant capacitor for smoothing the output

The voltage regulator is advantageously designed to have the same voltage as the known regulators of this

det that the blocking oscillator is known in itself. Type of construction is the case.

ter way a feedback transformer with more details and appropriate training

having an output winding. fertilize the invention result from the in the Furthermore, it is advantageous to use the voltage regulator 50 drawing illustrated embodiments. It

designed so that the voltage divider points over the Aus

output winding of the blocking oscillator and via F i g. 1 shows the circuit diagram of an inventive

a diode of the rectifier connected to this semiconductor voltage regulator in conjunction with a

three-phase alternating current generator with the cathode of the controllable rectifier, is bound. 55 Fig. 2 and 3 diagrams to explain the effec-

According to a further feature of the invention, the voltage regulator according to FIG. 1 and

The voltage regulator is constructed in such a way that the reverse Fig. 4 corresponds to the circuit diagram of a voltage regulator.

coupling transformer having a first winding up F i g. 1 in a simplified design,

has that in the emitter-collector circuit of a first The circuit arrangement shown in FIG Transistor lies, and has a second winding, 60 shows an alternating current generator 10 with a three-

the one end with the base of this transiphase, star-connected winding 11 and

stors and at its other end to the output of a shunt field winding 12. The latter can

a non-linear network is connected, be rotating, while the winding 11 as a stator

the output voltage of which is a function of the voltage winding, but it is also an opposite of the direct current network. 65 returned arrangement conceivable. It is essential that the

The accuracy of the regulator is thereby further increased output voltage of the alternator

improved that parallel to the series connection of Emit over the excitation current in the field winding 12 controlled

ter-colector path of the transistor and one of them.

The winding 11 is connected to a rectifier set (three-phase bridge rectifier) 13, the consists of six semiconductor diodes. Its output terminals are connected to a plus line 14 and a minus line 15 connected, which together form a direct current network to which a consumer may be connected 16 and a buffer battery 19 can be connected via terminals 17, 18. However, it is a The advantage of the present circuit arrangement is that it can be put into operation even without such a backup battery and can be used, even with large load fluctuations.

In parallel with the field winding 12 there is a diode 22 to prevent voltage peaks in the event of an interruption of the excitation current. One end of the field winding 12 is connected to the positive line 14, while the other end to the anode of a controllable rectifier 23 and one pole of a switch 24 is connected, the switching state of which depends on the voltage of the direct current network, as follows will be explained. Its other pole is via a resistor 25, the resistance value of which is smaller than that of the field winding 12 is connected to the negative line 15, with which the cathode of the controllable rectifier 23 via a fuse 26 is in connection.

The controllable rectifier 23 is of a type which is positive with respect to the cathode potential Potential of its control electrode conductive and with a negative compared to the cathode potential Potential of its control electrode is blocked. Such rectifiers are among other things under the designation "Gate controlled switch" in stores.

The switching state of the controllable rectifier 23 is controlled by a voltage regulator 27, the has the task of maintaining the voltage between the positive line 14 and the negative line 15 at a constant To hold value that can be set on a potentiometer arm 28 of a potentiometer 29, which is in series with two fixed resistors 32, 33 between the lines 14 and 15.

The voltage regulator 27 consists essentially of a first npn transistor 34, which together forms a blocking oscillator with a feedback transformer denoted by 35, and a second npn transistor 36, which together with one of the voltage stabilization Zener diode 37 forms a non-linear network. The output of the voltage regulator 27 is an inductive one to the transformer 35 coupled output winding 38, the midpoint rectifier circuit is switched. The inductive coupling is indicated by a dashed line 39. The output voltage this rectifier 53, 54 serves to convert the controllable rectifier 23 into the non-conductive Control state, the more often and longer, the higher the voltage between the lines 14 and 15 increases.

In detail, the voltage regulator 27 is constructed as follows: The base is on the potentiometer arm 28 of the transistor 36 and the cathode of a protective diode 42, the anode of which is connected to a line 43 is connected to the emitters of transistors 34 and 36, the anode of a second protective diode 44 and the Zener diode 37 and the tapping of a voltage divider consisting of two resistors 45, 46, which lies between the lines 14 and 15, is connected. The Zener diode 37 is used to increase the potential the line 43 to keep stable with respect to that of the positive line 14, so that the two transistors 34 and 36 work with constant operating voltage.

The collector of transistor 34 is connected to the positive line via a first winding 47 of transformer 35 14 connected, while its base with the cathode of the protection diode 44 and the cathode of a Compensation diode 48 is connected, the anode of which via a second winding 49 of the transformer 35 is connected to the collector of transistor 36, which in turn has a collector resistor 50 is on the positive line 14.

A tap 52 of the output winding 38 is connected to the negative line 15 and thus the cathode of the controllable rectifier 23 connected, while her one winding end 51 at the cathode of a rectifier diode 53 and its other winding end 59 is connected to the cathode of a rectifier diode 54. The anodes of the two diodes 53 and 54 are connected to one another and to the control electrode via a resistor 55 of the controllable rectifier 23, from which a resistor 56 leads to the positive line 14. . The control winding 57 of a relay labeled 58 is located between the lines 14 and 15; it is so set that it opens the switch 24 at a voltage value that is just below the desired Setpoint voltage between lines 14 and 15 is located. (The circuit is for the alternator at rest and a battery voltage is shown, which corresponds to a heavily discharged backup battery).

For the explanation of the mode of operation it is assumed that the backup battery 13 is not connected and that the alternator 10 starts up from a standstill. Then there is initially no tension between the lines 14 and 15, so that the controllable rectifier 23 does not initially have a positive Can receive signal at its control electrode and remains blocked. Through him, then, can also

4P no excitation current to flow field winding 12 when the alternator 10 due to the magnetic Retentivity emits a small voltage. Self-excitation of the alternator 10 via the controllable rectifier 23 is therefore not possible (

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To remedy this situation, the switch 24 is provided, which is closed at low voltages so that an excitation current can flow through it to the field winding 12 and the alternating current generator 10 can excite itself. A sufficient voltage then arises between the lines 14 and 15 and a current flows from the positive line 14 via the resistors 56 and 55, the diodes 53 and 54 and the output winding 38 to the negative line 15. This gives the control electrode of the controllable rectifier 23 a positive voltage to the cathode. This tension is shown in FIG. 2 in the top row labeled _{M 20.}

When a certain voltage is reached on

Direct current network between the lines 14 and 15, the control winding 57 opens the switch 24, so that the excitation current now only through the controllable rectifier, which has now become conductive 23 is controlled.

If a short circuit occurs in the field winding 12, the excitation current becomes too large and the fuse 26 responds, whereby the excitation current is interrupted and the voltage between the lines

gen 14 and 15 decreases after an e-function until the relay 58 turns the switch 24 on again. To get in In this case, to limit the short-circuit current via the switch 24, the resistor 25 is provided. Its resistance value should be below that of the field winding 12 so that the self-excitation is not impaired will.

As long as the voltage between lines 14 and 15 is below the desired value (setpoint), the transistor 36 is conductive because its base is positive with respect to its emitter. There his collector then is approximately at the potential of the line 43 and this potential via the second winding 49 and the compensation diode 48 is also at the base of transistor 34, the latter transistor is blocked. The rest The voltage drop between the emitter and collector of the transistor 36 is caused by the compensation diode 48 compensated, so that in this state the transistor 34 is safely blocked and does not oscillate can. As stated above, the controllable rectifier 23 is conductive in this state and it can be a Excitation current flow.

The protection diodes 42 and 44 are used to route the base-emitter the transistors 34 and 36 to protect against overvoltages, such as when switching off larger loads, especially inductive loads, can occur.

If the voltage between lines 14 and 15 is greater than the desired value (setpoint), then the base of transistor 36 more negative, so that it conducts less and its collector - and thus also the Base of transistor 34 - becomes more positive. Through the emitter-collector path of the transistor 34 and the First winding 47, a current flows which induces a voltage in the second winding 49, which the Base of transistor 34 makes it even more positive, and this process increases until the collector current has reached its maximum. Then no more voltage is induced in the second winding 49, and the base voltage becomes more negative again, as a result of which the collector current also becomes smaller again, which The base voltage becomes further negative via winding 49, until transistor 34 again, locks. He remains in this locked position the shorter, the more positive the collector of transistor 36 is, and then repeats what has just been described Swing process.

With each oscillation process, when the current increases in the output winding 38, a first half-wave is generated and when the current decreases, an oppositely polarized second half-wave is generated. After rectification by the midpoint rectifier circuit 38, 52, 53, 54, these two half-waves result in the one shown in FIG. 2 in the top row. The first half-wave is designated here with 61 and the second half-wave with 62. After the rectification, both are negative and have the effect that the potential of the control electrode is temporarily more negative than the cathode potential of the controllable rectifier 23, so that it is blocked during this time. The voltage U ₂ between its anode and its cathode rises during this time to approximately the value of the voltage between lines 14 and 15, like that in the lower row of FIG. 2 is shown.

The more the voltage between the lines 14 and 15 is the desired on the potentiometer arm 28 exceeds the set value, the closer the oscillations of the blocking oscillator (Transi disturb 34 and transformer 35) on each other until they see that in FIG. 3 shows where the Potentu the control electrode is permanently more negative than the cathode (Fig. 3, top row), so that the controllable Rectifier 23 no longer conducts at all (Fig.? Bottom row). In this case the voltage drops between the lines 14 and 15 very quickly again to the desired value.

ίο In F i g. 4 is a circuit arrangement shown which works in the same way as that in FIG. 1 shown, but mainly for operation with Pui remote battery is intended. However, it can also be operated without a backup battery if the Las; changes or shutdowns occurring exercises; tensions below a certain allowable who stay.

Since the structure of the circuit arrangement naci F i g. 4 similar to that of FIG. 1 is, were fü identical or similar parts identical reference numerals ver turns.

In addition to the bridge rectifier 13, a three-phase exciter rectifier 65 is provided here see, at the output of which the anode of the controllable rectifier 23 is connected, the cathode of which is connected to one end of the field winding 12; the other end of the field winding 12 is on de Minus line 15. Between the plus line 14 and the anode of the controllable rectifier 23 is "a" Charge indicator lamp 66, which lights up as long as the alternator 10 is insufficiently charged voltage supplies.

The voltage regulator is shown in FIG. 4 denoted by 27 'and consists essentially of a pnp tran sistor 67, which together with a 68 denote th feedback transformer has a blocking oscillation Forms an oscillator, which together with a Zener diode 69, which serve as a non-linear network As the output of the controller 27 'is an output winding 72 of the transformer 68, which is in the middle point rectifier circuit is switched. From output voltage of the associated rectifier 75, 7 is used to control the controllable rectifier 23 in de to control the non-conductive state, the more frequently and longer, the higher the voltage between the lines 14 and 15 increases.

In detail, the rectifier circuit is similar; like the one according to FIG. 1 trained. A tap Fung 73 of the output winding 72 is connected to the cathode of the controllable rectifier 23, while rend her one winding end 74 at the cathode a rectifier diode 75 and her other winding ^ end 76 at the cathode of a rectifier diode 7 '. lies. The anodes of both diodes 75 and 77 are with each other and through the resistor 55 with the control electrode of the controllable rectifier 23 verbun the; they are also connected to a smoothing capacitor 78 with one of the layers whose covering is connected to the tap 73. Ei is used at the output of the diodes 75, 77 the voltage to smooth.

The emitter of transistor 67 is connected to the Pluslei device 14; its collector is via a first winding 7 ' of the feedback transformer 68 and a KoI lector resistance 80 with the negative line 15 verbur den, while its base via a resistor 8 and a second winding 82 to the cathode d < Zener diode 69 and a connection of a resistor

209 536Π

des 83 is connected, the other terminal of which is connected to the positive line 14. The anode of the zener diode 69 is connected to the potentiometer arm 28 and one surface of a capacitor 84, the other surface of which is on the positive line 14.

The arrangement according to FIG. 4 works as follows: As long as the voltage between lines 14 and 15 does not exceed a setpoint voltage which can be set on the potentiometer arm 28, the Zener diode 69 is not conductive and the base of the transistor 67 is at the potential of the positive line 14, so that no base current flows and the transistor 67 is blocked. At the same time, the diodes flow through the resistors 56, 55 75, 77, the output winding 74 and the field winding 12 a current so that the control electrode of the controllable rectifier 23 opposite the cathode has a positive voltage. The controllable one Rectifier 23 is therefore conductive and an excitation current flows through field winding 12.

If the voltage on the direct current network (lines 14 and 15) exceeds the setpoint voltage, so the Zener diode 69 becomes conductive and a base current flows in the transistor 67, causing it to oscillate starts with small base currents (corresponding to a small excess of the nominal voltage) with a low frequency, with large base currents with a high one. The oscillation process itself corresponds the one at F i g. 1 for the transistor 34 described.

Through the diodes 75 and 77, the switch-on pulse and the switch-off pulse are rectified with each oscillation and fed via the resistor 55 to the control electrode of the controllable rectifier 23 as voltage u ₂ so that a negative control current can flow, which the controllable rectifier 23 for the duration of this turns off negative control current (see. F i g. 2).

As with increasing frequency of the blocking oscillations

ίο these switch-off times can become longer and longer this way the excitation current can be controlled continuously from a maximum to zero. The last value is in FIG. 3 shown.

Instead of the midpoint rectifier circuit described, a half-wave rectifier circuit can also be used be used. This arises, for example, when in the circuit arrangement according to FIG. 1 the Diode 54 or in the case of the FIG. 4 the diode 77 is removed. Then only the switch-on or the Switch-off half-wave of each blocking oscillation is used to switch off the controllable rectifier 23. This then results in shorter switch-off times, which is why the blocking oscillations have a higher frequency is required, which is undesirable in many cases, e.g. B. because of the radio interference suppression in a motor vehicle. A certain compensation is here, however, by using a larger smoothing capacitor (e.g. capacitor 78 in FIG. 4) is possible.

1 sheet of drawings

Claims (11)

Patent claims: 1. Semiconductor voltage regulator for an alternating current generator that can be driven with variable speed, which feeds a direct current network via a rectifier set, with one in series with the field winding of the alternator, which can be switched on and off at its control electrode controllable rectifier whose control electrode has a voltage divider at a positive compared to its cathode Potential is and is also connected to a switching arrangement for generating the switch-off pulses is, characterized in that the switching arrangement for generating the switch-off pulses a blocking oscillator (34, 35; 67, 68) contains, which is above a certain Setpoint voltage on the direct current network (14, 15) with a frequency that increases as the voltage increases oscillates, and its output via a preferably as a full-wave rectifier in the midpoint circuit trained rectifier (53, 54; 75, 77) on the one hand with the cathode and on the other hand is in connection with the control electrode of the controllable rectifier. 2. Voltage regulator according to claim 1, characterized in that the blocking oscillator (34, 35; 67, 68) in a known manner a feedback transformer (35; 68) with a Has output winding (38; 72). 3. Voltage regulator according to claim 1 or 2, characterized in that the voltage divider (55, 56) via the output winding (38; 72) of the blocking oscillator and via one connected to this Diode (53; 75) of the rectifier with the cathode of the controllable rectifier (23) is connected. 4. Voltage regulator according to claim 2 or 3, characterized in that the feedback transformer (35; 68) has a first winding (47; 79), which in the emitter-collector circuit of a first transistor (34; 67) is, and a second winding (49; 82), which with its one End with the base of this transistor (34, 67) and with its other end with the output of one non-linear network (36, 37; 69) is connected, the output voltage of which is a function the voltage of the direct current network (14,15). 5. Voltage regulator according to claim 4, characterized in that in parallel with the series circuit of the emitter-collector path of the transistor (34) and one winding (47) of the feedback transformer (35) a Zener diode (37) is located. 6. Voltage regulator according to claim 4 or 5, characterized in that the non-linear Network is designed as a Zener diode (69), the input electrode of which is connected to one of the voltage of the Direct current network (14, 15) proportional direct voltage - potentiometer arm (28) - connected while its output electrode is connected to the other end of the second winding (82) of the Feedback transformer (68) communicates. 7. Voltage regulator according to claim 5, characterized characterized in that the non-linear network is designed as a second transistor (36), the input electrode of which to a direct voltage proportional to the voltage of the direct current network (14, 15) - Potentiometer arm (28) - is connected while its output electrode with the other End of the second winding (49) of the feedback transformer (35) in connection stands. 8. Voltage regulator according to claim 7, characterized in that between the output electrode of the second transistor (36) and the base of the first transistor (34) a diode (48) is arranged is to the residual voltage drop between the emitter and collector of the second transistor (36) to compensate. 9. Voltage regulator according to claim 7 or 8, characterized in that parallel to the emitter-base path at least one of the two transistors (34, 36) has a diode (44, 42) connected is to protect these transistors from overvoltages. 10. Voltage regulator according to one of claims 7 to 9, characterized in that the Series connection of collector resistor (50) and emitter-collector path of the second transistor (36) is parallel to the Zener diode (37). 11. Voltage regulator according to one of claims 1 to 10, characterized in that parallel to the controllable rectifier (23) the break contact (24) one to the direct current network (14, 15) connected relay (58) is arranged, which opens at a voltage below the target voltage is.