DE1293303B - Circuit arrangement for regulating a direct current - Google Patents

Description

The invention relates to a circuit arrangement for controlling a Direct current obtained from a variable alternating voltage via a rectifier is with a transducer in current limiter control as an actuator and a transistor arrangement as a regulator in which the auxiliary voltages required for the regulator are also used are derived from the AC supply voltage via rectifiers.

DC regulators, which in many cases are used to supply power to electrical facilities are required are in various designs known. If you disregard the pure stabilization circuits, then heard here the group of electronic current regulators, in which electron tubes are used as actuators or transistors that operate as variable DC resistors will.

All of these current regulators have the disadvantage that they are relatively consume a lot of power dissipation, especially if the load resistance and the supply voltage can fluctuate within wide limits. The efficiency of such Facilities is bad.

In this regard, regulators with actuators in the alternating current section are more favorable of the circuit and that work with reactive power control. This includes regulators with transducers in different types of circuit.

Transductors are particularly suitable as actuators for current regulators in current limiter control. The series connection is because of the rectification The more favorable square-wave curve of the output voltage is preferable to the parallel connection.

However, in these circuits in the control windings are noteworthy Alternating voltages are induced, which may have an unfavorable effect on the control amplifier and to have the entire scheme.

If a transistor arrangement is used as a regulator, usually the power transistor in series with the control winding of the transductor and one Filter choke, the pentode characteristic of the transistor has a particular effect disadvantageous, because also when using a large filter choke on the transistor a large part of the AC voltage induced in the control winding drops and adversely affects the operation of the transistor. One does it with the help of big ones Capacitors low-resistance the transistor for alternating currents, so one affects as a result, the dynamic control properties are inadmissible.

Another property that increases with the use of linear amplification Regulator circuits - as they are normally represented by transistor amplifiers - at A disadvantageous effect on current regulators is the strong dependency of the loop gain from the output voltage. It is often impossible to use current regulators with such arrangements with satisfactory static and dynamic properties.

The invention represents the further development of such circuit arrangements for regulating a direct current, in which the advantageous properties of a Transduktors in current limiter control as an actuator and a transistor arrangement come fully into their own as a controller, and those adhering to the previously known arrangements Disadvantages are avoided. The drawing shows the circuit diagram of a circuit arrangement according to the invention.

1 is the connection for the supply of the alternating voltage, 2 is a transducer connected in series in one of the mains supply lines with current limiter control as an actuator, 3 is a transformer, 4 is a rectifier in a bridge circuit and 5 is a direct current filter chain, 6 is the consumer resistance. The measuring resistor 7 is still in the consumer circuit.

The auxiliary voltages required for the transistor regulator are Via the transformer 8 and the two midpoint rectifiers 9, 9 'and 10, 10' won. 11 and 12 are the filter capacitors for these two auxiliary voltages.

To the series connection of the control winding 13 of the transductor 2 and the filter choke 14 is the emitter-collector path of the power transistor 15 connected in parallel. This parallel connection is on the collector side of the transistor 15 connected to the common minus pole of the auxiliary voltages, while the emitter side leads via the series resistor 16 to the positive pole of the first auxiliary voltage. The transistor 17 is connected upstream of the power transistor 15 in a current amplifier circuit. Between the base of the transistor 17 and the minus pole of the auxiliary voltages are connected to a resistor 18th

A Zener diode 19, which is biased from the second auxiliary voltage via the resistor 20, serves as a reference voltage source for the regulation. This second auxiliary voltage is greater than the first auxiliary voltage by more than the amount of the comparison voltage.

The actual value of the current to be controlled is shown as the voltage drop across the Measuring resistor 7 tapped, the positive tapping of this resistor together connected to the plus pole of the Zener diode 19 to the plus pole of the second auxiliary voltage is, while the negative tap of the measuring resistor with the emitter of a third Transistor 21 and the base of this transistor with the minus pole of the Zener diode 19 and the collector are connected to the base of transistor 17.

The mode of operation of the circuit is as follows: With a certain Mains voltage and a fixed working point, the transductor will have a certain Current controlled. The magnitude of the current in the control winding of the transducer depends on the size of the ohmic resistances of the control winding 13 and the choke 14 as well as on the emitter-collector voltage of the transistor 15 dependent.

If one neglects the voltage drops across the emitter base paths of transistors 15 and 17, so is the emitter-collector voltage of the transistor 15 equals the voltage across resistor 18. The current through transistor 15 sets in such a way that the voltage drop across resistor 16, which is determined by the sum of the Control current caused by the transducer winding and the transistor current becomes, together with the voltage at transistor 15, just the size of the first auxiliary voltage achieved.

The voltage at transistor 15 and thus the control current through the voltage drop across the resistor 18, which determines the transductor winding, is determined by the sum of the collector current of the transistor 21 and the base current of the transistor 17 caused. The circuit is designed so that the influence of the base current of the transistor 17 opposite the collector current of the transistor 21 can be neglected.

The collector current of the transistor 21 is determined by the voltage difference between the comparison voltage which is dropped across the Zener diode 19 and the voltage drop across the measuring resistor 7. The measuring resistor 7 simultaneously causes negative feedback of the transistor 21 in this circuit.

If the load current increases for whatever reason, it increases also the voltage drop across the measuring resistor 7. This reduces the differential voltage between the measuring resistor and the zener diode; the emitter base current of the transistor 21 becomes smaller and thus also the collector current. As a result, the voltage drop decreases at resistor 18, and the voltage at transistor 15 decreases, so that the transistor draws more electricity. At the same time as the voltage on transistor 15 also increases Control current through the transductor control winding 13, and the transducer regulates the load current back to a value that was the same as the current before the load increase is equivalent to. The circuit works accordingly when the load current decreases.

Since the voltage at transistor 15 is practically only due to the voltage drop is determined at the resistor 18, only changes in the event of fluctuations in the supply voltage the current through the transistor so far that the change in voltage as a change in the Voltage drop across resistor 16 occurs.

The feedback alternating voltages from the transducer control winding are exactly the same Derived via the transistor 15 and cause a superimposed alternating current through the transistor. This alternating current is limited by the filter throttle 14.

To improve the dynamic properties of the regulator circuit it is expedient to add an appropriately dimensioned capacitor to the resistor 18 to connect in parallel.

By correctly dimensioning the first auxiliary voltage and the filter capacitor 22 and the resistor 16 can supply the auxiliary energy required for the regulation the most favorable value can be brought, whereby the efficiency of the entire controller arrangement is improved.

Claims (3)

Claims: 1. Circuit arrangement for regulating a direct current, which is obtained from a variable alternating voltage via a rectifier, with a transducer in current limiter control as an actuator and a transistor arrangement as a controller, in which the auxiliary voltages required for the controller are also derived from the AC supply via a rectifier are characterized by the following features: a) that the emitter-collector path of a power transistor (15) is connected in parallel to the series connection of the control winding (13) of the transductor (2) and a filter choke (14) and this parallel connection on the The collector side of the transistor is connected to the minus pole of a first auxiliary voltage, while the emitter side is connected to the plus pole of this first auxiliary voltage via a common series resistor (16), b) that the power transistor (15) has at least one further transistor (17) in Current amplifier circuit vorgesc is held and the base connection of this second transistor is connected to the minus pole of the first auxiliary voltage via a resistor (18), c) that a Zener diode (19) is used as a reference voltage source for the regulation and is connected to a second auxiliary voltage via a resistor (20) is positively biased, which is greater than the amount of the reference voltage than the first auxiliary voltage, d) that the actual value of the current to be regulated can be tapped as a voltage drop at a measuring resistor (7), which is in the working circuit, and the positive tap of this resistor together with the plus pole of the Zener diode is connected to the plus pole of the second auxiliary voltage, while the negative tap of the measuring resistor is connected to the emitter of a third transistor (21), e) that the base of this third transistor is connected to the minus pole the Zener diode and the collector is connected to the base of the current-amplifying second transistor. 2. Circuit arrangement according to claim 1, characterized in that to improve the dynamic properties of the resistor (18) which lies between the base of the second current-amplifying transistor (17) and the minus pole of the auxiliary voltages, a capacitor (22) is connected in parallel is. 3. Circuit arrangement according to claim 1 or 2, characterized in that a filter circuit with a starting capacitor (11) is used for the purpose of filtering primarily the first auxiliary voltage.