DE3612380A1 - Circuit arrangement for reducing an interference current which is caused in a load - Google Patents

Abstract

The invention relates to a circuit arrangement for reducing the interference current which is caused by a load (2). The frequency of the interference current is considerably higher than that of the current of a supply voltage source (1) which is coupled to the load (2). A compensation circuit is provided in order to reduce the interference current. This compensation current contains a parallel-connected series circuit which is arranged in the supply leads between the load (2) and the supply voltage source (1) and comprises a capacitor (3) and a controlled signal source (4). The signal source (4) supplies a current through the capacitor (3), which current is dependent on a control signal derived from the interference current and whose magnitude and phase are dimensioned such that the majority of the interference current can flow through the capacitor (3). <IMAGE>

Description

The invention relates to a circuit arrangement with a Load that is coupled to a supply voltage source and the interference in the current of the supply voltage source causes current whose frequency is significantly higher than that of the current of the supply voltage source, and with a Compens provided to reduce the interference current sation circuit that one in the leads between arranged the load and the supply voltage source Contains connecting branch with a capacitor.

Such a circuit arrangement is known from EP 00 59 053 ( Fig. 3). There, a supply voltage source, which supplies an alternating voltage, is coupled to a load, a switching power supply, via a filter. The switching power supply causes an interference current due to switching operations, the frequency of which is significantly higher than that of the current of the supply voltage source and which has a reaction on the supply voltage source. The filter consisting of a coil and a capacitor serves to prevent this interference current. On the one hand, the coil is connected to the supply voltage source and, on the other hand, to the load and the capacitor lying parallel to the load. By using a coil to reduce the interference current, a significant reduction in the size of the circuit arrangement is prevented.

The invention has for its object a circuit arrangement of the type mentioned in such a way that a reduction in the interference current without using a Coil is reached.  

The object is achieved in that in the connecting branch one with the capacitor in series switched controlled signal source is arranged, the delivers a current through the capacitor from one control signal derived from the interference current and its size and phase is such that the sturgeon most of the current can flow through the capacitor.

In the circuit arrangement according to the invention Help of the controlled signal source in the compensation circuit a current is passed into the capacitor, the corresponds approximately to the interference current according to phase and size. The interference current is transmitted through the controlled signal source largely derived the capacitor, so that only one small proportion of the interference current to the supply voltage source can reach. The control signal that the signal source supplied depends on the interference current. It is it is not necessary that this dependency is linear. It must only ensure that the interference current matches the current, which is led from the signal source into the capacitor, largely corresponds.

A control signal can be derived from the interference current, by the current of the supply voltage source with the interference current is measured. It is intended that from the a first measuring resistor in a supply line between the load and the series connection from the condenser sator and the signal source is arranged, falling Voltage the control signal is obtained.

The voltage across the measuring resistor depends on the Current that is supplied by the supply voltage source and the interference current caused by the load. To only one is to get signal dependent on the interference current seen that an amplifier circuit connected to its first  Input the voltage drop across the first measuring resistor and a reference voltage at its second input is supplied, the temporal course of the current of the Supply voltage source approximately corresponds to an output forms voltage that represents the control signal. It leaves also by means of a capacitor which is between the Measuring resistor and the controlled signal source arranged is independent of the current of the supply voltage source Win signal. The capacitance of the capacitor must be be chosen so that it is the low frequency of the current the signal caused by the supply voltage source presses.

The reference voltage can be connected to a second measuring resistor be obtained between the supply voltage source and the parallel branch is arranged and on which also the due to the incomplete compensation of the interference remaining residual interference current can be measured can.

In one embodiment for the controlled signal source it is envisaged that this will have a power amplifier a complementary output stage.

The invention can be used in such a circuit arrangement be used, which contains a switching power supply as a load.

The invention is described below with reference to the drawings explained in more detail. Show it:

Fig. 1 and Fig. 2 shows two embodiments of the inventive circuit arrangement.

The first exemplary embodiment according to FIG. 1 has a supply voltage source 1 which, for example, emits a DC voltage of 50 V. A DC voltage only has a portion at a frequency of zero. The supply voltage source 1 supplies a load 2 via feed lines, which can be, for example, a switching power supply designed as an upward voltage converter. Switching power supplies of this type are generally operated at switching frequencies of approximately 20 kHz to 200 kHz. These switching processes cause an interference current in the input current of the supply voltage source 1 , the frequency spectrum of which has components in the switching frequency and its harmonics.

To reduce this interference current, a compensation circuit is provided which contains a capacitor 3 , a controlled signal source 4 and an amplifier circuit 5 . The current Ya, which flows through the load and which contains the interference current, causes a voltage drop across a measuring resistor 10 . The resistor 10 should preferably be selected such that it is on the one hand as small as possible in order to limit the losses occurring on it, but on the other hand the voltage drop across it is sufficiently high to control the amplifier 11 . The measuring resistor 10 is arranged between the negative reference point of the supply voltage source 1 and a connection point of the load 2 . At the connection point between the load 2 and the measuring resistor 10 , the amplifier circuit 5 is connected. The amplifier circuit 5 includes an amplifier 11 , the inverting input of which is connected via a resistor 12 to the connection point mentioned above and via a resistor 13 to its output. A resistor 14 connected to the negative reference point of the supply voltage source 1 and a resistor 15 connected to a reference voltage source Uref are connected to the non-inverting input of the amplifier 11 . Furthermore, the amplifier circuit 5 contains an amplifier 16 , the non-inverting input of which is connected to the negative reference point and the inverting input of which is connected to the output of the amplifier 11 via a resistor 17 and to its output via a resistor 18 . The output of amplifier 16 forms the output of amplifier circuit 5 .

In the amplifier circuit 5 , the difference between the comparison voltage, which is an image of the voltage supplied by the supply voltage source 1 , and the voltage drop across the first measuring resistor is formed. The voltage at the output of the amplifier circuit 5 is dependent on the interference current generated by the load 2 . The opposites 12 to 15 and 17 , 18 and the reference voltage Uref, which is an order of magnitude smaller than the DC voltage of the supply voltage source 1 , can be chosen so that a DC adjustment of the amplification circuit 5 and the following controlled signal source 4 is present.

The controlled signal source 4 contains a power amplifier with a complementary output stage of class AB. The complementary output stage contains an NPN transistor 20 and a PNP transistor 21 . The collector of the transistor 21 is connected to the negative reference point of the supply voltage source 1 and the base on the one hand to a resistor 22 connected to the negative reference point and on the other hand to the cathode of a diode 23 . The anode of the diode 23 is connected on the one hand to the output of the amplifier circuit 5 , which supplies the control voltage, and on the other hand to the cathode of a diode 24 . The base of transistor 20 is connected to the connection point between the anode of diode 24 and a resistor 25 . A supply voltage Ub, which is an order of magnitude lower than the DC voltage of the supply voltage source 1 , is placed on the collector of the transistor 20 and on the other connection point of the counter 25 . The emitters of the two transistors 20 and 21 are connected via a connection point to the capacitor 3 , which in turn is connected to the positive connection point of the supply voltage source 1 .

Depending on the output voltage supplied by the amplifier circuit 5 , the controlled signal source 4 drives a current Yc, which is approximately equal to the interference current, through the capacitor 3 . Depending on the control voltage applied, either transistor 20 or transistor 21 is conductive. If the transistor 20 is conductive, the required current Yc is drawn from the voltage source, which supplies the voltage Ub and which is connected to the ground terminal of the supply voltage source 1 , which is not shown here. If the transistor 21 is conductive, the current Yc flows through it to the negative reference point. The capacitor 3 prevents the DC voltage of the controlled signal source on the supply voltage source 1 and the load 2 acts. At the capacitor 3 , the voltage difference between the voltage at the load 2 and the voltage at the output of the signal source 4 drops, which is generally an order of magnitude smaller than the voltage at the load 2 .

Due to the non-ideal components and the non-linearity of the signal source 4 , no complete compensation of the interference current is achieved.

In a further exemplary embodiment, which is shown in FIG. 2, a possibility is shown of how a further reduction of the interference current can be achieved. The circuit elements with the same functions as in Fig. 1 are provided with the same reference numerals. A difference in the exemplary embodiment in FIG. 2 arises in comparison to the exemplary embodiment in accordance with FIG. 1 only in the amplifier circuit 5 . At the connection of the measuring resistor 10 and the load 2 , the resistor 12 is connected, which on the other hand is connected to the inverting input of the amplifier 11 . The inverting input is connected to its output via the resistor 13 . The non-inverting input is connected to the negative terminal of the supply voltage source 1 in this embodiment. At the non-inverting input of the amplifier 11 there is a voltage which drops across a second measuring resistor 30 which is arranged between the negative connection of the supply voltage source 1 and the first measuring resistor 10 . The negative connection of the voltage source Ub, from which both the signal source 4 and the amplifiers 11 and 16 are supplied, is connected to the connection point between the two measuring resistors 10 and 30 . The further construction of the amplifier circuit 5 is identical to the structure according to the embodiment of FIG. 1. In the United amplifier circuit 5 , the difference between the voltage across the measuring resistor was 10 and the voltage across the measuring resistor 30 is formed according to the embodiment of FIG. 2.

In a practical circuit design, a switching power supply was used, which causes a triangular interference current. It has been shown that the first harmonic of the interference current, which is at 20 kHz, was reduced by 30 dB according to the exemplary embodiment from FIG. 1 and in the exemplary embodiment of FIG. 2 the first harmonic could be reduced by 50 dB.

The circuit arrangement according to the invention is not based on the Limited use of a supply voltage source that supplies a DC voltage, but can also be used be when a supply voltage source changes tension supplies. The proportions of the AC voltage source but must be at much lower frequencies than that Shares of the interference current.

Claims (6)

1. Circuit arrangement with a load ( 2 ), which is coupled to a supply voltage source ( 1 ) and which causes an interference current in the current of the supply voltage source ( 1 ), the frequency of which is substantially higher than that of the current of the supply voltage source ( 1 ), and with A compensation circuit provided for reducing the interference current, which contains a connecting branch with a capacitor ( 3 ) arranged in the supply lines between the load ( 2 ) and the supply voltage source ( 1 ), characterized in that in the connecting branch one with the capacitor ( 3 ) arranged in series controlled signal source ( 4 ) which supplies a current through the capacitor ( 3 ), which is dependent on a control signal derived from the interference current and whose size and phase is dimensioned such that the interference current largely through the capacitor ( 3 ) can flow. 2. Circuit arrangement according to claim 1, characterized in that from the at a first measuring resistor ( 10 ) which is arranged in a supply line between the load ( 2 ) and the series circuit of the capacitor ( 3 ) and the signal source ( 4 ), falling voltage the control signal is obtained. 3. A circuit arrangement according to claim 2, characterized in that an amplifier circuit ( 5 ) which at its first input was at the first measuring resistor ( 10 ) dropping voltage and at its second input a reference voltage is supplied which corresponds to the time course of the current Supply voltage source ( 1 ) approximately corresponds, forms an output voltage that represents the control signal. 4. Circuit arrangement according to claim 3, characterized in that a second measuring resistor ( 30 ), on which the reference voltage is obtained, is arranged between the supply voltage source ( 1 ) and the parallel branch. 5. Circuit arrangement according to one of the preceding claims, characterized in that the controlled signal source ( 4 ) comprises a power amplifier with a complementary output stage ( 20 , 21 ). 6. Circuit arrangement according to one of the preceding claims, characterized in that the load ( 2 ) is designed as a switching power supply part.