DE3209975A1 - Circuit arrangement for controlling the magnitude of a pulsating voltage which is to be emitted, especially in a DC converter - Google Patents

Abstract

In a circuit arrangement for controlling the magnitude of a pulsating voltage, which is to be emitted, via a controllable inductance (8) on a rectification and smoothing circuit (11, 12, 13, 14), the output voltage (vA) emitted by the rectification and smoothing circuit (11, 12, 13, 14) is compared with a reference voltage (18) in order effectively to control a circuit (10, 19, 20) by means of which the demagnetisation of the inductance (8) can be selectively controlled. <IMAGE>

Description

b e s c h r e i b u n p

Circuit arrangement for controlling the level of a pulsating to be dispensed Voltage, particularly in a DC-DC converter The invention relates to on a circuit arrangement for controlling the level of a pulsating to be dispensed Voltage, especially in a DC voltage converter, with an input circuit, which emits a pulsating voltage, with one at the output of the input circuit Rectifier circuit connected via an inductance, which is a smoothing circuit is connected downstream, and with a comparator arrangement, which the of the Smoothing circuit emitted output voltage with a predetermined reference voltage compares and which is connected on the output side to the inductance mentioned.

A circuit arrangement of the type described above is already available known (journal IEEE-Trans. 1979, pages 282 to 288, especially page 288, Fig. 1).

A disadvantage of this known circuit arrangement is, however, that the inductance serving as the actuator during the occurrence of the pulsating Voltage with one polarity is completely demagnetized, so that the output voltage-time plane compared to the input voltage-time area in this known circuit arrangement is significantly reduced. Expressed in a formula, this means that the reduction the output voltage-time area versus the Input voltage-time area is at least U # t = Bsatt # A. 3satt means the saturation magnetization, A means the core cross-section and means the number of turns of the mentioned Inductance. The product U.t means the mentioned difference in the voltage-time area.

It is now also known that transducers are used as regulators in switched-mode power supplies to be used (company publication Z021 from the company Vakuumschmelze GmbH., edition 5/79). A disadvantage of such a constructed switching power supply is that two separate Magnetic circuits with up to five partial windings required for the single-ended flow converter are. Another disadvantage is that relatively expensive toroidal cores are required. the alloys with a high nickel content at high operating frequencies exist. In addition, it is disadvantageous that relatively high control currents for regulating transducers required are. Overall, this means a relatively high control output is to be regarded as disadvantageous.

The invention is based on the task of showing a way as in the case of a circuit arrangement of the type mentioned at the outset in a relatively simple manner Way the difference between the input voltage-time area in the circuit arrangement pulsating voltage occurring on the input side and the output voltage time surface the output voltage output by the circuit arrangement has different needs controlled accordingly and, in particular, can also be made practically zero.

The object shown above is achieved with a circuit arrangement of the type mentioned according to the invention in that the comparator arrangement with the inductance is connected in such a way that its demagnetization as a function controlled by the output voltage of the comparator arrangement ..

The invention has the advantage that on relatively simple Way it is ensured that the difference between the input voltage-time area the voltage occurring in the circuit arrangement according to the invention as an input pulsating voltage and the output voltage-time area of the circuit arrangement output voltage output according to the invention between a practically zero lying very small value and a very large value can be controlled so that it is possible in a simple way to meet different needs output voltage.

Preferably there is between the output of the comparator arrangement and the inductance is a semiconductor switching element controllable by the output signal of the comparator arrangement provided, which, if necessary, with its switching path via a diode Probes that connect inductance to one another. This results in a special simple circuit construction for controlling the demagnetization of the Inductance.

The semiconductor switching element is expediently a pulse width modulator upstream, through which the semiconductor switching element has a duty cycle of the output voltage of the comparator arrangement dependent signal is supplied. This has the advantage of a particularly effective control of the switch-on and switch-off times of the semiconductor switching element with itself.

The semiconductor element is preferably a transistor.

This brings the advantage of elrle, particularly low circuitry Effort with itself.

Between the output side of the inductance and one with the rectifier circuit or connected to the smoothing circuit circuit point is preferably a AC load connected. This measure has the advantage that the Core material of the inductance can be better used than usual due to magnetic reversal can. This will be discussed further below.

The named alternating current load is expediently due to an ohmic one Resistance formed. This has the advantage of a particularly low cost the realization of the AC load in question.

Preferably, the aforesaid range is through a single opule educated. This brings the advantage of a particularly simple circuit structure Circuit arrangement according to the invention with it.

Binding other appropriate embodiment of the invention is that the inductance is formed by a transformer having two windings, the one with its one winding between the input circuit or the rectifier circuit and the rectifier circuit or the smoothing circuit and the one with its other winding is connected to the comparator arrangement. This measure brings with the advantage that with a particularly low control power for the control the demagnetization of the inductance can be done.

Preferably, between the one with the semiconductor switching element connected winding of the transformer and the output emitting the output voltage the smoothing circuit is provided with a diode which receives a voltage from the same Able to give off polarity like the rectifier circuit. This brings the advantage with the fact that a voltage limitation can thereby be carried out and that, moreover, the magnetization energy present in the inductance for the output of the output voltage can be used.

If the circuit arrangement according to the invention is used in a push-pull forward converter arrangement applied, it is preferably with the voltages phase-shifted by 180 ° from one another delivering outputs of the input circuit are each the series connection of a rectifier circuit and an inductance, and the series circuits concerned is a single one Downstream smoothing circuit to which the comparator arrangement is connected, which allows to control the demagnetization of the two inductances. Through this there is the advantage of a relatively low circuit complexity for a push-pull forward converter arrangement.

The invention is illustrated below using exemplary embodiments with the aid of drawings explained in more detail.

Fig. 1 shows a circuit diagram of a Bintal: t flow converter according to the invention Fig. 2 shows ill a pulse diagram.m the course of voltages or currents at different circuit points of the single-ended forward converter shown in FIG.

FIG. 3 shows a modification of the single-ended flow converter shown in FIG.

Fig. Shows a circuit diagram of a push-pull forward converter according to the invention.

The circuit arrangement shown in Fig. 11 shows the structure a single-ended flow converter. This converter receives 1,2 at input connections an input voltage v1 is supplied, which may be a DC voltage.

This voltage feeds a control circuit 3, which is an astable multivibrator can be and the output side the base of an npn transistor 4 with pulses controls according to a pulse-pause ratio of 1: 1. In the collector circuit this transistor 4 is one winding 6 of a transformer 5 of a Winding 7 emits a voltage v2 which, as can still be seen with reference to FIG. 2 will be, is a pulsating voltage where the positive and negative Signal components are each the same size. This means that the base of the transistor 4 from the control circuit 3 corresponding control signals are supplied. In terms of of the two windings u and 7 of the transformer 5 it should also be noted that d-.e an These windings indicated points the direction of winding of the two windings 6.7 indicate.

The circuit described above represents, as it were, an input circuit represents, which emits a pulsating voltage. The relevant input circuit an inductance 8 is connected downstream which, according to FIG. 1, consists of two windings 9 and 10 consists, of which the winding 9 is connected directly to the output of the transformer winding 7 is connected.

The inductance 8 is connected to a rectifier circuit after which according to FIG. 1, the diodes 11 and 12 belong. The diode 11 is used for delivery the actual load current, and the diode 12 takes over in the blocking phase of the diode 11 the instantaneous current of an inductor 13 of this inductor 13 with a Smoothing circuit containing capacitor 14, which is connected to an output terminal 15 is, between which and an output terminal 16 an output voltage vA is removable. With the output terminal 16 are the capacitor 14, the diode 12 and the previously not considered .Jnde of the transformer winding 7 connected.

At which the output voltage vA emitting output terminal 15 is in the circuit arrangement according to FIG. 1, a comparator arrangement 17 with its connected to an input. This comparator arrangement 17, which is through an operational amplifier can be formed, a reference voltage is supplied to an input 18, with which the output voltage vA is compared.

The output of the comparator arrangement 17 is a semiconductor switching element controlled, which is formed by a transistor 20 of the npn conductivity type, which is connected with its base at the output of the comparator arrangement 17. Nit Its collector is the transistor 20 via a current flow via the collector-emitter path of the transistor 20 in the forward direction polarized diode 19 with one end of the already mentioned winding 10 of the transformer connected. The wiaitter of transistor 20 and the other end of the winding 10 are connected to each other as well as to the output terminal 16 connected.

The circuit arrangement shown in Fig. 1 has in addition to the previously elements still considered an alternating current load in the form of an ohmic resistance 22, which is connected in parallel to the diode 11. Furthermore, in the circuit arrangement 1, a diode 21 between the end connected to the anode of the diode the transformer winding 10 and the output connection (3 15 can be provided. In addition can between the output of the comparator tion 17 and the Base of the transistor 20 may be a pulse width modulator provided by the Output signals of the comparator arrangement 17 controlled output pulses corresponding to Width gives off. By these output pulses, the transistor 20 is then in his conductive state / blocked state controlled accordingly.

The mode of operation of the circuit arrangement shown in FIG. 1 is described below explained so far with reference to the timing diagram shown in FIG. In Fig. 2 is very one with v denotes the course of the .Tension, which is on the in Fig. 1 with v2 designated circuit point occurs. Appropriate are the positive ones and negative phases of the voltage v2 are equal here, and the frequency is also the pulsating voltage v2 constant. When the transistor 4 is conductive, the input DC voltage is v1 corresponding to the transmission ratio between windings 6 and 7 of the transformer 5 transformed to the secondary winding 7, so that the relationship v2 = VI n7 no where n6 is the number of turns of winding 6 and n7 is the number of turns of winding 7 of the transmitter 5 mean. When the transistor 4 is blocked, the polarity is then reversed the voltage v2 around. In order to achieve that the positive amplitude unci negative Amplitude of the voltage v2 are the same, the transformer 5 can either be a separate one Have degaussing winding, or the collector of transistor 4 may be connected to a corresponding degaussing circuit.

As a result of the inductance or the transformer 8 according to FIG will be explained that Voltage v2 is somewhat reduced, so that the voltage v3 occurs at the connection point between the winding 9 and the diode 11, as Fig. 2 illustrates.

After rectifying this voltage v3, the voltage v4 occurs, from which, after smoothing by the smoothing circuit, the output voltage vA is obtained will. This output voltage vA creates a between the output connections 15 and 16 horizontal consumer resistance fed.

As already mentioned, the comparator arrangement 17 sets the output voltage vA compared with the reference voltage applied to terminal 18. This means, da.3 caused by input voltage fluctuations # vi or by load current changes Output voltage fluctuations # v # can be detected with the aid of the comparator arrangement 17 can. The comparator arrangement 17 controls the transistor @ 0 in such a way that this transistor; 20 becomes non-conductive when the output voltage vA is higher than the reference voltage at circuit point 18. Is the output voltage vA, however, lower than the reference voltage at node 18, the transistor 20 is thus controlled to be conductive. While the transistor 20 in the non-conductive State does not act on the inductance 8 via the winding 10, there is such a situation However, it has an effect when the transistor 20 is in the conductive state. The winding 9 of the transformer is then in the non-conductive state of the transistor 20 8 with their relatively high alternating voltage impedance in the alternating voltage circuit between the transformer 5 and the rectifier circuit. This has the consequence that the output voltage vA drops.

If the transistor 20 of the comparator arrangement 17 is in the conductive state State controlled, so @@@@ a current flows through the winding @ of the transformer 8 when voltage v occurs with a positive amplitude. the spawn at the anode of the diode 19 negative or too liull with magnetic saturation of the transformer 8. This has the consequence that the diode 19 is blocked. In the currentless phase, i.e. with negative voltage v2, however, the voltage at the anode of diode 19 becomes positive, since a magnetization current flows through the winding 9 of the transformer 8.

This means that now the diode 19 goes into the conductive state, so that the transistor 20 now has a current via its roller gate-emitter path can lead. The demagnetization of the transformer 8 is prevented or strongly delayed. This has the effect that with de afterwards occurring positive amplitude of the voltage v2 caused by the inductance of the transformer 8 available voltage-time area due to the increased Residual inductance Brest is reduced so that it has the relationship # = (Bsatt - Brest) # A # n9 is sufficient, where Bsatt is the saturation inductance of the transformer 8, A the The core cross-section of the transformer 8 and n9 mean the number of turns of the winding 9.

The consequence of the aforementioned phenomenon is that the magnetic Saturation of the transformer 8 is reached faster than usual. This means that the transformer 8 means overall a lower impedance for the voltage v2. This increases the voltages v3, v4 and vA.

If the amplitudes of the two voltages v2 and v3 are the same, then the following applies following relationship: v3 = v2 - (Bsatt - Brest) # A # n9 # ### Here T means the period of the voltages v3 and v4.

If the transistor 20 is continuously controlled in the conductive state, so is the demagnetization time t1 'and consequently also the magnetization time t1 equal to zero (t1 - t1 '= 0) neglecting voltage losses in the Inductance 8, the diode 1 19 and the transistor 20.

This means that v3 = v2.

In the foregoing it has been assumed that the transistor 20 is pulse width controlled is. In this control, the use of the pulse width modulator 23 between the output of the comparator arrangement 17 and the base of the transistor 20 may *, the following appear, which have not yet been considered but can be seen from FIG. 2 Voltages or currents.

The voltage on the winding 9 is denoted by v9; with 113 is denotes the current flowing through the inductance 13; with 111 it is the diode 11 denotes the current flowing through it, with I12 the diode 12 is the current flowing through it denoted, I19 denotes the magnetic angsstrom flowing through the diode 19; I21 denotes the current flowing through the above-mentioned diode; with v5 finally denotes the voltage that is applied to the corresponding node v5 in Fig. 1 occurs.

* (Fig. 2, signal 20) The one in the circuit arrangement Diode 21 provided in accordance with FIG. 1 limits the positive amplitude of voltage v5, and at the same time, the diode 21 feeds the magnetization energy (E = 1 / 2LI²) from that Transformer 8 her beneficial in the output circuit.

The voltage limitation can also be applied to other voltages than the output voltage vA. The winding 10 of the transformer can do this 8 provided with a corresponding tap or with an additional winding be.

As already explained above, the resistor 22 operates in connection with the diode 12 a reversal of magnetization of the transformer 8. This is a better one Utilization of the core material of the transformer 8 is achieved. In other words this means that by the measure in question the difference between Bsatt and Brakes becomes larger as the inductance Brest can be made negative. The resistance 22 may also be formed by any alternating current impedance that meets the with the diode 11 connected circuit point of the winding 9 of the transformer 8 also can connect to any other node in Fig. 1, for example to the output port 15 or to the output port 16. The flow through the the low magnetizing current in the winding 9 of the transformer 8 via the Resistance 22 caused alternating current component is related to the rest of the This winding of the transformer 8 to be neglected pulsating direct current flowing through.

In relation to the circuit arrangement shown in FIG. 1, it should be noted that that with this circuit arrangement a different type of voltage regulation thereby can be achieved that the control winding 10 of the Transmitter 8 is reversed, s @ that the transistor 29 occurs with a positive amplitude Voltage v2 is controlled conductive. Although this increases the control current, the is to be provided in the winding 10 of the transformer 8, but that remains simple Control principle obtained as it has been explained before.

FIG. 3 shows a modification of a circuit part of the circuit shown in FIG. 1 illustrated circuit arrangement. This circuit modification relates to the inductance 8 formed by a transformer in FIG. 1, which according to FIG 3 is formed by a single inductor 30. This means that the Inductance 30 take the place of winding 9 of transformer 8 according to FIG. 1 can. With the inductance 9 is the series connection of a diode 31 and the collector-emitter path an npn transistor 32 is connected. The diode 31 corresponds to the diode 19 according to FIG. 1, and transistor 52 corresponds to transistor 20 according to FIG. 1.

In fig. 4 is a circuit diagram of a push-pull forward converter. This converter has two transistors 41 and 42, which have their bases on one Control circuit 40 are connected, which a pulse-shaped voltage with iinen Able to deliver a pulse-pause ratio of 1: 1. This control circuit is at supply voltage connections -U / + U connected. The emitters of the transistors are connected to the supply voltage connection -U 41 and 42 connected.

The collectors of the transistors 41 and 42 are at one end the windings 44 and 45 of a transformer 43 verbuiiden; the other ends of the both windings 44, 45 are connected to the voltage terminal + U.

The transformer 43 has two further windings 46 and 47, the with their one ends to ground.

The winding sense of the windings of the transformer 43 is otherwise indicated by dots. With the ends of the windings 46 not yet considered and 47 of the transformer 43 are rectifier circuits in the form of two diodes 48 or 54 connected. The diode 48 is via a winding 50 of a transformer 49 as well via an inductance 60 with an output terminal which is associated with a smoothing circuit 67 connected.

The smoothing circuit in question also includes a capacitor 61. The other This 54 is about a wrap 56 of an amount 55 with the mentioned Inductor 60 connected.

The two transformers 49 and 55 each have a further winding 51 or 57, with which the series connection of a diode 52 or 58 and the collector-emitter path of a transistor 53 or 59 is connected. These last viewed arrangements correspond to elements 10, 19 and 20 explained in connection with FIG. 1.

The two transistors 53 and 59 have their bases at outputs a pulse width modulator 70 connected to each other at its outputs emits anti-phase output signals. This pulse width modulator 70 is at the exit connected to a comparator arrangement formed by an operating amplifier 69, which at the output terminal 67 - with reference to the output terminal 68 - occurring Output voltage with the reference voltage occurring at a node 71 obscure @.

The circuit arrangement shown in Fig. 4 basically works taken as that shown in FIG Circuit arrangement. Of the Diode 12 in the case of the circuit arrangement according to FIG. 1, corresponding separate diodes are not required in the circuit arrangement according to FIG. 4, since in this case Circuit arrangement the function of the relevant diode 12 through the diode 54 or 48 is adopted.

With regard to the circuit arrangement shown in FIG noted that the circuit variant shown in FIG. 3 also in this circuit arrangement is applicable.

It should also be noted that the comparator arrangements in the A direct voltage is supplied to the described embodiments as a reference voltage obtained, which is preferably an i; iit of the switching frequency of the circuit arrangement occurring sawtooth or triangular voltage is superimposed, whereby the function a pulse duration modulator is achieved, which in this case the respective comparator arrangement then does not have to be connected separately. In addition, instead of the explained Pulse width modulation also means a simple variable current-voltage limitation through the transistor 20 according to FIG. 1, through the transistor 92 according to FIG. 3 and through the transistors 53 and 59 according to FIG. 4 are strengthened.

Finally it should be noted that the magnetic material for the transformer 8 according to FIG. 1, for the inductance 30 according to FIG. 3 and for the transducers 49 and 55 according to FIG. 4 is preferably highly permeable and therefore it is high-frequency application of the circuit arrangement in question made of ferrite will.

The circuit arrangements described above are not using Voltage feed, but operated with current feed via a current transformer, so there is no need for switching elements, the inductance 13 and the diode 12 in the Circuit arrangement according to FIG. 1 or the inductance 60 in the circuit arrangement according to Fig. 4 correspond.

Claims (10)

Claims 0 circuit arrangement for controlling the level of a pulsating voltage (v3) to be output, especially in a DC voltage converter, with an input circuit (1 to 7) that emits a pulsating voltage (v2), with one connected to the output of the input circuit (1 to 7) via an inductance (8) Rectifier circuit (11,12), which is followed by a smoothing circuit (13,14) and with a comparator arrangement (17) which is that of the smoothing circuit (13, 14) output voltage (vA) with a given voltage (18) compares un.l soft connected on the output side with the mentioned inductance (8) is, characterized in that the comparator arrangement (17) with the inductance (8) is connected in such a way that its demagnetization as a function of the output voltage the comparator arrangement (17) takes place in a controlled manner. 2. Circuit arrangement according to claim 1, characterized in that between the output of the comparator arrangement (17) and the inductance (8) a from Output signal of the comparator arrangement (17) controllable semiconductor switching element (20) provided is which with its switching path, if applicable connects the ends of the inductance (10 of 8) to one another via a diode (19). 3. Circuit arrangement according to claim 2, characterized in that the semiconductor switching element (20) is preceded by a pulse width modulator (23), through which the semiconductor switching element (20) has a duty cycle of the output voltage the comparator arrangement (1 ') dependent signal is fed. 4. Circuit arrangement according to claim 2 or 3, characterized in that that the semiconductor switching element (20) is a transistor (20). 5. Circuit arrangement according to one of claims 1 to 4, characterized in that that between the output side of the inductance (8) and one with the rectifier circuit (11,12) or a circuit point connected to the smoothing circuit (13,14) AC load (22) is connected. 6. Circuit arrangement according to claim 5, characterized in that the alternating current load (22) is formed by an ohmic resistor (22). 7. Circuit arrangement according to one of claims 1 to 6, characterized in that that the inductance (8) is formed by a single coil (30). 8. Circuit arrangement according to one of claims 1 to 6, characterized in that that the inductance (8) through a transformer having two windings (9, 10) (8) is formed with its one winding (8) between the input circuit (1 to 7) or the rectifier circuit (11, 12) and the rectifier circuit (11,12) or the smoothing circuit (13,14) and the one with its other winding (10) is connected to the comparator arrangement (17). 9. Circuit arrangement according to claim 8, characterized in that between the winding (10) of the connected to the semiconductor switching element (20) Via tragers (8) and the output voltage emitting output (15) of the smoothing circuit (13,14) a diode (21) is provided which has a voltage of the same polarity can deliver like the rectifier circuit (11, 12). 10. Circuit arrangement according to one of claims 1 to 9, characterized characterized in that in a push-pull flow converter arrangement (Fig. 4) with the Outputs of the input circuit outputting 180 voltages out of phase with one another (40 to 47) each the series connection of a rectifier circuit (48, 54) and an inductance (49,55) is connected and that the two series circuits one only smoothing circuit (60,61) is connected downstream with which the comparator arrangement (69) is connected, which demagnetizes the two inductances (49,55) allowed to control.