DE2250575C3 - Circuit arrangement for low-loss constant control of a direct voltage - Google Patents

Description

40

The invention relates to a circuit for low veikist constant rules of a direct voltage a load, with a first two-point switching regulator, a choke with a free-loop diode and an ohmic 4 «, Resistance connected in series with the load and with a trigger that switches the switching regulator, which dun Ii a set of rules depending on one Soll Istwenvergleah for the direct current with actual value acquisition can be controlled at the ohmic resistor. so

Ls is such a position without throttle and Ftoilaufdniile with a single switching regulator in Altitude, attitude with one I ast known (RCA-Silicon Γονή «ncuits Manual Technical / Series SP-50, IU \ l-i (i S 184), in which the switching regulator according to ss Fig. 207 / for constant regulation of the DC voltage vTiwendi.1 is and when parallel to the load one liiK'hohiMiii.-r Voltage divider at which the voltage risk In the Jen regulator is detected, is connected in parallel. Si hiiliiiiigcn used with a .ils switching regulator Sihalttransistor cause a relatively low power dissipation in the acoustic transistor, since the transistor either has a high or a A transistor controller delivers a constantly regulated, but 1, ii ht sufficiently smoothed DC voltage. The still The rewarding ripple of the direct voltage is achieved with the! ■ im ·! - known arrangement for low-loss stabilization a DC voltage (see. DT-AS 16 16 728) largely eliminated by the series connection of a Control regulator and a control regulator with the load as well as in that the control regulator depends on a target value comparison of one of the stabilized DC voltage derived voltage is controlled with a separate nominal voltage This is known The arrangement is provided with a current limiter, which consists in the switching regulator in the event of a load short circuit delivers constant current instead of constant voltage

There are similar circuits with a switching regulator and a control regulator connected in series with the load in DT-OS 15 13 420 and 15 88 157 described, the have essentially the same properties as the known circuit explained above. The circuit described in DTOS 15 88 157 also contains a device for achieving this a largely linear control characteristic.

The invention is based on the object of setting up a circuit of the type described at the beginning for constant control of a heavily loaded direct voltage, in such a way that the constant control also takes place with little loss and the highly loaded direct voltage is largely smoothed and; .d that a / .. B . effective current limitation is achieved in the event of a load short-circuit.

In the above-described known circuits, the ripple of the DC voltage increases when the load is high and the load current is greater than with a getinger load. This is accompanied by an increase in Actuator losses.

According to the invention, a direct voltage loaded with a high load current is used to regulate constant According to the task set out above, a second two-point sound controller via one for the Lastsirom permeable diode a capacitor and a high-resistance voltage divider as well as the Load connected in parallel, there is also a switching regulator switching trigger I use a control amplifier as a function of a target / actual value comparison for the DC voltage at the load is controlled with actual value acquisition at the voltage divider, and os is independent of it the first two-point switch controller for constant control of the direct current in the throttle and used to limit the load range.

According to a further training of the invention are the control amplifier for the /.weipiinkt- switching controller with one differential input each for a target isi value comparison executed, and there are the actual values of the load current and the load-side DC voltage each fed to the differential input of the assigned control amplifier via a low-pass filter.

An embodiment of the invention is shown in the drawing which is described below. The drawing shows the basic structure according to the invention. Hs - are two Sv h.ilttiansistors as switching regulators 1 and 2 \ necessary by means of which an unregulated operating splitting voltageiiii-: / 'I can even then be controlled constantly with a given setpoint i'- · // and as a DC voltage 1/2 low ripple is available at a load 3 / iir connected to the output of the circuit, if this load draws a large list current. Hin first switching regulator 1 is connected in series with a choke 12 and with the load ί and also with an ohmic measuring resistor 13, and it is in diesel series connection between the choke 12 and the I ast 3 for one

Load current permeable diode 21 arranged between the negative pole of the unregulated DC operating voltage U 1 and the connection of the switching regulator 1 with the choke 12, a diode 11 blocked by the voltage U \ is switched with the function of a freewheeling diode switched, which is controlled by a control amplifier 15 with differential input as a function of a setpoint / actual value comparison made for the direct current flowing in the choke 12, which is made at the differential input of the control amplifier. The actual value of the choke current is detected at the ohmic measuring resistor 13 and fed as a voltage to the comparison input of the differential input via a low-pass filter 16 and a setpoint value for the choke current predetermined by a constant direct voltage is fed directly to the reference input of the differential input. A second switching regulator 2 is connected in parallel across the diode 21 of the load 3 and also a storage capacitor 22 and a high-resistance voltage divider 23. The second switching regulator is also switched by means of a Schmitt trigger 24, which is controlled by a control amplifier 25 with a differential input as a function of a set-actual value comparison carried out at this differential input for the constant direct voltage V2 to be regulated. Here, the actual value of the voltage U 2 is detected at the high-resistance voltage divider 23 and fed to the comparison input of the differential input via a low-pass filter 26, and a setpoint value (Λ.; / For LJ2 for LJ2) is fed directly to the reference input of the differential input. Es the mode of operation of the circuit will now be explained below.

The two switching regulators I and 2 work like two-point switching regulators in the circuit described above. In the quasi-stationary operation of the circuit, the direct current in the choke 12 is given an almost saw-tooth shape due to the switching activity of the switching regulator 1, which fluctuates around an average value of the direct current, which is specified by the setpoint present at the differential input of the control amplifier 15. The fluctuation amplitudes of this current are determined by the switching hysteresis of the Schmitt trigger 14 and the switching points of the switching regulator 1 are dependent on this and also on the inductance of the choke 12. The switching times are still influenced by the low-pass filter 16, which smooths the causes the actual value detected at the resistor 13 and keeps interference pulses, which can arise from parasitic reactances, away from the input of the amplifier 15. The switching frequency as well as the duty cycle of the switching regulator! set themselves automatically in two-point switching operation and are otherwise determined by the influences listed above. The ripple of the direct current in the choke decreases at a given voltage Ul , the greater the inductance L of the choke 12, the higher the switching frequency, the smaller the ohmic resistance in the load circuit and the lower the hysteresis of the trigger 14. Furthermore, the switching frequency depends on whether the switching regulator 2 is open or closed, because in the latter case the throttle also carries the current that flows through the switching regulator 2.

Assuming a low ripple of the choke current / with a triangular current curve, the switch-on time ft and the switch-off time t- \ of the switching regulator 1 for the four possible switching states of the switching regulators 1 and 2 can be simply represented by the following relationships. It is taken into account that the inductor current can continue to flow via the diode 11 during the switch-off time. Let Δ I <I = hull and 1/2 = const., R = ohmic resistance of the choke 12, then when the switching regulator 2 is closed

L-I /

'' Vl IR

and

therefore

/, + r _x
and

ι κ, + /, ι -

IR

i / I

LI /
IR '

~ Switch-on alarm

IR (VX IR) LM-VX

Switching Frcquen /:

with ueölTnei switching regulator 2

and

therefore

and

LI /
l.'lt / 2 - IR

Ll /
12 IR

V 2 IR
(I 2 IR

ItI VI - IR) [L 2 IR) I. I / ((VI - 2 IR)

--- = scarf 1-IVcqucn /.

From the formula for the switch-on time t'i. it can be seen that when the denominator t'i: becomes very large, the inductor current I (t) becomes stationary. However, this can be avoided and the effective losses in the choke can be kept small if its ohmic resistance R is small and the voltage difference U 1 -U 2 is correspondingly small.

When constant control of the direct current in the choke 12, the load current is controlled accordingly, and the switching voltage pulses caused by the switching regulator 1 are picked up by the choke 12, so that the direct voltage switched through to the load has a ripple. With the aid of the switching regulator 2 and the capacitor 22, this ripple can be reduced with little loss and the load voltage IJ 2 can be constantly regulated to a predetermined setpoint value Usoii. At the times when the ripple DC voltage and the voltage of the capacitor 22 have decreased to a minimum value, the switching regulator 2 is controlled in the open state. An almost constant current then flows through the switching regulator I _1, the choke 12 and the diode 21 into the capacitor 22, as a result of which the voltage across the capacitor increases. If the voltage on the capacitor has reached a maximum value, the

Switching regulator 2 is again controlled in the closed state, and a discharge current then flows from the capacitor through the load 3. The switching regulator 2 is switched by a Schmitt trigger 24, which is controlled by a control amplifier 25 with a differential input as a function of the set-actual value comparison for the load voltage U2 is controlled. This nominal / actual value comparison is carried out at the differential input of the amplifier 25 by means of a nominal voltage Usoii, the actual value of the load voltage being detected at the voltage divider 23 and being fed to the comparison input of the amplifier 25 via a low-pass filter 26.

If the voltage U = U 2 has a low ripple requirement, the charging time ft and the discharging time U- of the capacitor 22 are indicated by the following relationships. Be there

Δ U <U = Ό2 = lK.li and / = const., C = capacitance and / i = charging current of capacitor 22,
then applies when the switching regulator is closed 2

with the switching regulator open 2

If.

If

With a vanishing denominator, i. H. if / ι -> /goes.

ii will be very big. Here the circuit goes into current limitation, and it becomes U = U2 = / · R, the current is then limited by the resistor R and other neglected resistances of the load circuit.

By the circuit described as a whole it is achieved once that the fluctuations in the direct current in the choke 12 - as already mentioned above - the smaller the greater the inductance of the choke and the smaller the hysteresis of the trigger 14 is. d. H. the higher the switching frequency of switching regulator 1 is. To the on the other hand, the lower the ripple in the voltage across the capacitor 22 and thus in the load voltage achieved, the greater the capacitance of the capacitor 22 and the lower the hysteresis of the trigger 24, d. H. the higher the switching frequency of the switching regulator 2, which is under the aforementioned conditions accordingly results.

In the event of an overvoltage occurring at the output of the circuit, the circuit reacts advantageously in the Way that the switching regulator 2 is instantly controlled in the closing state, the switching regulator 1 can remain unchanged. On the other hand, the circuit according to the invention has the advantage that it also - as already said - is short-circuit proof. In the event of a short circuit at the output of the circuit, the Switching regulator 1 is immediately controlled to a maximum possible duty cycle, with the sound frequency can adjust freely.

For this 1 sheet of drawings

Claims (2)

Patent claims: L Circuit arrangement for low-loss constant control of a DC voltage on a load with a first two-point switch controller, a choke with a freewheeling diode and an ohmic one Resistance connected in series with the load and with a trigger that switches the switching regulator, which by a control amplifier as a function of a set-actual value comparison for the direct current in the choke can be controlled with actual value acquisition at the ohmic resistance, characterized in that that for constant control of a high-load equalization load second two-point switch (2) via one for the Load current permeable diode (21) a capacitor (22) and a high-resistance voltage divider (23) and also the load (3) is connected in parallel that a trigger switching this switching regulator (2) (24) by a control amplifier (25) as a function of a target / actual value comparison for the DC voltage at the load is controlled with actual value detection on the voltage divider (23) and that independently of this, the first two-point switch controller (1) for constant control of the direct current in the choke (12) and is used to limit the load current. _{2. Circuit arrangement} according to claim 1, characterized in that the control amplifiers (15, 25) for J0 the two-point switch controllers (1, 2) are each designed with a differential input for the set-actual value comparison and that the actual values of the load current and the load-side DC voltage are each fed to the differential input of the associated control amplifier via a low-pass filter (16 or 26).