DE3013633A1 - Delay circuit for switch off current - includes capacitor connected to inductance and diode - Google Patents

Abstract

The device is used for delayed switching off of a current in an inductive circuit. It may be used in control circuits, and incorporates a capacitor (C2) series with a discharge electrode in parallel with an inductive load. The circuit also includes an auxiliary diode (D2) whose cathode is connected to the positive pole of the input. The two poles of the input are connected to a capacitor (C1). There is a first transistor (T1) with a connection via a transformer primary (O) from the positive to the negative poles running through its collector emitter path. An auxiliary transistor (T2) has its emitter connected to the negative pole and its collector connected to the choke (L) and the anode of the auxiliary diode (D2). A rectangular control signal is fed to the bases of the two transistors. The delay capacitor (C2) is connected to the cathode of a diode (D1) whose anode is connected to the negative pole.

Description

Circuit arrangement for delayed power switch-off in the

inductive circuits, especially for switching regulators on a circuit arrangement for the delayed power cut-off in the inductive Circles, especially for @switching controls. The task of the circuit arrangement is the activity of the current during the shutdown of a switch, e.g. a switching transistor to entertain, so that a smooth transition to the switched-off state, chne induced transients will achieve. Such transients occur on, especially in switching regulators, their effect in the periodic switching on and off of the current in a9, a choke coil or a primary winding of a transformer containing circles. Is not a delay circuit in a switching regulator built in, so in the switching transistor, at the moment the power is switched off, large power surges, as well as overvoltages, which, as a result of the exceedance the permissible range of the characteristic curve can lead to the destruction of the transistor. The power losses occurring in the switching transistor reduce the efficiency of the switching regulator. At the same time, due to the steep changes in current and voltage, large radio interference is caused. @ie delay the Power cut doshall is a technical question of great importance.

A circuit applicable in switching regulators is known, e.g. in a bulletin "Mullard Technical Communications, @r 127, July 1975" is. The known, in Fig. 1 visible circuit arrangement for delayed power cut-off consists of a delay capacitor C2 and one connected in series with it Bntladedeicde D1, to which a charging resistor R is attached. The remaining, are components drawn in Fig. 1; a load containing an inductive component 0, which takes the output power of the rectangular shape, with an adjustable ratio the conduction time #T to the duty cycle T controlled switching transistor T1, and on Input capacitor Cl, which is parallel to the input terminals of the supply voltage is switched on. The delay circuit can either be parallel to the load 0, according to Fig. La, or be connected in parallel to the switching transistor Tl.

In switching regulators with galvanic isolation, the load is 0 Shape of the primary winding of a transformer. its secondary winding with a, Rectifier diodes and a low-pass filter containing network is connected. Sololle arrangement is made visible in Fig. La. In switching regulators, they are more galvanic Separation is common in the form of a low pass filter, with a load O Choke in series and a diode in parallel with the input, how to do it in fig. Ib sees.

During the switching off of the switching transistor T, the continuity of the electricity in the inductive load 0 insured thanks to the electricity delivery the delay capacitor C2 connected in series with the discharge diode D1, what brings the expected effect of the delayed power cutoff.

before each next switch-off cycle of the switching transistor Tl must the delay capacitor C2 can be recharged again, to a voltage that should be the same as the supply voltage.

This is achieved with the help of the charging resistor P, in the period when the switching transistor T1 is conductive and the discharge diode D1 is blocked Remain state.

There is a disadvantage of the delay circuit described above in the fact that with each charge reversal of the delay capacitor, energy is lost arise which is proportional to the capacitance and to the square of the capacitor emerging tension. With regard to the efficiency of the switching regulator It is therefore not possible to use a large capacity for the reduction the switching losses occurring in the switching transistor, as well as - overvoltages and radio interference would be more beneficial.

A procedure has been published (Offenlegungsschrift No. 2719026 B R D), which aims to reduce switching losses. According to this procedure an additional branch is to be introduced into the circuit shown in Fig.la, which consists of a choke L and an auxiliary diode D2 connected in series with it. The branch is between the connection node of the delay capacitor C2 with the discharge diode D1 on the one hand, and the positive pole of the supply voltage on the other hand included, wherein the cathode of the auxiliary diode is geriohtet to the positive pole, as it Fig.2 shows.

The delay effect of elements C2 and D1 during switch-off of the switching transistor T1 is the same as above, in reference to the, in the circuit shown in Fig.la has been explained. The one in the inductance of the primary winding The current excited by the transformer flows after the blockage of the Switching transistor uninterrupted because it is taken from the delay capacitor. Consequently the capacitor discharges and, ultimately, its top layer becomes negative compared to the negative pole of the supply voltage. So the polarity reversal arises, which in the entrusted circuit for the reloading required in the next step of the delay capacitor is indispensable. If the switching transistor T1 in turn introduced into the conductive state, the lower layer of the delay capacitor positive compared to the positive pole of the supply voltage. With this condition arises a current through the choke L with the auxiliary diode D2 in series, which the discharge of the Delay capacitor begins. The voltage on the capacitor goes above zero, but the current excited via the throttle continues to flow and leads to further recharging of the capacitor.

The transshipment ends only after half of the oscillation period of the IC2 resonance circuit at the moment when the current tries to reach zero to change its direction in which the auxiliary diode prevents it.

The circuit arrangement under consideration had some disadvantages limit their applicability to a significant extent.

The delay capacitor C2 should be reversed to a voltage that is equal to the supply voltage. However, this is only possible in the resonance circuit under the condition that the voltage occurring at the capacitor C2 at the moment when the latching transistor T1 is kept in place is negative and not less than the supply voltage in terms of its magnitude. Such a condition is not to be fulfilled if either the supply voltage or the load current does not remain constant during the operation of the Sohaltreglepra. It therefore turned out to be necessary to provide an additional charge reversal of the delay capacitor in spite of the resonance charge. The purpose already known from Fig.la, and retained in Fig.2 charging resistor R, which again leads to undesirable energy losses.

The resonance charge reversal of the capacitor C2 can only become effective on condition that the conduction time dT of the switching transistor T1 is not shorter than half the period of oscillation of the LC2 circuit. The smallest admissible Value of the factor; is therefore limited, which in turn limits the stabilization range of the switching regulator leads. You have to take this into account when choosing the L and C2 values.

The next disadvantage of the circuit under consideration according to Fig.2, in which the resonance charge of the delay capacitor is based on the fact that it is in no way applicable in cases where the load 0 is the one shown in Fig.lb Takes shape. With such a load, during the blocked state of the switching transistor T1 there is no polarity reversal of the voltage at capacitor C2. After switching on of the switching transistor Tl therefore remains the auxiliary diode D2 always blocked, and the Choke is not presented as an opportunity to participate in the reloading of the capacitor.

The invention is based on the problem of lossless reloading of the delay capacitor without the disadvantages of the known Keep circuits.

The created circuit arrangement for delayed Stromaussohaltung in an inductive circuit, especially for switching regulators, unifasst one, in parallel to the inductive load included branch, consisting of a delay capacitor in series with a discharge diode, and another branch consisting of a choke in series with an auxiliary diode, where the ICathode of the diode is the positive pole of the Supply voltage, the Throttle connection, on the other hand, the connection node of the delay capacitor with the discharge diode closed.

The circuit arrangement according to the invention contained an auxiliary transistor, its emitter is with the negative pole of the supply voltage, and the collector with connected to the anode of the auxiliary diode, a square-wave control signal being fed to the base is to be synchronous with the control signal tor of the base of the switching transistor target.

In the circuit arrangement according to the invention, the charge reversal of the delay capacitor takes place without energy losses and in a shorter time than in the previously known positions. As a result, it is possible to use the delay capacitor with a larger capacitance, especially with regard to the attenuation of the rcansl - states Reliability of the switching transistor, as well as low radio interference, in that a high efficiency of the switching regulator is obtained. The charge reversal of the delay capacitor is always effective and independent of the supply voltage and the load current. The circuit arrangement according to the invention can be used in switching regulators with galvanic isolation, in which the load has the form of the primary winding of a transformer, and just as well in level regulators without galvanic isolation, where the load is in the form of a low-pass filter, with a choke in series, and a diode is implemented in parallel with the input of the filter.

The subject matter of the invention is explained below, with reference to a, in Fig.3 illustrated embodiment of one equipped with the delay circuit Switching regulator, explained in more detail.

The basic components of the solenoid control are: the, with adjustable ratio of the line §U to the duty cycle T controlled switching transistor Tl 'the, inductive portion containing load 0, which takes the output power of the right waveform, and the input capacitor C1, which is switched on in parallel with the input terminals of the supply voltage is. The elements of the delay circuit known from the prior art are: the delay capacitor C2 in series with the discharge diode D1, in parallel to the load 0 closed, and the choke L in series with the auxiliary diode D2, on the one hand with the connection node of the delay capacitor C2 with the Discharge diode D1, on the other hand connected to the positive pole of the supply voltage.

A new, essential element of the circuit according to the invention forms the auxiliary transistor T2, the emitter of which is connected to the negative pole of the supply voltage, the collector with the anode of the auxiliary diode and at the same time with the connection of the Choke L connected, with the base being connected to a square wave signal, synohronisoh with the base of the switching transistor T1 is controlled.

The simultaneous control of the bases of both transistors can be done with With the help of an additional winding on the one used to control the switching transistor Achieve transformer. Another solution is to control the base of the translator T2 from an auxiliary winding, either on the load transformer in switching regulators with galvanic isolation, or on the choke in the low-pass filter. The base of the transistor T2 can also consist of a load 0 in parallel to dep Voltage divider can be controlled.

The effect of the holding arrangement according to the invention is as follows: When the switching transistor T1 is switched on, the auxiliary transistor is also activated at the same time Ta switched on. The, at the moment of Activation at the cathode the voltage generated by the discharge diode D1 will temporarily become positive. in the the time passes, but, as a result of the flowing through the choke L and the transistor T2 Discharge current, the voltage goes to zero. After a good reloading, the tension will be across the capacitor C2 is equal to the supply voltage. That way, for the moment the capacitor will prepare for the next switching off of the switching transistor, to perform its delay task. The one connected with the charge reversal of the capacitor C2 Energy is provisionally in the, through the conductive transistor T2 in series with the diode D1 short-circuited choke L.

While the sohalttransistor T1 is being kept off, the continuity of the current flowing through the inductive load is achieved by the fact that the current is supplied from the capacitor C2 as it is is common in the previously known solutions. At the same time, the auxiliary transistor T2 is also blocked, and as a result the energy stored in the choke L is returned to the source of the supply voltage via the auxiliary diode D2 without losses.

An additional, excellent property of the invention Circuit consists in that at the moment of switching off the switching transistor Tl the discharge diode D1 is introduced into the conductive state, and therefore capable is to take over the power surge in a moment. In this state none voltage peaks originating from the inertia of the carriers arise across the diode, which are usually visible when you look at a previously non-conductive semiconductor diode supplies a current surge in the direction of the discharge.

When selecting the elements in the circuit arrangement according to the invention The following must be taken into account: the process of recharging the delay capacitor about the Throttle 1, should not take longer than #T, the output the, in this time in the throttle L stored energy, however, should be in the Time (1 - #). T must be completed.

The time of charge reversal of the delay capacitor C2 forms in the involved circuit arrangement only a quarter of the oscillation period of the LC2 circuit. Be it so desired, you can track the time, with the help of one, in the throttle L to the moment the residual current left behind when the auxiliary transistor T2 is switched on, even shorter maohen. In the circuit shown in Fig. 2, however, the resonance charge lasts of the capacitor C2 a half cycle of the LC2 circuit, with other conditions for the effective charge reversal cannot always be achieved in this circuit.

Claims (1)

Iatent claim circuit arrangement for the revamped power cut-off in inductive circles, especially for switching regulators, containing one, in series with a discharge diode connected delay capacitor, in parallel with the inductive Load lock closed, and a throttle, on the one hand with the connection node the cathode of the discharge diode with the delay capacitor, on the other hand with the Anode of an auxiliary diode connected by connecting the cathode of the auxiliary diode to the positive pole the supply voltage is connected, d u r c h, e k e n n n z e i ¢ h n e t that contained an auxiliary transistor (T2 j, whose emitter is connected to the iniispol the supply voltage,, collector with the connection node of the choke (L) with connected to the anode of the auxiliary diode (D2), with the base sin square-wave control signal is supplied, which is simultaneously with the control signal at the base of the switching transistor should be.