FR2502418A1 - CUT-OUT POWER SUPPLY FOR ELECTRONIC DEVICES - Google Patents

Abstract

This switched-mode power supply consists of a first regulated switched-mode power supply in the form of a parallel voltage converter with an inductance and a controlled switch, and a second regulated switched-mode power supply with a controlled switch in series with an inductance and a primary winding of a current transformer, the secondary winding of which supplies the base current for the controlled switch and is bypassed by a controlled thyristor which can be switched on and off by a control circuit. The invention consists in that the two switched-mode power supplies are coupled to one another via a transformer, as a result of which the regulated overall switched-mode power supply formed by this means is capable of outputting even very low powers with good efficiency in standby mode, in spite of a wide mains voltage range, even if the power supply is designed for high powers.

Description

Switching power supply for appliances
electronic.

 The present invention relates to a regulated switching power supply making it possible to obtain one or more regulated output voltages from a variable input voltage. Switching power supplies of this type are known and are constituted by a switching circuit supplied with direct voltage and being in the form of an inductor and a controllable switch mounted in series with the inductor, this circuit switching element being associated with a transformer whose primary winding is arranged in the circuit of the controllable switch and whose secondary winding delivers the control current of the controllable switch, a measurement resistance by J> which passes the control current being by The measurement resistance is mounted between the cathode of a thyristor and a reference potential. The thyristor is mounted in parallel on the secondary winding of the transformer and switches the controllable switch when the current exceeds a predetermined limit value (US patent 3,925,717 and patent FR 2,431,807). There are also known switching power supplies in the form of parallel voltage transformers (patent DE 23 36 110) comprising a controlled switch connected in series with an inductor in which is stored magnetic energy which, when the switch command is open, is sent to a rectifier circuit to produce operating voltages. If switching power supplies thus formed are designed for large powers, then it is very difficult to obtain low no-load powers, or else known voltage transformers are not suitable for supplying very low powers such as those which are necessary for example for the standby operation of an electronic device. Therefore, the known circuits do not work reliably because, when the electronic device draws small powers, the duration of the switching of the switching transistor must not fall below a few microseconds because, otherwise, the block switching power supply no longer starts. In this case, the frequency of the switching power supply must be very greatly reduced, but this involves the drawback of audible noise produced by mechanical oscillations, which are caused by the magnetic field of the transformer windings or by magnetostriction electrolytic capacitors. Due to the reduced duration of the conductive state of the transistor, the efficiency of the circuit is also significantly reduced. For a determined nominal power of, for example, 180 W, a power in standby operation is obtained between 15 and 25 watts. This depends on the characteristics of the circuit adopted to limit the changes in voltage over time (rise in voltage) of the power transistor, on the characteristics adopted to limit the peak voltage as well as on the efficiency of the power transformer when the voltage pulses are very short.

 This is why the object of the invention is to improve a switching power supply so that it is possible to obtain standby operation requiring only a very low no-load power with simultaneously a voltage range large input, for example between 90 and 270 V, the combinative power supply unit, however, being able to provide a high nominal power, these improvements relating to a power supply unit & cutting for electronic devices, constituted by a first regulated switching power supply consisting of a return generator comprising a switch constituted by a transistor and a diode associated in an anti-parallel arrangement between an inductor. to which a DC voltage is applied and a capacitor connected in series to this inductor, as well as a current transformer whose primary winding is mounted between the inductor and the collector terminal of the transistor and whose l the secondary winding is connected, on the one hand, to the base of the transistor and, on the other hand, to a measurement resistor, the secondary winding providing a base current proportional to the collector current of the transistor, this base current determining a voltage drop in the measurement resistor connected to the cathode of a thyristor, which voltage drop triggers the thyristor when a predetermined current value is exceeded, the thyristor being mounted in parallel on the secondary winding of the current transformer, said switching power supply further comprising a second regulated switching power supply in the form of a parallel voltage transformer comprising a controlled switch connected in series with an inductor in which, at the passing state of the controlled switch, is stored magnetic energy which, in the open state of the controlled switch, is sent to a rectifier circuit to create tens operating ions for the electronic device.

 This result is obtained in accordance with the invention by the fact that the two switching power supplies are coupled to each other by means of a magnetic circuit in such a way that the winding of the inductor of the first switching power supply and the winding of the inductance of the second switching power supply constitute a transformer, the transformation ratio of the windings being chosen so that the switching power supply works when also many large powers as low powers are taken from the second switching power supply and in a large range of the input voltage of the first switching power supply.

 In the second switching power supply, a control circuit can be provided for the controlled switch which keeps it open when the electronic device draws a lower power, and an auxiliary winding mounted on the core of the transformer, this winding transmitting in connection with a rectifier circuit a very low power from the first switching power supply.

 Advantageously, the control circuit of the second switching power supply which is synchronized by a winding of the transformer as a function of the output voltage (UB) maintains the latter constant.

 In order to maintain the rectified peak voltage at a constant level during the return of the first switching power supply, the control circuit appropriately shifts the ratio between the duration of the return and the duration of the period, so that 'a constant area corresponding to the total range of the input voltage remains constant.

 To keep the peak voltage of the tips at the transistor constant, the control circuit appropriately determines the ratio between the duration of the return and the duration of the period.

 Finally, the adjustment circuit of the first switching power supply unit shifts the conduction point of the switching transistor so that the output power is kept constant regardless of the input voltage.

 It can therefore be seen that the solution to the problem consists in the combination of two known separate switching power supplies, forming, thanks to their combination and in connection with the control circuits, a regulated switching power supply of a new type with the targeted properties.

The invention will now be described in more detail with the aid of a nonlimiting exemplary embodiment and with reference to the attached drawings in which:
FIG. 1 represents a diagram of the electrical circuit of the power supply unit, and
FIG. 2 represents various curves of the current and the voltage at the switching points indicated in FIG. 1.

 The primary switching power supply 1 is supplied by an alternating voltage VN which is rectified using a rectifier 6 so that the direct voltage VA is applied to a filtering capacitor 7. The direct voltage is sent to a inductance 5 using a controlled switch 8. The switch 8 operates in both directions, considered from the point of view of the current, because it is constituted by a parallel connection of a transistor 9 and a diode 10, and in a single direction considered from the point of view of the current. The circuit is supplied by the voltage VA and works in a known manner as a counter-reaction generator. A distinction is then made between a go phase having a duration "ta" and a return phase having a duration "tr". During the second half of the go phase "ta", the switch 8 is closed, and it follows that an upward sawtooth current flows through the inductor 5. At the end of the outward period, the switch 8 opens because the transistor 9 is then closed by a control circuit using of a thyristor 11. The energy Es which is stored in inductance 5 and which corresponds to Es = 1/2. L. I2, where Im = 1/2. GO . ta / L5, is transmitted during the return phase "tr" to the capacitor 12 in which the voltage is in sinusordal form. Then, this energy is sent with a current directed in opposite direction in the inductance 5. When the voltage in the capacitor 12 fell to the value zero, the diode 10 opens the switch 8 at the end of the return period, and from this point begins a new period to go. A small part of the energy Es is lost and it follows that the no-load power is PO = k. Es. f, where "f" represents the frequency and "kZ a factor between 0.2 and 0.5 depending on the quality of the circuit.

 From the above, we can deduce the following.

 The voltage at inductance 5 is equal to the voltage VA during the outward period. The return voltage is sinusofdale and its importance is such that its average value during a period T = ta + tr is zero.

The peak value of this return voltage is however determined by the voltage VA and by the ratio tr / T. when a switching circuit is mounted in parallel on the inductor 5, this circuit draws a significant amount of energy during the return period. The residual energy remaining in the inductor 5 can then become too low to bring the switch 8 and the diode 10 to the conducting state, which means that the circuit can no longer work.

Any load on the circuit during the return phase has an influence on the duration of the return "tr" as well as on the shape of the voltage curve, and this results in a modification of the frequency and of the pulse ratio tr / T. From the formula
PO concerning the no-load power, it appears that Es must be kept as low as possible. This is obtained by adding a secondary switching power supply which is magnetically coupled using a transformer 3 to the primary switching power supply 1, the transformation ratio between the windings of the transformer being chosen so that the voltages and currents have an optimal value in the secondary switching power supply. The switch 8 of the primary switching power supply 1 is coupled via a current transformer 13 to a control circuit 14, a winding 15 located in the collector circuit of the transistor 9 supplying the basic current via the winding 16. When the collector current exceeds a predetermined limit value, a corresponding current passes through the measurement resistor 17, which switches on a thyristor 11, the transistor 9 being therefore closed. Therefore, the thyristor 18 of the switching power supply 2 closes before the end of a period.

 The secondary switching power supply unit 2 comprises a thyristor 18 which is coupled to the primary power supply unit 1 via the winding 4 which constitutes, in known manner, with the storage coils 19 and the capacitors 20 and via rectifiers 21, a parallel voltage transformer. Both the primary power supply 1 and the secondary power supply 2 are influenced as a function of demand via the control switches 22, 23 so that various operating conditions can be obtained. Thus, thanks to the control circuit 23 triggered by an auxiliary winding 27, the peak value of the peaks of the voltage of transistor 9 is kept constant, because the ratio tr / T is modified by the adjustment circuit. .When the voltage VA changes, the area of the voltage curve can also be kept constant using the adjustment circuit 23, this signifying that, for a large continuous voltage range VA, T and therefore "ta "are changed so that the VA product. your remains constant. The switching frequency of the primary part 1 is therefore appropriately controlled.

 Thanks to the switching power supply described, it is also possible to obtain a command in the case where the power supplied must be kept constant regardless of the input voltage VA. This can be obtained by means of the command 23, so that the tr / T ratio is modified correspondingly.

Conversely, the frequency and therefore the tr / T ratio can also be kept constant, the switch 18 being switched using the secondary control circuit 22 so that the output power is limited. In this case, the peak voltage is a function of the input voltage
VA during the return.

 In the case where it is necessary to modify the pulse ratio ta / T as a function of the load, the information of the secondary peak current appears transferred to the primary side, the base current of the transistor 9 supplying to the resistor 17 , as an image of its collector current, a control voltage suitable for the adjustment circuit 23.

 When it is desired to take a low power, for example the standby power for an electronic device, the thyristor 18 can be closed via the control circuit 22 so that only a low power is taken from the winding auxiliary 25.

 The arrangement thus described therefore makes it possible to obtain standby operation of the electronic device which is independent of the network. If a voltage independent of the input voltage V A is necessary for this operation, the area VA can be kept constant. ta using the adjusting circuit 23, and the voltage is obtained from the rectification of the return because the peak voltage is then constant.

The power that oscillates in the system comes from the E5 / T ratio. The no-load power represents a value which can be between 20% and 50% of this power. When the no-load power is so low that the sum of this and the no-load power Po is less than Es / T, the circuit can work stably with the rectification of the feedback. A much better yield is thus obtained during the standby operation, a yield which would be impossible to obtain with the switching power supplies known up to now.

 In FIG. 2 are represented diagrams of the voltage and the current which appear at the switching points indicated in a, b, c, d and e.

 FIG. 2a represents the shape of the voltage at the outlet of the winding 4, in the form ue. When one has a peak value of the peaks Uess and a maximum value ua during the duration wta ", one obtains a charge or discharge current passing through the winding 19 which corresponds to that of FIG. 2b due to the ignition of thyristor 18 during the second half of the outward journey, this thyristor being opened again during the return. At thyristor 18, the shape of the voltage is that shown in FIG. 2c. The voltages at the level of the coil 19 and diode 21 are shown in Figures 2d and 2. Figure 2 concerns the case where the duration of the discharge is longer than the duration of the return "tr".

Claims (6)

 1. Switching power supply for electronic devices, consisting of a first regulated switching power supply consisting of a return generator comprising a switch constituted by a transistor and an associated diode in an anti-parallel arrangement between an inductor to which a DC voltage is applied and a capacitor connects in series to this inductor, as well as a current transformer whose primary winding is mounted between the inductor and the collector terminal of the transistor and whose secondary winding is connected, on the one hand, to the base of the transistor and, on the other hand, to a measurement resistor, the secondary winding providing a base current proportional to the collector current of the transistor, this base current determining a fall voltage across the measurement resistor connected to the cathode of a thyristor, which voltage drop triggers the thyristor when a predetermined value of the co is exceeded urant, the thyristor being mounted in parallel on the secondary winding of the current transformer, said switching power supply further comprising a second regulated switching power supply being in the form of a parallel voltage transformer comprising a controlled switch connected in series with an inductor in which, in the conducting state of the controlled switch, is stored magnetic energy which, in the open state of the controlled switch, is sent to a rectifier circuit to create voltages of operation for the electronic device, characterized in that the two switching power supplies (1) and (2) are coupled to each other by means of a magnetic circuit so that the winding of the inductor (5) of the first switching power supply unit (1) and the winding of the inductance (4) of the second switching power supply unit (2) constitute a transformer (3), the transformat report ion windings being chosen so that the switching power supply works when high powers as well as low powers are taken from the second switching power supply (2) and in a large range of the voltage d input of the first switching power supply (1).  2. Switching power supply according to claim 1, characterized in that there is provided in the second switching power supply (2) a control circuit (22) for the controlled switch (18) and which maintains this open when the electronic device draws a lower power, and in that an auxiliary winding (25) is mounted on the core of the transformer (3), this winding transmitting in connection with a rectifier circuit (26) a very low power from the first switching power supply (1).  3. Switching power supply according to claim 1, characterized in that the control circuit (22) of the second switching power supply (2) which is synchronized by a winding (24) of the transformer (3) in as a function of the output voltage (UB) maintains the latter constant.  4. Switching power supply unit according to claim 1, characterized in that, in order to maintain the rectified peak voltage at a constant level during the return of the first switching power supply unit (1), the circuit of control (23) appropriately shifts the ratio between the duration of the return and the duration of the period (rev / T), so that a constant area (VA. ta) corresponding to the total range of the input voltage (VN) remains constant.  5. Switching power supply according to claim 1, characterized in that in order to maintain constant the peak voltage of the tips (Uss) at the transistor (9), the control circuit (23) determines so appropriate the relationship between the duration of the return and the duration of the period (tr / T).  6. Switching power supply unit according to claim 1, characterized in that the control circuit (23) of the first switching power supply unit (1) shifts the closing point of the switching transistor (9) so that the output power is kept constant regardless of the input voltage (VA).