FR2812475A1 - Supply circuit for equipment frequently on standby, comprises autofeeding circuit and voltage doubling starting circuit to start integrated circuit which controls interruptor in transformer primary - Google Patents

Abstract

The supply circuit consists of an alternating current supply (100) and rectifier(101) which feed a primary winding (103) connected to a switch (105) operated by an integrated circuit (109,110). A voltage doubling starting circuit (118) stores energy in a capacitance (300) during an initial start and supplies it to the integrated circuit subsequently using switches (303,404). After start operation is supplied by an autofeed circuit (107)

Description

The subject of the present invention is a switching power supply

  a switching power supply device. More particularly, the invention relates to switching power supply devices which find their advantage in their use within devices which are often put in a standby state. In general, the field of the invention is therefore that of television or decoder type devices. It can advantageously be implemented in all the devices which can be put in a standby state. The device according to the invention makes it possible to reduce the energy consumption of a device in standby state, the energy being drawn from a mains supply which serves to power the device considered in particular when this

last one is on standby.

  In the state of the art, a switching power supply is most often produced in the form of a circuit similar to the circuit shown in FIG. 1. In this figure, a mains supply 100 delivers an alternating voltage whose effective value is for example 220 Volts. A circuit 101 of the voltage rectifier bridge type, which in a preferred application can be of the Graetz bridge type, makes it possible to obtain a rectified voltage at the output of this circuit. The operation of such a voltage rectifier bridge is known: it operates with rectifiers 115, which are most often diodes, and a capacity of the chemical capacity type 116, these being arranged in such a way that the positive alternation and the negative alternation of the alternating voltage delivered by the mains supply are both rectified and thus provide a direct voltage at the output of the rectifier bridge. A transformer 102 which is composed of a primary winding 103, which receives primary power, and secondary windings 104, which provide secondary power, is arranged so that the primary winding can receive the primary power supplied by the bridge rectifier. One end of the primary winding 103 is therefore connected to the output of the voltage rectifier bridge 101, the other end being connected to a switch device 105 itself connected to ground 106. The switch device 105 may be a transistor bipolar or effect

field.

  One of the secondary windings 104, called the service winding 113, is connected on the one hand to ground and on the other hand to a self-supply circuit 107 which is composed in particular of a capacitor 108 and a diode 117. A integrated circuit 109 which controls the opening and closing of the switch device 105 receives a current from the self-supply circuit 107 at a supply input. A starting circuit 111 is connected to the output of the voltage rectifier bridge 101 in parallel with the transformer 102. The start-up circuit 111 is also connected to the power supply input 110 of the integrated circuit 109. The start-up circuit 111 consists in particular of a resistor 112, called

voltage drop resistance.

  In a known manner, the integrated circuit 109 for controlling the cutting of the primary power in a switching power supply starts in a mode where it draws its supply current directly from the mains supply 100. The operation of the integrated circuit 109 takes place under a low voltage - from 15 to 20 Volts -, the use of the voltage drop resistor 112 is essential. Thus, during the start-up phase, the integrated circuit 109 is supplied by the start-up circuit 111 which makes it possible to apply an appropriate voltage to the supply input 110 of the integrated circuit 109. Significant power is lost in this resistor 112 During the start-up phase, the integrated circuit delivers at its output a signal which controls the switch device 105 so as to operate the transformer 102 so that the latter delivers the adequate powers in the secondary windings 104, and in particular in the winding of service 113. Thus, during the start-up phase, the service winding 113 receives a certain energy which is stored in the capacity 108 of the self-supply circuit 107. A sufficient quantity of energy is then contained in the capacity 108 to supply the integrated circuit 109 for a certain time. Once started, that is to say in steady state, the integrated circuit 109 is self-powered by the service winding 113 of the transformer 102, whose capacity 107 is constantly recharged, but the power which has been dissipated in the

  voltage drop resistance 112 remains lost.

  More recent switching power supply controller integrated circuits include in the starting circuit 111 a high voltage switch 114 which opens when the switching power supply has started. This avoids losing power in the falling resistance of

  voltage 112 when the switching power supply operates in steady state.

  However, when the useful consumption becomes low, in particular in the case of the standby of the device considered, it is disastrous for the yield to continue to provide a significant primary power while the secondary power is underused. Modern integrated circuits are also provided to improve performance in this case. To this end, in the case of standby, these integrated circuits operate in a mode called burst mode when the secondary consumption becomes low, and therefore in particular when the device considered

is on standby.

  FIG. 2 is a timing diagram which shows the shape of the signals delivered by the integrated circuit 109 when the latter operates in burst mode. In FIG. 2, it can be seen that the integrated circuit emits pulses 200 non-continuously over time. Each of these pulses has a sufficient width, that is to say that it lasts long enough, to allow the switching device 105 to close for a period of time.

  sufficient to ensure correct conduction for a few moments.

  In practice, the time during which the switching device 105 is closed corresponds approximately to the duration of a pulse 200. The pulses 200 are grouped in the form of packets 201 of pulses, each packet of pulses 201 preferably comprising the same number of pulses 200. Each packet of pulses 201 generally comprises between 1000 and 2000 pulses. Between two pulse packets 201, no signal is emitted by the integrated circuit 109. The periods between two pulse packets 201 are called rest periods 202. A pulse packet 201 can last from 5 to 10 milliseconds . Preferably, all of the pulse packets have a similar duration and are separated by rest periods equal to about three times the duration of a pulse packet. So for a packet of pulses that lasts 5-10 milli

  seconds, the following rest period can last 20 to 30 milliseconds.

  In order to ensure optimal operation of the switching power supply, the different pulse packets 201 are identical and are separated by rest periods 202 of constant duration. About 5 milliseconds before each transmission of a pulse packet 201, the high-voltage switch 114 is placed in the closed position, for a sufficient time to reach an established speed during which the integrated circuit 109 will be supplied by the circuit of self-supply 107, in order to ensure the start-up of the integrated circuit 109. On the timing diagram shown in FIG. 2, a start-up period 203 thus precedes each transmission of a pulse packet 201. This start-up period 203 s' completes when the integrated circuit 109 has delivered a sufficient number of pulses for the transformer 102 to have had time to generate sufficient secondary power to charge the capacity 108 of the self-supply circuit 107, so that the circuit integrated can continue

  producing the last pulses of a pulse packet 201 considered.

  Once the start-up period 203 has ended, the high-voltage switch device 114 is open, the integrated circuit 109 then being supplied by the self-supply circuit 107 whose capacity 108 has had time to

  charge during the start-up phase.

  Thus, in this particular mode, the integrated circuit 109 delivers a signal by alternating periods of operation and rest, the power lost in the voltage drop resistor 112 during the start-up phase being weighted by the duty cycle between the operating time and the duration of the operation and rest cycle. However, in this mode, the number of starts is much greater than in a normal mode because a start phase is necessary for the emission of each packet of pulses 201, the capacitance 108 of the self-supply circuit 107 is subsequently discharging completely to generate the set of pulses contained in a packet of pulses. The share of power required for starting therefore becomes significant in the

  total consumed from the mains supply 100.

  The device according to the invention overcomes this problem. To this end, the device according to the invention implements means for limiting the energy consumed on the mains supply for each start-up phase of the integrated circuit. According to the invention, a starting circuit comprises a reactive impedance component in order to store reactive energy transmitted during a first starting phase, and to use this reactive energy in the starting phases which follow this first starting phase. By reactive impedance component,

  the components of the capacitance or inductance type are designated.

  The invention therefore relates to a switching power supply device involving a transformer comprising a primary winding and at least one secondary winding to perform a cutting operation of a primary power transmitted to the transformer, said device comprising an integrated circuit controlling the opening and closing of a switch device connected to the primary winding of the transformer, a starting circuit to ensure, via a power supply input of the integrated circuit, the supply of the integrated circuit for each start of said integrated circuit, and a self-supply circuit to supply the integrated circuit with power after it has started, characterized in that the start-up circuit

  has a reactive impedance component.

  In a preferred embodiment of the device according to the invention, the starting circuit is connected to a mains supply which supplies a power used by the transformer. The starting circuit includes a second switch device arranged between the reactive impedance component and the mains supply. In a preferred embodiment of the invention, the reactive impedance component is included in a voltage doubling circuit which is itself connected to the power supply input of the integrated circuit. Preferably, and for reasons of economy, the component to

  reactive impedance is a capacitance.

  The invention and its different applications will be better understood on

  reading the following description and examining the figures which

  I'accompagnent. These are presented for information only and in no way limit the invention. The figures show: - in Figure 1, already described, an example of a switching power supply device known from the prior art; - in Figure 2, already described, a timing diagram illustrating the operation of the switching power supply device in burst mode; - in Figure 3, a first embodiment of the switching power supply device according to the invention; - in Figure 4, a second embodiment of the device

  switching power supply according to the invention.

  In FIG. 3, all of the elements present in the circuit described in FIG. 1 are always part of the circuit shown and are always designated by the same references, with the exception of the starting circuit 111 which is replaced by another circuit start 118 connected on the one hand to the mains supply 100 and on the other hand to the power supply input 110 of the integrated circuit 109. In this figure, the start circuit 118 comprises a component 300 with reactive impedance, a diode 301, a voltage drop resistor 302, a first high voltage switch device 303 and a second high voltage switch device 304. The component represented in FIG. 3 is a capacitor, but a component of the inductance type could also have been used. The reactive impedance component 300 is a dipole, one of whose terminals is directly connected to the mains supply 100 and the other terminal of which is connected to the anode of the diode 301, the cathode of which is connected to ground. A connection point A located between the reactive impedance component 300 and the diode 301 is connected to one of the terminals of the voltage drop resistor 302, the other terminal of the voltage drop resistor 302 being always connected to the input d power supply 110 of the integrated circuit 109. In this figure, the high voltage switch 303 is arranged at the output of the starting circuit, for example between the mains supply 100 and the reactive impedance component 300. The second high voltage switch 304 is arranged between the point of

  connection A and the voltage drop resistor 302.

  The operation of the circuit described in FIG. 3, when it is used in burst mode, is as follows: for a first start-up phase, the high-voltage switch device 303 and the second high-voltage switch device 304 are closed so as to that the integrated circuit 109 is subjected to a voltage suitable for starting, that is to say 15 or 20 volts. By first start-up phase is meant a start-up phase during which the integrated circuit 109 draws its energy directly from the mains supply 100. The voltage drop resistor 302 makes it possible to apply an appropriate voltage to the input of the integrated circuit 109 of the voltage supplied by the mains supply, this voltage having been clipped due to the presence of the capacitor 300. The presence of the diode 301 makes it possible to obtain an almost continuous voltage at the input of the integrated circuit during the positive half-waves of the voltage of the mains supply 100, the negative half-waves are not transmitted. During this first start-up phase, which corresponds to the sending of a first packet of pulses 201, the presence of the capacity 300 makes it possible to store reactive energy transmitted by the mains supply 100 and which could not have been be operated directly by the integrated circuit. During the start-up phases which will follow, which correspond to the emission of the following pulse packets 201, this reactive energy will be used to supply the integrated circuit 109. For this purpose, for each start-up phase which follows the first phase the first high-voltage switch device 303 remains open, while the second high-voltage switch device 304 closes

during the start-up phase.

  FIG. 4 proposes an improvement of the circuit presented in FIG. 3. The circuit represented in FIG. 4 uses in the starting circuit a voltage doubling circuit 400 consisting, in this figure, of the capacity 300, of the diode 301, d a second diode 401 whose anode is connected to the connection point A, and a second capacitor 402 connected on the one hand to the cathode of the second diode 401 and on the other hand to earth. A second point of the connection B disposed between the second diode and the second capacitor is connected to a terminal of the drop resistor 302, the other terminal of which is always connected to the power input 110 of the integrated circuit 109. In this figure , the connection point A is no longer connected to the drop resistor 302. The second switch device 304 is replaced by a second switch device 404 disposed at the output of the starting circuit 118, for example between the connection point B and the resistance

voltage drop 302.

  The presence of such a voltage doubling circuit makes it possible to take advantage of both the positive and negative alternations of the mains supply 100 to supply the input of the integrated circuit. This voltage doubling circuit has a known operation which will not be repeated here. It could also be carried out using other components, and in particular using inductors which are reactive impedance components. Here again, a first start-up phase during which the two switch devices 303 and 404 are closed makes it possible to store reactive energy, transmitted by the mains supply 100, in the reactive impedance component 300, the following start-up phases using this charged energy for

  restart the integrated circuit 109.

  In all of the figures which have just been described, the voltage drop resistance can be incorporated into the integrated circuit. This does not change anything in the operation of the device considered. The value of the reactive impedance component 300 must be chosen so that the time constant of the series association of this component and of the voltage drop resistance is low compared to the period of the mains supply. Thus, a phenomenon of current peak which could possibly be observed becomes negligible. For example, the capacity 300 can have a value of the order of 500 nanoFarads, for example 470 nanoFarads, and the resistance

  voltage drop a value of the order of 10 Ohms.

  A control circuit, not shown in the figures, makes it possible to control the opening and closing of the switch devices of the starting circuit. This control circuit is moreover capable of determining a state of charge of the reactive impedance component 300. Thus, if the charge of the reactive impedance component 300 proves insufficient to ensure a new start-up phase, the control circuit causes closing the switch device 303 in order to trigger a new

first start-up phase.

Claims (7)

  1- Switching power supply device involving a transformer (102) comprising a primary winding (103) and at least one secondary winding (104) to perform a cutting operation of a primary voltage transmitted to the transformer (102), said device comprising an integrated circuit (109) controlling the opening and closing of a switch device (105) connected to the primary winding (103) of the transformer (102), a starting circuit (118) for ensuring, via a power supply input (110) of the integrated circuit (109), the power supply of the integrated circuit (109) for each start of said integrated circuit, a self-supply circuit (107) for supplying power to the integrated circuit (109) after its starting characterized in that the starting circuit (118)   includes a reactive impedance component (300).   2- Switching power supply device according to claim 1 characterized in that the starting circuit (118) is connected to a mains supply (100) which supplies a voltage used by the transformer (102).   3- Switching power supply device according to the preceding claim characterized in that the starting circuit (118) comprises a switch device (303) disposed between the impedance component   reactive (300) and the mains supply (100).   4- Switching power supply device according to one of   claims 2 or 3 characterized in that the starting circuit (118)   comprises a second switch device (304; 404) disposed at the outlet of the starting circuit (118).   - Switching power supply device according to one of   previous claims characterized in that the circuit   self-supply (107) is connected to a service winding (113) of the transformer (102).   6- Switching power supply device according to one of   previous claims characterized in that the component   with reactive impedance (300) is included in a voltage doubling circuit (400) connected to the power input (110) of the integrated circuit (109).   7- Switching power supply device according to one of the preceding claims characterized in that the component   with reactive impedance (300) is a capacitance.   8- Switching power supply device according to the preceding claim characterized in that the capacity has a   value of around 500 nanoFarads.