FR2810810A1 - Standby electrical supply for computer processing system uses electrical energy stored in capacitors to feed the system during an interruption the normal electrical supply - Google Patents

Abstract

The standby supply system includes a non volatile memory (5) in which a supply interruption management unit (4) writes, after receipt of a supply interruption signal, parameters relative to computer processing operations being carried out. These parameters permit the restarting of the computer operations. The parameter are recorded in memory after a date (TT). The standby supply includes a normal electrical supply (1) interruption sensor (3). It uses capacitors (2), to store electrical energy taken from the normal supply. A supply interruption management unit (4) fed from the capacitors comes into operation after it receives a signal from the sensor. The management unit permits restarting of the computer processing system and its operations following supply interruption after the capacitor energy has been used up when the normal supply is reconnected. The management unit starts the computer system operations after a data (TT) occurring later than the date at which the normal supply voltage (1) reaches a VOFF reference value

Description

The invention relates to a device for feeding an electronic device. Such a device powered by an external electrical network may be subject to mains power supply cuts harmful to its operation. In order to safeguard its operation, the apparatus may comprise energy storage means taken from the network. To fulfill this function, for example, storage batteries or capacitors are used. The storage means replace the electrical network during power failure to power the device.

To increase the operating time of the device when it is more powered by the storage means it is necessary to increase the capacity.

Moreover, when the cut-off of the supply network is prolonged after exhaustion of the energy contained in the storage means, the electronic device may lose the progress of programs that were being performed and / or the data that he manipulated before exhaustion and restart of the device then requires a significant time to restart the programs he was doing and / or re-acquire the lost data.

The object of the invention is to increase the operating time of the apparatus for given energy storage means as well as to reduce the restart time of the apparatus when the power supply via the network is again present after the cut.

In some fields, such as aeronautics, standards require keeping an electronic device in operation for power supply cut-off times predicted in advance, for example 50 milliseconds or 200 milliseconds. To meet such standards, the invention makes it possible to reduce the capacity of the storage means and for example to replace an accumulator battery with a capacitor. Indeed, a storage battery can store more energy per unit of volume than a capacitor but it has the disadvantage require periodic maintenance imposing including the change of the battery on scheduled dates. If a storage battery is replaced by a capacitor, the invention thus makes it possible to eliminate the periodic maintenance of the apparatus. More generally, the invention makes it possible to reduce the size of the storage means.

To achieve the object stated above, the invention relates to a device for supplying an electronic device supplied with a power supply, characterized in that it comprises means for detecting a power failure, energy storage means taken from the power supply, processing means fed to the storage means, receiving a signal from the detection means and shaping operations in progress after receiving a signal representative of a power failure. the power supply, so as to allow a restart of the device and ongoing operations after depletion of the energy present in the storage means when the supply is again present after the cut.

The invention will be better understood and other advantages will appear on reading the detailed description of an embodiment illustrated in the attached drawing in which: - Figure 1 shows a block diagram of an embodiment of the invention; FIG. 2 represents, in the form of a different chronogram, signals making it possible to better understand the operation of the synoptic diagram; - Figure 3 shows an embodiment of the means for detecting a power failure.

In FIG. 1, the supply 1 of electrical energy sends energy to energy storage means 2. These energy storage means comprise, for example, an accumulator battery or advantageously one or more capacitors. In addition, the supply 1 of electrical energy is connected to detection means 3 of a power supply cut-off 1. The device also comprises processing means 4 supplied with energy by the storage means 2. The processing means 4 receive information from the detection means 3. The processing means 4 are advantageously connected to the storage means 5. The other means processing means 4 can control connection means 6. These connection means 6 make it possible to connect or disconnect the power supply of secondary functions 7 to the device as an example of the display means. When there is no break on the supply 1 of electrical energy the secondary functions 7 are connected to the storage means 2 and the processing means perform specific operations of the electronic device and not described here. When the detection means 3 detect a cut-off of the power supply 1, they send information representative of the cutoff to the processing means 4. When this information is received, the processing means disconnect the power supply from the secondary functions 7 and shape the specific operations for example by memorizing in the storage means 5 which are advantageously a non-volatile memory such as for example a disk or an electrically programmable memory.

It is also possible to directly supply the secondary functions 7 by the supply 1 of electrical energy without passing through the storage means. This variant makes it possible to pass connection means 6. Indeed, as soon as a break occurs, secondary functions are no longer supplied with electrical energy. However, this variant does not allow to delay the disconnection of the secondary functions thus ensuring a period of transparency will be described later using the timing chart 2c.

The electronic device can of course comprise several types of secondary functions, some powered directly by the power supply 1 and others via the storage means 2 and the connection means 6.

Figure 2 shows three timing diagrams 2a, 2b and 2c. three chronograms have the same time scale. The first timing diagram 2a represents an example of time evolution of the voltage of the power supply 1 into electrical energy. At first, the supply voltage is at a value Vcc making it possible to operate the electronic device normally. Then a cut-off of the energy supply 1 appears and the supply voltage drops down a slope to a low value which is prolonged. Subsequently at the end of the break, the supply voltage rises also following a slope until reaching the value Vcc again. Between the low value and the value Vcc of the voltage, there is shown on the timing diagram 2a two voltages, one VOFF and the other VON higher than VOFF. The utility of these two voltages VON and VOFF will be described later.

timing diagram 2b, describes the output signal of the detection means 3. At first this signal is in the 1 state, this state is representative of the absence of cut-off on the power supply. Then at the moment when the voltage of the supply 1 in electrical energy drops until reaching the voltage VOFF or, advantageously, shortly thereafter, on the detection date TD, the signal represented on the timing chart 2b takes a zero value representative of a cutoff on the supply 1 in electrical energy.

Advantageously, the detection date TD occurs later than the moment the supply voltage 1 of the device decreases by reaching the voltage VOFF. This time lag makes it possible to avoid any untimely detections of power failure of very short duration, for example of the order of a few microseconds.

The signal represented on the timing diagram 2b remains in the zero state as long as the supply voltage does not go back to a value greater than the voltage VON.

The timing diagram 2c represents the power consumed by the electronic device during the power supply 1 cut in electrical energy. At first the apparatus operates normally and the consumed power is called nominal it is noted PN.

Then, when the cutoff appears, that is to say that voltage Vcc falls below the voltage VOFF, the power consumed advantageously remains equal to the power PN until the transparency date TT. Advantageously, the TT transparency date occurs later than the TD detection date thus ensuring a period during which the operation of the device is not impaired. Between the dates TD and TT, the processing means 4 ensure, in addition to their normal functions of processing the specific operations of the apparatus, a count of time until the transparency date TT. When this is reached, the processing means formats the specific operations in progress. For example, they store in the non-volatile memory 5 all the information necessary for the subsequent resumption of these operations.

 Also after the date TT, the processing means 4 disconnect the secondary functions 7 of the apparatus to thereby reduce the power consumed to a reduced power PR, lower than the nominal power PN. Then the apparatus consumes the energy contained in the storage means 2 by dissipating a power PR as long as the storage means 2 allow it.

Then, if the cut continues, the device stops and consumes no energy. It is understood that if the power failure 1 ends before the device has exhausted the energy contained in the storage means 2, the device will resume normal operation PN power before stopping .

FIG. 3 represents an exemplary embodiment of the detection means 3 of a power supply 1 cut-off. The voltage of the power supply 1 is connected to the detection means at the point 10. This supply voltage first undergoes a filtering step represented in the frame 11. Next to the frame 12 are determined the detection thresholds VON and VOFF. The signal coming from the frame 12 is then filtered at the frame 13 and then shaped at the frame 14. At the output of the frame 14, the frame 15 is used to galvanically isolate the output signal of the detection means with respect to the processing means 4 The frame 15 is followed by means 16 for shaping the signal representative of the cutoff of the supply 1, a signal supplied to the processing means 4.

More specifically, point 10 is connected to a ground 20 via two resistors 21 and 22 both forming a voltage divider. The resistor 21 is connected to the point 10 and the resistor 22 to the ground 20. The common point of these two resistors is connected to the ground 20 via a capacitor 23. The common point of the two resistors 21 and 22 is also connected to the input of the frame 12 via a resistor 24, the capacitor 23 and the resistor 22 both form a time constant for defining the time Tp. At the input of the frame 12, the resistor 24 is connected to the inverting input of an operational amplifier 25. The non-inverting input of the operational amplifier 25 is connected to a reference voltage 40, via The output of the operational amplifier 25 is connected to the anode of a diode 27. The cathode of this diode 27 is connected to the non-inverting input of the operational amplifier 25 via a resistance 28.

The electronic components grouped in the frame give an example of embodiment of the comparison of the supply voltage 1 to the two voltages VOFF and VON. When the supply voltage has a value Vcc, the operational amplifier 25 is saturated and its output voltage is close to its negative supply voltage. The diode 27 does not conduct and no current flows in the resistors 26 and 28. Thus, the voltage of the non-inverting input of the operational amplifier 25 equal to the reference voltage 40. Then, when the supply voltage 1 decreases , and that the potential of the inverting input decreases to less than the potential of the non-inverting input, then the output voltage of the operational amplifier 25 rapidly increases substantially to its positive supply voltage.

The potential of the reference voltage 40 is set such that the fast growth of the output voltage of the operational amplifier occurs at the moment when the supply voltage decreases by taking the value VOFF.

As a result, the diode 27 becomes conductive and the resistors 26 and 28 then behave as a voltage divider between the highly positive output voltage of the operational amplifier 25 and the reference voltage 40.

Thus, the potential of the non-inverting input of the operational amplifier 25 rises to form a new threshold defined as a function of VON. This threshold is that which will have to exceed the potential of the inverting input of the operational amplifier 25 so that the output voltage of the operational amplifier 25 decreases again. The values of the resistors 26 and 28 are defined as a function of the value of VON sought.

The output voltage of the operational amplifier 25 may be similar to a binary information in the form of a voltage close to one of the two positive and negative supply voltages of the operational amplifier 25. The electronic components grouped together in the frame 25 make it possible to perform a power cut detection 1 with hysteresis, that is to say that the information relating to the beginning of the cutoff occurs for a supply voltage 1 equal to VOFF, that the information relating to the end the cutoff occurs for a supply voltage 1 equal to VON and finally that values of VON and VOFF are different.

The output of the operational amplifier 25 is connected to the ground frame 13 via a resistor 29 connected in series with a capacitor 30. The common point of the resistor 28 and the capacitor 29 are connected to the input non-inverting of an operational amplifier 31 located in the frame 14. The inverting input of the operational amplifier 31 is connected to the common point of a resistor 32 and the cathode of a Zener diode 33. The anode of the diode Zéner is connected to the ground 20.

Resistor 31 is also connected to a reference voltage. The inverting input of the operational amplifier 30 thus remains at a stable voltage. The output of the operational amplifier is saturated either at its positive supply voltage or at its negative supply voltage. This makes it possible to format the detection signal. The output of the operational amplifier 30 is connected to isolation means represented in the frame 15. These isolation means comprise, for example, a light-emitting diode 34 whose radiation controls the base <B> a </ B> of a phototransistor 35. The collector of the phototransistor 35 forms the output of the frame 15 which is connected to the forming means, for example a non-16 cell. The output of the non-16 cell delivers the signal representative of the power failure 1 to the means of The emitter of the phototransistor 35 is for example connected to a mass 36 different from the mass 20.

Claims (1)

CLAIMS. Device for powering an electronic device powered by a power supply (1) for electrical energy, characterized in that it comprises means for detecting (3) a cut-off of the power supply (1), storage means (2) energy taken from the power supply (1), processing means fed by the storage means (2), receiving a signal from the detection means (3) and formatting operations in progress after receiving a representative signal of a power failure (1), so as to allow a restart of the device and ongoing operations after depletion of the energy present in the storage means (2) when the power supply (1) is new presents after the cut. Device according to Claim 1, characterized in that the processing means format the operations in progress after a transparency date (TT) occurring later than the date on which the power supply voltage (1) takes a reference VOFF value. . 3. Device according to one of the preceding claims, characterized in that it comprises nonvolatile storage means (5) in which the processing means (4) register, after receiving the signal representative of a cut of the power supply (1), parameters relating to operations in progress, the parameters allowing the restart of the device the continuation of operations in progress. 4. Device according to claim 3, characterized in that the processing means (4) inscribe the parameters relating to operations in progress, after a transparency date (TT) occurring later than the date on which the voltage of the power supply (1) takes a reference value VOFF. 5. Device according to one of the preceding claims, characterized in that comprises connection means (6) of the supply (1) of secondary functions (7) of the apparatus, in that the connection means (6) ) are controlled by the processing means (4) and in that the connection means (6) disconnects the supply of the secondary functions when a power failure (1) is detected. 6. Device according to claim 5, characterized in that the connection means (6) disconnect the supply of secondary functions (7) after a transparency date (TT) occurring later than the date on which the voltage of the power supply (1) takes a reference VOFF value. 7. Device according to one of the preceding claims, characterized in that the detection means (3) deliver to the processing means (4) a signal representative of a power failure at the date of detection (TE, intervening later than the date on which the voltage of the power supply (1) takes a reference value VOFF 8. Device according to one of claims 2, 4 or 6, characterized in that the transparency date (TT) occurs. later than the detection date (Tp) 9. Device according to one of the preceding claims, characterized in that the detection means (3) detect a cut with hysteresis.