RU2153190C2 - Method for uninterruptible power supply of radio electronic equipment - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: when power supply unit is switched off alternating current mains, it is supplied with direct voltage from redundant power supply. Value of direct voltage is located within minimal and maximal amplitudes of voltage of alternating current mains. EFFECT: increased reliability of equipment operations. 4 cl, 2 dwg

Description

 The invention relates to the field of electrical engineering, and more specifically to methods for uninterrupted or guaranteed power supply of electronic equipment. Even more precisely, the invention relates to methods for guaranteeing power to electronic equipment having a power supply unit with a transformerless AC input from a power supply network.

 Known methods for guarantee power supply of electronic equipment. In the uninterruptible power supply SOLA 600 (prospectus of EKONIKA-TECHNO JSC), an uninterruptible power supply method is used, which involves rectifying the AC alternating voltage, supplying the rectified voltage to the inverter, converting the DC voltage into a sinusoidal voltage in the inverter and supplying it through a switch to the input of the power supply electronic equipment; at the same time, the mains voltage is rectified in the charger and supplied to the battery, the voltage of which, in the event of a failure of the mains voltage, is converted into a sinusoidal voltage in the above-mentioned inverter, which is fed to the input of electronic equipment; in the event of a malfunction of the inverter, the mains AC voltage is supplied directly to the input of the electronic equipment.

 The specified uninterruptible power supply method first involves converting the alternating voltage to direct, and then the constant voltage into alternating current, which requires a significant amount of equipment.

 There is a method of guarantee power supply (Fig. 4.5 on page 157 in the book by Zh.A. Mkrtchyan. Fundamentals of building computer power supply devices. M .: Radio and communications, 1990. - 208 p.), Providing for the supply of alternating voltage via an input switch electronic equipment, the conversion of AC voltage to direct voltage, the battery charge from the specified constant voltage, the supply of direct voltage or voltage from the battery to the inverter, the conversion in the inverter constant voltage tions in a sinusoidal, sinusoidal voltage connection to the switch, which connects the sinusoidal voltage to the input of electronic equipment in the event of failure of the AC voltage or its output parameters exceed the limits. This method is selected as a prototype.

 However, in this method of guarantee power, a significant amount of equipment is required to implement the method, since the conversion is performed twice: first variable to constant, and then constant to variable, which also reduces the reliability of the device made by the specified method.

 Thus, the technical problem to which the invention is directed is to reduce the amount of equipment necessary for uninterrupted power supply of electronic equipment, and to increase the reliability of an uninterruptible power supply device.

 The essence of the proposed method of guarantee power supply of electronic equipment having a power supply unit with a transformerless AC voltage input is that the network AC voltage is connected to the power supply unit of the electronic equipment, the presence and parameters of the AC alternating voltage are controlled, and the mains voltage is disconnected from the power supply unit of the electronic equipment in in case of loss of the mains AC voltage or output of the parameters of the mains AC voltage The boundaries are drawn and supply voltage from the backup power source to the electronic equipment, moreover (the distinguishing features follow) after disconnecting the ac mains voltage from the specified power supply, it is supplied with constant voltage from the backup power source.

 In another embodiment of the proposed method (distinguishing features follow), the value of the constant voltage of the backup power source is set equal to the amplitude of the mains AC voltage.

 In another embodiment of the proposed method (distinguishing features follow), the value of the direct voltage of the backup power source is set in the range between the minimum and maximum amplitudes of the mains AC voltage corresponding to the minimum and maximum allowable effective value of the mains AC voltage at the input of the specified electronic equipment.

 In another embodiment of the proposed method (the distinguishing features follow), the ac mains voltage is rectified to control the ac alternating voltage, the first control rectangular pulses with a front are formed from the half-sine waves of the rectified ac alternating voltage with the front at the moment of the equality of the rectified increasing ac alternating ac voltage to the first threshold voltage and with a decrease in the moment of equality of the decreasing rectified mains AC voltage of the half-sine wave to the first thresholds the second voltage is formed from the sine wave of the rectified mains voltage, the second control rectangular pulses with a front at the moment of the equality of the rectified rising AC voltage of the half-sine wave to the second threshold voltage and with a decrease at the moment of the decrease of the decreasing rectified mains voltage of the half-sine wave to the second threshold voltage, form from the half-sinusoidal AC voltage voltage third control rectangular impulses with a front at the moment to reducing the indicated half-sine wave of zero voltage and a duration of a few tenths of a millisecond, with the first threshold voltage equal to the specified minimum amplitude of the mains AC voltage, the second threshold voltage equal to the maximum amplitude of the mains AC voltage, form a signal to disconnect the mains AC voltage from the power supply of electronic equipment at the time of the front the second control rectangular pulse or for less than half the period of the sine wave of the networks AC voltage after the last of the continuous sequence of the first control rectangular pulses has fallen before at least one next first control rectangular pulse disappears, the AC voltage is disconnected from the power supply unit of the electronic equipment along the front of the third control rectangular pulse following the appearance of the indicated signal to disconnect the network variable voltage, connect a constant voltage backup power supply to the specified power supply of electronic equipment for less than 8 ms after disconnecting the AC voltage, form, in the presence of the first control rectangular pulses and the absence of the second control rectangular pulses, a signal to disconnect the DC voltage of the backup power source from the power supply of electronic equipment through a few seconds after the last disappearance of one of the first control rectangular pulses or after the last appearance one of the second control rectangular pulses, disconnect the constant voltage of the backup power source from the power supply of electronic equipment for 2 to 9 ms after the third control rectangular pulse received after the appearance of the specified signal to disconnect the DC voltage of the backup power source, connect the alternating voltage to the power supply of electronic equipment along the front of the third control rectangular pulse, post drank after disconnecting the DC voltage of the backup power source.

 In another embodiment of the proposed method (distinguishing features follow), the direct voltage of the backup power source is compared with the third threshold voltage, which corresponds to the constant voltage on the backup power source at the time of reduction of the electricity stored in it to 15-30% of its rated capacity in a charged state, generate a warning signal if the third threshold voltage is greater than the constant voltage of the backup power source, compare the constant voltage vnogo power source to a fourth threshold voltage, which is equal to said minimum amplitude of the AC voltage. disconnect the constant voltage of the backup power source from the power supply of electronic equipment in the event that the fourth threshold voltage is equal to the constant voltage of the backup power source.

 The invention is illustrated by drawings. In FIG. 1 shows a device for guarantee power supply of electronic equipment having a power supply unit with a transformerless AC voltage input. In FIG. 2 shows a control unit for a warranty power device.

In the drawings indicated:
1 - the first wire supply AC voltage;
2 - the second wire supply AC voltage;
3 - backup power source;
4 - power output of the backup power source;
5 - switch network AC and backup DC voltage;
6 - the first power input of the switch network AC and backup DC voltage;
7 - the second power input of the switch network AC and backup DC voltage;
8 - the first control input switch network AC and backup DC voltage;
9 - the second control input of the switch network AC and backup DC voltage;
10 - power output switch network AC and backup DC voltage;
11 - control unit;
12 - network input of the control unit;
13 - the first output of the control unit;
14 - the second output of the control unit;
15 - signal output of the control unit;
16 - control input of the control unit;
17 - charger;
18 and 19 - wires for connecting the AC alternating voltage to the charger;
20 - charger output;
21 - input backup power source;
22 - control output of the backup power source;
23 - signal output of the backup power source;
24 - electronic equipment;
25 - transformerless power source of electronic equipment;
26 - input transformerless power source of electronic equipment;
27 - a rectifier;
28 - the first shaper;
29-second shaper;
30 - the third shaper;
31 - fourth shaper;
32 is a first OR scheme;
33 - output of the first OR circuit;
34 - the first circuit And;
35 - the first input of the first circuit And;
36 - the second input of the first circuit And;
37 - the second scheme And;
38 - the first input of the second circuit And;
39 - the second input of the second circuit And;
40 is a first delay circuit;
41 - fifth shaper;
42 - the third scheme And;
43 - the first input of the third AND circuit;
44 - the second input of the third circuit And;
45 is a second delay circuit;
46 is a second OR circuit;
47 - the first input of the second OR circuit;
48 - the second input of the second OR circuit;
49 - the first trigger;
50 - the first input of the first trigger;
51 - the second input of the first trigger;
52 - output of the first trigger;
53 - the second trigger;
54 - the first input of the second trigger;
55 - the second input of the second trigger;
56 - the output of the second trigger.

 The proposed method of guarantee power is used for electronic equipment having a power supply with transformerless AC voltage input. Initially, the AC power supply is connected to the power supply unit of the specified equipment, and if the mains voltage does not disappear and does not increase or decrease beyond the specified limits, then the equipment operates normally from the AC voltage. At the same time, the presence and parameters of the ac mains voltage are monitored. In the event that the AC alternating voltage disappears or the AC alternating voltage exceeds the specified limits, the AC alternating voltage is disconnected from the power supply unit of the electronic equipment and a constant voltage is supplied to it from the backup power source.

 The value of the DC voltage supplied from the backup power source is set equal to the amplitude of the AC alternating voltage. In another embodiment, the value of the constant voltage of the backup power source is set in the range between the minimum and maximum amplitudes of the mains alternating voltage corresponding to the minimum and maximum allowable effective voltage at the input of said electronic equipment.

 The description and implementation of the method is carried out on the example of the guarantee power device shown in FIG. 1.

 In the device of guarantee power supply of electronic equipment connected to an alternating voltage network of 220 V (wires 1 and 2), there is a backup power supply 3, at the output 4 of which there is a constant voltage. Wires 1 and 2 of an alternating voltage network of 220 V are connected to a switch 5 of the alternating current and backup direct voltage voltages to input 6, and the output 4 of the backup power supply is connected to input 7 of the switch. Inputs 8 and 9 of switch 5 are control and provide alternating connection of the AC and backup DC voltage to the load. The output 10 of the voltage switch 5 is connected to the electronic equipment 24. The guarantee power device includes a control unit 11, to the input 12 of which are connected wires 1 and 2 of the mains alternating voltage. The control outputs 13 and 14 of the control unit 11 are connected respectively to the inputs 8 and 9 of the switch 5. The signal output 15 is necessary for issuing the first signal warning the operator about disconnecting the AC voltage from the load. In electronic equipment 24 there is a power supply 25 with transformerless input 26, to which the output 10 of switch 5 is connected.

 As a backup power source 3, a rechargeable battery can be used, while it is necessary to ensure, as usual, all operating conditions of the rechargeable battery: a charge with control of the voltage on the battery, control of the battery discharge. The voltage of the battery is set equal to the amplitude value of the mains AC voltage. In another embodiment, the voltage of the battery is set in the range between the minimum and maximum amplitudes of the AC alternating voltage corresponding to the minimum and maximum permissible effective (effective) voltage at the input 26 of the specified electronic equipment 24. In any case (including after the battery is discharged for a specified time) the voltage on the battery should not go beyond the specified range. The backup power source 3 has an input 21 for charging the battery, an output 22 for transmitting a signal about the battery discharge and the need to turn it off, and a signal output 23 for transmitting to the operator a second warning signal about the possible soon shutdown of the backup power source 3 due to the discharge of the battery.

 To charge the battery, there is a charger 17, on the wires 18 and 19 of which the mains AC voltage is supplied. From the output 20, a constant voltage is supplied to the input 21 of the backup power source to charge the battery.

 As switch 5, two semiconductor switches or one thyristor switch (for connecting an alternating voltage mains) and a semiconductor switch (for connecting a constant voltage of a backup power source) can be used, and the DC voltage must be turned on later than the disconnection of conductors 1 and 2 ( mains AC voltage), and the inclusion of mains AC voltage (after its restoration in the network) should occur after disconnecting the backup DC voltage. This can be achieved by introducing the necessary delay elements, as described below. It should be borne in mind that electronic equipment can do without power for a limited time, and in this invention, this time is chosen equal to less than half the sine wave of the AC alternating voltage. This time limits the time for switching the operation of electronic equipment from AC mains to standby DC voltage and vice versa.

 In addition, the mains AC voltage may not meet the specified requirements during one (for example, the first) half-cycle in each period of the sinusoid of the mains AC voltage. Then switching power supplies to electronic equipment with a frequency of 50 Hz would require the use of very powerful thyristors and transistors. Therefore, the reverse connection of the AC alternating voltage to the electronic equipment (after a failure in the AC alternating voltage network) is made only after a few seconds, during which the AC alternating voltage must be of good quality, that is, there should be no cases of failure, which is controlled by the control unit.

 The control unit 11 may contain analog comparison circuits (comparators), which compare the value of the mains AC voltage with predetermined threshold values set using, for example, voltage dividers. Mains AC voltage is connected to the control unit 11 at the input 12, and a signal is inputted to the control input 16 to turn off the backup power source 3 when its voltage is below an acceptable level. The signal output 15 is a warning signal about disconnecting the AC voltage from the load. This signal is necessary for the operator to take measures to prepare the equipment for shutdown, if the mains AC voltage does not recover and the standby DC voltage is disconnected due to the discharge of the battery. Shutdown of the computer by this signal can also be done automatically according to the program. The control unit is described below in more detail.

 A transformerless power supply unit 25 of electronic equipment 24, consisting, for example, of a bridge bridge, a capacitive filter and an inverter and designed to supply alternating voltage, will operate normally from a constant voltage, which, passing through the valve bridge, will charge the filter capacitor, which then feeds inverter. After the battery is discharged to the maximum level, the constant voltage is turned off and, if the mains alternating voltage is not restored, then the electronic equipment will remain without power and will not work. But after turning off the AC alternating voltage, due to the backup power source, the operator will be able to prepare the equipment for shutdown so as not to lose, for example, the necessary computer information or take any actions to ensure minimal damage from turning off the equipment.

 In the control unit 11 shown in FIG. 2, there is a rectifier 27, to which an AC line voltage is supplied at input 12. At the output of the rectifier 27 there is a unipolar voltage in the form of a half-sine wave, which is supplied to the first, second and third shapers 28, 29 and 30 (respectively). The first driver 28 generates from the half-sine waves of the rectified mains AC voltage the first control rectangular pulses with a front at the moment of the equality of the rectified rising half-sine wave voltage to the first threshold voltage and with a drop at the moment of the decrease of the decreasing rectified half-sine wave voltage to the first threshold voltage. The first shaper has a comparator, one of the inputs of which is supplied with a rectified mains AC voltage, and the first threshold voltage is connected to the other input, which is equal to the minimum amplitude of the mains AC voltage for this electronic equipment 24. The presence of pulses at the output of the shaper 28 indicates that mains AC voltage is above this lower limit.

 The second driver 29 generates, from the half-sine wave of the rectified mains AC voltage, the second control rectangular pulses with a front at the moment of the equalization of the rectified rising half-sine wave voltage to the second threshold voltage and with a drop at the moment of the equalization of the decreasing rectified half-sine wave voltage to the second threshold voltage, and the value of the second threshold voltage is equal to the maximum network voltage amplitude voltage for this electronic equipment 24. The second driver 29 has a comparator, on one of the inputs of which there is a rectified mains AC voltage, and on the other input, a second threshold voltage. The appearance of the second control pulses indicates that the mains AC voltage has increased beyond the permissible limit.

 The third driver 30 generates from the half-sine wave of the rectified mains AC voltage the third control rectangular pulses with a front at the moment the specified half-sine wave reaches zero voltage and lasts in tenths of a millisecond. The third control pulses are used as synchronizing when switching the AC alternating voltage and the voltage of the backup power source to the load.

 The fourth driver 31 generates a signal when the first rectangular control pulse does not arrive at its input, that is, when the mains AC voltage disappears or the magnitude of the mains AC voltage is less than the permissible value. The fourth driver, for example, may contain a capacitor connected through a resistor to a constant voltage and charged from it, and upon receipt of the first control pulse, the capacitor is quickly discharged (through a transistor) and the voltage on it does not have time to reach the value at which a signal is generated at the output of the fourth driver . If the first control pulse does not arrive, then the capacitor in the fourth shaper is charged to the desired value and causes the appearance of a signal about the disappearance or unacceptable decrease in the mains voltage. The capacitance of the capacitor and the resistor in the circuit of its charge are selected so that the signal at the output of the fourth shaper 31 appears for less than half a period of a sine wave of the AC alternating voltage after the last of the continuous sequence of the first control rectangular pulses decays before at least one next first control rectangular pulse disappears.

 The signal from the output of the shaper 31 and the signal from the output of the second shaper 29 are sent to the first OR 32 circuit. In any of these cases, and at the output 33 of the circuit 32, a signal is generated that the mains AC voltage has either disappeared or is out of limits.

 The signal to disconnect the ac alternating voltage from the power supply unit of the electronic equipment from the output 33 of the OR 32 circuit arrives at the input 35 of the first And 34 circuit. At the moment (along the front) the third control pulse arrives from the output of the third driver 30 to the input 36 of the first And 34 circuit the output signal appears, which is input 50 of the first trigger 49 and the output 52 of the trigger 49 there is a signal that is fed through the output 13 of the control unit 11 to the first control input 8 of the switch 5 network variable and standby th stress. When this happens, the AC mains voltage is disconnected from the power supply unit 25 of the electronic equipment 24 by turning off the thyristors in the switch 5. The thyristor in the switch 5 turns off when the AC voltage on the thyristor is zero.

 The signal from the output of the first circuit And 34 also arrives at the first delay circuit 40 and after less than 8 ms (delay time) is supplied to the first input 54 of the second trigger 53. The signal from the output 56 of the second trigger goes through the second output 14 of the control unit 11 to the second control input 9 of the switch 5 network AC and backup DC voltage for connecting a backup DC voltage to the power supply 25 of the electronic equipment 24 using a transistor switch in unit 5. Thus, the electronic equipment is OK yvaetsya without voltage less than 8 ms.

 From the output 52 of the first trigger 49, a warning signal is generated about the disconnection of the AC alternating voltage from the power supply unit of the electronic equipment, which is issued to the signal output 15.

 The signal from the output 33 of the first OR 32 circuit also arrives at the fifth driver 41. The fifth driver 41 generates a signal at its output only when within a few seconds it has not received a signal from the output 33 of the circuit 32. For this, the fifth driver 41 may contain a capacitor charged through a controlled transistor and a resistor for discharging the capacitor, the signal coming to the fifth driver 41 from the output 33 opens the controlled transistor and quickly recharges the capacitor again to the limit. At the output of the fifth driver 41, the signal will appear in the case of a complete discharge of the capacitor (if the signals from the output 33 do not arrive for several seconds, that is, with the normal state of the mains AC voltage for several seconds) and will be maintained on it until the output signal arrives 33 of the first OR 32 circuit (the RC time constant is selected accordingly). Thus, the output signal of the fifth shaper 41, in the case of the presence of the first control rectangular pulses and the absence of the second control rectangular pulses, a signal to disconnect the DC voltage of the backup power source from the power supply of electronic equipment a few seconds after the last failure of one of the first control rectangular pulses or after the last appearance of one of the second control rectangular pulses.

 From the output of the fifth driver 41, the signal enters the first input 43 of the third AND circuit 42, which is triggered when the signal from the third driver 30 arrives at its other input 44. The signal from the output of the circuit 42 passes through the second delay circuit 45 (from 2 to 9 ms) to the first input 47 of the second OR circuit 46 and the second input 55 of the second trigger 53, which switches and disconnects the backup power source from the load (from the output 56 of the second trigger 53, the signal goes to the second control output 14 of the control unit 11 and to the second control input 9 of the switch 5 ) Thus, they are carried out after 2 to 9 ms after the third control rectangular pulse received after the signal to disconnect the backup power source, disconnect the DC voltage of the backup power source from the power supply unit of the electronic equipment.

 In addition, the signal from the output of the second delay circuit 45 is fed to the first input 38 of the second circuit And 37. During the third control pulse received by the second input 39 of the second circuit And 37, a signal appears at the output of the circuit 37, which is fed to the second input 51 of the first trigger 49, which switches and output 52 connects the AC voltage to the power supply of electronic equipment. Thus, the AC mains voltage will connect after 1 to 8 ms after the DC voltage of the backup power source is disconnected (depending on the amount of time delay in the second delay circuit 45) at the moment of zero AC mains voltage, which is important for the operation of the thyristor switch.

 In the backup power source 3, there may be a third and fourth comparator connected to the output 4 of the backup power source 3. The third comparator compares the output voltage of the backup power source with the third threshold voltage, which corresponds to the voltage on the backup power source at the time of reduction of the energy stored in it to 15 -30% of its nominal capacity when charged.

 If the third comparator is triggered, the operator is given a warning signal on output 23 that the battery is close to full discharge.

 The fourth comparator compares the output voltage of the backup power source with the fourth threshold voltage, which is equal to the lowest allowable voltage of the backup power source after discharge. In the case of the fourth comparator, output 22 gives a signal for emergency shutdown of the backup power source 3. This signal is fed to input 16 of the control unit and to the second OR circuit 46, through which it passes to the second trigger 53 and immediately disconnects the backup power source 3 from load 25 .

 The present invention allows to reduce the number of equipment required for warranty power, and to increase reliability by reducing the number of equipment.

Claims (4)

 1. The method of guarantee power supply of electronic equipment having a power supply unit with a transformerless AC voltage input, which consists in connecting a network alternating voltage to the power supply unit of the electronic equipment, monitoring the presence and parameters of the alternating mains voltage, and disconnecting the alternating voltage from the power supply unit of the electronic equipment in in case of disappearance of the AC alternating voltage or the output of the AC alternating voltage parameters beyond the established boundaries give voltage from the backup power source to the electronic equipment through its power supply with transformerless AC input, and characterized in that when the voltage from the backup power source to the electronic equipment specified voltage is constant, and the constant voltage of the backup power source is set in the range between the minimum and maximum amplitudes of the mains AC voltage corresponding to the minimum and maximum permissible effective value of the mains alternating voltage at the input of the specified electronic equipment.  2. The method according to claim 1, characterized in that the DC voltage of the backup power source is set equal to the amplitude of the AC alternating voltage.  3. The method according to claim 1, characterized in that the mains AC voltage is rectified to control the AC alternating voltage, the first control rectangular pulses are formed from the half-sine wave of the rectified mains voltage with a front at the moment of the equality of the rectified rising AC voltage of the half-sinusoid to the first threshold voltage and with a drop at the moment of equality of the decreasing rectified mains AC voltage, the half-sinusoids to the first threshold voltage are formed from the half-sinusoids in of the direct AC alternating voltage, the second control rectangular pulses with a front at the moment of the equality of the rectified increasing AC voltage of the half-sine wave to the second threshold voltage and with the decrease at the instant of equality of the decreasing rectified mains AC voltage of the half-sinusoid to the second threshold voltage, form the third control rectangular pulses from the half-sine rectified AC voltage front when the specified sine wave reaches zero voltage values and durations of a few tenths of a millisecond, the first threshold voltage being equal to the specified minimum amplitude of the AC alternating voltage, the second threshold voltage equal to the maximum amplitude of the alternating AC voltage, generate a signal to disconnect the AC alternating voltage from the power supply of the electronic equipment at the moment of the front of the second control rectangular pulse or for a time less than half the sine wave of the ac mains voltage after the decay of the last of one continuous sequence of first control rectangular pulses before the loss of at least one next first control rectangular pulse, disconnect the ac alternating voltage from the power supply of the electronic equipment along the front of the third control rectangular impulse following the appearance of the indicated signal to disconnect the ac alternating voltage; voltage of the backup power supply to the specified power supply electronic equipment for less than 8 ms after disconnecting the ac mains voltage, form in the presence of the first control rectangular pulses and the absence of the second control rectangular pulses, the signal to disconnect the DC voltage of the backup power source from the power supply of the electronic equipment a few seconds after the last failure of one of the first control rectangular pulses or after the last appearance of one of the second control rectangular x pulses, disconnect the DC voltage of the backup power source from the power supply of the electronic equipment within 2 to 9 ms after the third control rectangular pulse received after the appearance of the specified signal to disconnect the DC voltage of the backup power source, connect the AC voltage to the power supply of the electronic equipment along the front of the third control rectangular pulse received after disconnecting a constant voltage backup power supply.  4. The method according to claim 1, characterized in that the direct voltage of the backup power source is compared with a third threshold voltage, which corresponds to a constant voltage on the backup power source at the time of reduction of the electricity stored in it to 15-30% of its nominal capacity in a charged state generate a warning signal if the third threshold voltage is greater than the constant voltage of the backup power source, compare the constant voltage of the backup power source with the fourth threshold With a voltage equal to the indicated minimum amplitude of the mains alternating voltage, the direct voltage of the backup power source is disconnected from the power supply of the electronic equipment in the event that the fourth threshold voltage is equal to the constant voltage of the backup power source.

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