SU762085A1 - Secondary power supply source - Google Patents

Description

The invention relates to the field of electrical engineering, in particular to power conversion devices that convert the voltage of the original AC mains to one or more different voltages, ⁵ necessary to provide power to electronic equipment, computer equipment, automation and remote control, i.e., secondary power sources (VIP).

Known TIP with intermediate frequency conversion (VFR), consisting of a transformerless rectifier - key transistor stabilizer " _{) 5} with pulse-width modulation, having a capacitor at the output, a transistor inverter working with increased frequency and loaded on a high-frequency transformer And-. 20

Closest to this invention is a secondary power supply containing a rectifier

bridge to the output pins of which is under-

²

Keys stabilizer consisting of a power switch connected in series to the power bus, in parallel with which the switch-on sensor of the reference unit is connected, and an output capacitor connected in parallel. output pins stabilizer ,. To which a high-frequency converter is connected, a control unit consisting of drivers of on and off control signals with outputs connected to control inputs of the power switch, input of the control switch signal generator connected to the output of the comparator and output of the overload sensor, driver of control signals, output which is connected to the input of the inverter and the master frequency generator ^ 2 ^.

A disadvantage of the known structures of VIP with PCF is the presence of significant inrush currents during the initial connection to the network, the value of which is two to three orders of magnitude higher than the nominal. Ta—

3 7620;

Some excess current reduces the reliability of the elements and circuits along which the current flows, as well. It is also a source of interference that can disorganize the operation of adjacent equipment. _five

The goal is to increase the reliability in the start-up mode and reduce interference with the operation of foreign equipment.

This is achieved by the fact that in the secondary power source [d} in th

the control unit includes an activation trigger, a preparation trigger, an input element I, an stabilizing element AND, an inverter element AND, and a signal generator of the initial setup, with one of the inputs 15 of the input element E connected to the activation sensor, one of the inputs of the activation trigger is connected to the comparison unit , the output of the activation trigger is connected to another input of the input element I 20 and to one of the inputs of the inverter element. And, the other input of which is connected to the master oscillator, the output of the inverter element I is connected to the input of the driver of control signals, the output 25 of the input element I is connected to one of the preparation trigger inputs And to one of the inputs of the stabilizing element I, the output of the preparation trigger is connected to another input of the stabilizer element 30 And, the output of the stabilizer element And is connected to the driver of the switch-on control signal, the other inputs of the switch-on and preparation triggers are connected to the driver of the initial 35 installation.

To increase the reliability of operation in conditions of a distorted sinusoidal voltage of the supply mains, a delayed 40% shaper was inserted into the control unit, and an additional input connected to the output of the delayed pulse shaper, whose input is connected to an on sensor, was added to the stabilizer element. 45

In order to increase the reliability of operation in the conditions of varying load, an additional input connected to the comparison unit was added to the stabilizer element.

To improve the reliability of the automatic protection in emergency modes, an overload trigger is introduced into the control unit, and an additional input is added to the stabilizer element And connected to the output of the overload trigger, one of the inputs of which is connected

with an overload sensor, and the other input is connected to an initial setup shaper.

FIG. 1 is a functional block diagram of a secondary power supply; in fig. 2 - time diagram of his work in the starting period.

The secondary power source consists of a diode bridge 1 that is connected to the AC network, a stabilizer 2, a high-frequency converter (inverter) 3, and a control unit 4.

The stabilizer 2 consists of a power switch 5, an activation sensor 6 connected in parallel with the power switch, an output capacitor 7 and a comparison unit (switch-off sensor) 8 connected in parallel with the output capacitor 7.

The control unit 4 contains the driver 9 control signal on, the driver 10 of the control signal off, connected to the sensor off 8, the master oscillator 11, the driver 12 of the control signals of the power keys of the converter (inverter) 3.

To ensure a given program for starting the VIP, the control unit contains an activation trigger 13, preparation trigger 14, input element 15 and 15, stabilizer element 16 and an inverter element 17, a driver of the initial setup signal.

One of the inputs of the input element And 15 is connected to the inclusion sensor 6.

One of the trigger input inputs 13 is connected to the shutdown sensor 8, the output of the trigger trigger 13 is connected to another input of the input element 15 and one of the inputs of the inverter element 11. The other input of the inverter element 17 is connected to the master oscillator 11. The output of the inverter element 11 17 is connected to the input of the driver 12 of the control signals by the power keys of the converter (inverter) 3. The output of the input element I 15 is connected to one of the inputs of the trigger preparation 14 and to one of the inputs of the stabilizing element I 16. The output of the trigger trigger Preparations 14 is connected to another input of the stabilizer element and the stabilizer 16. The output of AND 16 is connected to the control input of the power key 9 enable signal 5 stabilizatotora 2. Other inputs triggers vklyuche762085

13 and preparation 14 are connected to the initial setup signal generator 18.

The scheme works as follows. When the power is initially turned on, the initial setup signal is generated by the shaper 18. This signal sets the switch-on trigger 13 to a position such that the output signal of the trigger 13 supplied to the input element 15 and the inverter element 17 also prohibits these elements. Thus, after turning on the device, the signals of the switch-on sensor 6 and the master oscillator 11 do not pass to the power keys of the stabilizer and inverter, the stabilizer and the inverter do not work. The initial setup signal from driver 18 sets up preparation trigger 14 to such a position that the output signal of trigger 14 applied to AND 16 stabilizer element is prohibiting.

After the initial installation, the signal from the driver 18 is terminated and no longer occurs in this device operation cycle. The initial setup signal appears again after the device is disconnected from the source network and then switched on again.

Since the power switch · 5 of the stabilizer 2 does not work after switching on the device, the output capacitor 7 of the stabilizer 2 is connected to the network bridge 1 only through the enable sensor circuit 6. The voltage at the output of the network bridge is shown in FIG. 2a The relatively weak circuit of the on sensor 6 provides a relatively slow charge on the output capacitor 7. The voltage on the output capacitor 7 is shown in FIG. 26

As soon as the voltage on the capacitor 7 reaches the preset stabilization voltage, fixed by the shutdown sensor (comparison unit) 8, the latter generates a signal which, "arriving at the trigger trigger input 13, switches this trigger, to the inputs of the And 15 and 17 elements it will receive an enable signal. The signals from the shutdown sensor (comparator) 8 are shown in FIG.

2d, and the state of the trigger trigger 13 is shown in FIG. 1e In the future, until the device is turned off, the switch-on trigger will be in a state that ensures the

the signal to the inputs of the elements 15 and 17. After the receipt of the enabling signal — la to the input of the inverter element I — 17 signals from the master oscillator 11 pro—

5 go to the shaper 12 signals yn—. Power key converter (inverter) 3. In the future, ensure the normal operation of the inverter.

10 Changing the state of the trigger inclusion 13 although allows the input element And 15, the output of which receives a signal to the input of the stabilizing element And 16, but does not

5 to the appearance of the signal at the output of the element ’And 16, since one of the inputs of the latter continues to receive a inhibitory signal from preparation trigger 14. (The output signal of the input element I 15

0 is shown in FIG. 2e). In the opposite case, the launch of a key stabilizer in an arbitrary phase, for example, in the region of the maximum of the next half-wave, would lead to the flow of significant currents.

5 The state of trigger preparation 14 will change after the end of the next signal of the switch on sensor 6. The signals of the switch sensor 6 are shown in FIG.

2c, and the state of the trigger preparation

About 14 in FIG. 2g <. At the same time, the preparation trigger 14 removes the inhibit signal from the input of the element AND 16, however, the launch of the key 5 of the stabilizer 2 at this moment will not occur, since there is no

5 the on signal of the switch-on sensor. The trigger preparation only prepares the possibility of such a launch in the future. The state of the preparation trigger after its switching does not change until the end of the device operation, from this cycle.

With increasing voltage at the leading edge of the regular half-wave to a value exceeding the voltage value

₍ On Capacitor 7, the switch-on sensor is triggered, and its signal, passing elements 15 and 16, will start? Shaper 9 of the switch-on signal of the stabilizer power switch 5. 2. (The output signal of the stabilizer circuit of AND 16 is shown in Fig. 2h). the key 5 of the stabilizer 2 will occur in the region of the approximate equality of the voltage of the rising regular half-wave at the bridge output and at the output capacitor 7, the current arising in the circuit of the key 5 of the stabilizer 2 will be relatively small and equal to the nominal value of the operating pulse current stationary

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mode. After reaching the set value of the voltage on the output capacitor 7, the switch-off sensor 8 is triggered, the signal of which will ensure the response of the driver 10 to turn off the power switch 5 of the stabilizer 2. In the future, the system will repeat with a period set by the frequency of the power supply.

Thus, the work of the considered system provides a transition from a relatively small initial current. at the start of operation to the rated operating current consumed by the VIP in stationary mode. Any surge current is excluded.

To ensure normal operation in conditions of distorted sinusoidal mains voltage to the control unit; introduces a delayed pulse shaper, which prohibits the triggering of the shaper 9 of the turn-on signal of the power switch 5 of the stabilizer 2 during the passage of the trailing edge of the half-wave; rectified voltage at the output of the bridge. The delay is necessary in order that the main signal of the switch-on sensor, having passed the elements 15 and 16, would have time to start the driver 9;

The duration of the pulse generated by the former 19 should be

. 70-80% of the half-period duration of the mains voltage. The signal of the delayed pulse former 19 is shown _: in FIG. 2i.

The considered control circuit of the TIP is able to function normally if sufficient current is provided in the load connected to the inverter 3. EC-., Whether the characteristics of the load are such that the magnitude of the load current, varying over time, will remain quite small for more than half the period of the mains voltage , the comparison unit 8,

due to the inherent hysteresis in such circuits, it will remain in the state corresponding to the voltage on the output capacitor 7 above the preset value, i.e. it will continue to give a continuous' off signal. Such a situation will lead to disruption of the stabilization system, since the driver 10 of the power switch off signal of the power switch 5, usually triggered on the front of the signal of the comparator unit 8, will not be able to start in this case. To restore the performance of this control unit under varying load conditions

from the nominal to close to zero values, you must add an additional input to the element And 16, having executed its four-input, and lead to this input a signal with

5 c. Comparison unit 8. Then, if the voltage on the output capacitor 7 is sufficiently large by the time the leading edge of the next half-wave approaches, the shaper turn on the power switch of the stabilizer does not occur due to the ban on the additional input element And 16 from the comparison unit. In this case, the next switching-on of the power key of the stabilizer will occur with the approach of the subsequent leading edge of the half-wave of the rectified voltage, as driver 19 will prohibit ’start in the active part of the half-wave. It should be noted that the presence of the former 19, if there is a connection between the comparison unit and the element I16, is necessary, since otherwise it would have been possible to start the former 9 to turn on the power switch p of the stabilizer 2 in any phase of the active part, which would lead to power flows in the circuit stabilizer. The considered VIP control unit creates prerequisites for using the power switch 5 of the stabilizer 2 as a protection circuit breaker. To implement the function of the automatic protection of the power, with the key of the stabilizer, an overload trigger 20 is additionally introduced into the control unit. One of the inputs of this trigger is connected to the driver 18 of the initial installation signal. The other input of the overload trigger .20 is connected to the known sensor (or sensors) of the overload (overflow, overvoltage) existing in the equipment 21. It is advisable to connect the overload sensor also with. shaper 10 of the shut-off signal of power switch 5 of stabilizer 2. The output of the overload trigger is connected to the auxiliary input of element AND 16. The overload trigger is set by the initial setup signal to a state that the enable signal arrives at the input of element 16, and thus the trigger overload 20 does not affect the operation of the circuit. When an overload sensor is triggered, the overload trigger 20 overturns and the element 16 is prohibited, after which the activation of the power key of the stabilizer becomes impossible. Further normal operation resumes after shutdown.

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and then turn on the entire device.

In the proposed power supply, power elements are selected by nominal, not starting currents, ₅ which reduces the size and weight of the power unit and increases the reliability of the elements in the start-up mode. Reducing interference with the operation of adjacent equipment increases the performance of the proposed source.

Claims (4)

Claim 1 $ 1, A secondary power supply containing a rectifier bridge, to the output terminals of which a stabilizer is connected, consisting of a switch connected in series to the power bus of the power switch 20, a switching unit, an output unit and an output capacitor connected in parallel with the high-frequency output terminals 35 converter, control unit, consisting of driver control on and off signals with outputs connected to control inputs C of the left key, the input of the driver for the off control signal is connected to the output of the comparator and to the output of the overload sensor, the driver of the control signals, the output of which is connected to the output of the converter and the master oscillator, which is in order to increase reliability in the start-up mode and reduce interference with the operation of extraneous equipment, a switch-on trigger, a preparation trigger, an input element And, a stabilizer element And, an inverter element AI were entered into the control unit One of the inputs of the input element I is connected to the switch-on controller, one of the inputs of the switch-on trigger is connected to the comparison unit, the output of the switch-on trigger is connected to another input of the input element AI with one of the inputs of the inverter AND element, the other whose entrance is connected to master oscillator, the output of the inverter element And is connected to the input of the forks of the control signals, the output of the input element And is connected to one of the inputs of the preparation trigger and one of the inputs of the stabilizing element And, the output of the preparation trigger And connected to the other input of the stabilizing element And, the output of the stabilizing element And connected to the driver control signal enable, the other inputs of the trigger enable and training connected to the driver of the initial setup. 2. Secondary power supply on π. 1, different. The heme that, in order to improve the reliability of work under the conditions of a distorted sinusoidal voltage of the supply network, a delayed pulse driver was inserted into the control unit, and an additional input connected to the output of the delayed pulse driver, the input of which is connected to an on sensor, was added to the stabilizing element. 3. Secondary power supply in PP. 1 and 2, characterized by the fact that, in order to increase the reliability of work in conditions ^! varying load, to the stabilizer element; And an additional input is added, connected to the comparator unit. 4. Secondary power supply according to paragraphs. 1 to 3, characterized in that, in order to increase the reliability of the automatic protection in emergency modes, the <control unit пере an overload trigger has been entered, and an additional input connected to the output of the overload trigger, one of the inputs of which is connected to the overload sensor, has been added to the stabilizer element, '& another input is connected to the initial setup shaper. ’: