SU1677704A1 - Secondary electric power source - Google Patents

Abstract

The invention relates to secondary power sources for various electronic equipment. The aim of the invention is to increase reliability by limiting the voltage surges on input pins. The secondary power supply comprises a limiting element 5, a capacitive filter 6 and a voltage converter 7, connected in series between the input and output terminals, as well as a key element 8 and a control unit 9. The source operates the current limiter also in the voltage limiting mode and the dependence of the operating time in the voltage limiting mode on the level of the input voltage. In the event of a surge in input pins 1.2, the key element 8 is open and a voltage drop from the current flowing from the primary power source is created on the resistor 5. At the same time, the voltage supplied to the capacitor 6 and the converter 7 is less by the amount of voltage drop across the resistor 5 2 cp ff, 3 Il. cl

Description

The invention relates to a secondary power supply and can be used to power various electronic equipment.

The aim of the invention is to increase reliability by limiting the voltage spikes on the input pins.

Fig. 1 shows a functional diagram of a secondary power source; 2 and 3, an embodiment of the control unit

The secondary power supply source contains a limiting element - a resistor 5, a capacitive filter 6 and a voltage converter 7 - and a key element 8 connected by a control input to its control unit 9 in series between the input 1.2 and output 3.4 outputs. 10. The key element 8 is connected in parallel with the resistor 5, and the first input 11 of the control unit 9 is connected to the auxiliary output 12 of the voltage converter 7. The resistor 5 is connected to the input terminals 1.2 via the rectifier 13. In addition, the device contains a voltage divider 14, a reference voltage source 15 and a comparator 16. The control unit 9 has

ABOUT

the second input 17 connected to the output of the comparator 16. The voltage divider 14 is connected to the input terminals 1.2 via rectifier 13, and the inputs of the comparator 16 are connected to the outputs of the voltage divider 14 and the source 15 of the reference voltage, respectively. The control may comprise analog elements 2I-HE 18 and 19, an inverter 20 and a level converter 21, the output of which is used as the output 10 of the control unit 9. The first and second inputs of element 18 are used as the first 11 and second 17 inputs of control unit 9, respectively, and the output is connected to the first input of element 19, the second input of which is connected to the first input of element 18, and the output through inverter 20 is connected to the input of level converter 21 .

In addition, control unit 9 may contain two logic elements 2ILIHA 22.2.3 and a level converter 24, the output of which is used as output 10 of control unit 9. The first and second inputs of element 22 are used as the first 11 and second 17 inputs of control unit 9, respectively, and the output is connected to the first input of element 23, the second input of which is connected to the second input of element 22, and the output is connected to the input of level converter 24.

The voltage converter 7 can be performed on any of the known circuits, for example, using a half bridge transistor circuit, and contains a transformer 25 having a primary 26, a secondary 27 and an additional 28 windings, rectifiers 29 and 30, as well as a master oscillator 31. The master The generator 31 can be made, for example, by a push-pull circuit with magnetic connections.

The source 15 of the reference voltage is connected to the input terminals 1.2 via the rectifier 13. However, the source 15 can also be connected to the voltage converter 7, for example, through the rectifier 30 to the auxiliary winding 28 of the transformer 25 of the converter 7,

Rectifier 13 is required to connect the secondary power source to the primary AC voltage source. When connected to the primary DC voltage source, the rectifier 13 may be absent.

Key element 8 can be performed on transistors, thyristors, relays and other elements.

The device works as follows.

When connecting input pins 1 and 2 to the primary voltage source, capacitor 6 is charged through resistor 5. At the same time, resistor 5 limits

inrush current through capacitor b As the capacitor 6 charges, the converter starts to work. The master oscillator31 generates a rectangular-shaped control voltage supplied in opposite phase to the bases of the half-bridge transistors. The transistors are alternately open and closed. At the same time on the primary winding 26 of the transformer 25 is induced variable

5 voltage. The transformed voltage from the winding 27 through the rectifier 29 enters the load connected to the output pins 3 and 4. The voltage from the winding 28 through the rectifier 30 goes to

0 output 12 of the converter 7 and to the input 11 of the control unit. At the same time, the voltage from the divider 14 and from the output of the source 15 of the reference voltage is fed to the inputs of the comparator 16.

5 Depending on the ratio of the voltages at the inputs of the comparator 16c, its output to the input 17 of block 9 receives a logical signal O or logical 1, if the voltage at the input of the comparator 16 connected to divider 14 exceeds the voltage at the other input and output comparator 16, the signal is logical 1, Divider 14 is calculated so that in the absence of emissions at 5 voltages on the input terminals 1.2 the input voltage of the comparator 16 connected to the divider 14 is less than the voltage on the other input. In this case, the output of the comparator 16 is a signal

0 logical 0. Accordingly, when a surge occurs at input pins 1.2, exceeding a predetermined level, the voltage at the input of the comparator 16 connected to the divider 14 exceeds

5, the voltage at the other input and at the output of the comparator 16 produces a logical 1 signal.

At input 11 of block 9 there is a signal of logical 0, when converter 7.

not working and the signal is logical 1 when

0 A capacitor 6 charge to a certain level occurred and converter 7 began to work.

If on both inputs 11 and 17 of block 9, i.e. the inputs of element 18 are present

5 logical O, then the output of this element is logical 1. This signal goes to the first input of element 19 and, together with the logical O present on the second input of element 19, gives the output

of this element logical 1. incoming at the input of the inverter 20. At the output of the inverter 20 there will be a logical O, and at the input of the level converter 21 there is also a logical O.

If logic level O is present at input 11 of block 9, and logic level G is at input 17 of block 9, then at the first and second input of element 18 there are levels O and 1, respectively. At these levels, the output of element 18 appears logical 1. This signal, together with the level O at the other input of element 19, produces the output of this element level 1, which, at the input of the inverter 20, is converted at the output of this element into logical O. Thus, a logical O is present at the output of the level 21 converter.

If at input 11 of block 9 there is a logical 1st, and at input 17 of the same block is logical O, then logical 1 and O will also be present at the inputs of element 18. As a result, logical 1 is present at the output of element 1, which arrives at the first input element 19, together with level 1 at the second input of element 19, produces at the output of this element a logic O which enters the input of inverter 20. Logic 1 appears at the output of inverter 20. Thus, 1 is present at the input and output of level converter 21.

If logical 1 arrives at inputs 11 and 17 of block 9, then logic 1 is outputted at element 18. In this state, logical element O is present at the output of element 18 and is fed to the first input of element 19. Logic 1 is fed to the second input of element 10 and in this state, logical 1 is present at the output of this element. This logical 1 is fed to the input of inverter 20 and logical 0 is output at the output of inverter 20, which is fed to the input of level converter 21. Thus, at the output of the converter of 21 levels there is a logical O.

If at inputs 11 and 17 of block 9 there are levels of logical O, then at the inputs of element 22 there are also levels of logical O. At the output of element 22, logical 1 appears in this state.

From the output of element 22, logical 1 is fed to the second input of element 23, at the first input of which there is a level O coming from the second input of element 22. In this state, the output of element 23 contains a logical O. This signal is fed to the input of level converter 24, the output of which establishes a logical O,

If logical block O is at input 11 of block 9 and logical 1 is at input 17 of this block, then logical first and second are present at the first and second inputs of element 22. In this state, logical 0 is set at the output of element 22 at the second input of the element 23. At the first input of the element 23 there is a logical 1.

0 At the output of element 23, a logical O is established, which is fed to the input of a level converter 24, at the input of which a logical O is established.

If logic level 1 arrives at input 11 of block 9, and logical O is input to input 17, then levels 1 and O are present at the first and second inputs of element 22. Logic level 0 is set at the output of element 22,

0 which is fed to the second input of the element 23. At the first input of the element 23 there is a logical O. At the output of the element 23 a logical level 1 is set, which is fed to the input of the converter 24

5 levels. Logic 1 is set at the output of level 24 converter.

If the inputs 11 and 17 of block 9 are supplied with the levels of logical 1, then at the input of the element 22 there are the same levels. In such

The 0 state at the output of the element 22 is set to logical O, which is fed to the second input of the element 23, on the first loop of which logical 1 is present. The output of the element 23 is set to logical O1, which is fed to the input of the level converter 24. At the output of the latter is established logical O.

The signal from output 10 of block 9, i.e. from the exit

0 converter 21 or level 24, goes to the key element 8, which, with logical 1 at output 10, closes and bridges the resistor 5.

Thus, in the event of the appearance of a high voltage across the input pins 1.2, the key element 8 opens and a voltage drop from the current flowing from the primary power source is created on the resistor 5. In this case, the voltage supplied to the capacitor 6 and the converter 7 is less by the amount of voltage drop across the resistor 5.

Compared to the prototype with voltage surges at input terminals 1.2 in

5, this device improves reliability. Moreover, to limit the voltage, it is not necessary to introduce additional elements into the power circuit of the secondary power supply source. For this purpose, a restrictive element 5 and a key element 8 are used, which were used in the prototype only at the moment of switching on the device. Thus, in the proposed secondary power supply, reliability is increased by limiting voltage selections at the input terminals without degrading the weight and size characteristics. In addition, the instability of the output voltage of the device is reduced.

Claims (3)

1. A secondary power source containing a limiting element connected in series between the input and output terminals, a capacitive filter and a voltage converter, a key element connected by a control input to the output of the control unit, the key element being connected in parallel to the limiting element and the first input of the control unit connected with an additional output voltage converter, characterized in that, in order to increase reliability by limiting the voltage spikes on the input output x, a voltage divider, a voltage source and a comparator are entered into it, and the control unit is equipped with a second input, the voltage divider being connected to the input terminals, and the comparator inputs are connected to the outputs of the voltage divider and the voltage source, respectively The second input of the control unit, which forms at its output a signal that closes the key element, only when there is a signal at its first input, and is absent at the second input, is connected to the output of the comparator. 2. The source according to claim 1, characterized in that the control unit contains two logic elements 2I-NOT, an inverter and a level converter, the output of which used as the output of the control unit, and the first and second inputs of the first logic element 2I-NOT are used as respectively the first and second inputs of the control unit, while the output the first logic element 2И-NOT is connected to the first input of the second logic element 2И-НЕ, the second input of which is connected to the first input of the first logic element 2И-НЕ, and the output through the inverter connected to the input of a level converter. 3. The source according to claim 1, characterized in that the control unit contains two logical elements 2IL-NOT and a level converter, the output of which is used as the output of the control unit, and the first and second inputs of the first logical element 2 OR-NOT used as respectively the first and second inputs the control unit, wherein the output of the first logic element 2IL-NOT is connected to the first input of the second logic element 2IL-NOT, the second input of which is connected to the second input of the first logical element 2 or not. and the output is connected to the input of a level converter. W I i Ij-r-y 25 1 eleven P 19 || G} FIG. Z eleven P yy c Fig.Z Yu ten