KR950003873B1 - S. m. p. s - Google Patents

Abstract

The circuit comprises; a synchronization detecting part for detecting a synchronization of the output power by the comparison with the reference value by detecting the second coil of the power supply; an on-time counter for counting a predetermined on-time after completing the off-time on basis of the synchronization signal and the outer switching control signal; an off-time counter for counting a predetermined off-time after completing the on-time on basis of the synchronization signal; an oscillator for applying a count clock signal of a predetermined frequency to the on-time and off-time counters; an on/off signal outputting part for receiving the output signal of the on-time counter as a data input signal, receiving the output signal of the off-time counter as a clear signal after performing an AND operation with the synchronization; and a driver for operating the switching circuit of the power supply by driving the on/off signal.

Description

Switching Control Circuit of Resonant Power Supply

1 (a) to 1 (c) are waveform diagrams for explaining problems of the resonant power supply apparatus according to the prior art.

2 is a switching control circuit diagram of a resonance type power supply according to the present invention.

3 (a) to 3 (n) are timing diagrams of respective parts of the switching control circuit of the resonance type power supply apparatus according to the present invention.

* Explanation of symbols for main parts of the drawings

10: power supply unit 11: bridge diode

12: smoothing portion 13: switching portion

14 transformer 15 rectifier

16: magnetron 20: on time counter

21: delay circuit 22: first counter

30: off time counting unit 31: the second counter

40: oscillation unit 50: on / off signal output unit

60: drive circuit 70: synchronous detection unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switching control circuit of a switching power supply, and more particularly, to a switching control circuit of a resonant power supply which can prevent breakage of a switch by controlling the resonance time so that the switch is not turned on continuously.

In general, a resonant power supply converts an AC power source into a DC source and applies the transformer to the primary coil of the transformer. High pressure can be obtained from the side coil.

As the switching element of the resonant power supply device, a transistor TR, a MOSFET or the like is usually used, and a pulse wave is applied to the gate of the switching element by switching from a switching control circuit.

On the other hand, when a pulse wave is applied to the gate of the switching element, the switching maximum on time is determined by the breakdown voltage (C _CE max) and the set output of the switching element, and the energy accumulated in the coil during the maximum on time in the off time is It must be reversed.

However, in the resonant power supply apparatus according to the prior art, the switching pulse is applied to the gate of the switching element from the switching control circuit as shown in the waveform shown in FIG. 1 (a), and the voltage (C) between the terminals of the switching element. _CE ) is represented by the waveform as shown in FIG. 1 (b). Here, FIG. 1C is a waveform showing a coil current.

However, if the on-signal is applied to the gate again by an external signal (noise or an on-signal from the outside) in a state where a proper time has not elapsed after the switching pulse signal applied to the gate of the switching element is turned off (first ( a) in part a), since the energy accumulated in the primary coil of the transformer is not completely discharged and energy is accumulated again, both ends of the switching element when the off signal is applied to the gate of the switching element again. The resonance voltage shown in FIG. 1 (b) exceeds the maximum voltage (C _CE max) of the switching device, as shown in FIG.

SUMMARY OF THE INVENTION An object of the present invention is to improve the conventional problems as described above. By counting the switching off time so as to turn off the appropriate time, it is possible to prevent the switching device from being turned on continuously by an external signal or the like, thereby preventing damage to the switching element. The present invention provides a switching control circuit of a resonance type power supply device.

The switching control circuit of the resonant power device according to the present invention converts AC power into DC power and applies it to the transformer 14 as shown in FIG. 2, and through the switching element on the primary side of the transformer 14. A switching power supply unit 10 for fast switching to apply the secondary output of the transformer 14 to the load side, and a synchronization for detecting the output signal by comparing the secondary output signal of the power supply unit 10 with a reference value to detect synchronization of the output power supply. An on-time counting unit 20 that counts a predetermined on-time after completion of the off-time based on the detection unit 70, the synchronization signal of the synchronization detection unit 70, and an external switching control signal (Enable), and the synchronization signal An off-time counting unit 30 for counting a predetermined off-time after completion of the on-time counting of the on-time counting unit 20 based on the synchronization signal of the detection unit 70, the on-time counting unit 20, and the off-time counting unit 20. Predetermined weeks in the time counting section 30 An oscillator 40 for applying the wave count clock signal, and an output signal of the on-time counter 20 as a data input signal, and an output signal of the off-time counter 30 and the synchronous detector 70. And an on-off signal output unit 50 for receiving a combination of synchronous signals and outputting an on / off signal of a switching element, and driving the on / off signal to drive the switching element of the power supply unit 10. It consists of a drive circuit 60 for driving the.

Here, the power supply unit 10 stabilizes the bridge diode unit 11 for converting AC power into DC power, and the output power of the bridge diode unit 11 through the choke coil CC1 and the smoothing capacitor C1. A transformer 12 for supplying the high voltage to the secondary side by high speed switching by receiving the smoothing unit 12, the output power of the smoothing unit 12, and the switching element TR1 at the primary side of the transformer 14; It is composed of a switching unit 13 for switching the DC power on / off at a high speed through the), the secondary output power of the transformer 14 is the current through the capacitor (D3) and diodes (D4, D5) To be applied to the load (here, magnetron (MGT)) 16.

The on-time counting unit 20 supplies a delay circuit 21 for shaping an external drive signal (Enable), an output signal of the delay circuit 21, and a synchronization signal of the synchronous detection unit 70. NAND gate NAND1 for NAND combining the AND gate AND1 to be combined, the output signal of the off-time counting unit 30, and the external drive signal Enable inverted through the inverter face IN1, and the NAND. A first counter 22 that receives an output signal of the gate NAND1 as an enable signal EN and receives an output signal of the AND gate AND1 as a load signal / LOAD to count a predetermined on time; And an OR gate OR1 for ringing the n (n) bit output signal of the first counter 22 and outputting it as an on-time counting signal.

The off-time counting unit 30 receives the on-time counting signal of the on-time counting unit 20 as an enable signal through the inverter gate IN2 and receives the sync signal of the sync-detecting unit 70. The second counter 31, which is applied as a load signal / LOAD through the inverter gate IN4 and counts a predetermined off time, and an n (n) bit output signal of the second counter 31 are ringed. It consists of an OR gate OR2 output as an off-time counting signal.

The on / off signal output unit 50 may include an AND gate AND2 for and combining the output signal of the off time counting unit 30 with the synchronization signal of the synchronous detection unit 70 through the inverter gate IN3. The output signal of the AND gate AND2 is applied as a clear signal CLR, and the output signal of the on-time counting unit 20 is applied as a data input signal D to switch on / off in synchronization with a clock signal. It consists of a flip-flop (F / F1) which outputs a signal.

In addition, the synchronous detection unit 70 detects the output of the transformer 14 secondary side of the power supply unit 14 and compares the reference voltage set by the two resistors R1 and R2 through the comparator 71 to the load side. The synchronization of the output power supply is detected.

Referring to the operation of the switching control circuit of the resonant power device according to the present invention configured as described above are as follows.

First, an external drive signal (Enable) is applied to the on-time counting unit 20 as shown in FIG. 3 (b) by a user's selection, and the like, as shown in FIG. 3 (b), and low potential through the inverter gate IN1. The signal is converted into a signal, which is combined with the output signal of the off-time counting unit 30 through the NAND gate NAND1 and applied as an enable signal of the first counter 22. At this time, the external driving signal is delayed by a predetermined timing as shown in FIG. 3 (d) through the delay circuit 21, and then is combined with the synchronization signal of the synchronization detector 70 through the AND gate AND1 to form a third signal. Also applied as a load signal of the first counter (22).

Accordingly, when the external counter signal is applied to the first counter 22 and the output signal of the off-time counter 30 is at low potential, that is, when the off-time is completed, as shown in FIG. After the same enable signal is applied, and after a predetermined timing delay, the load signal is applied at the timing shown in FIG. 3 (e) through the AND gate AND1 to start an on time count. The on-time count counts for a preset on-time, which is outputted as a high potential signal at the timing as shown in FIG. 3 (f) through the oragate OR1.

When such an on-time signal is output as a high potential signal, the high potential signal is maintained during the on-time time through the flip-flop F / F1 of the on / off signal output unit 50, which causes the driving circuit 60 to operate. Through this, the switching element TR1 of the switching unit is turned on.

Subsequently, when the set count value of the first counter 22 is counted, the output signal of the OR gate OR1 becomes a low potential signal, and thus the output signal of the flip-flop F / F1 becomes a low potential signal. The switching transistor TR1 is turned off through the driver 60.

When the switching element TR1 of the switching unit 13 is turned on / off in this manner, resonance occurs in the transformer 14, and the period of the waveform of the resonance voltage is determined by the coil N3 and the capacitor C3. Then, the comparator 71 of the synchronous detection unit 70 receives the resonance waveform, the voltage of the negative terminal becomes high, and the output signal of the comparator 71 is output as a low potential signal. The low potential signal is output as a signal for determining load signals of the on-time counting section 20 and the off-time counting section 30, respectively.

On the other hand, the output signal of the OR gate OR1 of the on-time counter 20 is passed through the inverter gate IN2 of the off-time counter 30 as shown in FIG. 3 (g). 31) is applied as an enable signal. In addition, the output signal of the synchronous detection unit 70 is applied as a load signal of the second counter 31 through the inverter gate IN4. Accordingly, the second counter 31 counts for a preset off time, and the count value is output as an off time signal through the oragate OR2.

At this time, the value set as the off-time coefficient value of the second counter 31 is set to the coefficient value corresponding to the resonant period of the power supply unit 10, when the output signal of the synchronous detection unit 70 becomes a low potential signal, The low potential signal is inverted through the inverter gate IN4 and applied as a load signal of the second counter 31 as a high potential signal. Accordingly, the second counter 31 counts the off-time coefficient value corresponding to the preset resonance period, and the off-time signal is generated at the timing as shown in FIG. 3 (i) through the ORA gate OR2. Is output.

Subsequently, the output signal of the OR gate OR2 disables the first counter 22 through the NAND gate of the on-time generator 20, and the AND gate of the on / off signal output unit 50. The clear state of the flip-flop F / F1 is maintained through (AND2). That is, the flip-flop F / F1 is cleared during the off-time count so that the low potential signal is output, and the low potential signal maintains the state in which the switching element TR1 is turned off through the driving circuit 60.

Therefore, even if the external driving signal is applied as an active signal due to noise or a user's selection during such off time, the first counter of the on-time counting unit 20 is based on the output signal of the off-time counting unit 30. Since 22) is in a disabled state and at the same time the flip-flop F / F1 of the on / off signal output section 50 is clear, the switching element TR1 reliably remains in the off state for the off time.

Thereafter, in the synchronous detection unit 70, the resonance waveform is reduced by passing the zero voltage, and the output signal of the comparator 71 is outputted with the high potential signal, which is through the inverter gate IN4 of the off-time counting unit 30. The load in sign of the second counter 31 is inactive, and is applied to the first counter 22 of the on-time counter 20 as an active load signal, and the on / off signal output unit 50 is cleared. Is applied as a signal. At this time, when the off-time count is completed, the second counter 31 ends the count, and the output signal of the OR gate OR2 becomes a low potential signal, thereby checking the first counter 22 of the on-time counting unit 20. In addition to enabling the signal, the clear state of the flip-flop F / F1 of the on / off signal output unit 50 is released.

Accordingly, the on time counting unit 20 repeats the above process by performing the on time counting. That is, the off time of the switching element TR1 is accurately maintained without being changed by external noise or drive signal.

As described above, the present invention sets a counter for determining on-time and a counter for counting off-time according to the resonance period (off-time), respectively, in the on-time generator that generates the on-time of the power switch (switching element). In addition, the on-time and off-time counts are linked to each other to control the on and off signals, thereby preventing the switch element from being continuously turned on, thereby preventing damage to the switch element.

That is, when the on-signal is received from the outside after the switch is turned off and before the count value of the off-counter is counted, or when the on-signal is generated incorrectly due to noise generated in the synchronous detection unit, or to configure the inverter power supply unit in series and parallel It is generated by prolonging the on time of the switch element by preventing the switch element from being turned on continuously due to the ON signal generated when the resonant circuit is momentarily cut off by the chattering of the relay during operation using a relay or the like. There is an effect that can prevent damage to the switch element, thereby improving the performance and safety of the power supply circuit.

Claims (4)

In a switching control circuit for controlling the on / off of the switching element of the resonant power supply unit 10, the synchronization detection unit for detecting the secondary output signal of the power supply unit 10 and detecting the synchronization of the output power by comparison with a reference value 70, an on-time counting unit 20 for counting a predetermined on-time after completion of the off-time based on the synchronizing signal of the synchronizing detection unit 70 and an external switching control signal (Enable), and the synchronizing signal detecting unit An off time counting unit 30 for counting a predetermined off time after completion of the on time counting of the on time counting unit 20 based on the synchronization signal of 70, the on time counting unit 20 and the off time; An oscillation unit 40 for applying a clock signal to a count of the predetermined frequency to the water collecting unit 30, and the output signal of the on-time counting unit 20 is applied as a data input signal, and the off-time counting unit 30 The output signal AND combines the synchronization signal of the synchronization detection unit 70. And an on / off signal output unit 50 that is applied as a clear signal and outputs an on / off signal of the switching element, and a drive circuit 60 for driving the on / off signal to drive the switching element of the power supply unit 10. Switching control circuit of the resonant power device, characterized in that consisting of. The on-time counting unit 20 includes a delay circuit 21 for shaping an external drive signal (Enable), an output signal of the delay circuit 21, and the synchronization detection unit 70. NAND gate NAND1 for NAND combining the AND gate AND1 for AND-combining the synchronous signal, the output signal of the off-time counting unit 30, and the external drive signal Enable inverted through the inverter gate IN1. And a first counter that receives an output signal of the NAND gate NAND1 as an enable signal EN and receives an output signal of the AND gate AND1 as a load signal / LOAD to count a predetermined on time. A switching control circuit of a resonant power supply device, characterized in that it comprises an OR gate OR1 that outputs an n-bit output signal of the first counter 22 and outputs it as an on-time signal. . The synchronous detection unit 70 of claim 1, wherein the off-time counter 30 receives an on-time counter signal of the on-time counter 20 as an enable signal through an inverter gate IN2. Is supplied as a load signal / LOAD through the inverter gate IN4 to count a predetermined off time, and the n-bit output signal of the second counter 31. Switching control circuit of a resonant type power supply, characterized in that consisting of an OR gate (OR2) to output the off-time coefficient signal by ringing. The on / off signal output unit 50 performs an AND combination of the output signal of the off time counting unit 30 and the synchronization signal of the synchronous detection unit 70 through the inverter gate IN3. The AND gate AND2 and the output signal of the AND gate AND2 are applied as the clear signal CLR, and the output signal of the on-time counting unit 20 is applied as the data input signal D to the clock signal. A switching control circuit of a resonance type power supply, characterized in that consisting of a flip-flop (F / F1) for synchronously outputting a switching on / off signal.