JPS58127568A - Power source - Google Patents

Abstract

PURPOSE:To reduce the capacity of an auxiliary DC power source which supplies a voltage to an oscillator which drives a switching transistor in a power source of a high frequency inverter type by improving the power source supplying means to the oscillator. CONSTITUTION:An AC voltage applied to input terminals 1, 2 is applied alternately in polarity through a rectifier 4 and switching transistors 6, 7 to the primary coil 9 of a high voltage transformer 8. The AC voltage which is induced at the secondary coil 10 is rectified by diodes 11, 12 and supplied as high voltage DC to a load. In this case, the transistor 6, 7 are controlled ON of OFF by a pulse signal from an oscillator 15, and higher voltage of the secondary DC power source of the auxiliary power source which is formed of an auxiliary transformer 23 and a rectifier 24 or transformer 8 is supplied through a power source converting unit 20 to the oscillator 15.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention improves a power supply means for a driving oscillator of a switching transistor in a high frequency inverter type power supply device, IfIl.
#This relates to a power supply device that makes it possible to reduce the power supply capacity of an auxiliary DC voltage that supplies voltage to an oscillator.

The power supply equipment using the conventional high frequency inverter method [
is for the oscillator and switching transistor switching circuit that generates the drive signal for on/off control of the switching transistor that supplies voltage to the primary winding of the transformer.

An auxiliary DC power supply is provided to provide a predetermined power supply voltage. The auxiliary DC power supply must have a capacity necessary to operate the oscillator normally. For this reason, the auxiliary DC power supply has a relatively large capacity.

In general, when trying to improve conventional equipment, although it does not apply to copying machines, major improvements include not only improving performance but also streamlining the equipment by making it smaller, lighter, and cheaper. It has become an element. As one of these, it is desired to make it possible to reduce the capacity of the auxiliary DC power supply used in conventional power supply devices to achieve miniaturization. And -1, for example, if a short-circuit condition occurs in the load of the power supply device, it would be possible to protect the power supply device and restore the short-circuit condition to a normal state.
There are also demands that it be even more desirable.

The present invention aims to solve the above-mentioned demands,
In a power supply device, the auxiliary DC power supply supplies power to an oscillator that generates a drive signal for on/off control of a switching transistor that applies voltage to the primary winding of a high-voltage transformer only when the power supply device is started. Do it by.

By using the secondary side DC voltage of the transformer after startup, it is possible to reduce the capacity of the auxiliary DC power supply, thereby achieving a voltage capacity that can realize miniaturization of the auxiliary DC power supply. is intended to provide. Furthermore, the present invention provides a power supply device that controls the output signal of the oscillator to stop driving the switching transistor when a short circuit occurs, thereby preventing overcurrent at the time of a short circuit. It is an object.

This will be explained below with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of an embodiment of the power supply device of the present invention, and FIG. 2 is a waveform diagram of an output signal of an oscillator in the embodiment shown in FIG. Reference numerals 1 and 2 in the figure are input terminals.

For example, an AC voltage of 100r or 200V is applied, 5 is a filter, 4 is a rectifier, 5 is a changeover switch that is switched depending on the voltage value applied to the input terminals 1 and 2, and 6 is a first switching transistor, 7&S second switching transistor,
8 is Trance, 9 is Transli Volume 1! , 10 is the transformer 80 secondary winding, 11 and 12 are diodes, and 15 and 14 are output electrons.

15 is an oscillator and a control IC 116 and 17 are control transistors, 1B and 19 are pulse transformers,
20 is an oscillator power supply switching section, 21 and 22 are diodes, 23 is an auxiliary transformer, 24 is a rectifier, 25 is a transistor, 26 to 36 are resistors, 57 to 41 are capacitors, 42 is a short circuit detection section, 45 and 44 are diodes 45 is a thyristor, 46 is a transistor, 47 is a chi,
-represents the coils and coils, respectively.

In FIG. 1 showing an embodiment of the present invention, AC voltage applied to input terminals 1 and 2 is converted to DC in a rectifier 4, and the converted DC voltage is alternately turned on and off as described later. The polarity of the primary winding 9 of the high voltage transformer 80 is alternately changed by switching transistors 6 and 7 which are controlled to be off.

It is applied after The AC voltage passed through the secondary winding 10 is rectified by diodes 11 and 12, and high voltage big is supplied to a load (not shown) connected to output terminals 15 and 14. The on/off control 1 of the switching transistors 6 and 70 is performed by a pulse signal outputted from an oscillator 15 as shown in FIG. The pulse signal is 1. For example, if the waveform of a pulse signal outputted from the output terminal E1 of the oscillator 15 is as shown in FIG. A pulse signal with a waveform is output. That is, as shown in FIG. Oscillator 15
The reference voltage of the reference voltage terminal REF of the resistors 27 and 281
It is determined by the voltage divided by and applied to the duty determination signal terminal DT. In this way, for example, while a pulse signal is being output from the output terminal E1,
16 control transistors are turned on. As a result, via the pulse transformer 18, the first switching
Transistor 6 is turned on, and a DC voltage rectified by rectifier 4 is applied to primary winding 9 of transformer 8 . During this time, as mentioned above, the output terminal E2 of the oscillator 15
Since no pulse signal is output from the second switching transistor 7, the second switching transistor 7 remains in the off state. Further, while the pulse signal is being output from the output terminal E2 of the oscillator 15, the second switching transistor 7 is similarly turned on. Needless to say, during this time, the first switching transistor 6 is in an off state. In this way.

By alternately controlling the first and second switching transistors 6 and 7 on and off, direct current is output from the output terminals 15 and 14, as described above.

By the way, in order to drive the i generator 15 that outputs a pulse signal for controlling the on/off 11 of the first and second switching transistors 6 and 7,
Naturally, a power source is required. In the present invention, as shown in FIG. 1, there is provided an oscillator power supply switching section 20 constituted by diodes 21 and 22. and.

The diode 21 is connected via a transistor 25 to an auxiliary power source constituted by an auxiliary transformer 23 and a rectifier 24, and the diode 22 is connected via a resistor 26 to the secondary DC power source of the transformer 80. Therefore, in the power supply switching section 20.

Voltage applied to diode 21 and diode 22 -
10,000 diodes to which high voltage is applied.

When the oscillator 15 becomes conductive, power is supplied to the power supply terminal voltage FCC of the oscillator 15. A detailed explanation of the driving conditions of the transistor 25 will be given later, and here we will explain the conditions at which AC voltage is input to the input electrons 1 and 2 at startup. You can think of it as being in the on state.

Now, in a state where a current voltage is applied to the input electrons 1 and 2, that is, in a state where the transformer 8 is still waiting for activation before being excited, the voltage is naturally applied to the second order a of the transformer 802. It's so transparent that it's so hot.

Therefore, at the time of starting, the output voltage of the auxiliary power supply 1gI], that is, the output voltage of the rectifier 24 is the same as that of the transistor 25. diode 21
t' to the power supply terminal voltage VC'C" of the oscillator 15. As a result, the oscillator 15p'-ranox signal is output, and as described above, l!1!1 and the second Switching transistors 6 and 7 turn on
Due to the off-control, the high-voltage transformer 8 is excited and the [fi voltage is outputted from the output terminals 15 and 14, and at the same time, the diode 22 is connected via the resistor 26.
A voltage is also applied to. Since the voltage division ratio of the resistor 26 is set so that the voltage applied to the diode 22 in this state is higher than the output voltage of the rectifier 24 which is applied to the diode 21 via the transistor 25, The power supply voltage supplied to the voltage terminal voltage FCC of the oscillator 15 is supplied from the secondary side of the transformer 80. P), power is supplied from the auxiliary power supply, that is, the rectifier 24 to the oscillator 15 (not only to the w1 oscillator 15 but also to the pulse transformers 18 and 19) only at the time of startup. It turns out. Therefore, the oscillator 1 powered by the auxiliary power source
Since the power supply time to 5 can be made very short, the IF auxiliary power supply, that is, the auxiliary transformer 25 and 5, can be made very short. It is possible to make the capacity of the rectifier 24 and the rectifier 24 very small.

In addition, in the illustrated embodiment of 1i41, the output terminal 13
．． A short circuit detection section 42 is provided to prevent overcurrent when a short circuit occurs between the terminals 14 and 14. That is, the voltage drop across the resistor 56 when the short circuit occurs is detected and the thyristor 45 is turned on. the result.

In the transistor 46, the resistance 31% diode 4
4. Base current flows through the thyristor 45) and turns it on. By turning on the transistor 46, the reference voltage of the reference voltage terminal REF is directly applied to the date determination signal terminal DT.

Therefore, the pulse width D (shown in FIG. 2) of the pulse signal output from the output terminals E1 and E2 of the first oscillator 15 is controlled to be zero, and the first and second switching transistors 6 and 70 are turned on.・Off control is stopped. In this way, when a short circuit occurs, the transformer 80
Excitation of the primary winding 9 is stopped and no voltage is transmitted through the secondary winding #10, thereby making it possible to prevent overcurrent. In addition, the aforementioned σ transistor 2
5, the details of the driving conditions of the transistor 25 have been omitted, but the driving conditions will be explained here. That is, the auxiliary power supply section, ie, the auxiliary transformer 23 and the rectifier 24, not only supplies power to the generator 15 at the time of startup, but also constantly supplies power to the short circuit detection section 42.

Compared to the short circuit detection section 42, the power supplied to the oscillator 15 (including pulse transformers 18 and 19) is large, but the power is supplied to the oscillator 15 only at the time of startup, and at all times it is a small capacity power supply. Since it is sufficient to supply power only to the short-circuit detection section 42, in the present invention, each amount of the auxiliary power supply V can be significantly reduced. However, if the transistor 25 is always on, 1, for example, when the aforementioned short circuit occurs, the diode 2 is connected to the cape.
As the voltage applied to 2 decreases, power is supplied to the oscillator 15 from the auxiliary power supply.As mentioned above, in the present invention, the capacity of the auxiliary power supply is extremely small. There is a possibility that the output voltage of the short-circuit detector 42 decreases, and the operation of the short-circuit detector 42 becomes uncertain. Therefore, after the oscillator 15 is powered on via the diode 22 after startup, the circuit is constructed such that the transistor 25 is turned off.

As explained above, according to the present invention, the power supply circuit configuration for the oscillator 15 that generates the drive signal for controlling on/off of the switching transistor for excitation of the transformer is performed by the auxiliary power supply at the time of startup. Later, by using the DC output of the transformer, it is possible to provide a power supply device that can reduce the capacity of the auxiliary power supply. Furthermore, a short circuit detection section is provided to stop the driving of the switching transistor by controlling the output signal of the oscillator when a short circuit occurs, thereby making it possible to prevent overcurrent at the time of a short circuit.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention, and FIG. 2 is a diagram showing the output signal waveform of the oscillator in the embodiment shown in FIG. 1. In the figure, 1 and 2 are input terminals; 3 is a filter, 4 and 24 are rectifiers, 5 is a selector switch, 6
and 7 are first and second switching transistors, 8 is a transformer, 941st winding #i1% 10 is a secondary winding, 11.12.21.22 #43 and 44 diodes, 13 and 14 output terminal. 15&X oscillator, 16 and 17 are transistors for I1IllI.

Claims (1)

[Claims] An oscillator, a switching transistor that is turned on and off by an output signal of the oscillator, and a transformer whose primary winding is supplied with a DC voltage that is turned on and off by the switching transistor, A power supply device configured to convert the output of the transformer into direct current via a rectifier and supply the same, comprising: an auxiliary direct current power supply provided to supply a power supply voltage to the oscillator at the start of operation; Connected to the DC output of the transformer. An oscillator power supply switching unit is provided that supplies a higher voltage between the auxiliary DC power supply voltage and the DC output voltage of the transformer as the power supply voltage of the oscillator, and the oscillator power supply switching unit switches between the auxiliary DC power supply and the DC output voltage of the transformer. A power supply device characterized in that it is configured to supply the higher of the output voltage and the output voltage as the power supply voltage of the oscillator.