KR960001248Y1 - Temperature compensating circuit of power supply - Google Patents

Abstract

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Description

Temperature compensation circuit of power supply

1 is a circuit diagram showing a conventional power supply

2 is a circuit diagram showing a temperature compensation circuit of the power supply of the present invention

* Explanation of symbols for main parts of the drawings

10: direct current circuit 100: power supply switching circuit

200: constant voltage circuit T1: transformer

F: Fuse D11-D14: Diode

C11, C201: Capacitor ZD201, ZD202: Zener Diode

Q101-Q103, Q201, Q202: Transistor

R101-R103, R201, R202: Resistance

The present invention relates to a power supply device in which the input AC power is converted into the power required for the system and outputted. In particular, a temperature compensation circuit of the power supply device that can prevent a temperature rise due to heat generated by excessive current flow. It is about.

In general, as shown in FIG. 1, the power supply device includes a transformer T1 for causing the AC power input to be stepped down and outputted, and a DC circuit for converting the power stepped down by the transformer into DC power. 10), a power switching circuit 20 through which the power output to the DC circuit 10 passes, and a constant voltage circuit 20 for causing the power output from the power switching circuit 20 to be output to the power required for the system. It consists of.

Here, the DC circuit 10 is composed of full-wave rectification diodes (D11)-(D14) and a smoothing capacitor (C11), so that the input AC power is full-wave rectified, smoothed, and converted into a DC power source. .

The power supply switching circuit 20 includes a bypass resistor R21, switching transistors Q21 and Q22, distribution resistors R22 and R23, and is applied to an input signal S21. The transistor Q21 is operated so that the transistor Q22 is operated by the operation of the transistor Q21 so that the DC power output from the DC circuit 10 passes.

The constant voltage circuit 30 includes switching transistors Q31 and Q32, a voltage selection zener diode ZD31 and ZD32, a signal shaping resistor R31, and a capacitor C31. The transistor Q31 is operated by the power selection signal S31 input from the outside, and the set voltages of the diodes ZD31 and ZD32 are selected by the transistor Q31, and the voltage outputted by the selected voltage. It is configured to remain constant at all times.

In the existing power supply device configured as described above, when the AC power is input, the transformer T1 is operated to output the step-down power, and the power output from the transformer T1 is supplied to the DC circuit 10. Is approved.

At this time, full-wave rectification is performed by the rectifying diodes D11-D14 of the DC circuit 10, and the rectified power is applied to the capacitor C11 and smoothed.

On the other hand, the transistor Q21 of the power supply switching circuit 20 is turned on by the signal S21 input from the outside, and the transistor Q22 is turned on by the operation of the transistor Q21. Therefore, the power output from the DC circuit 10 is bypassed by the resistor R21 of the power switching circuit 20, and the bypassed power passes through the transistor Q22.

In addition, the transistor Q31 of the constant voltage circuit 30 is operated by the power selection signal S31 input from the outside, and one of the voltages set in the zener diodes ZD31 and ZD32 is operated by the operation of the transistor Q31. Is selected. That is, when the transistor Q31 is turned on, the set voltage of the zener diode AD32 is selected, and when the transistor Q31 is turned off, the set voltage of the zener diode ZD31 is selected.

Then, the switching transistor Q32 is operated by the voltage selected by the zener diodes ZD31 and ZD32, and a constant power supply is always output by the operation of the transistor Q32.

However, in the conventional power supply device as described above, when overcurrent flows, heat is generated in the transistor Q22 of the power switching circuit 20 and the transistor Q32 of the constant voltage circuit 30, and this heat causes the inside of the apparatus. The temperature of is increased, there is a problem that the transformer is destroyed by the rise of this temperature.

The present invention is to solve such a problem, an object of the present invention is to provide a temperature protection circuit of the power supply device to be eliminated the temperature rise caused by the overcurrent by passing the input overcurrent is distributed.

In order to achieve the above object, the present invention provides a transformer for inputting AC power to be stepped down and outputted, a DC circuit for converting the power stepped down by the transformer into a DC power source, and the DC circuit. A power supply device comprising a power switching circuit through which an output power passes and a constant voltage circuit for causing the power output from the power switching circuit to be output to the power required by the system, the transistor for distributing current passing through the power switching circuit. And a resistor for distributing a current passing through the constant voltage circuit, and a fuse connected to an output side of the constant voltage circuit to shut off the output when an input current is an overcurrent.

Hereinafter, the temperature protection circuit of the power supply apparatus according to the present invention will be described in more detail with reference to the accompanying drawings.

2 is a circuit diagram showing a temperature protection circuit in the power supply device of the present invention, in which a transformer T1 for inputting AC power is stepped down and outputted, and a DC power source for converting the power stepped down by the transformer into DC power. Constant voltage for causing the circuit 10, the power switching circuit 100 through which the power output from the DC circuit 10 passes, and the power output from the power switching circuit 100 to be output to the power required for the system. The circuit 200 is comprised.

Here, the DC circuit 10 includes the full-wave rectifying diodes D11 to D14 and the smoothing capacitor C11, so that the input AC power is full-wave rectified and smoothed to be converted into a DC power source. It is composed.

The power supply switching circuit 100 includes a bypass resistor R101, switching transistors Q101 to Q103, and a voltage drop resistor R102 and R103 to input an input signal S101. The transistor Q101 is operated, and the transistors Q102 and Q103 are operated by the operation of the transistor Q101 so that the DC power output from the DC circuit 10 passes.

At this time, the transistors Q102 and Q103 are constituted of Darlington so that the current passing through is distributed.

The constant voltage circuit 200 includes a switching transistor Q201 and a Q202, a voltage selection zener diode ZD201 and a ZD202, a signal shaping resistor R201 and a capacitor C201, and a current distribution resistor. R202, the transistor Q201 is operated by the power selection signal S2o1 input from the outside, and the set voltage of the zener diodes ZD201 (ZD202) is selected by this transistor Q201. The voltage output by the voltage is always kept constant.

Here, the resistor R202 is connected between the collector side and the emitter side of the transistor Q202 so that the current passing through the transistor Q202 is distributed.

A fuse F is connected to the output side of the constant voltage circuit 200 to block the output of the overcurrent passing through the constant voltage circuit 200.

In the power supply device configured as described above, when AC power is input, the transformer T1 is operated so that the step-down power is output, and the power output from the transformer T1 is applied to the DC circuit 10. .

At this time, the rectification diodes D11 to D14 of the direct-current circuit 10 are rectified by a wave, and the rectified power is applied to the capacitor C11 to smooth.

On the other hand, the transistor Q101 of the power switching circuit 100 is turned on by the signal S101 input from the outside, and the transistors Q102 and Q103 are turned on by the operation of the transistor Q101.

Therefore, the power output from the direct current circuit 10 is bypassed by the resistor R101 of the power switching circuit [00], and the bypassed power passes through the transistors Q102 and Q103.

At this time, the current passing through the resistor R101 is distributed by the transistors Q102 and Q103 and output.

In addition, the transistor Q201 of the constant voltage circuit 200 is operated by the power selection signal S201 input from the outside, and one of the voltages set in the zener diodes ZD201 (ZD202) is operated by the operation of the transistor Q201. Is selected. That is, the transistor Q201 is turned on, the set voltage of the zener diode ZD202 is selected, and when the transistor Q201 is turned off, the set voltage of the zener diode ZD202 is selected.

Then, the switching transistor Q202 is operated by the voltage selected by the zener diodes ZD201 and ZD202, and a constant power source is always output by the operation of the transistor Q202.

At this time, the current passing through the transistor Q202 is divided with the resistor 202 and outputted.

When the current output from the constant voltage circuit 200 is an overcurrent, the output of the power source is cut off by the fuse F.

As described above, the present invention distributes the current passing through the power supply switching circuit and the current passing through the constant voltage circuit, thereby preventing the rupture caused by the overcurrent passing through the switching transistor, and thus the temperature inside the system. The rise is prevented, which has the effect of reducing the system failure caused by the temperature rise.

Claims (2)

A transformer for causing the AC power inputted to be stepped down to be output, a direct current circuit for converting the power stepped down by the transformer into a direct current power source, a power switching circuit through which the power output from the direct current circuit passes; In the power supply device consisting of a constant voltage circuit for causing the power output from the switching circuit to be output to the power required for the system, A transistor Q103 for distributing a current passing through the power switching circuit 100; A resistor (R202) for distributing a current passing through the constant voltage circuit (200), And a fuse (F) connected to an output side of the constant voltage circuit to shut off the output when the input current is an overcurrent. The method of claim 1, Temperature compensation circuit of a power supply, characterized in that a transistor (Q103) forms a Darlington circuit together with the switching transistor (Q102) to distribute a current passing through the switching transistor (Q102).