KR100231234B1 - High voltage dc power device having dual structure - Google Patents

Abstract

The present invention is composed of a front end power supply circuit for performing phase angle control and a rear end power supply circuit for series stabilized power so that an output element is always controlled at an appropriate voltage, and a protection circuit is provided between the front end power supply circuit and the rear end power supply circuit. It relates to a high voltage direct current device having a dual structure to protect the power supply in the event of a short circuit.

The present invention as described above is carried out by phase angle control or switching control to control the falling voltage of the output element of the rear end power supply device to the appropriate voltage, and the rear end in the event of an output short circuit between the front end power supply and the rear end power supply. It is characterized by consisting of a protective circuit portion to protect the output element by blocking it.

Description

High Voltage DC Power Supply with Double Structure

The present invention is composed of a front end power supply circuit for performing phase angle control and a rear end power supply circuit for series stabilized power so that an output element is always controlled at an appropriate voltage, and a protection circuit is provided between the front end power supply circuit and the rear end power supply circuit. It relates to a high voltage direct current device having a dual structure to protect the power supply in the event of a short circuit.

In the conventional DC power supply apparatus, as shown in FIG. 1, the output current and voltage detected by the current detector 30 and the voltage detector 31 are applied to a controller 32 made of TR and FET, and the controller 32 ) Is configured to apply a control signal to the base of the output transistor TR in comparison with the signals of the voltage adjusting unit VR ₁ and the current adjusting unit VR ₂ .

The conventional DC power supply device supplies the output maximum voltage of the power supply device to the input terminal of the power supply device and outputs it through the output control unit 32. At this time, in order to obtain a stable output voltage against the variation of the input voltage, the device of the output control unit 32 should drop the voltage by the difference between the input voltage and the output voltage, the voltage drop (Vce) and the load current (IL) is the power The Ohm's law of (P) = I x V results in power dissipation in the output device, resulting in heat generation. That is, the capacity of the control element is determined according to the loss amount.

However, the situation is different in the case of high pressure.

In general, even a device with a large amount of power loss, even if the proper voltage rises only a little, the current that can be controlled in the safe operating region is drastically reduced to a much smaller range than the power loss of the device.

This can often be seen in the device characteristic chart where the current flowing at the appropriate voltage decreases to a certain hundreds of currents near the stable region threshold voltage.

In other words, if one output device is configured at an appropriate voltage (low voltage), it is necessary to configure hundreds of output devices near the threshold voltage (high voltage).

Therefore, the high voltage DC power supply control device requires a lot of output elements compared to the current capacity, thereby bringing up the size and weight of the power supply control device, as well as the problem that the manufacturing cost is high due to the cost increase, it is pointed out, It is pointed out that a defect that does not function properly as a power supply device because the power supply device cannot be protected in case of an output short circuit accident.

The present invention has been made to solve the above problems of the conventional DC power supply, and the output element is always controlled at an appropriate voltage so that the configuration of the power supply can be made smaller and lighter, and the voltage of the output control element of the subsequent stage is monitored. However, when the voltage rises above a certain voltage, the front and rear power supply devices are blocked for protection, and the front and rear power supply devices are automatically restored and the purpose is to increase the convenience of use.

The present invention for achieving the above object is performed by a phase angle control or switching control and the front power supply for controlling the drop voltage of the output element of the rear end power supply to an appropriate voltage, between the front power supply and the rear power supply It is characterized in that it consists of a protection circuit section to protect the rear output device in the event of an output short circuit.

1 is a circuit diagram of a conventional DC power supply device

2 is a circuit diagram of a power supply device of the present invention.

3 is a partial waveform diagram of FIG.

4 is a circuit diagram illustrating a power supply device according to another embodiment.

※ Explanation of code about main part of drawing

1: Shear power supply device 1A: CE voltage detector

2: Back stage power supply 1B: Front voltage control circuit

3: protection circuit part 3A: CE overvoltage protection circuit

3B: Duty Signal Generator Q ₁ : Triac

Q ₄ : Output element (output transistor)

FIG. 2 is a detailed circuit part of the present invention, FIG. 3 is a waveform diagram of each part of FIG. 2, and FIG. 4 is another embodiment of the shear power supply device in FIG.

The present invention is characterized in that the direct current power supply device includes a front end power supply device 1 and a rear end power supply device 2, and the front power supply device 1 is a phase control using a thyristor shown in FIG. It is composed of switching control, so that the dropping voltage of the output element of the rear stage power supply 2, that is, the output transistor Q ₄ is managed at an appropriate voltage, so that the rear stage output element is operated in the low voltage safe region.

In addition, the present invention is to monitor the voltage of the output control element, when the predetermined voltage rises above a predetermined voltage protection circuit section (3) to cut off the front and rear power supply device (1) (2) the front power supply device (1) and the rear power supply device. It is also a feature of the present invention to be provided between (2).

After the front and rear power supply devices 1 and 2 are cut off, a pulse having a large duty ratio is generated by the protection circuit unit 3 to switch the rear power supply device 2 so as to automatically return.

Hereinafter, each part will be described in detail with reference to the accompanying drawings.

The front end power supply (1) is a power transformer (T ₁₎ to the alternating voltage converted into ever rectified by the bridge diode (BD _1), and said power transformer (T ₁₎ and a bridge diode (BD ₁₎ triacs (Q _1, ) Is connected in series to control the phase, and the opto triac (ISO ₁ ) optically insulated at the gate of the triac (Q ₁ ) is combined with Darlington, but the rear end power supply (2) is connected to the output terminal of the front power supply. and in the output transistor collector voltage (Vcc) CE voltage detector (1A), which ever detects the (Q _4), said output transistor (Q ₄₎ the front end voltage control circuit (1B, which ever the voltage is such that the phase control is a constant required voltage of ).

In the above, the capacitor (C ₂ ) is a capacitor for smoothing the phase controlled DC voltage, the resistor (R ₁ ) and the capacitor (C ₁ ) is the noise absorption generated when the triac (Q ₁ ) turn on / off Is a time constant.

Further, since the emitter of the output transistor Q ₄ , which is the rear output element, is grounded, the output terminal, ① point of the front end power supply 1 becomes the drop voltage of the rear output element, and the detected voltage of the rear output element is the front end. It is applied to the CE and the voltage protection circuit 3A in the voltage control circuit 1B and the protection circuit section 3, and the front end voltage control circuit 1B controls the phase so that the voltage of the output element Q ₄ becomes a constant proper voltage. ever, but, opto-triacs operate the triacs (Q ₁₎ through the optical isolation diode (LED) phase by Kane outputs each conductive signal opto-triac (ISO ₁₎ and the protective resistor (R ₂₎ to the inside (ISO ₁₎ Let it be

On the other hand, the protection circuit unit 3 is a CE over-voltage protection circuit (3A) to output a detection and blocking signal when the CE voltage, that is, the collector-emitter voltage (VCE) of the output element (Q ₄ ) rises above the reference voltage ), A NAND gate (NAND ₁ ) (NAND ₂ ), a resistor (R ₃ ) (R ₄ ) (R ₈ ), a diode (D ₁ ), a capacitor (C ₃ ), and an output terminal of the CE overvoltage protection circuit 3A. And a duty signal generator 3B composed of a transistor Q _3. The duty signal generated by the duty signal generator 3B releases the cutoff signal supplied to the rear end power supply 2 for a short time. (See also Figure 3 waveform).

Then, the rear end of the power unit (2) is the front end to the output of the power supply device (1) sikimyeo emitter grounding of the output transistor (Q _4), a current detection resistor connected to the emitter teocheuk of the output transistor (Q ₄₎ as normal (R ₇ ), The rear stage control circuit 2C to which the current and voltage signals obtained from the current and voltage detection circuits 2A and 2B are applied, and the signals of the rear stage control circuit 2C are connected to the voltage adjusting unit VR ₁ and the current. A control signal is applied to the base of the output transistor Q ₄ through the protection resistor R ₆ and the driver 2D in comparison with the signal of the adjusting unit VR ₂ , and the output of the rear stage control circuit 2C. The base end of the transistor Q ₂ connected to the stage is connected to the collector of the transistor Q ₃ in the protection circuit section 3.

The ground and the output terminal (+) are connected to the current detection resistor (R ₇ ), the output terminal (+) is connected to the current detection circuit (2A), and the output terminal (-) of the front end power supply (1) Same as (-) terminal, and apply both ends of (+) and (-) to voltage detection circuit 2B.

In such a rear end power supply device 2, the emitter of the output transistor Q ₄ is grounded, and as described above, the dropping voltage of the output transistor Q ₄ whose output terminal, ① point of the front end power supply device is a rear output element. This allows the circuits of the control system to operate stably at low voltages.

As described above, the present invention is a phase control or switching control using the triac (Q ₁ ) by the front power supply device 1 is to control the voltage drop of the output element (Q ₄ ) of the rear end power supply device 2 to an appropriate voltage. Since the high voltage is controlled and the front output device Q ₁ does not operate in a linear region like a conventional power supply or a rear stage power supply, but operates in a cutoff region or a saturation region as described below, the shear output element Q is an ideal device. ₁ ) no power loss occurs.

As a result, the output current capacity does not drop even at high voltages, so it can always be operated at the maximum current capacity of the device, and can immediately respond to the output voltage change due to the load variation, thereby obtaining a high quality voltage.

However, it is difficult to fine-tune the output voltage and current and to obtain a low ripple voltage quality when designing a power supply only with the front-end power supply, and a repeating control cycle at 60HZ when using only the phase control method. Is very long, 8.3 ms, which prevents immediate response to variations in output voltage due to load variations.

As described above, if the CE voltage rises above the reference voltage while controlling the drop voltage of the output element Q ₄ of the rear end power supply device 2 to the appropriate voltage by the configuration of the front end power supply device 1, the rear power supply device 2 In addition to outputting the cutoff signal at the same time, the duty signal generator 3B is operated to output a pulse wave having a very large duty ratio. That is, transistor (Q ₃₎ and (Q ₂₎ to and alternating conductive / non-communicated with the short time only operating the rear power unit (2), to cut off the rear end of the power unit (2) during a long time the rear end the power unit (2 the output element is an output transistor (Q ₄₎ in a) is thereby operating in saturation, walls (see the waveform in Fig. 3)

Therefore, when the output element is operated above the appropriate voltage by the cause of the output stage short-circuit accident of the rear stage power supply 2, the rear stage output device Q ₄ is blocked and protected, and the rear stage power supply 2 is cut off. By flowing the voltage charged in the smoothing capacitor C ₂ of the front end power supply device 1 to the load within a range not exceeding the power supply of the rear end power supply device ₂ , the charging voltage of both ends of the smoothing capacitor C ₂ is lowered. The power supply will automatically return.

As described above, the present invention provides a power supply device having a dual structure in which an output element is always controlled at an appropriate voltage and is freely controlled from a low voltage to a high voltage, and thus does not require many output elements compared to a current capacity. It has the effect of miniaturization and light weight, protection of output elements in case of output short-circuit, automatic return and high quality voltage.

Claims (5)

A front end power supply 1 which is carried out by phase angle control or switching control and which controls the drop voltage of the output element Q ₄ of the rear end power supply 2 to an appropriate voltage; A high-voltage DC power supply having a dual structure, characterized in that it consists of a protection circuit section (3) for blocking and protecting the rear output element (Q ₄ ) in the event of an output short circuit between the rear end power supply (2). The method of claim 1, In the front end power supply (1) is a power transformer (T ₁₎ and the bridge diode opto-triac (ISO ₁₎ and a rear end of the power unit (2) which connect the gates of the series-connected triacs (Q ₁₎ to (BD ₁₎ and CE voltage detector (1A), which ever detects the collector voltage (Vcc) of the output element (Q _4), the front end voltage control circuit (1B) to the voltage of said output element (Q ₄₎ ever phase control so as to achieve a constant required voltage High-voltage DC power supply having a dual structure, characterized in that consisting of and. The method of claim 1, The protection circuit unit 3 includes a CE overvoltage protection circuit 3A for outputting a detection and blocking signal when the CE voltage rises above the reference voltage, and a NAND gate NAND ₁ at an output terminal of the CE overvoltage protection circuit 3A. ) And a duty signal generator (3B) consisting of (NAND ₂ ), resistor (R ₃ ) (R ₄ ) (R ₈ ), diode (D ₁ ) capacitor (C ₃ ) and transistor (Q ₃ ). High voltage DC power supply with dual structure. The method according to claim 1 or 2, A high voltage direct current power supply having a dual structure, characterized by grounding the emitter of the output element (Q ₄ ). The method according to claim 1 or 3, A high-voltage DC power supply having a dual structure, characterized in that to generate a pulse having a large duty ratio after the power supply unit (1) (2) of the front and rear stages is cut off to return the rear power unit (2).

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