KR20200031859A - Apparatus for rectifying full wave of 3phase with function of blocking to rush current - Google Patents

Abstract

According to an embodiment of the present invention, the present invention relates to a three-phase full wave rectifier having an inrush current preventing function, which comprises: a three-phase full-wave rectification circuit including a bridge diode including three SCRs and three diodes corresponding to three phases of R, S, and T, and a bulk capacitor corresponding to the bridge diode; a zero-voltage detecting unit for detecting zero voltage between R and S among the three phases; a thyristor driving unit for separately driving a thyristor for each of the SCRs of the three phases; and a micro-controller for controlling an R phase to generate a discontinuous section in a state in which the SCRs of S and T phases by the three-phase full-wave rectification circuit are in an off-state by controlling a driving operation of the thyristor driving unit when voltage between R and S of the zero-voltage detecting unit is zero voltage. According to the present invention, an existing inrush current limiting circuit is miniaturized. Also, an inrush current is reduced by providing an inrush current reducing technique applicable to a full-wave rectification circuit having an SCR thyristor embedded therein and a half controlled rectifier.

Description

Apparatus for rectifying full wave of 3phase with function of blocking to rush current}

The present disclosure relates to an apparatus for preventing inrush current. In particular, the present invention relates to an inrush current prevention device to which a rectifying circuit is applied.

Unless otherwise indicated herein, the content described in this section is not prior art to the claims of this application and is not admitted to be prior art by inclusion in this section.

In general, a device for preventing an inrush current is to prevent an inrush current, which is an transient current that increases instantaneously but immediately returns to a normal state, as can be seen when a circuit breaker such as a line, a transformer, an electric motor, or a capacitor is turned on.

There are several types of such inrush current prevention devices. However, in the existing inrush current prevention device, there are limitations in many ways. The limitation will be described as follows.

1. Limitations of existing technology-1

(Patent Document 1) KR10-168484 Y1

This prior art switch mode power supply includes a smoothing capacitor that eliminates the ripple component of the DC voltage of the power converter.

However, as the power of the power conversion unit increases, a smoothing capacitor having a large capacity is required.

Therefore, a large-capacity smoothing capacitor causes a large inrush current when the power is turned on.

Therefore, the inrush current causes damage to the diode and the input circuit for full-wave rectification.

Therefore, an inrush current suppressing circuit is used to prevent the inrush current from flowing.

Further, in addition to this, the inrush current suppressing circuit has a contactor arranged in parallel between the power supply and the power converter-an inverter and a converter, and connected in parallel to the inrush current suppressing resistor and the inrush current suppressing resistor.

Therefore, it is a problem that resistors and contactors require large sizes.

2. Limitations of existing technology-2

(Patent Document 2) KR10-1691343 Y1

(Patent Document 3) KR10-1611010 Y1

In the prior art and the like, in a device for preventing inrush current, the problem is that a resistor and a contactor require a large size.

(Patent Document 4) KR10-1147257 Y1

This prior art problem is verified only in the DC circuit. And, the circuit configuration is rather complicated. In addition, it is unsuitable for a large-power circuit because it must pass through the transistor even in the normal state. Moreover, another problem is the need for an initial charge diode and an initial charge resistance.

Therefore, there is a need for an inrush current prevention device that satisfies the point that such a resistor and contactor require a large size, is universally verified, is suitable for a simple circuit configuration and a large power circuit, and does not require a separate device during initial charging. Do.

Disclosed is to provide a three-phase full-wave rectification device having an inrush current prevention function to reduce inrush current by providing an inrush current reduction technique applicable to a full-wave rectifier circuit with a SCR thyristor and a half-controlled rectifier.

In addition, in addition, the three-phase full-wave rectifying device having the inrush current prevention function can be applied to a circuit with a large amount of power and can be universally used for the three-phase full-wave rectification circuit.

A three-phase full-wave rectification device having an inrush current prevention function according to an embodiment,

A module incorporating 3 SCR thyristors and 3 diodes to reduce inrush current using a full-wave rectifying circuit with a built-in SCR thyristor, but in this case, to miniaturize the inrush current limiting circuit and simplify the installation and configuration of the system. Apply. And, in this case, the diode turns on in an unwanted section. So, for this purpose, in this three-phase full-wave rectification circuit, two switches are left off and the remaining one phase is adjusted to allow a discontinuous section to enable phase control. In addition, there is a section in which the voltage is 0, and is characterized in that a soft start is performed for control.

According to the embodiments, the existing inrush current limiting circuit is miniaturized.

And, by providing an inrush current reduction technique applicable to a full-wave rectifier circuit with a built-in SCR thyristor and a Half Controlled Rectifier, the inrush current is reduced.

In addition, accordingly, a soft start is performed in a three-phase full-wave rectifying circuit incorporating three SCR thyristors and three diodes. So, this prevents inrush current.

Therefore, further through this, product reliability due to such inrush current reduction is secured.

In addition, further, there is no additional circuit connected in series, and thus an inrush current limiting circuit applicable to a circuit with a large amount of power is constructed and a miniaturized inrush current limiting circuit is provided.

In addition, universal use is made in a three-phase full-wave rectifying circuit.

1 is a block diagram showing the configuration of a three-phase full-wave rectifier having an inrush current prevention function according to an embodiment
FIG. 2 is a circuit diagram showing the configuration of a thyristor driver according to an embodiment applied to a three-phase full-wave rectifier having the inrush current prevention function of FIG. 1;
3 is a view specifically showing the configuration of the zero voltage detection unit according to an embodiment applied to the three-phase full-wave rectifier having the inrush current prevention function of FIG. 1;
4 is a timing diagram showing a control sequence according to the three-phase full-wave rectifier having the inrush current prevention function of FIG. 1;
FIG. 5 is a view showing a soft start actual operation waveform through one phase control of an SCR according to an embodiment of the three-phase full-wave rectifying device having the inrush current prevention function of FIG. 1.
6A to 6B are flow charts sequentially showing the operation of the three-phase full-wave rectifier having an inrush current prevention function according to the embodiment of FIG. 1.

1 is a block diagram showing the configuration of a three-phase full-wave rectifier having an inrush current prevention function according to an embodiment.

As shown in Figure 1, the device of one embodiment is a three-phase full-wave rectification circuit 110 of three SCR / diode, the zero voltage detection unit 120 between the RS, the thyristor driving unit 130 and the S / T phase SCR Includes a microcontroller 140 that phase-offs only the SCR on R.

The three-phase full-wave rectifier circuit 110 is a bridge diode 111 of three SCRs and three diodes corresponding to three phases of R, S, and T, and a bulk capacitor 112 corresponding to the bridge diode 111. It is equipped with. Thus, the three-phase full-wave rectifier circuit 110 forms two switches of S, T and one switch of R by pairing these three SCRs and three diodes according to an embodiment. Accordingly, such a switch is controlled differently, and the bulk capacitor 112 is charged through the switching operation of the switch, thereby operating a three-phase full-wave rectification with an inrush current prevention function according to an embodiment. The inrush current prevention function is achieved by the phase control by the microcontroller 140 below. This specific operation will be described later. Additionally, the three-phase full-wave rectifying circuit 110 of one embodiment performs power dissipation compensation and discharge resistance R1 of the current limiting inductor L1 of the SCR thyristor and its bulk capacitor 112 and substantially power conversion, It includes a power converter (not shown) connected in parallel with the bulk capacitor 112.

The zero voltage detector 120 detects a zero voltage point of the voltage between R-S by the three-phase full-wave rectifying circuit 110. So, it is easy to apply the zero voltage to perform phase control according to an embodiment. The detected zero voltage is input to the microcontroller 140, and is applied to synchronize the phase control.

The thyristor driver 130 drives the thyristor of the three-phase full-wave rectifying circuit 110 by controlling the phase of the microcontroller 140. The thyristor driving unit 130 is generated by generating an operating voltage of thyristor driving according to the phase control of the embodiment. The specific operation will be described later with reference to FIG. 2 below.

The microcontroller 140 controls the driving operation of the thyristor driving unit 130 when detecting zero voltage between RSs by the zero voltage detection unit 120, and S / by the three-phase full-wave rectifying circuit 110. The T-phase SCR is turned off and only the R-phase SCR is phase controlled. The microcontroller 140 makes the phase control by allowing a discontinuous section to occur during the phase control, and it is easy to control because there is a section with a voltage of zero. So, the phase control with the inrush current prevention function according to the above-described embodiment is performed. The control algorithm of the phase control will be described in detail with reference to FIG. 6, and the control sequence will be described with reference to FIG.

FIG. 2 is a circuit diagram showing the configuration of the thyristor driver 130 according to an embodiment applied to the three-phase full-wave rectifier having the inrush current prevention function of FIG. 1.

As shown in FIG. 2, the thyristor driving unit 130 includes a switching unit 131 which is turned on or off according to the phase control, a photo thyristor 132 generating the thyristor operating voltage according to the on and off, and the same. It includes an SCR driving voltage distribution unit 133.

In addition, the thyristor driving unit 130 is additionally provided for each of three phases of R, S, and T. Specifically, the thyristor driver 130 has a simple configuration, and is configured for each thyristor of the above-described bridge diode.

The switching unit 131 is to turn on only one SCR on the R when the SCR on the S / T is turned off when detecting the zero voltage point of the R-S voltage during phase control according to an embodiment. The switching unit 131 is, for example, PWM output to the transistor Q1 so that a discontinuous section is generated by the microcontroller 140, so as to perform phase control according to an embodiment (see FIG. 1). So, when the Q1 is turned on, the switching unit 131 generates the operating voltage of the thyristor by the three-phase full-wave rectifying device during its phase control according to an embodiment due to the photo thyristor 132. Additionally, the operation of the phase control according to the PWM output will be described later with reference to FIG. 5.

The photo thyristor 132 emits light when turned on by the switching unit 131 to generate a basic operating voltage of the thyristor according to the phase control.

The voltage divider 133 distributes a basic operating voltage by the photo thyristor 132 to provide a driving voltage to the gate of the SCR. Specifically, the voltage divider 133 applies the voltage distributed to R2 and R7 due to the photo thyristor 132, for example, to the gate of X1, which is an SCR thyristor on R. So, thyristor driving for each SCR for phase control according to an embodiment is performed by the voltage thus applied.

FIG. 3 is a diagram specifically showing the configuration of the zero voltage detection unit 120 according to an embodiment applied to the three-phase full-wave rectifier having the inrush current prevention function of FIG. 1.

As shown in FIG. 3, the zero voltage detection unit 120 according to an embodiment is made according to a circuit that detects a zero voltage point of a voltage between RSs during phase control of the thyristor. Accordingly, when controlling the phase of the thyristor, The voltage is 0.

Specifically, when the voltage between R-S of the zero voltage detection unit 120 of this embodiment is positive, a low signal is generated at the input of the microcontroller. For example, a signal is generated at the microcontroller input in response to a voltage between R and S by a photo coupler. Then, the zero voltage detection unit 120 according to the embodiment generates a signal for synchronizing during phase control in response to the zero voltage point of the voltage between R-S.

Therefore, in phase control according to an embodiment, there is a section in which the voltage is 0, so it is easy to control.

FIG. 4 is a timing diagram showing a control sequence according to the three-phase full-wave rectifier having the inrush current prevention function of FIG. 1.

As shown in FIG. 4, the control sequence according to an embodiment first receives a voltage between S-T and T-R having a phase difference according to 3 phase corresponding to a voltage between R-S according to 3-phase full-wave rectification.

Next, according to the voltage between the R-S and the T-R voltage, the A-K voltage of the SCR on R by phase control in one embodiment is generated. In this case, the A-K voltage of the SCR on the R is a rectified voltage according to the thyristor driving of the voltage between the R-S and the voltage between T-R.

Next, according to an embodiment, when the phase is controlled, there is a section in which the voltage between the AKs on the R phase is 0, and the RS is applied by the output signal of the zero voltage detection circuit of the voltage between the RSs corresponding to the SCR on the Rs. Detect the point where the inter-voltage is zero.

Then, the phase control by PWM is synchronized according to the point where the voltage between R-S is 0. So, PWM is output according to the synchronization. Synchronization of the PWM is performed by a PWM counter, in which case the PWM counter is first turned on for the first PWM, resets every cycle when the voltage between RSs is a falling edge, and turns off as the voltage of C1 is charged. The point is fixed, and the turn-on point is advanced to increase the flow rate of the PWM. Additionally, the operation of increasing the flow rate of the PWM gradually increases from hundreds to thousands of steps, not several steps.

Then, the thyristor of the SCR on the R is driven by the synchronized PWM output, and thus the gate voltage of X1 of the thyristor on the R is generated so that a discontinuous period is generated, thereby controlling phase according to an embodiment. In this case, the turn-on time increases as the gate voltage of X1 continues to elapse.

In addition, according to the phase control, since the current of X1 is generated corresponding to the discontinuous section, it is turned on until the reverse bias is applied to the existing SCR thyristor, so that the turn-on section overlaps with the thyristor of another phase. In this case, the current of X1 is increased according to the following Equation in response to the increase in the turn-on time of the gate voltage of X1.

[expression]

i (t) = 1 / L ₁ ∫V _L1 dt, i (t) = (V _RS -V _X1 -V _C1 ) t / L ₁

Therefore, according to one embodiment, in response to the three-phase full-wave rectifying circuit of one embodiment, the voltage of the bulk capacitor C1 installed at the rear stage is charged by such phase control. Thus, inrush current is prevented.

Therefore, a soft start is performed accordingly.

FIG. 5 is a diagram showing an actual operating waveform of soft start through one phase control of an SCR according to an embodiment of the three-phase full-wave rectifier having the inrush current prevention function of FIG. 1.

As shown in FIG. 5, the soft start described above is made with reference to FIG. 4 through one phase control of one SCR according to an embodiment, and it is seen that such a soft start is made.

The soft start generates the waveform described below, and the operation is performed, which describes the specific operation.

First, the microcontroller is booted here at t1, and the power supply voltage frequency is measured at t2.

So, in response to the power frequency, the R-S voltage is controlled by one SCR phase according to an embodiment.

Accordingly, through the phase control of one SCR, X1 PWM output, which is an R-phase SCR thyristor at t3, and an increase in the flow rate are achieved. In this case, the R phase current is increased according to the R phase SCR control signal. So, the DC-Link voltage gradually increases accordingly.

Accordingly, through this, the charging voltage of C1, which is a bulk capacitor at the rear end of the three-phase full-wave rectifying circuit according to an embodiment is checked at t4, and it is checked whether the other phases overlap each other.

Therefore, according to this, the entire turn X1 to X3 is maintained at the time t5. Where X2 is the S-phase SCR thyristor and X3 is the T-phase SCR thyristor.

Therefore, through this, an inrush current is prevented, and a soft start is performed.

Thus, product reliability due to inrush current reduction is thereby secured.

Then, an inrush current limiting circuit applicable to a circuit with a large amount of power is constructed.

In addition, it provides a cost-competitive and compact inrush current limiting circuit.

6A to 6B are flow charts sequentially showing the operation of the three-phase full-wave rectifier having an inrush current prevention function according to the embodiment of FIG. 1.

Specifically, FIG. 6A is a flow chart sequentially showing the operation of the three-phase full-wave rectifying device having the inrush current prevention function according to the embodiment of FIG. 1 in a large context. And, Figure 6b is a view showing in detail the operation of the three-phase full-wave rectifying device according to an embodiment of the large context of Figure 6a.

 As shown in FIG. 6A, the three-phase full-wave rectifying device of one embodiment first includes a bridge diode of three SCRs and three diodes corresponding to three phases of R, S, and T, and a bulk capacitor corresponding to the bridge diode. A three-phase full-wave rectification circuit is provided (S601).

Next, among these three phases of R, S, and T, a zero voltage between R and S is detected (S602).

Then, when the voltage between the RSs is zero voltage, each thyristor is driven by controlling the driving operation of the thyristor driving unit for each three-phase SCR. In this case, the SCR on the S and T phases by the three-phase full-wave rectifying circuit is left off, and the phase on the R phase is controlled so that a discontinuous section occurs.

The operation of the three-phase full-wave rectifying device according to this embodiment will be described in detail with reference to FIG. 6B.

As shown in Figure 6b, the three-phase full-wave rectifier having an inrush current prevention function according to an embodiment first turns off the three-phase SCR X1, X2, X3 (S611). Here, X1 is an R phase SCR thyristor, X2 is an S phase SCR thyristor and X3 is a T phase SCR thyristor.

Next, in this state, the power supply voltage frequency is measured (S612).

Thus, when the measured power supply voltage frequency is a preset reference frequency, it is not corresponding to a reference time delay, and correspondingly, at a time delay smaller than the reference time, the PWM output is made to X1, which is an R phase SCR. So, according to one embodiment, synchronization is performed in correspondence to the point where the voltage between R-S for phase control of one SCR is zero.

For example, when the power supply voltage frequency is 60 Hz, a 60 Hz delay time is set (S613). Then, if it is not 60Hz, a 50Hz delay time is set (S614).

Next, in this state, the PWM output for X1 is performed (S615). The PWM output is based on an SCR thyristor applied to a three-phase full-wave rectifying circuit according to an embodiment and phase control by driving the thyristor. So, the PWM output causes the SCR voltage of X1 to continue to increase as the turn-on time increases, and correspondingly, the current of X1 is integrally generated, resulting in a discontinuous section, and thus the DC-Link voltage is gradually softened. Is increased.

Thus, the PWM flow rate for X1 is increased by the PWM output (S617).

Next, it is checked whether or not the maximum flow rate at which the PWM flow rate for X1 becomes maximum (S618).

As a result of the above check, in the case of the maximum flow rate, the bulk capacitor-C1 charging is checked (S619).

On the other hand, if it is not the maximum flow rate, it continues to increase the PWM flow rate for X1 until the maximum flow rate. Thus, overlapping of the other phases is restricted.

Next, as a result of the check, in the case of charging the bulk capacitor-C1, X1, X2, and X3 are turned on (S620).

On the other hand, if it is not the charging of the bulk capacitor-C1, the maximum flow rate is continued until the charging of the bulk capacitor-C1.

Therefore, a soft start is performed by limiting the inrush current.

As described above, in one embodiment, the three-phase SCR is turned off, and the time is delayed in response to the frequency of the power supply voltage, so that the PWM output is performed to the R-phase SCR, thereby turning on the charging current when charging the bulk capacitor of the maximum flow rate. Limited soft start.

Therefore, the product reliability due to the reduction of the inrush current is secured, and further, there is no additional circuit connected in series, thereby constructing an inrush current limiting circuit applicable to a circuit with a large amount of power and providing a miniaturized inrush current limiting circuit.

In more detail, one embodiment is a technique for miniaturizing an existing inrush current limiting circuit, and for this purpose, using a full-wave rectifying circuit with a built-in SCR thyristor to reduce inrush current, in this case three SCR thyristors and three Apply a module with a built-in diode.

In addition, in addition, in this case, since the diode configured in the module is turned on in an undesired section, it is solved that soft starting through general phase control is not easy.

Accordingly, an inrush current reduction technique applicable to a full-wave rectifier circuit with a built-in SCR thyristor and a Half Controlled Rectifier is provided to reduce the inrush current.

So, for this purpose, the two switches are left off, and the remaining one phase is adjusted, so that a discontinuous section is generated to enable phase control, and there is a section with a voltage of 0 to facilitate soft control, thereby soft starting.

Through this, since it is turned on until reverse bias is applied to the SCR thyristor, it solves the problem caused by the overlapping of the thyristor and the turn-on section of other phases, thereby reducing the inrush current.

Therefore, through this, product reliability due to such inrush current reduction is secured.

Further, further, there is no additional circuit connected in series, and thus an inrush current limiting circuit applicable to a circuit having a large amount of power is provided, and a miniaturized inrush current limiting circuit is provided.

In addition, universal use is made in a three-phase full-wave rectification circuit.

* Explanation of reference numerals for main parts of drawings *
110: three-phase full-wave rectifier circuit 111: bridge diode
112: bulk capacitor 120: zero voltage detection unit
130: thyristor drive unit 140: microcontroller

Claims (5)

A three-phase full-wave rectification circuit having a bridge diode of three SCRs and three diodes corresponding to three phases of R, S, and T and a bulk capacitor corresponding to the bridge diode;
A zero voltage detection unit for detecting a zero voltage between RSs among the three phases;
A thyristor driver for driving thyristors for each of the three-phase SCRs; And
When the voltage between the RSs of the zero voltage detection unit is zero voltage, the driving operation of the thyristor driving unit is controlled so that the SCRs on S and T by the three-phase full-wave rectifying circuit are turned off and the phases on R are discontinuous. A three-phase full-wave rectifying device having an inrush current prevention function, comprising a phase-controlled microcontroller. According to claim 1,
The microcontroller
Turn off the three-phase SCR, detect the power supply voltage frequency, and if it is a preset reference frequency, correspond to the non-reference time delay, respond to a time delay less than the reference time, PWM output to the R-phase SCR to maximize the flow rate A three-phase full-wave rectifying device having an inrush current prevention function, characterized in that it turns on when charging the bulk capacitor. The method of claim 1 or 2,
The thyristor driving unit
A switching unit that turns off in the off state of the microcontroller and turns on in phase control;
A photo-thyristor that emits light when turned on by the switching unit to generate a basic operating voltage of the thyristor;
A three-phase full-wave rectifying device having an inrush current prevention function, comprising a voltage divider for distributing a basic operating voltage by the photo-thyristors and providing a driving voltage to a gate of the SCR. The method of claim 1 or 2,
The zero voltage detection unit
When the voltage between RS is positive, a low signal is generated in the microcontroller, and in phase control in response to a zero voltage point of the voltage between RS, a signal for synchronizing is generated to prevent inrush current. Three-phase full-wave rectifier. The method of claim 1 or 2,
The three-phase full-wave rectification circuit
A bridge diode composed of three SCRs and three diodes corresponding to three phases of R, S, and T;
A power converter converting power according to three-phase full-wave rectification by the bridge diode;
A bulk capacitor that charges according to the rectified voltage by the bridge diode and removes a ripple component of the DC voltage of the power converter;
An inductor installed between the bridge diode and the bulk capacitor to compensate for power factor and limit the current of the SCR thyristor; And
A three-phase full-wave rectifying device having an inrush current prevention function, characterized in that it comprises the discharge resistance of the bulk capacitor.

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