KR100819793B1 - Direct-current voltage control circuit for inverter utilizing two direct-current voltage levels measured at different locations - Google Patents

Abstract

The inverter DC voltage control circuit according to the present invention is connected between a DC power supply and an inverter, and the inverter DC voltage control circuit for controlling the DC voltage supplied to the inverter from the DC power supply includes: a first voltage measuring unit and a second Voltage measurement, inrush current limiter, capacitor and discharge. The first voltage measuring unit is connected to the DC power supply to measure the instantaneous level of the DC voltage from the DC power supply. The second voltage measuring unit measures an instantaneous level of the DC voltage from the DC power source while being connected to the inverter. The inrush current limiting unit is positioned between the first voltage measuring unit and the second voltage measuring unit so that a difference between the first voltage measured by the first voltage measuring unit and the second voltage measured by the second voltage measuring unit is a predetermined reference value. If greater than the voltage, it restricts the inflow of direct current from the direct current source. The capacitor is located between the inrush current limiting portion and the second voltage measuring portion to charge the DC voltage from the DC power supply. The discharge unit is positioned between the inrush current limiting unit and the second voltage measuring unit to perform discharge by a switching operation when the first voltage is lower than the lower limit voltage or the second voltage is higher than the upper limit voltage.

Description

Direct-current voltage control circuit for inverter utilizing two direct-current voltage levels measured at different locations}

1 is a view showing a conventional DC voltage control circuit for an inverter.

2 is a view showing a DC voltage control circuit for an inverter according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1 ... DC voltage control circuit, D1 ... blocking diode,

11,21 ... inrush current limiter, K1 ... relay,

C1 ... capacitor, 12 ... off discharge,

13, regenerative discharge section, 14, 24P, 24F ... voltage measurement section,

141, 24P1, 24F1 ... voltage measuring element, INV ... inverter,

23 ... discharge part.

The present invention relates to a DC voltage control circuit for inverters, and more particularly, to a DC voltage control circuit for inverters connected between a DC power supply and an inverter to control a DC voltage supplied from the DC power supply to the inverter.

Referring to FIG. 1, a conventional DC voltage control circuit 1 for an inverter INV includes a diode D1, an inrush current limiting unit 11, a capacitor C1, an off discharge unit 12, and a regeneration. The discharge unit 13 and the voltage measuring unit 14 are included. In FIG. 1, reference numerals VDC_IN_HOT and VDC_IN_RTN denote DC voltage terminals applied from a DC power supply (not shown), and MC_ON_H and MC_ON_L denote control units for driving the relay K1 included in the inrush current limiting unit 11. Voltage terminal from the control unit for driving the switching transistor Qs included in the regenerative discharge unit 13, and VDC_SEN_H and VDC_SEN_L are the voltage terminals included in the voltage measuring unit 14. The voltage terminals input to the controller from the measuring element 141 are indicated.

The blocking diode D1 blocks the reverse current so that the change in the DC voltage due to the operation of the inverter INV does not affect the DC power.

The inrush current limiting unit 11 performs the following operation by the controller such that the sudden inrush current is not applied to the inverter INV at the initial time when the DC voltage from the DC power is applied. First, when the output of the DC power is turned on by the user, the control unit turns off the relay K1 included in the inrush current limiting unit 11 by not applying a voltage between the MC_ON_H voltage terminal and the MC_ON_L voltage terminal. Off). Accordingly, since the current flows through the blocking diode D1 and the first resistor R1 from the VDC_IN_HOT terminal, inflow of the inrush current can be prevented. During this initial time capacitor C1 performs charging. Accordingly, when the voltage between the output terminals VDC_SEN_H and VDC_SEN_L of the voltage measuring element 141 is greater than or equal to a predetermined level, the controller determines that the capacitor C1 has completed charging, and between the MC_ON_H voltage terminal and the MC_ON_L voltage terminal. Apply voltage to Accordingly, the relay K1 included in the inrush current limiting unit 11 is turned on to allow current to flow from the VDC_IN_HOT terminal through the relay K1.

The off discharge part 12 discharges the voltage charged in the capacitor C1 when the DC power is turned off by the user.

The regenerative discharge unit 13 operated by the control unit discharges the regenerative voltage of the counter electromotive force (hereinafter referred to as the regenerative voltage hereinafter) returned from the winding of an electric motor (not shown) driven by the inverter INV. In more detail, when the voltage between the output terminals VDC_SEN_H and VDC_SEN_L of the voltage measuring element 141 is greater than or equal to a predetermined upper limit level, the controller determines that the regenerative voltage has been applied and applies a voltage to the REGEN voltage terminal. Accordingly, the switching transistor Qs is turned on so that the regenerative voltage is discharged through the resistor R3 and the switching transistor Qs.

According to the conventional DC voltage control circuit for an inverter as described above, there are the following problems.

First, a relatively large current flows continuously through the resistor R2 of the off discharge unit 12. This increases power consumption. For example, when the inverter INV is used in the defense industry apparatus, since the off discharge must be completed within 2 (seconds), the resistance value of the corresponding resistor R2 is relatively low, resulting in higher power consumption.

Second, it is preferable that the regenerative discharge part 13 performs the function of the off discharge part 12 according to the first problem. However, since the control part controls the operation of the switching transistor Qs of the regenerative discharge part 13 only by the output side measurement voltage, the switching is performed due to the presence of the input side voltage at the turn-on time of the switching transistor Qs. Transistor Qs may not be turned on or may be destroyed.

Third, since the controller controls the operation of the relay K1 only by the voltage at the rear end of the relay K1 of the inrush current limiting unit 11, the variable range of the voltage applied to the front end of the relay K1 is considered. To increase the breakdown voltage capacity of the relay K1.

SUMMARY OF THE INVENTION An object of the present invention is to provide a circuit in which a DC voltage control circuit for an inverter can reduce power consumption generated in a discharge operation and can set a breakdown voltage of a means for limiting inrush current.

In the inverter DC voltage control circuit of the present invention for achieving the above object is a DC voltage control circuit for an inverter connected between a DC power supply and an inverter to control a DC voltage supplied from the DC power supply to the inverter, the first And a voltage measuring unit, a second voltage measuring unit, an inrush current limiting unit, a capacitor, and a discharge unit.

The first voltage measuring unit is connected to the DC power supply to measure the instantaneous level of the DC voltage from the DC power supply. The second voltage measuring unit measures the instantaneous level of the DC voltage from the DC power source while being connected to the inverter. The inrush current limiting unit is positioned between the first voltage storage unit and the second voltage measuring unit to determine the first voltage measured by the first voltage measuring unit and the second voltage measured by the second voltage measuring unit. If the difference is greater than the predetermined reference voltage, the inflow of the direct current from the direct current power source is restricted. The capacitor is located between the inrush current limiting unit and the second voltage measuring unit to charge a DC voltage from the DC power supply. The discharge unit is positioned between the inrush current limiting unit and the second voltage measuring unit to perform discharge by a switching operation when the first voltage is lower than the lower limit voltage or the second voltage is higher than the upper limit voltage.

According to the inverter DC voltage control circuit of the present invention, the first voltage measured by the first voltage measuring unit is lower than the lower limit voltage or the second voltage measured by the second voltage measuring unit is higher than the upper limit voltage. The discharge unit performs a discharge by a switching operation. Accordingly, when the DC power is off, not only the discharge may be performed by the discharge unit, but also the regenerative voltage of the counter electromotive force returned from the winding of the motor driven by the inverter may be discharged. As a result, current does not flow through the discharge unit during a normal operation time, thereby reducing power consumption. On the other hand, since the inrush current limiter operates according to the difference between the first voltage measured by the first voltage measurer and the second voltage measured by the second voltage measurer, it is possible to set the breakdown capacity of the inrush current limiter to be smaller. Can be.

Hereinafter, preferred embodiments according to the present invention will be described in detail.

2, the inverter DC voltage control circuit according to the present invention is connected between the DC power supply and the inverter (INV), the inverter DC voltage for controlling the DC voltage supplied from the DC power supply to the inverter (INV). In the control circuit 2, the blocking diode D1, the first voltage measuring unit 24P, the second voltage measuring unit 24F, the inrush current limiting unit 21, the capacitor C1, and the discharge unit 23. It includes. In FIG. 1, reference numerals VDC_IN_HOT and VDC_IN_RTN denote DC voltage terminals applied from a DC power supply (not shown), and MC_ON_H and MC_ON_L denote a controller (not shown) for driving the relay K1 included in the inrush current limiting unit 21. Voltage terminal from the control unit for driving the switching transistor Qs included in the discharge unit 23, and VDC_SEN_H and VDC_SEN_L are corresponding voltage measuring units 24P and 24F. The voltage terminals input to the control unit from each of the voltage measuring elements 24P1 and 24F1 included therein.

The blocking diode D1 blocks the reverse current so that the change in the DC voltage due to the operation of the inverter INV does not affect the DC power.

The first voltage measuring unit 24P is connected to the DC power supply to measure the instantaneous level of the DC voltage from the DC power supply. The second voltage measuring unit 24F is connected to the inverter INV and measures the instantaneous level of the DC voltage from the DC power supply. The capacitor C1 is located between the inrush current limiting portion 21 and the second voltage measuring portion 24F to charge the DC voltage from the DC power supply.

The inrush current limiter 21 performs the following operation by the controller so that the sudden inrush current is not applied to the inverter INV at the initial time when the DC voltage from the DC power is applied. First, the output of the DC power is turned on by the user, and a difference between the first voltage measured by the first voltage measuring unit 24P1 and the second voltage measured by the second voltage measuring unit 24F1 is predetermined. If the reference voltage is greater than 20 volts (V), for example, the control unit turns off the relay K1 included in the inrush current limiting unit 21 by not applying a voltage between the MC_ON_H voltage terminal and the MC_ON_L voltage terminal. Let's do it. Accordingly, since the current flows through the blocking diode D1 and the first resistor R1 from the VDC_IN_HOT terminal, inflow of the inrush current can be prevented. During this initial time capacitor C1 performs charging. Accordingly, when the difference between the first voltage measured by the first voltage measuring unit 24P1 and the second voltage measured by the second voltage measuring unit 24F1 is less than or equal to a predetermined reference voltage, the controller controls the MC_ON_H voltage terminal and the MC_ON_L voltage. Apply a voltage between the terminals. Accordingly, the relay K1 included in the inrush current limiting unit 11 is turned on to allow current to flow from the VDC_IN_HOT terminal through the relay K1. As such, the controller controls the operation of the relay K1 by the difference between the front end and the rear end voltages of the relay K1 of the inrush current limiting unit 21. It can be set less depending on the voltage. For example, when the control reference voltage is 20 volts (V), it is possible to use a relay K1 having a breakdown voltage corresponding to a voltage slightly higher than this, for example, 24 volts (V).

The discharge part 23 operated by the control part is located between the inrush current limiting part 21 and the second voltage measuring part 24F so that the first voltage measured by the first voltage measuring part 24P is lower than or equal to the lower limit voltage. Or when the second voltage measured by the second voltage measuring unit 24F is equal to or higher than the upper limit voltage, discharge is performed by a switching operation. More specifically, when the DC power is turned off by the user and the voltage between the output terminals VDC_SEN_H and VDC_SEN_L of the voltage measuring element 24P1 of the first voltage measuring unit 24P falls below a predetermined lower limit level, The control unit applies a voltage to the REGEN voltage terminal. Accordingly, the switching transistor Qs is turned on so that the voltage that has been charged in the capacitor C1 is discharged through the resistor R3 and the switching transistor Qs. Meanwhile, between the output terminals VDC_SEN_H and VDC_SEN_L of the voltage measuring element 24F1 of the second voltage measuring unit 24F due to the regenerative voltage of the back electromotive force returned from the winding of the motor (not shown) driven by the inverter INV. When the voltage at is lower than or equal to the predetermined upper limit level, the controller applies a voltage to the REGEN voltage terminal. Accordingly, the switching transistor Qs is turned on so that the regenerative voltage is discharged through the resistor R3 and the switching transistor Qs.

As described above, according to the inverter DC voltage control circuit according to the present invention, the first voltage measured by the first voltage measuring unit 24P is less than the lower limit voltage or the second voltage measured by the second voltage measuring unit. If the voltage is higher than or equal to the upper limit voltage, the discharge unit 23 discharges by the switching operation. As a result, when the DC power is off, not only the discharge unit 23 can discharge the power, but also the regenerative voltage of the counter electromotive force returned from the winding of the motor driven by the inverter INV. Can be. As a result, current does not flow through the discharge unit 23 during a normal operation time, thereby reducing power consumption. On the other hand, since the inrush current limiter 21 operates according to the difference between the first voltage measured by the first voltage measurer 24P and the second voltage measured by the second voltage measurer 24F, the inrush current limiter 21 The pressure resistance capacity of (21) can be set smaller.

The present invention is not limited to the above embodiments, but may be modified and improved by those skilled in the art within the spirit and scope of the invention as defined in the claims.

Claims (2)

In a DC voltage control circuit for an inverter connected between a DC power supply and an inverter to control a DC voltage supplied from the DC power supply to the inverter, A first voltage measurement unit connected to the DC power supply to measure an instantaneous level of the DC voltage from the DC power supply; A second voltage measurement unit connected to the inverter and measuring an instantaneous level of the DC voltage from the DC power supply; Located between the first voltage measuring unit and the second voltage measuring unit, a difference between the first voltage measured by the first voltage measuring unit and the second voltage measured by the second voltage measuring unit is a predetermined reference voltage. An inrush current limiting unit to limit the inflow of direct current from the direct current power source if greater than; A capacitor positioned between the inrush current limiting unit and the second voltage measuring unit to charge a DC voltage from the DC power supply; And A DC voltage for an inverter including a discharge unit disposed between the inrush current limiting unit and the second voltage measuring unit and configured to perform discharge by a switching operation when the first voltage is lower than the lower limit voltage or the second voltage is higher than the upper limit voltage. Control circuit. The method of claim 1, wherein the discharge unit, And a resistor and a transistor connected in series with each other between the positive and negative lines of the DC voltage.

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