KR0121247Y1 - Breaking circuit for inrush current - Google Patents

Abstract

The present invention relates to an inrush current blocking circuit. In particular, the inrush current blocking circuit is designed to improve the reliability of the circuit, improve productivity, and reduce the PCB area while sufficiently preventing the inrush current generated at the initial power-up time by using a device having NTC characteristics. It is about a circuit.

Inrush current blocking circuit of the present invention for achieving the above object is a commercial power supply switch, a rectifier for converting the commercial AC power (110V-220V) transferred by the commercial power supply switch to a DC power source, and the rectifier Smoothing means for charging with DC power to output smoothing voltage, and low voltage for outputting control power during normal operation, by preventing the inrush current when the power is turned on again by prolonging the discharge time with respect to the smoothing voltage of the smoothing means when the power is cut off. And a power supply circuit unit for supplying power to the entire control system by the control power of the low voltage blocking means, and an element having a negative temperature characteristic (NTC) for preventing the initial inrush current of the commercial power supply. do.

Description

Inrush Current Break Circuit

1 is a block diagram of a general BLDC motor control device for driving a washing machine.

2 is a circuit diagram of a conventional inrush current blocking circuit.

3 is a circuit diagram of an inrush current blocking circuit of the present invention.

4 is a graph of the temperature and resistance characteristics of the negative temperature characteristic (NTC) device of the present invention.

Figure 5 is a graph of the discharge characteristics of the smoothed capacitor when the power supply of the present invention.

* Explanation of symbols for main parts of the drawings

21: commercial power supply switch 22: rectifier

23: smoothing capacitor 40: low voltage circuit breaker

35: negative temperature characteristic (NTC) element 41: zener diode

42: light emitting diode 43: first transistor

44: second transistor 45: power supply circuit

The present invention relates to an inrush current blocking circuit. In particular, the inrush current blocking circuit is designed to improve the reliability of the circuit, improve productivity, and reduce the PCB area while sufficiently preventing the inrush current generated at the initial power-on time by using a device having NTC characteristics. It is about a circuit.

In general, in a washing machine driving BLDC motor control, when a power is turned on, an element such as a rectifier diode, a capacitor, a switch, or the like may be damaged or degraded by an excessive charge current of a capacitor at an input moment.

In order to solve this problem, the initial power supply is used by connecting NTC elements that reduce the resistance loss due to the characteristic that the resistance is high at low temperature and the instantaneous charging current of the capacitor is lowered and the resistance is lowered due to the temperature rise after the power is turned on. However, it could not prevent the charging current (inrush current) that occurs when it is turned on again after the power is cut off.

However, in recent years, there is a tendency to have a power circuit section and a circuit to cut off the power circuit at low voltage for the purpose of reducing the inrush current when the power is turned on again.

Hereinafter, a conventional inrush current blocking circuit will be described with reference to the accompanying drawings.

1 is a block diagram of a general BLDC motor control apparatus for driving a washing machine, and FIG. 2 is a circuit diagram of a conventional inrush current preventing circuit.

The general washing machine driving BLDC motor control apparatus is as shown in FIG. 2, and the control circuit unit 16, the filter unit 1, the inrush current prevention unit 2, the rectifying unit 3, the smoothing capacitor 4, It is divided into an inverter part 5, a power supply circuit part 7, and the like.

When power is applied, the smoothing capacitor 4 is charged through the inrush current preventing unit 2 and the rectifying unit 3 via the filter unit 1.

The charging voltage of the smoothing capacitor 4 is converted into an alternating current power source of a required voltage and frequency according to the control of the control circuit unit 16 through the inverter unit 5, and the electric motor 6 is supplied.

The control circuit unit 16 detects the rotational speed of the rotor of the electric motor 6 in the sensor unit 11, transmits a signal to the microcomputer 12, and outputs a phase signal and a PWM signal in accordance with the rotor position in the microcomputer 12. The modulation circuit 13 and the buffer circuit 14 process the gate signal, and the gate driver 10 generates a signal capable of directly driving the gate of the power switching element (triac) of the inverter unit 5. Will be supplied.

The AC voltage detecting unit 8 detects the power failure to process the microcomputer 12, and the overcurrent protection circuit unit 9 detects the overload signal and transmits the overload signal to the microcomputer 12 for overcurrent protection. Control overload signal.

The control circuit unit 16 receives and outputs a command signal to the microcomputer 12 by a display for displaying the stroke state and each state of the washing machine and the interface circuit 15 for user mode selection, and receives the charging voltage of the smoothing capacitor. There is a power supply circuit portion 7 for supplying power to the power supply.

The conventional inrush current blocking circuit includes a commercial power supply switch 21 for applying and cutting off commercial power as shown in FIG. 2, a rectifier 22 for converting the commercial power supply into a DC power by the commercial power supply switch 21, and the rectifier. The control voltage of the smoothing capacitor 23 is composed of a smoothing capacitor 23 which charges a voltage by the voltage 22 to output a control voltage, and a resistor 30, a capacitor 29, a diode, and an operational amplifier 31. And a voltage detector 28 and a triac driver IC for generating a detection signal. The driver 27 outputs a gate signal by the voltage detector 28, a PTC element 25, a triac 26, and the like. And an inrush current blocking unit 24 for receiving and driving the gate signal of the driving unit 27.

The operation of the conventional inrush current blocking circuit configured as described above is applied to the commercial power supply through the commercial power supply switch 21, changes to DC power through the rectifier 22, and converts the DC voltage through the smoothing capacitor 23. A smooth voltage is obtained.

At this time, the generated current passes through the inrush current blocking unit 24.

On the other hand, when the power is initially applied, the PTC element 25 of the inrush current blocking unit 24 having low resistance at low temperature is operated to charge the smoothing capacitor 23 through the rectifying unit 22.

When the charging of the smoothing capacitor 23 is completed, the control voltage is generated in the voltage detector 28, and the operational amplifier 31 calculates the voltage charged in the capacitor 29 of the voltage detector 28 and the voltage between the resistor 30. In comparison with, if the voltage charged in the capacitor 29 is large, the detection signal is output to the driver 27.

The current path through the PTC element 25 through the triac 25 through the gate signal is output to the triac 26 of the inrush current interruption unit 24 by receiving the detection signal from the driver 27 Change to current path.

That is, when power is applied, a path is passed through the PTC element 25 having low resistance at low temperature, and after the power is applied, the time and voltage detector generated by the control voltage generated by the smoothing capacitor 23 are generated. During the charging time of the capacitor 29 of the 28, the PTC element 25 rises in temperature to increase resistance, so that the signal passing through the voltage detector 28 and the drive unit 27 becomes a triac of the inrush current interruption unit 24. Conducts 26 to form a path through triac 26.

In the conventional inrush current blocking circuit as described above, the circuit is complicated and the number of parts is high, the unit cost is high, occupies a large area of the PCB, and when the commercial power supply switch is cut and then energized again, the smooth capacitor is not completely discharged. By operating the triac by the inrush current blocking unit had a disadvantage that can not block the excess current initially flowing when the power supply again.

Invented to solve the above problems, in particular the inrush current to improve the reliability of the circuit, improve the productivity and reduce the PCB area, while sufficiently preventing the inrush current generated during the initial power-up using the device having the NTC characteristics The purpose is to provide a blocking circuit.

Inrush current blocking circuit of the present invention for achieving the above object is a commercial power supply switch, a rectifier for converting a commercial AC power (110V-220V) transferred by the commercial power supply switch to a DC power source, and the rectifier Smoothing means for charging with a DC power supply to output a smoothing voltage, and to prevent excessive inrush current when the power is re-supplied by extending the discharge time for the smoothing voltage of the smoothing means when the power is cut off, and outputs the control power during normal operation And a device having a low voltage blocking means, a power circuit unit for supplying power to the entire control system by the control power of the low voltage blocking means, and a negative temperature characteristic (NTC) for preventing the initial inrush current of the commercial power supply. It is done.

Hereinafter, the inrush current blocking circuit of the present invention will be described with reference to the accompanying drawings.

Figure 3 is a circuit diagram of the inrush current blocking circuit of the present invention, Figure 4 is a graph of the temperature and resistance characteristics of the NTC device of the present invention, Figure 5 is a graph of the smoothing capacitor discharge characteristics when the power supply of the present invention.

The inrush current blocking circuit of the present invention includes a commercial power supply switch 21 for applying and cutting off commercial power as shown in FIG. 3, a rectifier 22 for converting into a DC power by the commercial power supply switch 21, and The smoothing capacitor 23 charges the voltage by the rectifier 22 to output the control voltage, and the first and second transistors 43 and 44, the LED 42, the zener diode 41, and the like. The low voltage blocking circuit unit 40 is configured by a low voltage blocking circuit unit 40 for interrupting the low voltage generated by the incomplete discharge of the capacitor 23 to completely discharge the smoothing capacitor 23, and outputting a driving voltage. A power supply circuit section 45 for supplying a driving voltage to the control circuit for controlling the entire washing machine system with the control voltage output from the control circuit, and an NTC element 35 for controlling the initial inrush current with low resistance at high temperature and high resistance at low temperature. Including The lure is.

Operation of the inrush current blocking circuit of the present invention configured as described above is converted to DC power through the rectifier 22 when commercial power is applied through the commercial power supply switch 21 as shown in FIG. 3 and FIG. This voltage is converted to a smoothing voltage (driving voltage) by the smoothing capacitor 23.

At this time, the inrush current generated is passed through the NTC element 35, and the initial power supply is controlled at the low temperature 101 as shown in FIG. 4 due to the characteristics of the NTC element 35, thus controlling excessive initial inrush current (102). After that, the temperature is increased due to the heat loss generated by the flowing current (101) and the resistance is lowered (102) to reduce the resistance loss during operation.

However, if the thermal time constant of the NTC element 35 is large and the NTC element 35 does not have sufficient time to cool down when the power is turned on again, the temperature of the NTC element 35 is high, the resistance is low, and excessive inrush current flows to the peripheral element. It will cause damage.

However, the smoothing voltage (driving voltage) generated by the smoothing capacitor 23 is formed as an applied voltage to the low voltage blocking circuit unit 40, and the driving voltage (smoothing voltage) after the power is turned on is the zener diode (40) of the low low voltage blocking circuit unit 40. Since the zener voltage of 41 is greater than or equal to the Zener voltage, current flows in the A path to operate the first transistor 43 and the second transistor 44.

At this time, the power is supplied to the control circuit unit by applying the driving circuit unit 45 and the driving voltage.

The 5:00 assist power down as (T ₁₎ a smoothing capacitor (23) when the driving voltage (smoothed voltage) is reduced to an optimal voltage (Zener voltage) generated in the LED (light emitting diode) (42 of undervoltage lockout circuit 40, Current flows in the B path (103, 104) so that the natural discharge is slow (103, 104).

When the NTC element 35 is turned on again before the table is cut, the resistance reduction by the NTC element 35 is reduced because only the self-discharge of the smoothing capacitor 23 is allowed to maintain the smoothing voltage (driving voltage) with a longer discharge time. Compensation should be made by reducing the differential (commercial power supply voltage-smoothing voltage).

At this time, even if excessive inrush current flows, the inrush current is prevented by compensating for the voltage difference reduction.

The inrush current blocking circuit of the present invention as described above can easily configure the circuit, and can sufficiently prevent the inrush current, thereby increasing the reliability and reducing the cost of the circuit, improving productivity, and reducing the PCB area.

Claims (2)

A commercial power supply switch, a rectifier for converting a commercial AC power source (110V-220V) transmitted by the commercial power supply switch into a DC power source, smoothing means for outputting a smooth voltage by charging the DC power by the rectifier unit; When the power is turned off, the discharge time with respect to the smoothing voltage of the smoothing means is extended to prevent excessive inrush current when the power is turned on again, and the low voltage blocking means outputs the control power during normal operation, and the control power of the low voltage blocking means. An inrush current interrupting circuit comprising a power circuit unit for supplying power to a control system, and an element having a negative temperature characteristic (NTC) for preventing an initial inrush current of a commercial power supply. The low voltage blocking means includes: a zener diode for blocking and flowing a current as the smoothing voltage is greater than or less than the zener voltage, first and second transistors operated by the zener diode, and the zener diode. An inrush current interrupting circuit comprising a light emitting diode that extends a discharge time with respect to a smoothed voltage charged when cut off.