KR100198452B1 - A protection circuit of the inrush current using the r/c port of on board power module - Google Patents

Abstract

The present invention is caused by the initial power is directly input to the capacitor in the on-board power supply module when the on-board power module is mounted, removed or mounted on the system in operation or the circuit pack power on / off. A circuit for inrush current control, and a circuit for inrush current prevention using a remote control function of an on-board power supply module. In the prior art, it is difficult to mount the inrush current prevention circuit inside the power supply of the on-bond power module, so that the on-board power module is mounted on the system power supply system in which several circuit packs are accommodated on one mother board. When the pack is removed / mounted or when the power supply of the circuit pack is turned on / off, an initial power is directly input to a capacitor in the on-board power module, thereby causing an inrush current. In the present invention, in order to prevent the instantaneous inrush current, by using a resistor and a switch element on the remote control terminal of the on-board power supply module, a very simple inrush current prevention compared to the circuit used in the power supply of the conventional package type The circuit was constructed.

Description

Inrush Current Prevention Circuit of On-Board Power Module Using Remote Control

The present invention relates to an inrush current prevention circuit of an on-board power module using a remote control. Specifically, the present invention relates to a circuit pack equipped with an on-board power module in a system in which the on-board power module is mounted, mounted or turned on / off. In this case, the present invention relates to a circuit for controlling inrush current generated by directly supplying initial power to a capacitor in an on-board power module.

In general, the package-type DC / DC power supply device has been improved until the inrush current countermeasures are constructed after the resistance, thermistor, and relay method are constructed.

FIG. 1 is a block diagram of an on-board power module having a remote control terminal. Referring to some components of FIG. 3, the operation principle of the on-board power module and the inrush current prevention circuit of the related art will be described as follows. .

DC power is supplied through the input filter 10, and the input / output is electrically insulated by the conversion transformer (the output voltage is determined by the turns ratio of the primary side and the secondary side of the transformer) 40. As for the output voltage, the rectangular pulse of the output terminal of the PWM control unit 20 drives the field effect transistor 30 (Q1 in FIG. 3), thereby transferring the primary side energy of the transformer 40 to the secondary side to provide the rectifier 50. Through rectification, the desired output voltage can be obtained. The stabilization rate of the output stage is influenced by the drive circuit configured by the pulse width modulation (PWM) control unit 20. The output of the error amplifier provides a voltage level proportional to the output voltage and affects the PWM controller 20. The current limiting action at the output serves to reduce the duty cycle.

The remote control terminal 1 is connected to an on / off terminal (normal operation when high level is applied and no operation when low level is applied) inside the PWM control unit 20 (see FIG. 3). Is operated to pull down the on / off terminal of the PWM control unit 20 to a low level, and the output is turned off.

FIG. 2 is a configuration diagram of the inrush current prevention circuit of the power supply in the form of a package. The operation principle is that the input power Vin is supplied when the switch SW is turned on, and the resistor R1 before the field effect transistor FET is operated. The capacitor C2 is charged and started, and is limited by the inrush current I = V (input power source) / R1 generated initially. After the input power is turned on, the transistor operates when the voltage of capacitor C1 is gradually charged above the voltage required to drive the charged field effect transistor with the time constant of resistor R2 and capacitor C1. After the transistor operates, the input current flows through the transistor. In FIG. 2, the inrush current limiting circuit of the package-type power supply device limits the inrush current by the resistor R1 for a time until the transistor is driven by the time constant of the resistor R2 and the capacitor C1.

As described above, in the case of the on-board power supply module in the related art, it is difficult to mount the inrush current prevention circuit inside the power conversion circuit as in the package type power supply device due to the pursuit of light and small size such as the number of components, size, and mounting space.

Therefore, the on-board is used when the circuit pack including the on-board power module is mounted / detached or the power supply of the circuit pack is turned on / off on a system power supply system in which several circuit packs are accommodated in one mother board. Inrush current is inevitable because the initial power is directly input to the capacitor in the power module. This is an instantaneous short circuit of the input voltage, resulting in a very large input current, affecting the reliability of the system supply voltage and the reference potential of the input voltage, affecting the neighboring circuit packs in operation.

Therefore, the present invention uses a remote control terminal of the on-board power module and one resistor and a switch element to prevent the instantaneous inrush current in the prior art, to the circuit used in the power supply of the existing package type. The purpose is to provide a very simple inrush current prevention circuit.

1 is a block diagram of an on-board power module.

2 is a conventional inrush current prevention circuit diagram.

3 is a circuit diagram of the inrush current prevention using the remote control terminal of the on-board power supply module according to an embodiment of the present invention.

4 is a circuit diagram of the inrush current prevention using the remote control terminal of the on-board power supply module according to another embodiment of the present invention.

Inrush current prevention circuit of the present invention for achieving the above object is connected between the ground terminal (GND) and the power input terminal (-48V) is input via a capacitor (C1) for charging the input voltage, and the remote control terminal The transistor Q1 is driven by the pulse width modulation control unit and the square wave pulse output from the pulse width modulation control unit in response to the signal fed back through the feedback detector to output the output voltage through the transformer and the rectifier. In the circuit for preventing the inrush current generated by the initial power is directly input to the capacitor in the board power module, the resistance connected to the power input terminal (-48V) to limit the inrush current when the initial power input, and the pulse It is connected to the remote control terminal of the width modulator in accordance with the switching, to prevent the generation of inrush current generated in the state connected in parallel with the resistance And a switch for turning off the power supply voltage to charge the capacitor with the time constant of the resistor and the capacitor, and connecting the resistor and the switch to the ground terminal GND in the same manner as the above configuration. It is characterized by a very simple inrush current circuit compared to the circuit used in the device.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a circuit diagram of the inrush current prevention circuit using the remote control terminal of the on-board power module according to an embodiment of the present invention, when the remote control terminal of the on-board power module is connected to the -48V power supply side.

Since the circuit pack is mounted in a system (external power applied) operating in the switch (SW1) in the off state (connecting terminal 2 and terminal 3 of SW1), the power supply voltage is gradually supplied via R1 to the on-board power supply. Capacitor C1 in module 200 is charged with RC time constant [Vc (charging voltage of C1) = V (input voltage) x (1-e ^{(-t / RC)} )]. Capacitor C1 goes from a discharged state (impedance = 0) to a charged state (impedance = ∞). Since the input power supply Vcc is supplied to the PWM control unit 20 inside the on-board power supply module 200 and the PWM control unit 20 is in operation, but the on / off terminal is at a low level, the square wave of the output terminal is not output. The output voltage is not output.

When the initial power is input, the capacitor C1 in the discharged state starts to charge, but the inrush current is driven by the resistor R1, even though the capacitor C1 in the discharged state is impedance = 0, I = V (input voltage) / R (impedance of R1 + C1). Limited by

The input loop is formed by GND-C1-R1-(-48V).

In the case where there is no resistor R1, when the input power is supplied, the input loop is formed as GND-C1-(-48V), and the capacitor C1 in the discharged state is impedance = 0, so the inrush current I = V (input voltage) / R ( The inrush current becomes ∞ by the impedance of C1 = 0).

This inrush current instantaneously directs the input current to the capacitor C1, which drops the input power of other circuit packs operating in the system, thereby providing an error source of the operating system due to the instability of the reference power supply.

When the switch (SW1) is turned on (connected terminal 1 and terminal 2 of SW1), the on / off terminal maintained at the 'low' level by the R / C terminal is at the 'high' level (on / off terminal). Is connected to the reference potential (5V) terminal) so that the square wave of the output terminal is supplied to the transistor Q1 to output the output voltage. Since the capacitor C1 is charged (impedance C1 = ∞) when the switch SW1 is off, the inrush current due to the impedance of the capacitor C1 = 0 is not generated.

The constant of the resistor R1 is turned on by the time constant Vc (charge voltage of C1) = V (input voltage) x (1-e ^{(-t / RC)} ) of the resistor R1 and the capacitor C1 in the OFF state of the switch SW1. Determine the time t1 of the minimum input power branch for the board power module to operate and the time t2 until the input power is supplied from the switch (SW1) off state to the on state of the switch (SW1), and the constant of the resistor R1 to be t1t2. Determine. However, since resistor R1 limits the input current, it should not be limited below the maximum input current required by the on-board power module.

4 is an inrush current prevention circuit using the remote control terminal of the on-board power module according to another embodiment of the present invention, and is a circuit diagram when the remote control terminal of the on-board power module is connected to the GND side.

Same as the operation principle described in FIG. 3, but when the connection position of the resistor R1 is not -48V and the switch (SW1) is turned off (connecting terminal 1 and terminal 3 of SW1) to the GND side, Since the potential is 'high', the potential applied to the on / off terminal using the transistor Q2 is 'low' so that the square wave of the output terminal is not output, thereby implementing the same operation principle as in FIG.

As shown in FIG. 3 and FIG. 4, the inrush current prevention circuit of the on-board power supply module using the remote control, after charging the capacitor C1 through the resistor R1 in the off state, the on / off terminal of the PWM control unit 20 Limit the inrush current by operating the on-board power module.

In the present invention, due to the need for an inrush current prevention circuit that cannot be mounted in the on-board power supply module, an external inrush current prevention circuit is composed of a resistor R1 and a switch SW1 to the input terminal and the R / C (remote control) terminal. Connected. In the circuit method, since the circuit pack is mounted with the switch SW1 turned off, the power supply voltage gradually charges the capacitor C1 in the on-board power supply module through the resistor R1, and the PWM control unit 20 starts through the input power supply Vcc. To supply the square wave pulse to the transistor Q1, but the R / C terminal side is off, it cannot be started and the switch SW1 is on when the switch SW1 is turned off to the capacitor C1 in the on-board power module. Since the voltage is charged, the generation of the inrush current at the time of the switch SW1 can be suppressed as much as possible.

As described above, the present invention can be used to unmount / mount a circuit pack equipped with an on-board power module or to turn on / off a power supply of a memoirs pack on a system power supply system in which several circuit packs are accommodated in one mother board. When the initial power is directly input to the capacitor in the on-board power module, the input voltage is momentarily short-circuited and the input current is infinitely large, thereby preventing the fatal inrush current that adversely affects the stability of the input voltage. This can have a significant effect on the stable operation of the mounted circuit pack.

Claims (4)

The capacitor C1 is connected between the ground terminal GND and the power input terminal (-48V) to charge the input electrical signal, and operates according to the signal input through the remote control terminal to return the signal fed back through the feedback detector. The transistor Q1 is driven in response to the square and the pulse outputted from the pulse width modulation control unit 20 and the pulse width modulation control unit 20 to output an output voltage through the transformer 40 and the rectifier 40. In the circuit for preventing the inrush current generated by the initial power is directly input to the capacitor in the board power module, the resistance connected to the power input terminal (-48V) to limit the inrush current when the initial power input, and the pulse The power supply voltage is connected to the remote control terminal of the width modulator 20 according to the switching, and the power supply voltage is connected to the resistance in order to prevent generation of an inrush current generated in a state in which it is connected in parallel with the resistance. On using a remote control, characterized in that consisting of a switch-off order in which the time constant of the panel capacitors to charge the capacitor-preventing rush current of the power module circuit board. The method of claim 1, wherein the constant of the resistor is switched to the minimum input power supply for the on-board power supply module to operate by the charge voltage = input voltage * (1-e ^{(-t / RC) of the} capacitor) Time t1 and the time t2 from the switch off state to the input power supply and the switch on state are obtained, and t1 is smaller than t2 (but larger than the maximum input current required by the on-board power module). Inrush current prevention circuit of on-board power module using remote control. The capacitor C1 is connected between the ground terminal GND and the power input terminal (-48V) to charge the input electrical signal, and operates according to the signal input through the remote control terminal to return the signal fed back through the feedback detector. On-board receiving the pulse width modulation control unit 20 and the transistor Q1 is driven in accordance with the square wave pulse output from the pulse width modulation control unit 20 to output the output voltage through the transformer 40 and the rectifier 40 In the circuit for preventing inrush current generated by the initial power is directly input to the capacitor in the power module, a resistance connected to the ground terminal (GND) to limit the inrush current when the initial power input, and in parallel with the resistance A switch for turning off the power supply voltage to charge the capacitor with the time constant of the resistor and the capacitor to prevent generation of inrush current generated in the connected on state; Inrush of the on-board power supply module using a remote control characterized in that the drive is driven in accordance with the signal input by the switching of the switch to supply a pulse width modulation control signal to the remote control terminal of the pulse width modulation control unit. Current prevention circuit. 4. The method of claim 3, wherein the constant of the resistor is switched to the minimum input power supply for the on-board power supply module to operate by the charging voltage of the capacitor = input voltage * (1-e ^{(-t / RC)} ). Time t1 and the time t2 from the switch off state to the input power supply and the switch on state are obtained, and t1 is smaller than t2 (but larger than the maximum input current required by the on-board power module). Inrush current prevention circuit of on-board power module using remote control.