KR910007047Y1 - Control circuit for ripple current - Google Patents

Abstract

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Description

Inrush Current Control Circuit

1 is a conventional circuit diagram.

2 is a circuit diagram according to the present invention.

3 is an operating waveform diagram according to FIG.

* Explanation of symbols for main parts of the drawings

100: rectification means 200: inrush current limiting means

300: smoothing means 400: power transmission means

500: main power supply start means 600: current sensing means

700: main power supply means 800: main power supply blocking means

The present invention relates to an inrush current control circuit in a power supply system, and more particularly, to an inrush current control circuit capable of controlling inrush current generated during initial power supply and system operation.

In-rush current generally refers to the over-current flowing more than necessary when the initial power is "on", when the power is turned on / off during system dynamics, or when a sudden momentary static occurs. However, this must be controlled because it has a significant adverse effect on the circuit.

1 is a conventional circuit for removing such inrush current.

In FIG. 1, the AC power input through the AC input terminals 1 and 2 at power-on is rectified and smoothed by the bridge diode 6 and the capacitor 8 via the resistor 3. The rectified smoothed DC voltage is applied to the primary coil 16 of the transformer 13. The residual voltage applied to the primary coil 16 is the first secondary coil when the first secondary coil 18 and the second secondary coil 14 are turned on when the transistor 14 is turned on. 18 and the second secondary coil 17 are induced by the magnetic induction phenomenon in the corresponding form of the predetermined turns ratio they have. In this case, the voltage induced in the first secondary coil 18 is applied as a gate voltage to the diode 11, the resistor 5, and the gate. The triac 7 is a bidirectional rectifier and is turned on when a trigger voltage is supplied to the gate.

On the other hand, the capacitor 9 and the resistor 5 delay the input signal by a time proportional to the time constants of the capacitor 9 and the resistor 5 as an integral time.

Therefore, the time point at which the triac 7 is turned on is delayed by the time constant of the capacitor 9 and the resistor 5 even if sufficient voltage is induced in the first secondary coil 18. For this reason, the triac 7 turns on after being delayed by the time constant when the initial power is supplied. Since the input power is supplied through the resistor 3 before the triac 7 is turned on, the power induced in the primary coil 16 is smaller than the normal power, and the triac 7 is Normal power is supplied as it is turned on.

Thus, even if excessive current is initially introduced, the triac 7 is turned on after the time constant, so that the excessive current is reduced through the resistor 3, which does not adversely affect the circuit.

However, in the circuit of FIG. 1, if the capacitor 9 is not completely discharged, the triac 7 is turned on as soon as the input power is supplied, so that the inrush current is the circuit after the triac 7 as it is. Since it is supplied to, it has a disadvantage of adversely affecting the circuit. When the power is supplied in a state where the capacitor 9 is not completely discharged, it is a time like a power failure, which can often occur. And each time a circuit is adversely affected, the circuit will shorten its life considerably or be destroyed immediately.

Therefore, an object of the present invention is to provide an inrush current that can be eliminated even if the inrush current occurs during operation due to the cause such as instantaneous power failure as well as the initial power supply.

In order to achieve the above object, the present invention provides a rectifying means (100) for rectifying by receiving a commercial alternating current power, and a smoothing means (300) for smoothing and converting the flow of the rectified rectifier means into a direct current, and the Inrush current limiting means 200 which is connected between the rectifying means 100 and the smoothing means 300 to mitigate when the inrush current flows from the rectifying means 100 to the smoothing means 300, and the smoothing means. Connected to 300, the smoothing means 300 receives a smooth direct current, converts it into alternating current and branches it back into a plurality of power transmission means 400 for transmitting power to a plurality of means, and the rectifying means 100 and A main power supply means 700 which is connected between the smoothing means 300 and directly supplies the rectified power of the rectifying means 100 without reduction when the inrush current does not flow in the smoothing means 200, and the main power Current sensor that senses current flowing during supply Connected to the means 600 and the power transmission means 400 and the main power supply means 700, AC-coupling the predetermined power divided by the power transmission means 400, rectifying and smoothing the predetermined time constant Main power supply starting means 500, the current sensing means 600 and the main power supply to the main power supply means 700 by delaying the main power supply means 700 to supply the main power When the current sensed by the current sensing means 600 is excessively connected between the power supply starting means 500, the function of the main power supply starting means 500 may be invalidated so that the main power supply means may supply main power. Main power supply blocking means 800 so as not to be a component.

2 illustrates the above configuration as an actual circuit. And Figure 3 is its operating waveform.

FIG. 2 has only meaning as an embodiment suitable for the above objects and components, and does not in any way limit the invention.

In FIG. 2, the rectifying means 300 includes a fuse 5 and a bridge rectifying element 30, and when AC power is supplied through the input terminals 31 and 32, it rectifies and outputs it.

At this time, the rectifying output is supplied to the smoothing means 300 which is the capacitor 45 via the current limiting means 200 which is the resistor 42.

The smoothing means 300 converts the direct current into the direct current by charging the pulse flow introduced through the current limiting means 200 as the capacitor 45.

If the capacitor 45, the smoothing means 300, starts charging in a completely discharged state, instantaneous inrush current may occur as if it is completely shorted, but the resistor 42, which is the inrush current limiting means 200, may occur. Excessive current cannot flow because the current supplied by it is limited.

On the other hand, the direct current converted by the capacitor 45 smoothly appears between the primary coil 61 and the switching transistor 51 of the transformer 60, which is a power transmission means, and the switching transistor 51 is the base end 50. Since the switch receives a predetermined switching signal by using a reference signal, the direct current appearing in the primary coil 61 of the transformer 60 is converted into an alternating current having a width corresponding to the switching of the switching transistor 51.

When the alternating current is induced in the primary coil 61, the transformer 60 may form the primary coil 61 and the first secondary coil 81 in the first secondary coil 81 by magnetic induction. The predetermined voltage proportional to the number of turns ratio is induced.

The main power supply starting means 500 is composed of a diode 82, a resistor 93 and a capacitor 92. When the alternating current is induced in the first secondary coil 81 of the transformer 60, the resistance While delaying by the time corresponding to the predetermined time constant determined by the 93 and the capacitor 92, the rectification is smoothed and supplied to the gate of the SCR 91, which is the main power supply means 700, as a trigger voltage.

Therefore, when DC power is supplied to the power transmission means 700, the SCR 91, which is the main power supply means 700, is triggered after a predetermined time corresponding to the time constant as long as the switching transistor 50 performs a switching operation. do.

The time constant determined by the resistance 93 and the capacitor 92 of the main power supply starting means 500 is a value sufficient to allow the capacitor 45, which is the smoothing means 300, to complete charging and return to a normal state. Should be set to.

When the SCR 91 is turned on, the pulse flow rectified by the bridge rectifying element 30 of the rectifying means 100 is smoothed by DC in the capacitor 45 which is the smoothing means 300 and then the power transmission means 400. The phosphorus transformer 60 is supplied to the primary coil 61.

In this case, since the capacitor 45, which is the smoothing means 300, is in a normal state, the SCR 91 is not an excessive inrush current. As a result, a constant steady current flows at all times in the power supplied to the primary coil 61 of the transformer 60.

Main power supply blocking means 800 is composed of a resistor (43, 44) and a transistor 46, the resistor 44 is connected between the base emitter of the transistor 46 to form a bias of the transistor 46 The resistor 43 prevents overcurrent from flowing through the base of the transistor 46. The resistors 43 and 44 are connected in parallel with the resistor 42 which is the inrush current limiting means 200 in series with the resistor 60 which is the current sensing means. Therefore, when an excessive inrush current flows through the inrush current limiting means 200, a branched current also flows in the resistors 60, 43, and 44. At this time, the resistance 42 which is the inrush current limiting means 200 is much larger than the resistance 60 which is the sensing means 600, whereas the resistance 60 which is the current sensing means 600 is normally operated. In this case, it has a resistance value that drops across the both ends so low that the bias cannot be supplied to the transistor 46.

However, when the inrush current is generated, it becomes a value sufficient to form a bias in the transistor 46. Therefore, the transistor 46 is always turned on when an inrush current occurs. The transistor 46 is connected to the emitter and the base between the gate and the cathode of the SCR 91, the main power supply means 700, and at the same time both ends of the capacitor 92 of the main power supply start means 500 Connected. Therefore, when the transistor 46 is turned on, the SCR 91 stops its operation by releasing the bias, and the capacitor 92 is discharged rapidly by turning the turned on transistor 46 as a path.

The operation so far has described the operation at initial power-on. Next, the operation when the momentary power failure occurs will be described with reference to FIG.

When a momentary power interruption occurs, the AC flowing through the AC input terminals 31 and 32 of the rectifying means 100 generates a section in which AC is temporarily interrupted in the middle as shown in FIG. From the moment of power failure, as shown in (b) of FIG. 3, the potentials of both ends of the capacitor 45, which are the smoothing means 300, are reduced until the power is finally applied.

At the outset, the capacitor 45 is said to be a short-circuit instantaneously when the current is supplied in a completely discharged state, so that excessive inrush current flows, which is an ideal theoretical case. In fact, as a result of experiments, it was found that the inrush current similar to the short-circuit state occurred when the capacitor was large even when some charge remained.

Therefore, even when the electric charge charged in the capacitor 45 of the smoothing means 300 is not completely discharged due to the instantaneous power interruption, an inrush current is generated when it is energized after a while. At this time, in the conventional circuit of FIG. 1, since the charges that have not been discharged due to the capacitor 9 remain, the trigger voltage is immediately supplied to the gate of the triac 7, so that the inrush current as described above is supplied to the rear end as it is. However, in the present invention, when an instantaneous power failure is released and the electricity is supplied, the voltage dropping across the resistor 60, which is the current sensing means 600, becomes large before an excessive current flows through the capacitor 45 which is the smoothing means 300. Since a bias is formed in the transistor 46, the transistor 46 is turned on. As a result, as shown in FIG. 3C, the gate and the cathode of the SCR 91 are shorted, and the capacitor 92 is discharged at the same time. The gate of the SCR 91 is trig and no voltage is supplied. Therefore, since the transient current at the moment of the momentary power failure is supplied to the smoothing means 300 through the resistor 42 which is the current limiting means 200, the inrush current does not occur even at this time. Thus, conventionally, excessive inrush current occurs during instantaneous power failure as shown in (e) of FIG. 3, but excessive inrush current is excluded from the present invention as shown in (d) of FIG.

As described above, the present invention can limit the inrush current not only at the time of initial power supply but also during system operation by using the switching means, thereby completely eliminating the adverse effect on the fuse stage and the circuit due to the inrush current.

Claims (1)

In the inrush current control circuit, the rectifying means (100) for rectifying by receiving a commercial alternating current, the smoothing means (300) for smoothing and converting the pulsation rectified by the rectifying means (100) into direct current, and the rectifying means (100) ) Between the smoothing means 300 and the smoothing means 300 connected to the smoothing means 300 to mitigate when the inrush current flows from the rectifying means 100 to the smoothing means 300. The connection smoothing means 300 receives a smooth direct current, converts it into alternating current, and branches it back into a plurality of power transmission means 400 for transmitting the input to another means, the rectifying means 100 and the smoothing means 300. A main power supply means 700 for directly supplying the rectified power by the rectifying means 100 without a reduction when the inrush current does not flow through the smoothing means 300, and the main power supply means 700. And the rectifying means 100 is connected to the The current sensing means 600 for sensing the current flowing during the power supply, and the power transmission means 400 and the main power supply means 700 is connected between the AC power to the predetermined power divided by the power transmission means 400 A main power supply starting means 500 for supplying the main power to the main power supply means 700 by supplying the main power supply means 700 by delaying a predetermined time constant after the ring rectifying and smoothing, If the current sensed by the current sensing means 600 is excessive between the current sensing means 600 and the main power supply starting means 500, the function of the main power supply starting means 500 is invalidated. Inrush current control circuit, characterized in that the main power supply means for configuring the main power supply blocking means 800 to supply the main power.