JPH08205398A - Charging/discharging circuit for capacitor - Google Patents

Abstract

PURPOSE: To prevent wasteful power consumption and to enable quick discharge of a capacitor at disconnection concerning a charging/discharging circuit for the back-up capacitor of a power unit. CONSTITUTION: A charging/discharging circuit is provided with a power unit 2 having a constant-current charging circuit 3 containing a transistor 11, a shunt regulator 12, etc., and a capacitor unit 1 which is connected to this power unit 2 with a connector 4 and charged by the constant-current charging circuit 3, and supplies charged electric charges to the power unit 2 through a diode 13 at the time of instantaneous cut off of power voltage. The capacitor unit 1 is provided with a capacitor 6 and a discharging circuit 5. This discharging circuit 5 has a switching element 7 which keeps an off state when the capacitor unit 1 is connected to the power unit 2, and becomes in an on state by the charged voltage of the capacitor 6 when it is disconnected from the power unit 2, and discharges the charged electric charges of the capacitor 6 quickly.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a capacitor charging / discharging circuit for backing up a power supply unit. Power outages of various types of power sources are about 100% of instantaneous interruptions of several 100 ms. For such extremely short power outages, a capacitor is used as a backup power source. In addition, there is an advantage that the configuration, maintenance, etc. are easier than the case of using the secondary battery. There is a demand for ensuring the safety of maintenance and inspection of this capacitor.

[0002]

2. Description of the Related Art FIG. 3 is an explanatory view of a conventional example. 31 is a capacitor unit, 32 is a power supply unit, 34 is a connector, 35 and 36 are diodes, 37 is a charging resistor, and 3 is a charging resistor.
Reference numeral 8 is a capacitor, and 39 is a discharging resistor.

The capacitor unit 31 comprises a capacitor 38 such as a large-capacity electrolytic capacitor corresponding to the capacity of the power supply unit 32 and a discharging resistor 39, and is connected to the power supply unit 32 via a connector 34. The power supply unit 32 is supplied with, for example, 240 V AC as a power supply voltage and supplies a desired AC voltage or DC voltage to various devices. In that case, a DC voltage of about 380 V is supplied to the diode 36 and the resistor 36. 37, the capacitor 38 is charged in addition to the capacitor 38, and when the power supply voltage is interrupted, the charged charge of the capacitor 38 is supplied to the power supply unit 32 via the diode 35. Power is continuously supplied to various devices based on the charge.

During maintenance and inspection of the capacitor 38,
It will be disconnected from the power supply unit 32 by the connector 34, but at that time, the charging voltage of the capacitor 38 is 3
Since it is about 80V, it poses a danger to maintenance personnel. Therefore, when the discharging resistor 39 is connected in parallel to the capacitor 38 and is disconnected from the power supply unit 32 by the connector 34, the charge charged in the capacitor 38 is transferred to the resistor 3
It discharges through 9.

[0005]

Since the discharging resistor 39 is connected in parallel with the capacitor 38, even if the power supply voltage is normal, the power supply unit 32 causes the capacitor 38 to discharge.
As a result, a current flows through the resistor 39 for discharging and the power consumption by the resistor 39 becomes a problem.

Therefore, it is conceivable to increase the resistance value of the resistor 39. In that case, when the capacitor unit 31 is disconnected from the power supply unit 32 by the connector 34 for maintenance and inspection of the capacitor 38, the discharge time of the capacitor 38 becomes long and the terminal voltage of the capacitor 38 does not drop rapidly. There is a problem that poses a danger to maintenance personnel. If the resistance value of the resistor 39 is reduced, the capacitor 38 can be rapidly discharged, but as described above,
A current flows through the resistor 39 along with the charging current of the capacitor 38, and there is a problem that useless power is consumed. An object of the present invention is to reduce power consumption when charging a capacitor and to enable rapid discharge of the capacitor.

[0007]

A capacitor charging / discharging circuit of the present invention will be described with reference to FIG. 1. A power supply unit 2 having a constant current charging circuit 3 and a constant current charging connected to the power supply unit. A capacitor unit 1 having a capacitor 6 that is charged by the circuit 3 and that supplies a charging charge to the power supply unit 2 when the power supply voltage is interrupted; the capacitor unit 1 maintains an off state when connected to the power supply unit 2, There is provided a discharge circuit 5 having a switching element 7 that is turned on by a charging voltage of a capacitor 6 when it is disconnected from the power supply unit to perform rapid discharge.

[0008]

When the capacitor unit 1 is connected to the power supply unit 2 by the connector 4, the constant current charging circuit 3 charges the capacitor 6. At that time, the switching element 7 of the discharge circuit 5 is maintained in the off state and does not consume unnecessary power. When the power supply voltage is instantaneously cut off, the charge charged in the capacitor 6 is supplied to the power supply unit 2. When the capacitor unit 1 is disconnected from the power supply unit 2 by the connector 4, the switching element 7 of the discharging circuit 5 is turned on by the charging voltage of the capacitor 6, and the capacitor 6 is rapidly discharged through the switching element 7.

[0009]

1 is an explanatory view of an embodiment of the present invention, in which a capacitor unit 1 has a discharge circuit 5 and a single or a plurality of capacitors 6 connected in parallel, and a power supply unit 2 is, for example, 380V DC voltage output circuit, for example, +10
A constant current charging circuit 3 for controlling constant current charging by a bias voltage V _CC of V is provided. Further, the discharge circuit 5 has a switching element 7 such as a high breakdown voltage FET and resistors 8 to 10, and the constant current charging circuit 3 includes a transistor 11 such as FET, a shunt regulator 12, and a diode 13.
And resistors 14 and 15.

When the capacitor unit 1 is connected to the power supply unit 2 via the terminals a to e of the connector 4, the constant current charging circuit 3 is turned off by the reverse voltage being applied to the diode 13, and the resistor 14 and the transistor. A charging current of the capacitor 6 that flows through 11 and 11 flows. The shunt regulator 12 and the transistor 11 are used by the shunt regulator 12 so that the current flowing through the resistor 14 becomes constant.
Is controlled to charge the capacitor 6 with constant current.

At this time, the switching element 7 of the discharge circuit 5
The gate of 2 becomes the same as the potential on the source side by short-circuiting the terminals c and d of the connector 4, and the switching element 7 maintains the off state. The resistors 9 and 10 are
This is for applying a bias voltage to the gate of the switching element 7, and the resistor 9 can have a sufficiently high resistance value as compared with the discharging resistor of the conventional example, and therefore flows when the capacitor 6 is charged. The current can be ignored. That is, the power consumption by the resistor 9 is negligible. Further, the resistor 10 may be a Zener diode.

When the power supply voltage is cut off instantaneously, the charge charged in the capacitor 6 is supplied to the power supply unit 2 via the diode 13. The diodes 35 and 3 shown by the dotted line
The resistor 6 for charging and the resistor 37 for charging can be connected if necessary, but can be omitted by providing the constant current charging circuit 3 described above. Therefore, the terminals a and b of the connector 4 can be shared.

FIG. 2 is an explanatory view of the discharge circuit of the embodiment of the present invention, showing a state in which it is disconnected from the power supply unit 2, and since the terminals c and d are opened, the charging voltage of the capacitor 6 causes the resistance 9, The bias voltage of 10 is applied to the gate of the switching element 7, and the switching element 7 is turned on. As a result, the charge charged in the capacitor 6 is discharged through the resistor 8 and the switching element 7 in the path indicated by the arrow.

In this case, the resistance value of the resistor 8 can be reduced corresponding to the characteristics of the switching element 7, so that the capacitor 6 can be rapidly discharged. That is, by disconnecting the capacitor unit 1 from the power supply unit 2, the charge charged in the capacitor 6 can be automatically and rapidly discharged, and the terminal voltage thereof can be reduced. Therefore, the maintenance person at the time of maintenance and inspection of the capacitor 6 will not be injured.

The present invention is not limited to the above-mentioned embodiments, and for example, the constant current charging circuit 3 can be applied with various known structures. Also discharge circuit 5
It is needless to say that the switching element 7 can use a switching element other than the FET.

[0016]

As described above, the present invention comprises the power supply unit 2 having the constant current charging circuit 3 and the capacitor unit 1 connected to the power supply unit 2 by the connector 4 or the like. , The discharge circuit 5 of the capacitor 6 is provided, and the discharge circuit 5 is provided with a switching element 7 that continues to be off when the capacitor unit 1 is connected to the power supply unit 2, and the capacitor unit 1 is separated from the power supply unit 2. At this time, the switching element 7 is turned on by the charging voltage of the capacitor 6 so that the capacitor 6 is rapidly discharged through the switching element 7. In the state where the capacitor unit 1 is connected to the power supply unit 2, the capacitor 6 is discharged.
Since only the charging current to the battery is supplied, there is an advantage that unnecessary power consumption does not occur. Further, when the capacitor unit 1 is separated from the power supply unit 2, the discharge circuit 5 causes the capacitor 6 to be rapidly discharged, so that there is an advantage that the safety for the maintenance person can be ensured with a relatively simple configuration. Further, since rapid discharge is possible, there is an advantage that the maintenance work time can be shortened.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of an embodiment of the present invention.

FIG. 2 is an explanatory diagram of a discharge circuit according to an embodiment of the present invention.

FIG. 3 is an explanatory diagram of a conventional example.

[Explanation of symbols]

 1 Capacitor unit 2 Power supply unit 3 Constant current charging circuit 4 Connector 5 Discharge circuit 6 Capacitor 7 Switching element

Claims (1)

[Claims] 1. A power supply unit having a constant current charging circuit, and a capacitor unit having a capacitor connected to the power supply unit to be charged by the constant current charging circuit and supplying a charging charge to the power supply unit when the power supply voltage is interrupted. The capacitor unit includes a discharge circuit that maintains an off state when connected to the power supply unit and that rapidly discharges through a switching element that is turned on by a charging voltage of the capacitor when disconnected from the power supply unit. A capacitor charging / discharging circuit characterized by being provided.