JPH04121357U - backup circuit - Google Patents

Abstract

(57) [Summary] [Purpose] To reliably prevent current from flowing from the battery to the supercapacitor when a backup battery and a supercapacitor are used together to compensate for a power outage in a memory circuit or the like. [Structure] A supercapacitor 8 is connected to the power supply path from the main power supply to the memory circuit 4, and a backflow prevention diode 11 is provided in series on the memory circuit 4 side from the connection point with the supercapacitor 8 of this power supply path. A backup primary battery 5 is connected to the cathode side of the diode 11 via a backflow prevention diode 7.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

This invention combines a backup battery and an electric double layer capacitor (hereinafter referred to as Regarding a backup circuit that compensates for power outages by using a supercapacitor (also called a supercapacitor) .

0002

[Conventional technology]

Conventionally, microcomputer systems have a volatile storage device called RAM. Built using memory, and as a countermeasure against power outages, memory circuits are often powered by batteries. A method is taken to back up the data. In addition, recently, in order to back up the memory circuit for a short time (0.5 to 1 hour), A supercapacitor is installed for power outage compensation using a battery and a supercapacitor together. A circuit designed to do this is used.

0003 Figure 3 shows such a conventional backup circuit. Pass the power terminal 1 through the anode and cathode of the backflow prevention diode 2 and the power supply line 3. to the power supply terminal Vcc of the memory circuit 4 consisting of static memory (SRAM). A battery made of a lithium battery with excellent ambient temperature characteristics and storage characteristics. The primary battery 5 for backup is connected to the limiting resistor 6 and the anode of the backflow prevention diode 7, It is connected to the power supply line 3 via the cathode, and furthermore, a super Capacitor 8 is connected.

0004 The power supply voltage of the main power supply is 5V, and the battery voltage of the primary battery 5 is lower than the power supply voltage. The voltage that can hold the memory circuit 4, for example, 3.6V, is set to 3.6V. The rated voltage of the capacitor 8 is set lower than the power supply voltage and higher than the battery voltage. difference Furthermore, 9 supplies current to the power supply line 3 from the higher voltage one of the main power source and the primary battery 5. A hybrid with a built-in diode OR circuit using the diodes 2 and 7 It is an IC, has a power outage detection function, and outputs a power outage detection signal.

[0005] Normally, the main power is passed through diode 2 and power supply line 3 from power supply terminal 1. is supplied to the memory circuit 4, and when the power supply voltage drops due to a power outage, this When the voltage drops below the rated voltage of the capacitor 8, the charge accumulated in the supercapacitor 8 is released and the memory circuit 4 is held.

[0006] In addition, if the power outage lasts for a long time, the supercapacitor 8 will be discharged. When the voltage drops below the battery voltage, the battery power source of the primary battery 5 is connected to the resistor 6 and the die. It is supplied to the memory circuit 4 through the power supply line 3 and the power supply line 3, and the memory circuit 4 is protected. held.

[0007] Additionally, when the mains power recovers from its disconnected state, the supply voltage increases, which When the voltage exceeds the battery voltage, power is supplied from the main power supply from then on, and at this time , supercapacitor 8 is charged by the main power supply.

[0008] In this way, the backup primary battery 5 and supercapacitor 8 can be used together. Therefore, if the power outage is for a short time, only the supercapacitor 8 can prevent the power outage of the memory circuit 4. Compensation can be performed and the life of the primary battery 5 can be extended.

[0009]

[Problem that the idea aims to solve]

In the conventional backup circuit described above, the primary battery 5 and the supercapacitor 8, connect the super capacitor directly to the power supply line 3 connected to the primary battery 5. Since the configuration connects the capacitor 8, current flows from the primary battery 5 to the supercapacitor 8. may be supplied.

0010 For example, if the circuit is stopped for a long period of time, the supercapacitor 8 will be in a discharged state. However, when starting up the circuit from now on, if the power supply from the main power supply is delayed, , a charging current flows from the primary battery 5 to the supercapacitor 8, but As a result, the life of the primary battery 5 is significantly shortened.

[0011] The present invention has been made in consideration of these problems of the conventional technology. The purpose is to use a backup battery and a supercapacitor together. When backing up memory circuits, etc., the connection from the battery to the supercapacitor An object of the present invention is to provide a backup circuit that can reliably prevent current flow.

0012

[Means to solve the problem]

In order to achieve the above object, the backup circuit of the present invention Insert a supercapacitor in the power supply path to backup target circuits such as memory circuits and clock circuits. At the same time, connect the target circuit from the connection point with the supercapacitor of this power supply line. A backflow prevention diode is installed in series on the side, and the back is placed on the cathode side of this diode. Connect the up battery via a backflow prevention diode.

[0013]

[Effect]

With the backup circuit configured as described above, if the main power supply is When disconnected, the target circuit is connected to the target circuit through the reverse current prevention diode from the supercapacitor. Current is supplied to the circuit, and battery power is also supplied to the target circuit from the backup battery. It will be done. The supercapacitor is charged only from the mains power supply, the target circuit side of the supercapacitor The current from the battery flows to the supercapacitor by the backflow prevention diode installed in the It is prevented from entering.

[0014]

【Example】

An example will be explained using FIGS. 1 and 2. In addition, the same symbols as above are the same. Or something equivalent shall be indicated. In FIG. 1 showing Embodiment 1, the difference from the conventional one is that from the power supply terminal 1 of the main power supply Two backflow prevention diodes are connected in parallel to the backflow prevention diode 2 provided in the power supply path to the memory circuit 4. A series circuit of stopping diodes 10 and 11 is connected to form a main power supply line. A supercapacitor 8 is connected between both diodes 10 and 11. be.

[0015] Normally, power is supplied to the memory circuit 4 by power supply from the power supply terminal 1 of the main power supply. supply, and if the power supply voltage drops below the rated voltage of supercapacitor 8 due to a power outage, etc. When the voltage drops, the memory circuit 4 is connected through the diode 11 by the supercapacitor 8. Retained. Furthermore, due to the discharge of the supercapacitor 8, the voltage becomes higher than the battery voltage of the primary battery 5. When the voltage decreases, the memory circuit 4 is held by the primary battery 5 through the diode 11. be done.

[0016] Also, when the power supply voltage is restored, the supercapacitor 8 is connected via the diode 10. Charged by mains power. On the other hand, if the circuit is restarted after being inactive for a long period of time, Even if power supply is delayed, current from the primary battery 5 will not flow into the supercapacitor 8. Since this is blocked by the diode 11, the power of the primary battery 5 is wasted. Things will go away.

[0017] FIG. 2 shows Embodiment 2, in which a diode is connected from the power supply terminal 1 in Embodiment 1. The power supply path from the main power supply to the power supply line 3 through the power supply line 2 is omitted, and from the main power supply to the memory circuit 4. The power is always supplied through two diodes 10 and 11. Ru. In addition, in the embodiment described above, the case of power failure compensation of the memory circuit 4 was explained. It is clear that the present invention can be similarly applied to the case of compensating for power outages in clock circuits, etc. Ru.

[0018]

[Effect of the idea]

Since the present invention is configured as explained above, it achieves the effects described below. do. The supercapacitor is charged only from the main power supply, and a backup battery is used. It is now possible to block the charging current from flowing to the supercapacitor with a backflow prevention diode. Therefore, conventional methods such as consuming battery power to charge supercapacitors It is possible to eliminate this problem and improve the life of the battery.

[Brief explanation of drawings]

FIG. 1 is a wiring diagram showing a first embodiment of a backup circuit according to the present invention.

FIG. 2 is a wiring diagram showing a second embodiment of the present invention.

FIG. 3 is a wiring diagram of a conventional example.

[Explanation of symbols]

4 Memory circuit 5 Primary battery 7 Backflow prevention diode 8 super capacitor 11 Backflow prevention diode

Claims (1)

[Scope of utility model registration request] Claim 1: A backup circuit for compensating for a power outage in a backup target circuit such as a volatile memory circuit or a clock circuit by using a backup battery and an electric double layer capacitor in combination, wherein the power supply path from the main power source to the target circuit is In addition to connecting a capacitor, a backflow prevention diode is provided in series on the target circuit side from a connection point with the capacitor of the power supply path, and the battery is connected to the cathode side of the diode via the backflow prevention diode. backup circuit.