JP2001103740A - Power source circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power source circuit for obtaining a sufficiently operating time in a stand-by by reducing a drive loss in a DC-DC converter in stand-by. SOLUTION: A main DC-DC converter 12 is connected to a rear stage of a main battery 2, and a back-up DC-DC converter 13 is connected to the rear stage of a back-up battery 3. The converter 13 adopts a circuit configuration using component specified for a small load in stand-by state, can supply power for the stand-by in its capability, and has a small ratio of a drive loss to a load smaller than the converter 12. A detection switching circuit 11 detects the capacity of the battery 2, and switches the input power source from the battery 2 to the battery 3, turns OFF the converter 12, and turns ON the converter 13.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply circuit in a device such as a portable terminal that operates using a battery as a power supply source, and also includes a backup battery.

[0002]

2. Description of the Related Art Conventionally, in a power supply unit of a device such as a portable terminal which operates using a battery as a power supply source, a power supply circuit having two power supply sources of a main battery and a backup battery and one DC-DC converter is provided. Are known. FIG. 4 shows such a conventional power supply circuit. 4, a power supply circuit 1 includes a main battery 2, a backup battery 3, a detection circuit 4, an input switching circuit 5, and a DC-D
The DC-DC converter 6 is connected to a load 7.

The detection circuit 4 detects the capacity of the main battery 2 by detecting the voltage of the main battery 2. The input switching circuit 5 switches whether the DC-DC converter 6 is connected to the main battery 2 or the backup battery 3. Power is supplied to the DC-DC converter 6 from the main battery 2 or the backup battery 3.

The switching of the battery is performed by detecting the capacity of the main battery 2 by the detection circuit 4 and controlling the input switching circuit 5 based on the result. That is, when the voltage of the main battery 2 is higher than the battery voltage detection reference value, a signal for connecting the main battery 2 and the DC-DC converter 6 is sent from the detection circuit 4 to the input switching circuit 5. When the voltage of the main battery 2 is lower than the battery voltage detection reference value, the main battery 2 and the DC-DC
The signal for connecting the converter 6 is cut off, and a signal for connecting the backup battery 3 and the DC-DC converter 6 is sent. The connected battery 2 or 3 supplies power to the load 7 via the DC-DC converter 6. The load 7 is a load of a device such as a portable terminal, for example, a CPU.
And an LCD (Liquid Crystal Display).

[0005] In general, in a portable terminal, the load state is roughly divided into two states. That is, the operation state is divided into an operation state in which the operation is started and the LCD is displayed, and a standby state in which the operation and the LCD are stopped and only the memory and the clock are held. Comparing the magnitude of the load in both states, the magnitude of the load is much greater in the operating state than in the standby state.

On the other hand, when the main battery 2 is used as a power supply source, both an operating state and a standby state are possible. When the capacity of the main battery 2 is exhausted and the backup battery 3 is used as a power supply source, the operation state is not possible and only the standby state is possible, so that the load is kept to a minimum and the drive is performed for a long time. I have. In FIG. 4, when the main battery 2 is used as a power supply source, a power-on OK signal is turned on from the detection circuit 4 to the CPU to enable an operation state. If the backup battery 3 is used as a power supply, power on OK
By turning off the signal, the operation state is prohibited, and power management control is performed to limit the operation state to only the standby state.

[0007]

In the power supply circuit shown in FIG. 4, it is necessary to design a circuit of the DC-DC converter 6 according to a large load in an operating state. That is, DC
-FET (field effect transistor) of DC converter 6
It is necessary to select components that can supply a large load to components such as ICs and ICs. However, components capable of supplying a large load have a large drive loss, and the ratio of the drive loss to a small load in a standby state is large. Therefore, there is a problem that a sufficient operation time cannot be obtained in the standby state.

[0008]

In order to solve the above-mentioned problems, the present invention has a main battery and a backup battery, and when the capacity of the main battery falls below a reference value, the backup battery supplies power to a load. In a power supply circuit for supplying, a first DC-connected to a main battery and adapted to a load driven when the main battery operates.
Connected to DC converter and backup battery,
A second DC-DC converter adapted to a load driven during operation of the backup battery, and detecting a capacity of the main battery, and driving the first DC-DC converter when the capacity of the main battery is equal to or more than a reference value; When the capacity of the main battery is equal to or less than the reference value, the second DC-DC
And a detection switching circuit for driving the converter.

According to the above configuration, when the input power supply is switched from the main battery to the backup battery, the operation is switched to the second DC-DC converter having a small drive loss with a light load, so that the drive loss in the power supply section can be reduced. .

[0010]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a power supply circuit according to the embodiment. In FIG. 1, a power supply circuit 10 of the embodiment includes a main battery 2, a backup battery 3, a detection switching circuit 11, a main DC-DC converter 12, a backup DC-DC converter 13, and an FET 14. It is connected to the. The main DC-DC converter 12 is connected downstream of the main battery 2 and has a circuit configuration using components capable of supplying a large load in the operating state of the device.

The backup DC-DC converter 13 is connected to the subsequent stage of the backup battery 3 and has a circuit configuration using components specialized for a small load in a standby state. The backup DC-DC converter 13 can supply power only in a standby state in terms of performance,
As compared with the C-DC converter 12, the ratio of the drive loss to a small load is small. Therefore, driving in the standby state can be maintained for a long time. The two DC-DC converters 12 and 13 are connected between outputs via an FET 14.

The detection switching circuit 11 detects the capacity by detecting the voltage of the main battery 2 and outputs the following signal. That is, an on / off signal for the main DC-DC converter 12 and the backup DC-DC converter 13, a power-on OK signal for the load 7, and an on / off signal for the FET 14. Main DC-DC converter 12,
The backup DC-DC converter 13, the load 7, and the FET 14 receive the signal of the detection switching circuit 11 and perform respective operations.

Next, the operation will be described. Power is supplied from the main battery 2 to the main DC-DC converter 12. Power is supplied from the backup battery 3 to the backup DC-DC converter 13. Battery 2,
3, the DC-DC converters 12, 13 are selected by detecting the capacity of the main battery 2 by the detection switching circuit 11,
14 is controlled by turning on / off.

When the voltage of the main battery 2 is equal to or higher than the battery voltage reference detection reference value, the detection switching circuit 11 turns on the main DC-DC converter 12 and turns on the backup DC
A signal to turn off the DC converter 13 and turn on the FET 14 is sent, and power is supplied to the load 7 via the main DC-DC converter 12 and the FET 14 using the main battery 2 as an input power supply. At this time, the detection switching circuit 1
From 1 to the CPU of the apparatus, the power-on OK signal is turned on to enable the operation state.

When the voltage of the main battery 2 is lower than the battery voltage reference detection reference value, the detection switching circuit 11 turns off the main DC-DC converter 12 and turns off the backup DC
A signal to turn on the DC converter 13 and turn off the FET 14 is sent, and power is supplied to the load 7 via the backup DC-DC converter 13 using the backup battery 3 as an input power supply. At this time, the power-on OK signal is turned off and the operation state prohibition signal is sent from the detection switching circuit 11 to the CPU of the apparatus, thereby enabling only the standby state.

FIG. 2 is a time chart showing the operation of the power supply circuit when the voltage of the main battery 2 exceeds the battery voltage detection reference value during charging or when a battery is mounted. 2, when the detection switching circuit 11 detects that the voltage of the main battery 2 has exceeded the battery voltage detection reference value, it turns on the main DC-DC converter 12, subsequently turns on the FET 14, and turns on the backup DC-DC converter. 13 is turned off, and finally the power-on OK signal is turned on.

FIG. 3 shows the state when discharging or removing the battery.
In FIG. 3, the detection switching circuit 11 includes a main battery 2
, The power-on OK signal is turned off, then the backup DC-DC converter 13 is turned on, and the FET 14 is turned on.
Is turned off, and finally the main DC-DC converter 12 is turned off.

When the DC-DC converters 12 and 13 are switched, a timing in which both the DC-DC converters 12 and 13 are turned on is created to eliminate the time when power is not supplied. At the same time backup DC
-Control is performed so as not to be in the operating state when the power is supplied by the DC converter 13. Thereby, DC-D
It is possible to prevent a problem that the output cannot be supplied when the C converters 12 and 13 are switched and the voltage drops.

[0019]

As described above, according to the present invention, a first DC-DC converter connected to a main battery and adapted to a load driven when the main battery is operated, and connected to a backup battery to operate the backup battery A second DC-DC converter adapted to the load to be driven at times and a capacity of the main battery are detected, and when the capacity of the main battery is equal to or more than a reference value, the first DC-DC converter is driven and a capacity of the main battery is detected. When the input power is switched from the main battery to the backup battery, the DC-DC converter is also adjusted to the load driven when the backup battery is operating. Switching to the second DC-DC converter with small driving loss, Loss can be greatly reduced of. Therefore, the operation time of the device when the backup battery is used as the input power can be extended. Further, at the time of battery switching, there is no problem such as a drop in output voltage.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a power supply circuit according to an embodiment.

FIG. 2 is a time chart showing the operation of the power supply circuit when the voltage of the main battery exceeds a battery voltage detection reference value.

FIG. 3 is a time chart showing the operation of the power supply circuit when the voltage of the main battery falls below a battery voltage detection reference value.

FIG. 4 is a block diagram showing a conventional power supply circuit.

[Explanation of symbols]

 2 Main Battery 3 Backup Battery 7 Load 11 Detection Switching Circuit 12 Main DC-DC Converter 13 Backup DC-DC Converter

Claims (2)

[Claims] 1. A power supply circuit having a main battery and a backup battery, wherein the power supply circuit supplies power to a load from the backup battery when the capacity of the main battery becomes less than a reference value. A first DC-DC converter adapted to the load driven at the time; a second DC-DC converter connected to the backup battery and adapted to the load driven at the time of operation of the backup battery; A detection switching circuit for driving the first DC-DC converter when the capacity of the battery is equal to or more than the reference value, and for driving the second DC-DC converter when the capacity of the main battery is less than the reference value; A power supply circuit characterized in that: 2. A power supply circuit having a main battery and a backup battery, wherein the power supply circuit supplies power to the load from the backup battery when the capacity of the main battery falls below a reference value. A first DC-DC converter adapted to the load driven at the time; a second DC-DC converter connected to the backup battery and adapted to the load driven at the time of operation of the backup battery; When the battery capacity is less than the reference value, the first DC-DC converter is switched to the second DC-DC converter, and at the time of the switching, the first and second DC-DC converters are driven together. A power supply circuit, comprising: a detection switching circuit that generates a time zone in which the power supply circuit operates.