JPH0670486A - Battery switching-over circuit for electronic apparatus - Google Patents

Abstract

PURPOSE:To reduce the size and cost of a battery switching-over circuit for electronic apparatuses, wherein the battery used as the power supply of a portable electronic apparatus is switched over to an auxiliary battery when the voltage of the battery is lowered, by performing logically the switchover to the auxiliary battery through a gate IC. CONSTITUTION:A gate IC 4 has the flow-out current larger than the current necessary for maintaining the operation of a specific part 3 of an electronic apparatus, whose power supply requires a backup. The gate IC 4 is used as a battery switching-over circuit, and an auxiliary battery 2 for the backup is used as the power supply of the gate IC 4. Ordinarily, the current from a main battery 1 is given via a diode OR circuit 5 to the specific part 3 requiring the backup, and the reduction of the voltage of the main battery 1 is sensed on the input side of the gate IC 4. When the voltage of the main battery 1 becomes not higher than the threshold voltage of the gate IC 4, the flow-out current of the gate IC 4, which has the auxiliary battery 2 as its power supply, is given via the diode OR circuit 5 to the backed-up load 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic device such as a portable terminal device for maintaining operation of a specific portion of the electronic device when the voltage of a battery used as a power source drops, for example, for protecting data stored in a memory. The present invention relates to a battery switching circuit for an electronic device that switches to a sub battery.

[0002]

2. Description of the Related Art Many portable terminal devices equipped with a storage device use a rechargeable nickel-cadmium battery (hereinafter referred to as a Nicd battery) as an operating power source. This type of terminal equipment often used four Nicd batteries, but nowadays in order to reduce the weight of the terminal equipment,
The number of Nicd batteries may be two. This is because the weight of the terminal device largely depends on the number of batteries, and it is desired to reduce the weight of the device by reducing the number of batteries to the necessary minimum.

By the way, in this kind of terminal equipment,
In order to protect the contents stored in the memory when the voltage of the Nicd battery drops, it is usually equipped with a sub battery. A lithium battery or a mercury battery is generally used as the sub battery. These sub batteries are used only for backing up the memory, and when the voltage of the Nicd battery drops below a predetermined voltage, the sub battery works as a backup power source for the memory. Here, as mentioned above,
When the number of Nicd batteries is four, for example, two diodes are used as diode ORs, and a circuit that uses a Nicd battery with a high voltage as a power source is usually formed. When the voltage becomes lower than the voltage of a battery, for example, a lithium (L _i ) battery, a circuit using the L _i battery as a power source is formed. In other words, four Nicd
Voltage when the in series connected batteries is 4.0V～5.6V, which normally the voltage of the L _i cell is sub-battery is 3.0 V (mercury battery is 3.2 V) for the power supply a Nicd battery Is formed, and when the voltage of the Nicd battery drops to 3.0 V or less, a circuit using the sub battery as a backup power source for the memory is formed. Note that a memory backup voltage of 2 V or higher is usually required.

However, in this type of terminal device, the weight of the battery is a major obstacle to the weight reduction of the entire device, and at present, two Nicd batteries (2.0 V to 2.8 V) are used. There are cases.

However, the voltage connected in series two battery Nicd battery is about 2.0V～2.8V, secondary battery (L _i batteries 3.0 V, mercury battery 3.2 V) due to low voltage than was the In the battery switching system using the diode OR, a circuit using the sub battery as a power source is formed even in the normal time, and thus this switching system cannot be adopted. Therefore, as shown in FIG. 3, the transistor T _r1 ,
A switching circuit using T _{r2, a} comparison circuit CMP, an inverter IN, and the like is configured, and the comparator CMP compares the voltage of the Nicd battery with a predetermined constant voltage V _c, and the voltage of the Nicd battery is higher than V _c. when large, the output of the comparator CMP as "0", turns on the transistor T _r1, by turning off the transistor T _r2, to form a circuit for the power supply Nicd battery. On the other hand, the voltage of the Nicd battery is lowered, V _c
When it becomes smaller than the above, the output of the comparator CMP becomes "1", the transistor T _r1 is turned off, the transistor T _r2 is turned on, and the circuit using the sub battery (L _i battery in this figure) as a power source. To form.

[0006]

As described above, in the prior art, the number of Nicd batteries has been reduced in order to reduce the weight of the terminal equipment, so that a sub-battery as a backup power source for the memory when the voltage of the Nicd batteries drops. As a switching circuit for switching to, the circuit shown in FIG. 3, for example, is required. The switching circuit shown in FIG. 3 requires the transistors T _r1 and T _r2 , the comparator CMP, etc., and thus requires a large mounting space, which hinders downsizing of the entire device and also causes a cost problem. was there.

According to the present invention, a main battery as an operating power supply for an electronic device is provided with a sub-battery having a higher voltage than the main battery as a backup power supply for a specific portion of the electronic device when the voltage of the main battery drops. By logically switching from the main battery to the sub battery by means of a gate IC, cost reduction can be achieved, and the electronic device can be downsized by reducing the mounting space for the electronic device. Is intended.

[0008]

FIG. 1 is a diagram for explaining the principle of the present invention. In the figure, reference numeral 1 is a rechargeable main battery, and this main battery is used as an operating power source for the entire portable electronic device to which the present invention is applied. Reference numeral 2 is a sub-battery that backs up a specific portion 3 in the portable electronic device (a portion requiring a backup of the power supply, which will be referred to as a backup load hereinafter) when the voltage of the main battery 1 becomes a predetermined value or less. , Is also used as a power source for the gate IC 4.

A Nicd battery or the like is used as the main battery 1, but in order to reduce the weight of electronic equipment, the number of cells is kept to the minimum necessary for operation. Here, two cells (two voltage values 2.0 V to 2.8V), and since the secondary battery 2 is used only for backup of the power source of the backup load 3, it has almost no effect on the weight or size of the entire electronic device.
_i batteries (3.0V) and mercury batteries (3.2V) are used. Therefore, when the main battery 1 is composed of two Nicd batteries, the voltage of the sub battery 2 is higher than the voltage of the main battery 1.

Further, in FIG. 1, when the voltage of the main battery 1 becomes lower than a predetermined voltage (lower than the threshold voltage of the gate IC4), the gate IC4 changes its output from "L" level to "H" level. Further, in FIG. 1, reference numeral 5 denotes a diode OR circuit composed of diodes 5 ₁ and 5 ₂ , and the current from the main battery 1 is applied to the backup load 3 through the diode 5 ₁ in the forward direction along the path of i _1. The
On the other hand, the current flowing out of the gate IC using the sub battery 2 as a power source is given to the backup load 3 via the diode 5 ₂ in the forward direction along the path of i ₂ .

By the way, the relationship between the current required to back up the backup load 3 and the outflow current (fan-out) of the gate IC 4 is, for example, that the content of the backup load is stored in a memory using a normal CMOS. When it comes to protection, the current required for it is usually about several tens of MA, while CMOS
The flow-out current (fanout) of a standard specification IC (for example, an inverter, a NAND gate, etc.) using a large value is 1.6 mA, and the present invention focuses on this point.

[0012]

When the main battery 1 has a normal voltage, the backup load 3 is also supplied with a current through the path i ₁ in FIG. 1 by using the main battery 1 as a power source and maintains its operating state. The voltage of the main battery 1 drops, and eventually the gate IC
When the voltage goes below the threshold voltage of 4, the gate IC4
Output changes from "L" level to "H" level. As a result, the gate IC 4 powered by the sub-battery 2 supplies i
_The current starts to flow through the _second path. At this time, the diode 5 ₁
Becomes a reverse bias, the flow of current from the main battery 1 is blocked, and the current flowing out from the gate IC 4 is given to the backup load 3. Since the current (fan-out) flowing out from the gate IC 4 is large enough to maintain the operating state of the backup load 3 as described above, the backup load 3 can be backed up.

In this way, when the voltage of the main battery drops, it is possible to switch from the main battery to the sub battery by using the standard specification gate IC.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to FIG. In this embodiment, a case where the present invention is applied to data protection (memory backup) of a memory of a portable terminal will be described as an example.

In FIG. 2, reference numeral 11 denotes two Nicd batteries connected in series, the negative side is grounded, and the positive side is connected to the memory 13 as a backup load through the diode 12 ₁ in the forward direction. 14 is a standard CMO
S is a gate IC (in this embodiment, an inverter is used), and this gate IC has a characteristic as a Schmitt circuit here. This gate IC1
4 as (hereinafter referred to inverter 14) is a power source, L _i battery 15 is a secondary battery for memory backup is used, the resistance voltage of the Nicd battery 11 on the input side 1
The voltage V divided by 6 ₁ , 16 ₂ is applied.

The output side of the inverter 14 is connected to the memory 13 via the diode 12 ₂ in the forward direction. The diodes 12 ₁ and 12 _{2 form} a diode OR.

In such a structure, the terminal device is normally adapted to perform various operations by using the Nicd battery 11 as a power source, and also applies a predetermined voltage to the memory 13. In this case, the current from the Nicd battery 11 is applied to the memory 13 via the path i ₁ in FIG.

Then, by using the terminal device, the Nicd battery 1
When the voltage of 1 (normally set to 2.8 V in two series connection) is reduced and the divided voltage V becomes V <V _HL with respect to the threshold voltage V _{HL of the} inverter 14, The output of the inverter 14 changes from "0" to "1". As here supply of the inverter 14, the use of the L _i battery (voltage 3.0 V) as a backup power supply, current is given by the path of i ₂ with respect to the memory 13 from L _i battery 15. That is, the diode 12 ₁ is reverse-biased, the current flow from the Nicd battery 11 side is blocked, and L
An outflow current is given from the inverter 14 using the _i battery 15 as a power source. The current flowing out from the inverter 14 (fan-out) is the standard specification CM as described above.
Since the gate IC of the OS (inverter is used here) has a large characteristic of 1.6 mA (the current required for memory backup is as low as several 10 MA as described above), the memory 13 can be backed up.

In this way, the fanout of the inverter 14 with respect to the current required to back up the memory 13
It is large enough and the threshold voltage of the inverter 14 is used to change the logic output, so that
When the voltage of the Nicd battery 11 becomes a predetermined voltage or less, it can be switched to L _i batteries as secondary batteries, can be protected in the data stored in the memory 13.

Further, in this embodiment, the inverter 1
4 was used one having characteristics as Schmitt circuit is the voltage drop of Nicd battery 11, after switching to L _i battery, a voltage comes to recovering the characteristics of Nicd battery 11, thereby again Nicd It switches to the battery 11 side, such as that immediately switched to L _i battery side,
The reason is that frequent switching operations are not performed.
As a result, "L" to "H" of the inverter 14,
It is possible to prevent noise from being generated due to frequent changes from “H” to “L”.

In the above embodiment, the case where the memory is used as the backup load and the inverter is used as the gate IC has been described as an example. However, the present invention is not limited to this, and the current flowing out of the gate IC is A gate IC having a current larger than the current required to back up the backup load may be used. In this embodiment, the Nicd battery is used as the normally used battery (main battery) and the lithium battery is used as the backup auxiliary battery. However, the present invention is not limited to this. In short, the main battery, the sub battery, the gate IC, etc. can be appropriately selected in consideration of their respective characteristics according to the type of the electronic device to which the present invention is applied and the load for power backup.

[0022]

According to the present invention, with respect to a main battery as an operating power source of an electronic device, a secondary battery having a high voltage by the main battery serves as a backup power source for a specific portion in the electronic device when the voltage of the main battery drops. In the case of having a battery, the switching from the main battery to the sub battery is performed by using the IC gate, and the mounting space is significantly reduced compared to the conventional switching circuit using a transistor or a comparator. Therefore, the electronic device can be downsized and the cost can be reduced.

[Brief description of drawings]

FIG. 1 is a configuration diagram illustrating the principle of the present invention.

FIG. 2 is a configuration diagram illustrating an embodiment of the present invention.

FIG. 3 is a configuration diagram of a conventional switching circuit.

[Explanation of symbols]

 1 Main Battery 2 Sub Battery 3 Backup Load 4 Gate IC 5 Diode OR

Claims (2)

[Claims] 1. A main battery (1) as an operating power source for an electronic device, wherein the main battery (1) is used as a backup power source for maintaining operation of a specific portion (3) of the electronic device when the voltage of the main battery (1) drops. A sub-battery (2) having a voltage higher than the normal voltage of the main battery (1), wherein the sub-battery (2) has a flow-out current larger than the current required to maintain the operation of the specific portion (3) of the electronic device, and The battery (2) is used as a power source, and a gate IC (4) and a diode OR (5) for receiving the output of the gate IC (4) and the output of the main battery (1) are provided. The voltage is detected at the input side of the gate IC (4), and when the voltage of the main battery (1) becomes less than or equal to the threshold voltage of the gate IC (4), the gate IC ( 4) The current flowing out from A battery switching circuit for an electronic device, wherein the battery switching circuit is provided to a specific portion (3) of the electronic device via an ion or (5). 2. The battery switching circuit for electronic equipment according to claim 1, wherein the gate IC is a gate IC having characteristics as a Schmitt circuit.