JPH0962412A - Electronic equipment - Google Patents

Abstract

(57) 【Abstract】 PROBLEM TO BE SOLVED: To provide a function for carrying out charge control for quickly and surely charging a secondary battery incorporated as a drive power source for electronic devices regardless of the operating state of the device. An object is to provide an electronic device provided with the electronic device. In an electronic device equipped with a rechargeable battery as a power source, a device for detecting whether or not a charging device is connected, and a device for shifting the electronic device to a suspended state according to a detection result of the detection device. And means for starting charging of the battery after the electronic device has entered a suspend state.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic device having a structure for performing charge control for a built-in secondary battery of portable electronic devices and other small electronic devices.

In recent years, various types of portable electronic devices have become widespread, but these electronic devices are not limited by the place of use, and are particularly characterized in that they can be applied to a wide range of purposes regardless of the presence or absence of an external power source. I am trying.

Various batteries are indispensable as driving power sources for such portable electronic devices, and not only primary batteries but also
In particular, there is a demand for a secondary battery that is small and lightweight, has a large capacity, and can be charged and discharged many times.

Therefore, in this type of secondary battery,
It is strongly desired to establish a quick and reliable charging control means. One of the essential requirements for electronic devices powered by secondary batteries is that they are small and lightweight, and it is desirable that there be no interruption in the use of devices or that they be performed in the shortest possible time. Because it is rare.

[0005]

2. Description of the Related Art In such a battery-powered small electronic device, the capacity of the battery provided is limited. Therefore, when the battery capacity is reduced, the battery (primary battery) is replaced or the secondary battery is replaced. The battery capacity must be restored by charging the battery.

When the secondary battery is charged, it is charged by connecting a dedicated charger. However, in order to rapidly charge the secondary battery while the electronic devices are fully operating, the capacity of the charger is insufficient.

Therefore, in order to enable the rapid charging of the secondary battery, the power of the electronic devices should be completely cut off, or
Alternatively, it is necessary to shut off the main circuit except for the memory backup circuit, that is, in a so-called suspend state.

Also, when operating with an AC adapter attached to an electronic device, the current capacity of the AC adapter is not sufficient while the device is fully operating in the same manner.
The secondary battery can be charged only by a minute current, that is, trickle charging, for preventing the secondary battery from being consumed due to spontaneous discharge.

As described above, in the prior art, the charging operation can be performed only after confirming that the operating state of the electronic devices is chargeable and preparing in advance.

The electronic devices targeted here are often operated in a wide range by a large number of people who do not have special expertise in handling the devices themselves, apart from daily operations, so that they are simple and safe. Operational handling is desired.

[0011]

DISCLOSURE OF THE INVENTION The present invention provides a charge control which allows a secondary battery incorporated as a driving power source for electronic devices to be quickly and reliably charged regardless of the operating state of the device. It is an object of the present invention to provide an electronic device having a function for carrying out.

[0012]

In order to solve the above problems, the present invention provides a means for detecting whether or not a charging device 20 is connected in an electronic device equipped with a rechargeable battery as a power source, and A means for shifting the electronic device 10 to a suspended state according to a detection result of the detection means; and a means for starting charging of the battery after the electronic device 10 shifts to the suspended state. It is an electronic device.

The present invention also includes a power supply including a circuit for detecting that the charging device 20 is connected, and a circuit for forcibly shifting the electronic device 10 to the suspend state in response to detection of the type of the charging device 20. An electronic device including a control unit 1, wherein a charging method is selected and made executable according to an operating state of the electronic device 10.

According to the present invention, the charging device 20 is connected when the capacity shortage of the secondary battery power source 4 is revealed in the process of using the electronic device 10 by, for example, the remaining capacity display device. As a result, quick charging or operation by the AC adapter is automatically performed.

As a result, the charging device can be connected regardless of the usage state of the electronic device 10 such as the portable electronic device.

Therefore, it is possible to connect the charging device without requiring the operator to confirm the operating states of the devices in advance and request the charging preparation operation according to the predetermined operation procedure.

With such an operation, rapid charging with the main circuit 2 turned off or continuous operation with an AC adapter can be carried out safely and surely without consideration of data destruction.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a block diagram showing a basic configuration in which the present invention is applied to electronic devices. In the figure, 10 is an electronic device, and the electronic device 10 includes a charger 2
0 is connected. The charger 20 includes an AC adapter in addition to the original charger.

Reference numeral 1 is a power supply control circuit, and 2 is a main circuit that controls the operation of electronic devices. Reference numeral 3 is a DC-DC converter for supplying a direct current of a desired voltage to the main circuit 2. 4 is a secondary battery power source, D ₁ and D ₂ are backflow prevention diodes, and S ₁ is a charging switch.

The main circuit 2 includes input / output control, storage, arithmetic processing, display display, according to the functions of the electronic devices.
It controls various operations such as sound output and printing.
A circuit configuration suitable for performing the expected operation of the electronic device 10 is adopted.

The structure and expected function of such a circuit differ depending on each device, and a well-known circuit structure can be adopted.

The input side of the DC-DC converter 3 is
It is connected to the secondary battery power source 4 via the diode D ₁ and further connected to the charging device 20 via the diode D ₂ . A charging switch S ₁ is provided between the output of the charging device 20 and the positive and negative terminals of the secondary battery power source 4.

The DC-DC converter 3 converts the DC voltage received from the secondary battery power source 4 through the diode D ₁ into a DC voltage of a desired voltage and generates an output. The output voltage thus obtained is supplied to the main circuit 2 and
It becomes the drive source for executing the desired operation of.

The state of the output voltage of the DC-DC converter 3 is also fed back to the power supply control unit 1,
It is used to monitor the operating state of the main circuit 2 and the remaining capacity of the secondary battery power source 4.

The charger 20 is supplied with an external power source (not shown) and generates a DC output voltage corresponding to the output voltage of the secondary battery power source 4.

This DC output voltage is connected to the input side of the DC-DC converter 3 via the diode D ₂ and is selectively applied to the positive and negative terminals of the secondary battery power source 4 via the switch S _1. .

The power supply control unit 1 switches the operation of the main circuit 2 to a chargeable state based on the function of detecting the connection of the charger 20 and the detection result, and selects the switch S ₁ accordingly. It is equipped with a function for turning on the power.

When the main circuit 2 is in operation when the charger 20 is connected, the main circuit 2 is charged so that the main circuit 2 can be charged, for example, interruption of arithmetic processing, saving of data. And so on.

After that, the cut-off switch (not shown) of the electronic devices 10 included in the DC-DC converter 3 or the main circuit 2 is operated to bring it into the off state or the suspend state, and then the switch S ₁ is turned on. Turn on and shift to quick charging.

When an AC adapter is connected as a charging device and the main circuit 2 is in operation, the DC-DC converter 3 is operated through the diode D ₂ and the main circuit 2 is operated. Supply the desired voltage and current.

When the AC adapter is connected, the main circuit 2
When the power supply control unit 1 detects that the power supply control unit 1 is not in the operating state, that is, the power supply control unit 1 is in the off state or the suspended state, the power supply control unit 1 turns on the switch S ₁ to recharge the secondary battery power supply. 4 is charged.

When the secondary battery power source 4 has a sufficient capacity, it is not necessary to connect the charger 20 either.
The output of the secondary battery power supply 4 is DC− via the diode D _1.
The DC converter 3 is activated and the main circuit 2 is activated.

According to this structure, when the capacity shortage of the secondary battery power source 4 is revealed in the process of using the electronic device 10 by, for example, the remaining capacity display device (not shown), the charger 20 By connecting, the quick charging or the operation by the AC adapter is automatically performed.

As a result, the charging device can be connected regardless of the use state of the electronic device 10 such as the portable electronic device. Therefore, the charger can be connected without requiring the operator to confirm the operating state of the devices in advance and request the charging preparation operation according to the predetermined operation procedure. With such operations, quick charging or AC with the main circuit turned off
Continuing operation with the adapter will be carried out safely and surely without considering data destruction.

FIG. 2 is a diagram showing the configuration of the first embodiment of the present invention, and shows the circuit configuration for carrying out the charge control method according to the present embodiment. The same components as those in FIG. 1 are designated by the same reference numerals.

In this embodiment, the present invention is applied to a portable electronic device 100 such as a handy terminal, and the charger 2 is attached to the portable electronic device 100.
00 is connected.

In the figure, 1 is a power supply control circuit, and 2 is a main circuit which controls the operation of the portable electronic device 100. 3 is a D for supplying a direct current of a desired voltage to the main circuit 2.
It is a C-DC converter. In addition, 4 is a secondary battery power source,
D ₁ and D ₂ are diodes for preventing backflow, S ₁ is a switch, 200 is a charger, and C is a connector for connecting a charging device.

The main circuit 2 controls various operations such as input / output control, storage, arithmetic processing, display display, sound output, and printing according to the function of the portable electronic device 100, and is suitable for each. The circuit configuration is adopted.

The structure and expected function of such a circuit differ depending on each device, and a well-known circuit structure can be adopted, so a detailed description thereof will be omitted.

The input side of the DC-DC converter 3 is
It is connected to the secondary battery power source 4 via the diode D ₁ and connected to the connector C via the diode D ₂ . A switch S ₁ is provided between the connector C and the output of the secondary battery power source 4.

The DC-DC converter 3 generates a DC voltage of a desired voltage from the DC voltage received from the secondary battery power source 4 on the output side. The output voltage thus obtained is supplied to the main circuit 2 and serves as a drive source for executing a desired operation of the main circuit. The state of the output voltage is also fed back to the power source control unit 1 and used for monitoring the operating state of the main circuit 2 and the remaining capacity state of the secondary battery power source 4.

The charger 200 is supplied with an AC power supply (not shown) and generates a DC output voltage corresponding to the output voltage of the secondary battery power supply 4.

This DC output voltage is connected by the connector C, is connected to the input side of the DC-DC converter 3 via the diode D _2, and is selected as the terminal of the secondary battery power source 4 via the switch S _1. Is applied.

The power supply control unit 1 has a function of detecting that the charger 200 is connected to the connector C, and switches the operation of the main circuit 2 to a chargeable state based on the detection result.
It has a function of turning on the switch S ₁ accordingly.

When the main circuit 2 is in operation when the charger 200 is connected to the connector C, a process for bringing the main circuit 2 into a chargeable state, for example, interruption of arithmetic processing,
Perform processing such as saving data.

After that, the cut-off switch of the portable electronic device 10 included in the DC-DC converter 3 or the main circuit 2 is operated to be turned off or suspended, and at the same time, the switch S ₁ is turned on to shift to the rapid charging. .

When an AC adapter is connected to the connector C and the main circuit 2 is operating, the diode D ₂
The DC-DC converter 3 is operated via the
Supply the desired voltage and current.

When the AC adapter is connected, the main circuit 2
Is not in an operating state, that is, when the power supply control unit 1 detects that the power supply control unit 1 is in the off state or the suspend state, the switch S ₁ is turned on to charge the secondary battery power supply 4. .

When the secondary battery power source 4 holds a sufficient capacity, it is not necessary to connect the charger 200 either, and the output of the secondary battery power source 4 is D through the diode D _1.
The C-DC converter 3 is activated and the main circuit 2 is activated.

According to such a configuration, the portable electronic device 10
In the process of using 0, the capacity of the secondary battery power source 4 is insufficient,
When it becomes clear by a display device (not shown) or the like, by connecting the charger 200, quick charging or operation by an AC adapter is automatically performed.

FIG. 3 is a flow chart showing an operating state of the circuit configuration shown in FIG. Following the start of the flow, the determination as to whether or not the charger 200 has been connected is repeated (step S1). This determination is made in the power supply controller 1.

When the charger connection is confirmed in step S1, the power supply control unit 1 sends a request signal to the main circuit 2 to shift the operating state to the suspend state (step S2).

Then, in response to such a request, the determination of whether or not the main circuit 2 has completed the transition to the suspend state is repeated (step S3).

If it is confirmed in step S3 that the state has shifted to the suspend state, the switch S ₁ for charging is turned on to execute quick charging (step S3).
4).

As described above, according to this embodiment, the charger 20 can be used regardless of the operating state of the portable electronic device 100.
By connecting 0 to the connector C, the power supply control unit 1 automatically shifts to the suspend state according to the determination, and safe and quick rapid charging is performed.

FIG. 4 is a block diagram showing the configuration of the second embodiment of the present invention. Here, it is assumed that the electronic devices are the portable electronic device 100 as in the first embodiment. Note that the same reference numerals are used for the same components as in FIG.

In the portable electronic device 100, the first point is that the second switch S ₂ connected in series with the resistor R is connected in parallel with the switch S ₁ for charging in the first embodiment. Is different from the embodiment described above.

Further, the charging device 3 connected to the connector C
00 is a charger or an AC adapter. The other configuration is the same as that of FIG. 2, so the difference in operation will be described in detail below.

FIG. 5 is a flow chart showing the operating state of the circuit configuration shown in FIG. Following the start of the flow, the determination as to whether or not the charger as the charging device 300 or the AC adapter is connected is repeated (step S11). This determination is made in the power supply controller 1.

In step S11, the charger or AC
When the connection of any of the adapters is confirmed, the determination of whether or not the main circuit 2 is in the suspended state is repeated (step S12).

If it is confirmed in step S12 that it is in the suspended state, the switch S ₁ for charging is turned on to execute quick charging (step S1).
3).

On the other hand, if it is confirmed that the determination in step S12 is not in the suspend state, that is, the portable electronic device 100 is in the on state, the switch S ₂ connected in series with the resistor R is turned on ( Step S1
4).

When the switch S ₂ is turned on, the secondary battery power source 4 is output from the output terminal of the charging device 300 via the resistor R.
A charging circuit is formed between the positive and negative terminals of.

Therefore, the main current due to the voltage drop across the resistor R is DC-DC through the diode D _2.
The remaining current supplied to the converter 3 is supplied to the secondary battery power source 4
Is supplied to the battery, and so-called trickle charging is performed.

In this way, regardless of the operating state of the portable electronic device 100, by connecting the charging device 300 to the connector C, the power supply control unit 1 makes a determination that the rapid charging is performed in the suspended state ( In step S13), if it is in the operating state, trickle charging (step S14) is performed.

Even during this trickle charge, if the power consumption of the main circuit 2 decreases due to the transition of the main circuit 2 to the suspend state, the charging current automatically increases and the secondary battery is charged.

In the second embodiment, trickle charging or quick charging is automatically performed based on the determination and control of the power supply control unit 1, not only for the dedicated charger but also for the AC adapter.

[0068]

According to the charging control method of the present invention,
Quick charging can be performed by connecting the charging device without being aware of the operating state of the electronic devices. Therefore, even if the operator is unfamiliar, a quick and reliable charging process is performed.

In addition, the quick charge or the trickle charge is automatically selected according to the operating state of the electronic devices. Therefore, not only the dedicated charger but also the AC adapter can perform the quick charge in addition to the trickle charge.

As the AC adapter, a commercially available one or an already used one can be used. Therefore, a dedicated charger usually attached to the device can be omitted, and the electronic device can be omitted. It is possible to reduce the cost of the class.

[Brief description of drawings]

FIG. 1 is a basic configuration diagram of a charge control system according to the present invention.

FIG. 2 is a configuration diagram of electronic devices for implementing the charging control method according to the first embodiment of the present invention.

FIG. 3 is a control flow chart of the first embodiment of the present invention.

FIG. 4 is a configuration diagram of electronic devices for implementing a charge control method according to a second embodiment of the present invention.

FIG. 5 is a control flow chart of the second embodiment of the present invention.

[Explanation of symbols]

1 Power Supply Control Section 2 Main Circuit 3 DC-DC Converter 4 Secondary Battery Power Supply D _1, D ₂ Diodes S _1, S ₂ Switch 10 Electronic Device 20 Charging Device (Charger)

Claims (2)

[Claims] 1. An electronic device equipped with a rechargeable battery as a power source, means for detecting whether or not a charging device is connected, and a transition of the electronic device to a suspend state according to a detection result by the detecting means. An electronic device comprising: means for causing the electronic device to start charging of the battery after the electronic device transitions to a suspended state. 2. An electronic device comprising: a power supply control unit including a circuit for detecting that the charging device is connected, and a circuit for forcibly shifting the electronic device to a suspend state in response to detection of the type of the charging device. An electronic device, wherein a charging method is selected and made executable according to the operating state of the electronic device.