JP2005261142A - Charging circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a charging circuit for selecting an external power supply with a margin for a supply current and an external power supply with a limited supply current, always charging in the minimum time at the maximum charging current if the power supply with the margin for the supply current is selected and charges, and preventing the external power supply from being damaged without a complicated control for a system circuit if the external power supply with the limited supply current is selected and charges. <P>SOLUTION: The charging circuit includes a connector for connecting at least the first and second external power supplies, first and second reverse current preventing means for preventing a reverse current to the first external power supply, a third reverse current preventing means for preventing a reverse current to the second external power supply, a charge controlling means for controlling from a current from the first or second external power supply and outputting it to a secondary battery, a power supply detecting means for the existence of the first external power supply, and a fourth reverse current preventing means for connecting or disconnecting between the secondary battery and the system circuit in accordance with an instruction from the power supply detecting means. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a charging circuit, and more particularly to a charging circuit that performs charging by selecting a plurality of external power sources.

A charging circuit for charging an electronic device equipped with a rechargeable secondary battery is widely known. A typical charging circuit is shown in FIG. 701 is a connector, 702 is an external power supply, 703 is a charge control means, 704 is a system circuit, and 705 is a secondary battery.
The external power source 702 supplies a charging current. The connector 701 is for connecting an external power source 702. The charge control circuit 703 controls the amount of current supplied from the external power supply 702. The system circuit 704 is a circuit that operates by receiving a current supply from the charging control unit 703 or the secondary battery 705.
The external power source 702 is connected to the charging control unit 703 via the connector 701. The output from the charging control means 703 is connected to the secondary battery 705 and the system circuit 704.

In a state where the external power supply 702 is not connected, the system circuit 704 operates by receiving a current supplied from the secondary battery 705. When the external power source 702 is connected to the connector 701, the external power source 702 starts supplying current to the charging control means 703 through the connector 701.
In a general lithium ion battery used for a mobile phone or a portable information terminal, it is necessary to limit a charging current in order to prevent destruction of the battery cell. The charging control means 703 also performs such charging current control. For example, when charging a battery with a capacity of 600 mAh, the charging control means 703 sets the charging current to a maximum of 600 mA and outputs it.

Therefore, in the configuration of FIG. 7, since both the secondary battery 705 and the system circuit 704 are connected to the output of the charging control means 703, the output current 600mA from the charging control means 703 is used for charging the secondary battery. It is used for the purpose of driving the system circuit 704.
In this configuration, since there is only one current supply path passing through the charging control unit 703, the amount of current supplied from the external power source 702 does not exceed 600 mA set by the charging control unit. USB (Universal), an interface standard widely used in recent years
(Serial Bus) defines the current that can be supplied by the standard. When the USB interface is used as the external power source 702, the system circuit 704 is designed to operate within the range in which the USB current can be supplied. There is an advantage that can be charged with.

However, if the system circuit 704 is not a circuit specially designed to operate on the assumption that current is supplied from the USB, but is a general circuit, as described above, the charging current is determined by the system circuit 704. It will change depending on the operating state.
The charging current to the secondary battery 705 is a value obtained by subtracting the consumption current of the system circuit 704 from 600 mA set by the charging control means. The larger the consumption current of the system circuit 704, the smaller the charging current. The time will be longer. Furthermore, there is a disadvantage that charging is not performed at all when the consumption current of the system circuit 704 is 600 mA or more.

In order to prevent such a situation, it is only necessary to limit the operation of the system circuit 704 and suppress the current consumption. However, since the operation of a mobile phone or a personal digital assistant is actually complicated, It is difficult to perform control so that the current consumption is always kept low in any case during use. In addition, performing control to reduce current consumption may lead to a limitation of usable functions. For example, in a mobile phone, there is a possibility that inconvenience such as inability to perform a call that is a function requiring a large current consumption during charging may occur.

  Many proposals are being made to solve such problems (see, for example, Patent Document 1).

The prior art disclosed in Patent Document 1 will be described with reference to FIG. In FIG. 8, 801 is an external power supply, 802 is a DC plug, 803 is a socket connector, 803a is a first connection terminal, 803b is a second connection terminal, 803c is a movable piece, 804 is a charging control means, and 805 is a secondary power supply. 806 is a switch means, 807 and 808 are resistors, 809 is a system circuit, and 810 is a backflow prevention means.
The DC plug 802 is for connecting an external power source 801. The socket connector 803 is connected to a DC plug 802.

The external power source 801 is assumed to be an AC adapter, and is connected to a DC plug 802 by a cable and can be supplied with current by being inserted into a socket connector 803.
The inside of the socket connector 803 includes a first connection terminal 803a, a second connection terminal 803b, and a movable piece 803c. The first connection terminal 803 a is a positive terminal (hereinafter referred to as VCC) connection terminal, and is connected to the backflow prevention unit 810 and the charge control unit 804. Here, the backflow prevention means 810 is assumed to be a diode.
The second connection terminal 803b is a connection terminal on the negative electrode side (hereinafter referred to as GND). The movable piece 803c constitutes a contact switch that contacts the second connection terminal 803b. When the DC plug 802 is not inserted, the movable piece 803c contacts the second connection terminal 802b and the DC plug 802 is inserted. When it is, the mechanism is such that it is separated from the second connection terminal 802b. The movable piece 803c controls the switch means 806 via a resistor 808.
In the prior art shown in Patent Document 1, the switch means 806 is assumed to be a P-channel MOS field effect transistor (hereinafter simply referred to as PMOSFET). Hereinafter, the switch means 806 will be described as a PMOSFET 806.

  The output of the charging control means 804 is connected to the secondary battery 805 and the drain of the PMOSFET 806. The source of the PMOSFET 806 is connected to the backflow prevention means 810, the system circuit 809, and the resistor 807. The gate of the PMOSFET 806 is connected to a resistor 807 and a resistor 808.

  When the DC plug 802 is not inserted, the second connection terminal 803b and the movable piece 803c are in contact with each other, and the gate of the PMOSFET 806 is at the GND level via the resistor 808. As a result, the PMOSFET 806 enters a connected state, and current is supplied from the secondary battery 805 to the system circuit 809.

  In the state where the DC plug 802 is inserted, the source of the PMOSFET 806 through the backflow prevention means 810 is at the VCC level. Since the second connection terminal 803b and the movable piece 803c are separated from each other, the gate of the PMOSFET 806 is set to the VCC level by the resistor 807. As a result, the PMOSFET 806 is disconnected and current from the external power source 801 does not flow into the secondary battery 805 through the PMOSFET 806.

The first connection terminal 803a is also connected to the charging control means 804. DC plug 802
Is inserted, the charging control means 804 controls the current supplied from the external power source 801 and charges the secondary battery 805 with a constant current. At this time, since the PMOSFET 806 is in a disconnected state, the charging current supply path is only from the charging control means 804, and charging is performed only with a controlled constant current, and the secondary battery 805 is not broken. Absent.

  Furthermore, when the DC plug 802 is inserted, the current supplied to the system circuit 809 and the current used for charging are supplied separately, so that the secondary battery can be driven at the maximum current amount regardless of the current consumption amount of the system circuit 809. 805 can be charged. Therefore, it is not necessary to limit the function of the system circuit 809 during charging, and charging can always be performed in the shortest time.

JP 2001-190034 (page 2-3, FIG. 1)

However, in the prior art disclosed in Patent Document 1, since the amount of current supplied from the external power source 801 is the sum of the charging current and the consumption current of the system circuit 809, it is difficult to estimate the maximum amount of current that can be passed.
Although it is good to use an external power source 801 that has a sufficient supply capacity such as an AC adapter, a system circuit that requires a current supply amount defined by the standard, such as a USB, is used. Depending on the operation state of 809, the specification may be exceeded, and the USB host side (for example, the personal computer main body) may be damaged.
For example, when charging is performed from a USB having a current limit of 500 mA, and the charging current is set to 400 mA, the control for suppressing the current consumption to 100 mA or less in the system circuit 809 becomes very complicated. Conversely, it may be possible to control the charging current according to the operation of the system circuit 809, but this is also difficult.

  In the case of a charging circuit that performs charging by selecting a power source that can provide a sufficient supply current, such as an AC adapter, and a power source that has a current limit, such as a USB, the general technique shown in FIG. When charging from USB, there is an advantage that it is not necessary to charge while controlling the operation state of the system circuit 704, but when charging from the AC adapter, a sufficient charging current can be supplied Nevertheless, there is a problem that charging in the shortest time is not possible.

  On the other hand, when the configuration of the conventional technique shown in Patent Document 1 is adopted, when charging from the AC adapter is selected, charging can be performed in the shortest time regardless of the operating state of the system circuit 809. If the system circuit 809 operation is not complicatedly limited, the amount of current that can be supplied in the USB standard will be exceeded depending on the operating state of the system circuit 809, and the USB host side There is a risk of breaking.

  In other words, there is a problem that efficient and safe charging cannot be performed from a plurality of external power sources having different characteristics, regardless of which of the conventionally known techniques is used.

  In order to solve this problem, an object of the present invention is to provide a supply current in a charging circuit that performs charging by selecting an external power supply having a supply current margin and an external power supply having a restriction on the supply current. When charging from the power source is selected, charging is always performed with the maximum charging current in the shortest time, and when charging from an external power source with limited supply current is selected, the system circuit is complicated. An object of the present invention is to provide a charging circuit that does not destroy an external power source without performing control.

  In order to achieve the above object, the charging circuit of the present invention employs the structure shown below.

In a charging circuit having an external power supply, a system circuit, a connector connectable to the external power supply, a charge control means, a power supply detection means, a secondary battery, and a backflow prevention means for preventing a backflow of current,
The backflow prevention means has a first backflow prevention means, a second backflow prevention means, a third backflow prevention means, and a fourth backflow prevention means,
The first backflow prevention means, the second backflow prevention means, and the third backflow prevention means prevent a backflow of current to the external power source, and the fourth backflow prevention means includes a backflow of current to the charge control means and the secondary battery. Prevent
The connector has a structure that can be connected to at least the first external power source and the second external power source, the power source detecting means detects the presence or absence of voltage supply from the first external power source, and the charge control means is the first external power source. Alternatively, the current from the second external power source or both is controlled as the charging current for the secondary battery,
The first backflow prevention means and the second backflow prevention means prevent a backflow of current to the first external power supply, and the third backflow prevention means prevents a backflow of current to the second external power supply, and the fourth backflow The prevention means is characterized in that the secondary battery and the system circuit are connected or disconnected according to an instruction from the power supply detection means.

  The third backflow prevention means is characterized in that a connection state or a disconnection state is established between the external power supply and the charge control means in accordance with an instruction from the power supply detection means.

  The charge control means switches the amount of charge current to the secondary battery according to an instruction from the power supply detection means.

In the present invention, when the first external power supply is connected, the fourth backflow prevention means is in a disconnected state. Thus, when the first external power supply is connected, the charging current to the secondary battery is performed from the charging control means, and the driving current to the system circuit is performed via the first backflow prevention means, and the separate paths Will be supplied at.
Therefore, if the first external power supply having sufficient current supply capability is used, the secondary battery can be charged with the maximum charging current regardless of the operating state of the system circuit. That is, the charging time can be minimized. In addition, since it is not necessary to limit the function of the system circuit during charging, complicated processing by a circuit or software for realizing the limiting means is not required.

On the other hand, when only the second external power supply is connected, the fourth backflow prevention means is set in the connected state. As a result, the output from the charging control means is divided into the charging current and the driving current for the system circuit, and the current is supplied.
Therefore, when the second external power supply having a limited current supply capability is used, the amount of current required in the second external power supply becomes equal to the amount of current output from the charging control means, and the second external power supply Excessive current will not flow. That is, the secondary battery can be safely charged without taking the risk of destroying the second external power supply.

  As described above, even when charging is performed by selecting the first external power source having a sufficient supply current and the second external power source having a current limit, charging can be performed in as short a time as possible according to the characteristics of each external power source. Can be charged safely.

  Furthermore, since the charging method can be switched depending on the characteristics of the connected external power source, the device equipped with the charging circuit of the present invention can cope with various places of use and charging sources as compared with the conventional case.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing a first embodiment of a charging circuit according to the present invention. FIG. 2 is a block diagram showing a second embodiment of the charging circuit according to the present invention. FIG. 3 is a block diagram showing a third embodiment of the charging circuit according to the present invention. FIG. 4 is a circuit example showing the power source detection means of the charging circuit according to the present invention. FIG. 5 is a circuit example showing the charge control means of the first embodiment of the charging circuit according to the present invention. FIG. 6 is a circuit example showing the charging control means of the third embodiment of the charging circuit according to the present invention.

[Description of structure and circuit diagram: FIG. 1]
First, the detailed operation of the first embodiment of the charging circuit according to the present invention will be described with reference to FIG. DESCRIPTION OF SYMBOLS 1 is a charging part, 101 is a connector, 102 is 1st external power supply, 103 is 2nd external power supply, 104 is power supply detection means, 105 is charge control means, 106 is a system circuit, 107 is a secondary battery, 111 is 1st The backflow prevention means, 112 is the second backflow prevention means, 113 is the third backflow prevention means, 114 is the fourth backflow prevention means, 114a is the first PMOSFET, and 114b is the second PMOSFET. S101 is a power input signal, S102 is a charge output signal, S103 is a first power input signal, and S104 is an instruction signal. The charging unit 1 is provided between the first external power supply 102 and the second external power supply 103 and the system circuit 106.

  The connector 101 can be connected to the first external power supply 102 and the second external power supply 103. The power detection means 104 detects the connection of the first external power supply 102. The charging control means 105 controls and outputs a current supplied from the first external power source 102, the second external power source 103, or both. Secondary battery 107 is assumed to be a lithium ion battery in the embodiment of the present invention. The system circuit 106 operates by receiving a current supplied from the secondary battery 107 or the first external power supply 102.

  The first backflow prevention unit 111 and the second backflow prevention unit 112 prevent a backflow of current to the first external power supply 102. The third backflow prevention unit 113 prevents a backflow of current to the second external power supply 103. In the first embodiment of the present invention, a diode is used as the first backflow prevention unit 111, the second backflow prevention unit 112, and the third backflow prevention unit 113.

  The fourth backflow prevention 114 is for disconnecting or connecting the secondary battery 107 and the system circuit 106. In the first embodiment of the present invention, an example in which two PMOSFETs are used as the fourth backflow prevention means 114 is shown. As shown in the figure, the fourth backflow prevention means 114 uses a combination of a first PMOSFET 114a and a second PMOSFET 114b so that the sources face each other. Note that a parasitic diode exists in the source and drain of the MOSFET. The parasitic diodes are also indicated by symbols in the first PMOSFET 114a and the second PMOSFET 114b.

  The first external power supply 102 and the second external power supply 103 are connected to the connector 101. The first external power source 102 is connected to the anodes of the first backflow prevention unit 111 and the second backflow prevention unit 112 via the connector 101. Similarly, the second external power supply 103 is connected to the anode of the third backflow prevention means 113 via the connector 101.

The cathode of the first backflow prevention unit 111 is connected to the input of the power supply detection unit 104, the system circuit 106, and the drain of the second PMOSFET 114 b of the fourth backflow prevention unit 114. This signal is referred to as a first power input signal S103.
The output of the power detection means 104 is connected to the gate of the fourth backflow prevention means 114. This signal is referred to as an instruction signal S104.
The cathode of the second backflow prevention means 112 is connected to the cathode of the third backflow prevention means 113 and the input of the charge control means 105. This is called a power input signal S101.
The output of the charging control means 105 is connected to the secondary battery 107 and the drain of the first PMOSFET 114a of the fourth backflow prevention means 114. This signal is referred to as a charge output signal S102.

[Description of overall operation: Fig. 1]
When neither the first external power source 102 nor the second external power source 103 is connected, no current is supplied to the power input signal S101, so that the secondary battery 107 is not charged. At the same time, since no current is supplied to the first power supply input signal S103, the power supply detection unit 104 outputs the GND level to the instruction signal S104. As a result, the gate of the fourth backflow prevention means 114 becomes the GND level. The voltage of the secondary battery 107 is applied to the source of the fourth backflow prevention means 114 by the action of a parasitic diode in the first PMOSFET 114a. In the embodiment of the present invention, since the secondary battery 107 is assumed to be a lithium ion battery, this voltage is 3.0V to 4.2V. Accordingly, the fourth backflow prevention unit 114 is in a connected state, and current is supplied from the secondary battery 107 to the system circuit 106.

In the first embodiment of the present invention, a 6.0 V output AC adapter is assumed as the first external power source 102. When only the first external power supply 102 is connected to the connector 101, the first power input signal S103 becomes 6.0V through the first backflow prevention means 111.
Next, the power source detection unit 104 outputs an instruction signal S104 of 6.0 V to the fourth backflow prevention unit 114. Since the source of the fourth backflow prevention unit 114 is 3.0V to 4.2V, when the gate voltage is 6.0V, the fourth backflow prevention unit 114 is cut off. As a result, even when a voltage of 6.0 V is applied to the drain of the second PMOSFET 114b, no current flows back to the drain of the first PMOSFET 114a. In this state, the system circuit 106 operates by receiving a direct current supply from the first external power supply 102 instead of the secondary battery 107.

  When the first external power supply 102 is connected, current is supplied to the charging control means 105 through the second backflow prevention means 112. The charging control means 105 charges the secondary battery 107 while controlling the current and voltage. At this time, since the fourth backflow prevention means 114 is in a disconnected state, no current is supplied from the secondary battery 107 to the system circuit 106. In other words, the secondary battery 107 is not consumed and charging is performed. Is called. In addition, due to the action of the third backflow prevention means 113, a backflow of current to the second external power source side does not occur.

  Such a configuration is effective in connecting a power source with a sufficient supply current, such as an AC adapter, because the secondary battery 107 can be charged while the system circuit 106 is operating.

  In the first embodiment of the present invention, a USB interface of 5.0 V output is assumed as the second external power supply 103. Even if the second external power supply 103 is connected to the connector 101, the backflow of current to the first external power supply side does not occur due to the action of the second backflow prevention means 112. Therefore, the power source detection unit 104 outputs the GND level to the instruction signal S104, and as a result, the fourth backflow prevention unit 114 enters a connected state. At the same time, the power input signal S101 becomes 5.0 V through the third backflow prevention means 113, and a current is supplied to the charge control means 105. The charge control means 105 charges the secondary battery 107 while controlling the current and voltage. . Since the fourth backflow prevention unit 114 is in the connected state, the charging output signal S102 from the charging control unit 105 is divided into the operation of the system circuit 106 and the charging of the secondary battery 107.

  In such a configuration, since it is necessary to supply only the same amount of current as the output current amount of the charging control means 105 from the second external power source 103, the amount of current that can be supplied by a standard such as USB is specified. It is effective when

  When both the first external power supply 102 and the second external power supply 103 are connected, the fourth backflow prevention means 114 is in a disconnected state as in the case where only the first external power supply 102 is connected. In addition, since the first external power supply 102 is a 6.0V AC adapter and the second external power supply 103 is a 5.0V USB, current supply to the charge control circuit 105 is performed from the first external power supply 102. Is called. Therefore, the operation is the same as when only the first external power supply 102 is connected.

  In the first embodiment of the present invention, the voltage of the AC adapter that is the first external power supply 102 is 6.0 V, and the USB that is the second external power supply 103 is 5.0 V. Since the diode is used, when the first external power supply 102 having a sufficient supply current is used with priority even when both power supplies are connected, the voltage of the first external power supply 102 is used as the second external power supply. This is because the voltage needs to be higher than the voltage 103. In other words, by making the voltage of the first external power supply 102 higher than the voltage of the second external power supply 103, it is not necessary to provide a complicated switch in the third backflow prevention means 113, and a simple and inexpensive configuration with only a diode is realized. it can.

  The above is a description of the overall operation, but the circuit example and operation of the power supply detection means 104 and the charge control means 105 in the first embodiment of the present invention will be described.

[Description of power supply detection means: FIG. 4]
In FIG. 4, 401 is a voltage detector, and 402 is a resistor. The first power input signal S103 is connected to the VCC terminal of the voltage detector 401. The instruction signal S104 is output from the OUT terminal of the voltage detector 401. The resistor 402 is provided between the VCC terminal and the OUT terminal.

  The voltage detector 401 has a circuit that outputs a GND level to the OUT terminal when a voltage of 3.5 V or less is applied to the VCC terminal, and becomes high impedance when a voltage of 3.5 V or more is applied. . Therefore, when a voltage of 3.5 V or higher is applied, the instruction signal S104 becomes the VCC level by the action of the resistor 402.

  The voltage detector 401 is configured by a generally known voltage detector (for example, a voltage detection IC manufactured by ROHM, model number: BD4835).

  When the first external power supply 102 is connected, the VCC terminal of the voltage detector 401 becomes 6.0 V, which is 3.5 V or higher, and 6.0 V is output to the instruction signal S104.

  In the first embodiment of the present invention, a detection voltage of 3.5 V is used. However, the detection voltage is not particularly limited and may be less than the voltage of the external power supply to be used.

[Explanation of charging control means: FIG. 5]
In FIG. 5, 501 is a charge controller, and 502 is a resistor. A power supply input signal S101 is connected to the VCC terminal of the charge controller 501. A charging output signal S102 is output from the BAT terminal. A resistor 502 is connected between the PROG terminal and GND.

  When a voltage of 4.5 V to 6.5 V is input to the VCC terminal, the charging controller 501 outputs a charging output signal S102 having a set current amount, and performs constant current charging. When the battery voltage becomes near 4.2V, switching to constant voltage charging is performed, and the current amount of the charging output signal S102 decreases. When the current amount of the charging output signal S102 becomes 10% of the set current amount, the charging is finished. The current amount of the charging output signal S102 is set by a resistor 502 connected to the PROG terminal.

The charge controller 501 is configured by a generally known charge controller (for example, a charge control IC manufactured by Linear Technology, model number: LTC1733).
The amount of current (unit: ampere) of the charging output signal S102 in the LTC 1733 is set according to an equation of (1.5 / resistance 502 value) × 1000. If 3.0 kΩ is applied to the resistance 502 value in this equation, (1.5 / 3000) × 1000 = 0.5 A = 500 mA. In order to set the current amount of the charging output signal S102 to 500 mA, the resistor 502 may be set to 3 kΩ.

  When the current amount of the charging output signal S102 is set to 500 mA, when the first external power supply 102 is connected, the charging controller 501 outputs 500 mA at a constant current and starts charging the secondary battery 107. At this time, since the fourth backflow prevention means 114 is in a disconnected state, all 500 mA is used for charging. When the voltage of the secondary battery 107 reaches around 4.2V, the battery is switched to constant voltage charging at 4.2V. When the current amount of the charging output signal S102 decreases and reaches 50 mA, the charging is terminated.

  Similarly, when only the second external power supply 103 is connected, a current of 500 mA is output from the charging controller 501, but since the fourth backflow prevention means 114 is in a connected state, the 500 mA current from the 500 mA The current minus consumption is sent for charging. Although there is a difference that a part of the system circuit 106 consumes the time required for charging, the battery voltage is switched to constant voltage charging near 4.2 V, and then the current amount of the charging output signal S102 is 50 mA. When it becomes below, there is no change in the operation of charging end.

[Description of structure and circuit diagram: FIG. 2]
Next, the detailed operation of the second embodiment of the present invention will be described with reference to FIG. The difference between the second embodiment of the present invention and the first embodiment of the present invention is the third backflow prevention means. In FIG. 2, the constituent elements other than the third backflow prevention means 213 that are constituent elements of the charging unit 2 are the same as those in the first embodiment of the present invention, and thus the description thereof is omitted.

In the second embodiment, the third backflow prevention unit 213 is a switch unit that connects or disconnects the second external power source 103 and the charge control unit 105.
The third backflow prevention means 213 uses a combination of two PMOSFETs so that the sources face each other, and is composed of a third PMOSFET 213a and a fourth PMOSFET 213b. Similarly to the fourth backflow prevention means 114 shown in FIG. 1, the third backflow prevention means 213 also shows a MOSFET parasitic diode.
The instruction signal S104, which is the output of the power supply detection unit 104, is connected to the gate of the third backflow prevention unit 213 and the gate of the fourth backflow prevention unit 114.

[Description of overall operation: Fig. 2]
When neither the first external power supply 102 nor the second external power supply 103 is connected, no current is supplied to the power input signal S101 and the first power input signal S103, and the same operation as in the first embodiment is performed. Therefore, explanation here is omitted.

As a second embodiment of the present invention, a 4.5V output AC adapter is assumed as the first external power supply 102. When only the first external power supply 102 is connected to the connector 101, the first power supply input signal S103 becomes 4.5V via the first backflow prevention means 111.
Next, the power source detection unit 104 outputs an instruction signal S104 of 4.5V to the fourth backflow prevention unit 114. Since the source of the fourth backflow prevention means 114 is 3.0V to 4.2V, when the gate voltage is 4.5V, the fourth backflow prevention means 114 is cut off. As a result, a voltage of 4.5V is applied to the drain of the second PMOSFET 114b, but it does not flow back to the drain of the first PMOSFET 114a. In this state, the system circuit 106 operates by receiving a direct current supply from the first external power supply 102 instead of from the secondary battery 107.

  When the first external power supply 102 is connected, current is supplied to the charging control means 105 through the second backflow prevention means 112. The charging control means 105 charges the secondary battery 107 while controlling the current and voltage. At this time, since the fourth backflow prevention means 114 is in a disconnected state, no current is supplied from the secondary battery 107 to the system circuit 106. In other words, the secondary battery 107 is not consumed and charging is performed. Is called.

  When the first external power supply 102 is connected, the source of the third backflow prevention means 213 has a potential of 4.5 V due to the action of the parasitic diode of the fourth PMOSFET 213b. Furthermore, since the instruction signal S104 is 4.5V, the third backflow prevention means 213 is cut off, and no backflow of current to the second external power supply 103 side occurs.

  In the second embodiment of the present invention, it is assumed that the second external power supply 103 is a 5.0 V output USB interface. When only the second external power supply 103 is connected to the connector 101, the source of the third backflow prevention means 213 is at a potential of 5.0 V due to the action of the parasitic diode of the third PMOSFET 213a. Since the first external power supply 102 is not connected and the gate of the third backflow prevention means 213 is at the GND level, the third backflow prevention means 213 is in a connected state, and current is supplied to the charge control means 105, thereby charging control. The means 105 charges the secondary battery 107 while controlling the current and voltage. At the same time, the fourth backflow prevention means 114 is connected. At this time, due to the function of the second backflow prevention means 112, no backflow of current to the first external power supply side 102 occurs, and the instruction signal S104 output from the power supply detection means 104 maintains the GND level. As in the first embodiment, the charging output signal S102 from the charging control means 105 is divided into the operation of the system circuit 106 and the charging of the secondary battery 107.

  When both the first external power supply 102 and the second external power supply 103 are connected, the third backflow prevention means 213 and the fourth backflow prevention means 114 are the same as when only the first external power supply 102 is connected. Is in a disconnected state. Therefore, the operation is the same as when only the first external power supply 102 is connected.

  The details of the power source detection means 104 and the charge control means 105 in the second embodiment of the present invention are also the same as those in the first embodiment, so that the description is omitted.

  In the second embodiment of the present invention, the PMOSFET is used as the third backflow prevention means 213, so that the first backflow prevention means 113 of the first embodiment uses a diode as in the case of using a diode. It is not necessary to set the voltage of the external power supply 102 higher than the voltage of the second external power supply 103. That is, the selection range between the first external power source 102 and the second external power source 103 is expanded.

[Description of structure and circuit diagram: FIG. 3]
Next, the detailed operation of the third embodiment of the present invention will be described with reference to FIG. The difference between the third embodiment and the second embodiment of the present invention is the charge control means. In FIG. 3, constituent elements other than the charging control means 305 that are constituent elements of the charging unit 3 are the same as those in the second embodiment of the present invention, and thus description thereof is omitted.

In the third embodiment, the charging control unit 305 has a function of switching the charging current according to an instruction from the power source detection unit 104.
The instruction signal S104, which is an output signal of the power source detection means 104, is connected to the gate of the third backflow prevention means 213, the gate of the fourth backflow prevention means 114, and the charge control means 305.

[Description of overall operation: Fig. 3]
When neither the first external power supply 102 nor the second external power supply 103 is connected, no current is supplied to the power supply input signal S101 and the first power supply input signal S103, and the first embodiment of the present invention Since the operation is the same as that of the second embodiment, a description thereof is omitted here.

In the third embodiment of the present invention, a 6.0 V output AC adapter is assumed as the first external power supply 102. However, the third backflow prevention means 213 may be a voltage lower than that of the second external power supply 103 as described in the second embodiment of the present invention.
When only the first external power supply 102 is connected to the connector 101, the first power input signal S103 becomes 6.0V through the first backflow prevention means 111. Next, the power source detection unit 104 outputs an instruction signal S104 of 6.0 V to the fourth backflow prevention unit 114. As a result, as in the second embodiment of the present invention, the fourth backflow prevention means 114 is disconnected, and the system circuit 106 receives a direct current supply from the first external power supply 102 instead of from the secondary battery 107. Works. Further, since the third backflow prevention means 213 is also cut off, a backflow of current to the second external power source 103 does not occur.

  When the first external power supply 102 is connected, current is supplied to the charging control means 305 through the second backflow prevention means 112. When the instruction signal S104 from the power supply detection means 104 is 6.0V, the charge control means 305 outputs the amount of current when the first external power supply 102 is connected to the charge output signal S102 to charge the secondary battery 107. Do.

  In the third embodiment of the present invention, it is assumed that the second external power supply 103 is a 5.0 V output USB interface. When only the second external power supply 103 is connected to the connector 101, the third backflow prevention means 213 and the fourth backflow prevention means 114 are in the connected state, as in the second embodiment of the present invention. When the instruction signal S104 from the power supply detection means 104 is at the GND level, the charge control means 305 outputs the amount of current when the second external power supply 103 is connected to the charge output signal S102. As in the second embodiment of the present invention, the charging output signal S102 from the charging control means 305 is divided into the operation of the system circuit 106 and the charging of the secondary battery 107.

  When both the first external power supply 102 and the second external power supply 103 are connected, the third backflow prevention means 213 and the fourth backflow prevention means 114 are the same as when only the first external power supply 102 is connected. Is in a disconnected state. Furthermore, the charging control means 305 outputs the amount of current when the first external power source 102 is connected to the charging output signal S102.

  Next, circuit examples of the power supply detection unit 104 and the charge control unit 305 will be described with reference to the drawings. Since the power source detection means 104 in the third embodiment of the present invention is the same as that in the first embodiment, the description thereof is omitted.

[Explanation of charging control means: FIG. 6]
A circuit example of the charging control means 305 in the third embodiment of the present invention will be described with reference to FIG. Reference numeral 501 denotes a charge controller, reference numerals 602 and 603 denote resistors, and reference numeral 604 denotes switch means.
The switch means 604 of the third embodiment of the present invention will be described as using an N-channel MOS field effect transistor (hereinafter simply referred to as NMOSFET). Hereinafter, the switch means 604 will be described as an NMOSFET 604.

A power supply input signal S101 is connected to the VCC terminal of the charge controller 501. A charging output signal S102 is output from the BAT terminal. A resistor 602 and a resistor 603 are connected in series between the PROG terminal and GND. The NMOSFET 604 is provided in parallel with the resistor 603 between the connection point between the resistor 602 and the resistor 603 and GND. The drain of the NMOSFET 604 is connected to the connection point between the resistor 602 and the resistor 603, and the source is connected to GND. An instruction signal S104 is applied to the gate.

  Similarly to the first embodiment of the present invention, the charge controller 501 is configured by a generally known charge controller (for example, a charge control IC manufactured by Linear Technology Corporation, model number: LTC1733). . Therefore, the description is omitted.

  The resistor 602, the resistor 603, and the NMOSFET 604 function to switch the current amount of the charging output signal S102 between when the first external power source 102 is connected and when only the second external power source 103 is connected. When the first external power supply 102 is connected, the instruction signal S104 becomes 6.0V. As a result, the NMOSFET 604 is connected, and as a result, the resistance component of the resistor 603 is ignored by short-circuiting both ends thereof, and the resistance value between the PROG terminal of the charge controller 501 and GND is the value of only the resistor 602. .

  When only the second external power supply 103 is connected, the instruction signal S104 is at the GND level, and the NMOSFET 604 is disconnected. As a result, the resistance value between the PROG terminal of the charging controller 501 and GND is the sum of the value of the resistor 602 and the value of the resistor 603.

For example, if 1.5 kΩ is used for the resistor 602 and the resistor 603, when the first external power supply 102 is connected, a 1.5 kΩ resistor is connected to the PROG terminal of the charge controller 501. Then, 1000 mA is output to the charging output signal S102.
When only the second external power supply 103 is connected, a resistor of 3.0 kΩ is connected to the PROG terminal of the charging controller 501 and a current of 500 mA is output to the charging output signal S102. .

  Thus, although the amount of current of the charging output signal S102 varies depending on the connected power source, the operation of the charging control means 305 is the same as in the first and second embodiments of the present invention.

As described above, in the third embodiment of the present invention, in addition to the function of the first embodiment, the amount of charging current can be switched by the connected power source.
If it is desired to use a secondary battery 107 having a capacity of 1000 mA, charging from the first external power supply 102 can be performed in the shortest time if the charging current can be switched to 1000 mA.

  As described above, since the charging circuit of the present invention switches the charging method according to the connected external power supply, it can cope with various different characteristics of the external power supply. Thereby, the use and charge which do not choose the place which becomes essential for portable equipment are realizable.

  Since the charging circuit of the present invention can switch the charging method depending on the characteristics of the connected power source, it can be applied to electronic devices that are used in various places or need to be charged from various power sources. In particular, it is suitable for a portable device equipped with a secondary battery and often charged.

It is a block diagram which shows the 1st Example of the charging circuit in this invention. It is a block diagram which shows the 2nd Example of the charging circuit in this invention. It is a block diagram which shows the 3rd Example of the charging circuit in this invention. It is a circuit example which shows the power supply detection means of the charging circuit in this invention. It is a circuit example which shows the charge control means in 1st Example of the charging circuit in this invention. It is a circuit example which shows the charge control means in the 3rd Example of the charging circuit in this invention. It is a block diagram which shows the charging circuit by a prior art. It is a block diagram which shows the charging circuit by a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Charging part 2 Charging part 3 Charging part 101 Connector 102 1st external power supply 103 2nd external power supply 104 Power supply detection means 105 Charge control means 106 System circuit 107 Secondary battery 111 1st backflow prevention means 112 2nd backflow prevention means 113 1st 3 Backflow prevention means 114 Fourth backflow prevention means 305 Charge control means 401 Voltage detector 501 Charge controller

Claims (3)

In a charging circuit having an external power supply, a system circuit, a connector connectable to the external power supply, a charge control means, a power supply detection means, a secondary battery, and a backflow prevention means for preventing a backflow of current,
The backflow prevention means includes a first backflow prevention means, a second backflow prevention means, a third backflow prevention means, and a fourth backflow prevention means,
The first backflow prevention unit, the second backflow prevention unit, and the third backflow prevention unit prevent backflow of current to the external power source, and the fourth backflow prevention unit includes the charge control unit and the second backflow prevention unit. Prevents backflow of current to the secondary battery,
The connector has a structure that can be connected to at least a first external power source and a second external power source, the power source detection unit detects presence or absence of voltage supply from the first external power source, and the charge control unit includes: The charging current to the secondary battery is controlled by controlling the current from the first external power source or the second external power source or both,
The first backflow prevention means and the second backflow prevention means prevent a backflow of current to the first external power supply, and the third backflow prevention means prevents a backflow of current to the second external power supply. The charging circuit according to claim 4, wherein the fourth backflow prevention means places the secondary battery and the system circuit in a connected state or a disconnected state in accordance with an instruction from the power supply detecting means.   2. The charging circuit according to claim 1, wherein the third backflow prevention unit sets a connection state or a disconnection state between the second external power source and the charge control unit according to an instruction from the power source detection unit. .   3. The charging circuit according to claim 1, wherein the charging control unit switches the amount of charging current to the secondary battery according to an instruction from the power source detection unit.

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