JP2007110820A - Battery pack - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an external auxiliary battery pack for simplifying a charging circuit and a system in an electronic device having a built-in main battery pack. <P>SOLUTION: The battery pack A for supplying DC power to the electronic device B is provided with a secondary battery 1 built in the battery pack A, the charging circuit for charging the secondary battery 1 using an external DC power supply C as a power supply, a discharging circuit for supplying the electronic device B with power from the secondary battery 1, and a bypass circuit for bypassing the charging circuit and the discharging circuit and supplying the electronic device B with power from the external DC power supply C. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a battery pack.

Conventional battery packs and electronic devices are disclosed in the following patent documents. In this publication, in an electronic device having a built-in charge / discharge circuit, a main pack battery that is detachably incorporated in the electronic device and an auxiliary pack battery that is attached to the outside of the electronic device are disclosed. And when charging both pack batteries, DC power is supplied to the charge / discharge circuit from the external DC power source, and either the main pack battery or the auxiliary pack battery is selectively charged according to the command of the charge / discharge circuit. .
JP-A-10-97875

  In the above-described conventional electronic device, the charging / discharging circuit for selectively charging the main pack battery or the auxiliary pack battery is complicated, and if the user does not use the auxiliary pack battery, this is the case. Such a function of the charge / discharge circuit becomes unnecessary.

  The present invention has been made to solve such problems, and provides an external auxiliary battery pack capable of simplifying a charging circuit and system of an electronic device incorporating a main battery pack. The purpose is to do.

  The battery pack of the present invention is a battery pack for supplying DC power to an electronic device, a secondary battery built in the battery pack, a charging circuit for charging the secondary battery using an external DC power supply as a power source, A discharge circuit for supplying power from the secondary battery to the electronic device, and a bypass circuit for bypassing the charging circuit and the discharge circuit and supplying power from an external DC power source to the electronic device. And

  The battery pack includes a control unit, an insertion / removal detection unit that detects insertion / removal of the electronic device, and an insertion / removal detection unit that detects insertion / removal of the external DC power supply. When mounting of the external DC power supply is detected, the control unit controls to supply the electric power of the external DC power supply to the electronic device via the bypass circuit.

  The battery pack is characterized in that when the electric power of the external DC power supply is supplied to the electronic device, the control unit supplies the electric power by a bypass circuit when a current of a predetermined value or more is supplied.

  In the present invention, a bypass circuit that bypasses the charging circuit and the discharging circuit and supplies power from the external DC power source to the electronic device is provided, so that the power of the external DC power source is directly supplied to the electronic device. be able to.

  In addition, since it is possible to supply direct current power to the electronic device via the bypass circuit without charging the secondary battery built in the battery pack, the charging circuit in the electronic device is conventionally used in the electronic device. The function of selectively charging the internal battery and the external battery is not required.

  In addition, an external DC power supply (usually an AC adapter that converts AC commercial power to DC power) can be supplied directly to an electronic device via a bypass circuit, so that the electrical Since the specifications (rated voltage, rated current, etc.) are the same as the electrical specifications for supplying power to the battery pack, the external DC power source used for the battery pack can be used for an electronic device as it is.

  Embodiments of the present invention will be described in detail with reference to the drawings. As shown in FIGS. 1 and 9, in this embodiment, the electronic device B containing a secondary battery (not shown) such as a mobile phone is attached to the outside of the electronic device B or electrically connected by an electric cord. The external auxiliary battery pack A and the external DC power source C which is an AC adapter for converting the AC commercial power source into the DC power source are provided.

  If the external DC power source C is a secondary battery built in the electronic device B, or the battery 1 in the battery pack A, which will be described later, is a lithium ion battery, the constant current / constant voltage (about approx. 5.4V) Supply power. Although not shown, the external DC power source C can be directly connected to the electronic device B to provide the constant voltage (about 5.4 V) / constant current power.

  In the battery pack A, a secondary battery 1 such as a lithium ion battery, a microprocessor unit MPU (hereinafter referred to as a microcomputer), which is a control unit that monitors and controls charging / discharging of the battery 1, and a battery 1 at the time of charging. A charging current detector 2-1 including a resistor for detecting current and a discharge current detecting unit 2-2 including a resistor for detecting current during discharge are provided. The charging current detecting unit 2-1 and the discharging current detecting unit 2-2 measure the supplied current when supplying the electric power of the external DC power source C to the electronic device B in a bypass circuit described later. Also used for. In the battery pack A, a temperature detection unit 3 including a thermistor disposed in close contact with the battery 1 is provided.

  In addition, a protection circuit 4-1 is provided that is connected to the battery 1 and works when the charge / discharge control of the microcomputer MPU does not function normally, or when a sudden overcurrent flows, so that the voltage and current of the battery 1 are It has a protection switch 4-2 made up of a protection FET or the like that performs a blocking operation when the reference value is exceeded.

  Further, in the battery pack A, a bypass current control element 6 composed of an FET or the like controlled by a microcomputer MPU provided in the bypass circuit so that power from the external DC power source A can be directly supplied to the electronic device B. It has.

  In the microcomputer MPU, the battery voltage (measurement point V) and the analog voltage output from the two current detection units 2 using the resistance are input via the current amplification amplifier 2-3, and the temperature detection is a thermistor. An analog voltage output from the unit 3 is input, and an A / D conversion unit (not shown) that converts the digital voltage into an actual voltage [mV] or an actual current value [mA] is provided. Then, the output from the A / D conversion unit is input to a charge control unit (not shown) in the microcomputer MPU, and calculation, comparison, determination, etc. are performed, and charging is performed with a signal from this charge control unit. On / off control of the charge control element 5-1 made of FET or the like provided in the circuit and the discharge control element 5-2 provided in the discharge circuit are performed. Using a known technique, the charge control unit in the microcomputer MPU calculates the remaining capacity by integrating the charge / discharge current. It is also possible to detect full charge of the battery 1 with this calculated remaining capacity. Further, at the measurement point X on the plus output side, the voltage is measured, and control such as stopping of discharge is performed when the voltage drop is abnormal.

  Moreover, in the lithium ion battery 1, since the voltage supplied from the external DC power source C is normally about 5.4V because it is normally charged at a constant voltage of about 4.2V, the charge control element is used at the time of charging. Pulse charging is performed with 5-1 turned on and off, and the average value of the charging voltage is lowered. Further, instead of such a charge control element 5-1, a DC / DC step-down converter including such a charge control element 5-1 as a switching element may be used.

  The output voltage of the lithium ion battery 1 is about 2.7 to 4.2 V, and the input voltage of the electronic device B is required to be about 5.4 V. Is provided with a DC / DC boosting circuit 7 for boosting the voltage of. In the electronic device B incorporating the lithium ion battery, about 5.4 V is supplied from the external DC power source C, so that the electronic device B is provided with a DC / DC step-down converter (not shown) to be stepped down. The battery is charged at a voltage of about 4.2V.

  Further, the battery pack A includes a connection detection circuit 8-1 that is an insertion / removal detection means for detecting insertion / removal of the external DC power supply C by measuring the output voltage of the external DC power supply C, and includes the electronic device B. A connection detection circuit 8-2 serving as an insertion / removal detection means for detecting insertion / removal of the electronic device B by measuring the pull-up voltage when the electronic device B is mounted and the pull-down voltage when the electronic device B is mounted is provided. -1 and 8-2 are obtained, and each insertion / removal is detected.

  Further, in the microcomputer MPU, a plurality of LEDs 9-1 are blinked to display the calculated remaining capacity. Such a capacity display by the LED 9-1 is displayed when the battery 1 is charged, and an LED switch 9- which is a push switch installed on the outer surface of the battery pack A is not charged. By pressing 2, the LED 9-1 can be turned on for a predetermined time (for example, several seconds). In such a capacity display by the LED 9-1, for example, two LEDs 9-1 are provided, two LEDs are lit when the capacity is 100 to 50%, one LED is lit when the capacity is 50 to 25%, and the capacity is 25 Each of the capacities can be displayed by blinking one LED at ˜5% and turning off all the LEDs when the capacity is less than 5%.

  In the present embodiment, as shown in FIG. 2, depending on the connection state of an external DC power source C (= AC adapter C) that is an AC adapter and an electronic device B (= mobile phone B) that is a mobile phone, The mode is determined, and control such as charging is performed by the battery pack A (= battery A) which is a battery.

  In mode 0, the battery is stored without being connected to the battery A, the AC adapter C, and the mobile phone B. At this time, the microcomputer MPU in the battery A recognizes that the AC adapter C and the mobile phone B are disconnected, and identifies this mode 0, whereby the charge control FET 5-1 and the discharge control FET 5 -2 is turned off.

  In mode 1, the battery A is in a state where the mobile phone B is connected, the battery A discharges from the mobile phone B, supplies power to the mobile phone B, and the secondary built in the mobile phone B Charge the battery.

  In mode 1, the microcomputer MPU in the battery A recognizes that the AC adapter C is unplugged and that the mobile phone B is attached, and the charging control is performed by identifying this mode 1. The FET 5-1 is turned off and the discharge control FET 5-2 is turned on. Then, the discharge from the battery A is performed until the capacity of the battery 1 becomes zero, and when the capacity becomes zero, the discharge control FET5-2 is turned off by an instruction from the microcomputer MPU.

  In mode 2, the AC adapter C is connected to the battery A, and the battery A is charged from the AC adapter C. In mode 2, the microcomputer MPU in the battery A recognizes that the cellular phone B is unplugged and the AC adapter C is attached, and identifies this mode 2, thereby charging control. The FET 5-1 is turned on and the discharge control FET 5-2 is turned off. The battery A is charged until the battery 1 is fully charged. When the battery 1 is fully charged, the charge control FET 5-1 is turned off by an instruction from the microcomputer MPU.

  In the above modes 1 to 3, in the initial state, the bypass FET 6 is in the off state.

  In mode 3, the AC adapter C and the mobile phone B are connected to the battery A and perform the following operations.

  First, if the bypass FET 6 is turned on and power and voltage from the AC adapter are applied to the mobile phone B so that a current flows, the mobile phone B needs to supply power (for example, the mobile phone B). And / or when the built-in secondary battery needs to be charged). At this time, the charge control FET 5-1 and the discharge control FET 5-2 are off. Thereafter, if current does not flow, if the mobile phone B does not need to supply power (for example, when the mobile phone B is not used and the built-in secondary battery is also fully charged), the bypass FET 6 is turned off. The charge control FET 5-1 is turned on to charge the battery 1 in the battery A. When the battery 1 is fully charged, the charge control FET 5-1 is turned off. The bypass FET 6 is turned on so that power can be supplied to the mobile phone B. This is because power is supplied from the bypass FET 6 when the mobile phone B needs to supply power (for example, when the mobile phone B is used and / or when the built-in secondary battery needs to be charged). Because you can.

  In the above mode, when power is supplied to the mobile phone B, the mobile phone B may operate functions such as telephone and communication while charging the built-in secondary battery, or even if it is stopped. good. Alternatively, the power of the mobile phone B can be used for operating functions such as communication and communication of the mobile phone B without charging the secondary battery built in the mobile phone B by the function of the mobile phone B. It is.

  In the present embodiment, as described above, various processes such as charging and discharging are performed in the modes 0 to 3 depending on the connection state of the battery A, the mobile phone B, and the AC adapter C. Various processes such as charging and discharging in this embodiment will be described with reference to FIG.

  After being controlled by the microcomputer MPU of the battery A and performing initialization processing of various set values in step S1, various voltages such as the voltage of the battery 1 are measured at the measurement point V in step S2, and overdischarge and overload are detected. In step S3, the current detectors 2-1 and 2-2 measure the current and use it for battery capacity by current integration. In step S4, the AC adapter C is inserted. The connection detection circuit 8-1 detects disconnection and the connection detection circuit 8-2 detects insertion / removal of the cellular phone B. Based on the determination of the insertion / removal state in step S4, it is determined in step S5 whether it belongs to the above modes 0-3.

  The detailed flow of each mode will be described later. After the processing in each mode, in step S7, protection processing is performed by the microcomputer MPU in order to protect from overdischarge, overcharge, large current, and the like. In step S8, the flag-cleared FET is turned off and the flag-set FET is turned on in each mode. Further, in step S9, the LED display is controlled in accordance with the remaining capacity calculated in the microcomputer MPU, and in step S10, waiting (= wait) until the elapsed time from step S2 reaches 250 msec. To do. And the flow of the above steps S2-S10 is repeated every 250 msec.

  FIG. 4 shows a flow of mode 0 in step S6-0 in FIG. As described above, the mode 0 is a case where the battery is stored without being connected to the battery A, the AC adapter C, and the mobile phone B. In step S01, the remaining capacity is 8%, 3%, 0 according to a known technique. When the battery voltage corresponds to% or the like, the remaining current accumulated is corrected. In step S02, the flag of the charge control FET 5-1 is cleared. In step S03, the flag of the discharge control FET 5-2 is cleared. In step S04, the flag of the bypass FET 6 is cleared. Thereafter, the process proceeds to step S7 and subsequent steps in FIG. 3, and in step S8, each FET is turned off because the flag of each FET is cleared. Then, each FET is kept off by the loop of steps S2 to S10 in FIG.

  FIG. 5 shows a flow of mode 1 in step S6-1 in FIG. In mode 1, as described above, the battery A is in a state where the mobile phone B is connected, and the battery A discharges from the mobile phone B to supply power to the mobile phone B. In step S11, according to a well-known technique, capacity calculation by current integration is performed in the microcomputer MPU. In step S12, when the battery voltage corresponds to the remaining capacity 8%, 3%, 0%, etc., the current integration is performed. Correct the remaining capacity.

  In step S13, it is determined whether or not the remaining capacity of the battery 1 is zero. If it is not zero (= when the capacity remains), the flag of the discharge control FET5-2 is set in step S14, and the process proceeds to step S15. Then, the flag of the charge control FET 5-1 is cleared, and the flag of the bypass FET 6 is cleared in step S16. Thereafter, the process proceeds to step S7 and subsequent steps in FIG. 3, and in step S8, the discharge control FET 5-2 is turned on, and the charge control FET 5-1 and the bypass FET 6 are turned off. If it is determined in step S13 that the remaining capacity is zero (or a small amount), a zero capacity flag is set in step S17, and the discharge control FET5-2 flag is cleared in step S18. Will do. Then, step S15, the flow of FIG. 3 is reached, and in step S8, the discharge control FET5-2 is turned off. Thus, when the remaining capacity of the battery 1 becomes zero, the discharge is stopped. Then, each FET is kept off by the loop of steps S2 to S10 in FIG.

  Thus, in mode 1, when the remaining capacity of the battery 1 is not zero, the discharge control FET 5-2 is turned on to supply power to the mobile phone B or to enable supply. In this mode 1, when the mobile phone B does not require power supply (for example, when the mobile phone B is not used and the built-in secondary battery is also fully charged), the energization element inside the mobile phone B is turned off. Therefore, the power supply is cut off.

  FIG. 6 shows a flow of mode 2 in step S6-2 in FIG. In mode 2, as described above, the AC adapter C is in a state where the battery A is connected, and the battery A is charged from the AC adapter C. In step S21, according to a well-known technique, capacity calculation by current integration is performed in the microcomputer MPU. In step S22, when the battery 1 is fully charged, the remaining capacity obtained by current integration is corrected to 100%.

  In step S23, it is determined whether or not the full charge flag of the battery 1 in the battery A is 1. If it is not 1, the battery is not fully charged, and in step S24, the microcomputer MPU turns on and off the charge control FET 5-1, and performs pulse charging. Subsequently, in steps S25 and S26, it is determined whether or not the battery 1 is fully charged. Such a determination is made based on whether or not the charging current is equal to or less than a specified value. If not fully charged, the flag of the discharge control FET5-2 is cleared in step S27, and the flag of the bypass FET6 is cleared in step S28.

  If it is determined in step S26 that the battery is fully charged, a full charge flag is set in step S41, and the charge control FET5-1 flag is cleared in step S42 (then charge control FET5- 1 off).

  If the full charge flag of the battery 1 is 1 in step S23, it is determined in step S30 whether or not the voltage of the battery 1 is a voltage threshold that requires recharging. This determines whether the remaining capacity is reduced due to the self-discharge of the battery 1 after full charge, the voltage is lowered, and recharging is necessary. If the voltage is equal to or lower than the threshold, in step S31, the full charge flag is cleared, and the flag of the charge control FET 5-1 is set (then, the charge control FET 5-1 is turned on in step S8).

  In step S30, if the voltage is equal to or higher than the threshold value, charging is not required, so the flag of the charge control FET 5-1 is cleared in step S33 (then, the charge control FET 5-1 is turned off in step S8). ).

  Then, the loop of steps S2 to S10 in FIG. 3 is repeated.

  Thus, in mode 2, as described above, the AC adapter C is in a state where the battery A is connected, and the battery A is charged from the AC adapter C. Then, when the battery 1 is charged to be fully charged and the capacity is reduced by self-discharge after full charging, the battery 1 is charged again to be fully charged.

  The flow of mode 3 in step S6-3 in FIG. 3 is shown in FIGS. Mode 3 is a state in which the AC adapter C and the mobile phone B are connected to the battery A as described above. First, in FIG. 7, in step S <b> 51, it is determined whether the rechargeable battery built in the mobile phone B has a full charge flag.

  Here, the secondary battery built in the mobile phone B is fully charged means that no current flows when the power and voltage from the AC adapter C are applied to the mobile phone B. In other words, it means that the mobile phone B needs to receive power supply. Even when the secondary battery is fully charged, when the mobile phone B is used for a call or the like, the current is supplied with power and the current flows. Therefore, in the expression of the flow of FIG. The battery is not fully charged.

  If the full charge flag is not 1 in step S51, it is detected in steps S52 and S53 whether or not the secondary battery built in the mobile phone B is fully charged. Here, the voltage of the AC adapter C is applied, and detection is made based on whether or not the current of the mobile phone B is equal to or less than a specified value. If the current value is equal to or greater than the specified value, the secondary battery is not fully charged (= the mobile phone B needs to be supplied with power) and the flag of the bypass FET 6 is set in step S54 (then, the step In step S8, the bypass FET 6 is turned on. In steps S55 and S55, the flags of the charge control FET 5-1 and the discharge control FET 5-2 are cleared (then, both FETs are turned off in step S8). Such a prescribed value of the current value is set larger than the current consumed in the standby state of the mobile phone B.

  Here, in the first flow of mode 3, since the initial value is set in step S1 of FIG. 3, the flag of the bypass FET 6 is cleared and is in an OFF state. In steps S52 and S53, the current is In step S52 and S53, the bypass FET 6 is in the on state and is determined by the current value. Therefore, when the bypass FET 6 is in the off state, it is not fully charged. The determination is made and the process proceeds to step S54.

  If it is determined in step S53 that the current is lower than the specified value and the battery is fully charged (= the mobile phone B does not need to be supplied with power), in order to complete the charging, the mobile phone B is set in step S57. In step S58, the flag of the bypass FET 6 is cleared (then, the bypass FET 6 is turned off in step S8).

  In step S51, if the full charge flag is 1, the secondary battery of the mobile phone B is fully charged, and the process proceeds to the procedure for charging the battery 1 in the battery A. In step S60, according to a well-known technique, capacity calculation by current integration is performed in the microcomputer MPU. In step S61, when the battery 1 is fully charged, the remaining capacity obtained by current integration is corrected to 100%. In step S62, it is determined whether or not the full charge flag of the battery 1 in the battery A is 1. If it is not 1, it is not a full charge, and in step S63, the microcomputer MPU turns on / off the charge control FET 5-1, and performs pulse charge. Subsequently, in steps S64 and S65, it is determined whether or not the battery 1 is fully charged. Such a determination is made based on whether or not the charging current is equal to or less than a specified value. If not full charge, the flag of the discharge control FET5-2 is cleared in step S66 (then, the discharge control FET5-2 is turned off in step S8), and the flag of the bypass FET6 is cleared in step S67 (then, step The bypass FET 6 is turned off at S8).

  If it is determined in step S65 that the battery is fully charged, a full charge flag is set in step S68, and the charge control FET5-1 flag is cleared in step S69 (then, in step S8, the charge control FET5- 1 off).

  If the full charge flag of the battery 1 is 1 in step S62, it is determined in step S70 of FIG. 8 whether or not the voltage of the battery 1 is a voltage threshold that requires recharging. This determines whether the remaining capacity is reduced due to the self-discharge of the battery 1 after full charge, the voltage is lowered, and recharging is necessary. If the voltage is equal to or lower than the threshold value, the full charge flag is cleared in step S71, the flag of the bypass FET 6 is cleared in step S72 (then, the bypass FET 6 is turned off in step S8), and the charge is performed in step S73. The flag of the control FET 5-1 is set (then, the charge control FET 5-1 is turned on in step S8), and the flag of the discharge control FET 5-2 is cleared in step S74 (then, the discharge control FET 5 is then switched in step S8). -2 off).

  In step S70, if the voltage is equal to or higher than the threshold value, charging is not necessary, so the flag of the charge control FET 5-1 is cleared in step S75 (then, the charge control FET 5-1 is turned off in step S8). ). In step S76, the flag of the bypass FET 6 is set (then, the bypass FET 6 is turned on in step S8). Then, the loop of steps S2 to S10 in FIG. 3 is repeated.

  As described above, in mode 3, when the bypass FET 6 is first turned on and the power and voltage from the AC adapter C are applied to the mobile phone B and current flows, the mobile phone B can supply power. When necessary (for example, when the mobile phone B is used and / or when the built-in secondary battery needs to be charged), power is supplied from the bypass circuit. At this time, the charge control FET 5-1 and the discharge control FET 5-2 are off. Thereafter, if current does not flow, if the mobile phone B does not need to supply power (for example, when the mobile phone B is not used and the built-in secondary battery is also fully charged), the bypass FET 6 is turned off. The charge control FET 5-1 is turned on to charge the battery 1 in the battery A. When the battery 1 is fully charged, the charge control FET 5-1 is turned off. Then, the bypass FET 6 is turned on so that power can be supplied to the mobile phone B. This is because power is supplied from the bypass FET 6 when the mobile phone B needs to supply power (for example, when the mobile phone B is used and / or when the built-in secondary battery needs to be charged). Because you can.

  In the present embodiment, the following additional functions can be added. In the battery pack A, the remaining capacity of the battery 1 is calculated, and how many times the secondary battery built in the mobile phone B can be charged from 0% to full charge (= nominal capacity) with the remaining capacity at that time. It is also possible to provide a function for calculating and displaying. The capacity discharged from the battery 1 can also be displayed.

  In addition, the above calculation and display of the number of times the battery can be charged may be performed by the mobile phone B. Similarly, the discharged capacity may be displayed on the mobile phone B. In this case, it is necessary to communicate information between the battery pack A and the mobile phone B.

It is a circuit block diagram of the battery pack of the present invention. It is a figure explaining the state of each mode in the Example of this invention. It is a flowchart which shows the Example of this invention. It is a flowchart which shows the mode 0 of the Example of this invention. It is a flowchart which shows the mode 1 of the Example of this invention. It is a flowchart which shows the mode 2 of the Example of this invention. It is a flowchart which shows the mode 3 of the Example of this invention. It is a flowchart which shows the mode 3 of the Example of this invention. It is an external view of the Example of this invention.

Explanation of symbols

A Battery pack (= battery)
B Electronic equipment (= mobile phone)
C External DC power supply (= AC adapter)
MPU Microprocessor unit 1 Secondary battery 5-1 Charge control element (= charge control FET)
5-2 Discharge control element (= discharge control FET)
6 Bypass current control element (= Bypass FET)

Claims (3)

A battery pack for supplying direct current power to an electronic device,
A secondary battery built in the battery pack, a charging circuit for charging the secondary battery using an external DC power source as a power source, and a discharging circuit for supplying power from the secondary battery to the electronic device ,
A battery pack comprising a bypass circuit that bypasses the charging circuit and the discharging circuit and supplies electric power from the external DC power source to the electronic device. The battery pack includes a control unit, insertion / removal detection means for detecting insertion / removal of the electronic device, and insertion / removal detection means for detecting insertion / removal of the external DC power source,
When the insertion / removal detection unit detects the attachment of the electronic device and the external DC power supply, the control unit supplies the electric power of the external DC power supply to the electronic device via the bypass circuit. The battery pack according to claim 1, wherein the battery pack is controlled. 3. The battery pack according to claim 2, wherein when the electric power of the external DC power supply is supplied to the electronic device, the control unit supplies the electric power by the bypass circuit when a current of a predetermined value or more is supplied.