JP5424633B2 - Charging apparatus, charging method and program - Google Patents

Description

The present invention relates to a charging device and the like .

  Conventionally, a rechargeable secondary battery is used as a power source for a video camera, a cellular phone, and the like. In recent years, the size of these portable devices has been reduced, and the size of liquid crystal panels and the like has increased, and a battery with a larger capacity and a smaller size has been demanded. Therefore, in recent years, a lithium ion battery having a high energy density and a light weight has been used as a power source for this type of portable device. Furthermore, some devices use a lithium ion battery (cell pack) in which a plurality of battery cells are connected in series.

  In such a charging system for charging a lithium ion battery pack, when the battery pack is charged until the battery pack is overcharged, a high voltage is applied to the lithium ion battery. There was a risk of loss of safety. In order to prevent this, when the voltage of the lithium ion battery applied to the lithium ion battery exceeds a certain voltage, a protection circuit for stopping the charging of the battery pack is provided to protect the secondary battery. The protection circuit detects each battery voltage applied to each battery cell to protect the lithium ion battery, and operates to stop charging the battery pack when any one of the battery voltages exceeds a predetermined voltage.

In addition, when charging the lithium ion battery, the charging device is charged with a constant current until the battery voltage of the battery cell rises to a predetermined voltage so as to lighten the burden on the battery cell, and then each battery voltage does not exceed the predetermined voltage. Thus, a constant current constant voltage charging method for charging at a constant voltage is known. (For example, see Patent Document 1)
Japanese Patent Laid-Open No. 10-150721

  In such a charging system, when the battery pack is charged by the charging device, the same charging current flows through each battery cell. The battery voltage rises the same and is charged.

  However, it is conceivable that the electrical characteristics of the battery cells vary due to deterioration of the battery cells accompanying charging / discharging, time-dependent changes or errors of the battery cells, and the like.

  Thus, when the electrical characteristics of all the battery cells are not the same, even if the battery cells are charged with the same charging current, a battery cell in which the battery voltage rises quickly and a battery cell in which the battery voltage rises slowly occur, and each battery cell There can be a difference in the value of the battery voltage.

  Therefore, even if the battery voltage of one of the battery cells exceeds the predetermined voltage before the other battery cell and the battery voltage of the other battery cell does not sufficiently reach the predetermined voltage, the protection circuit Charging will be stopped.

  Thus, in order to prevent the charging of the battery pack from being stopped due to variations in the electrical characteristics of each battery cell without stopping the charging of the battery pack by the protection circuit, the charging device outputs when charging the battery pack. It is necessary to lower the charging voltage. In this case, the charging device must set the output charging voltage so that the battery pack can be charged with a low voltage that allows the battery voltage of all the battery cells to have a margin with respect to the predetermined voltage.

  In recent years, the capacity of battery packs has been increasing, and it has been studied to set the operating voltage of the protection circuit low in order to ensure further safety during charging.

  In consideration of the above, when the charging voltage of the charging device is set and the battery pack is charged, the charging device cannot charge the battery pack at the maximum charging voltage that can be charged. There was a problem that the battery cell could not be charged to the maximum capacity.

The present invention aims to ensure that the charging of the battery is divided appropriately row.

The charging device according to the present invention includes a power supply unit that generates power for charging a battery including a plurality of cells, a current detection unit that detects a current flowing through the battery, and a current detected by the current detection unit. In response, it has a detecting means for detecting whether or not the current flowing through the plurality of cells is cut off, and a control means for controlling the charging of the battery according to the result detected by the detecting means, The control means controls to lower a charging voltage for charging the battery when it is detected by the detecting means that currents flowing through the plurality of cells are interrupted .

According to the present invention, it is possible to make the charging of the battery is divided appropriately row.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, embodiment shown below is an example to the last, Comprising: It is not necessarily limited to embodiment shown below.

[Embodiment 1]
FIG. 1 is a diagram illustrating an example of a schematic configuration of a charging system according to Embodiment 1 of the present invention, which includes a battery pack 100 and a charging device 200. The charging device 200 can charge the battery pack 100 attached to the charging device 200. FIG. 2 is a block diagram showing an example of the battery pack 100 and the charging device 200 of the charging system shown in FIG. These will be described in detail below.

<Battery pack>
The battery pack 100 includes a secondary battery 101, a protection circuit 102, and a cutoff circuit 103. When the battery pack 100 is attached to the charging device 200 and charging is started, the secondary battery 101 included in the battery pack 100 is charged by a constant current constant voltage charging method.

  The battery pack 100 also has a terminal for connecting to the charging device 200, and the + (plus) terminal 104 and the − (minus) terminal 105 are connected to the + terminal 209 and the − terminal 210 of the charging device 200. As a result, the battery pack 100 is attached to the charging device 200.

  The secondary battery 101 is included in the battery pack 100, and the secondary battery 101 includes secondary battery cells 101A and 101B such as lithium ion batteries. Two secondary battery cells 101A and 101B of the secondary battery 101 are connected in series as shown in FIG.

  The number of secondary battery cells is not limited to two battery cells, such as the secondary battery cells 101A and 101B, but three or more secondary battery cells are connected in series. Also good.

  The secondary battery cells 101A and 101B are non-aqueous solvent secondary batteries such as lithium ion batteries, secondary battery cells such as nickel-cadmium (Ni-Cd) batteries, nickel metal hydride (Ni-H) batteries, and lithium batteries. It may be.

  The protection circuit 102 acquires the voltage information of the + terminal 104, the voltage information of the-terminal 105, and the intermediate voltage information of the connection point between the secondary battery cell 101A and the secondary battery cell 101B, and the secondary battery cells 101A and 101B. Always detect each battery voltage applied to the terminal. Further, the protection circuit 102 compares the battery voltages of the secondary battery cells 101A and 101B with a predetermined voltage, and operates to control the cutoff circuit 103 according to the comparison result. In the first embodiment, this value is set to “4.22 V ± 0.03 V” as the value of the predetermined voltage.

  The cutoff circuit 103 is a circuit configured by a field effect transistor (FET) or the like. One end of the cutoff circuit 103 is connected to the secondary battery 101, and the other end is connected to the − terminal 105. The cutoff circuit 103 is controlled by the protection circuit 102 and operates to connect or shut off the secondary battery 101 and the negative terminal 105.

  When the protection circuit 102 determines that the battery voltage of at least one of the secondary battery cells 101A and 101B exceeds a predetermined voltage, the cutoff circuit 103 is controlled to be turned off (non-conduction state) by the protection circuit 102. . In this case, the cutoff circuit 103 operates so as to shut off the secondary battery 101 and the negative terminal 105. As a result, the charging current flowing through the secondary battery cells 101A and 101B of the battery pack 100 is cut off, and the charging of the battery pack 100 is stopped, thus preventing overcurrent from flowing through the secondary battery cells 101A and 101B. it can.

  When the protection circuit 102 determines that the battery voltages of both the secondary battery cells 101A and 101B are equal to or lower than a predetermined voltage, the cutoff circuit 103 is controlled by the protection circuit 102 to be turned on (conducting state). . In this case, the cutoff circuit 103 operates to connect the secondary battery 101 and the negative terminal 105. Thus, the operation is performed so that the charging current flows through the secondary battery cells 101A and 101B.

  The + terminal 104 and the − terminal 105 are external connection terminals for connecting the battery pack 100 to an external device. When the battery pack 100 is charged, the + terminal 104 and the − terminal 105 are connected to a connection terminal of the charging device 200, and charge power from the charging device 200 through the connection terminal of the charging device 200. Further, when the power is discharged from the battery pack 100, the + terminal 104 and the − terminal 105 are connected to a connection terminal of an external device that is a supply destination for supplying power, and the power is discharged through the connection terminal of the external device. To do.

<Charging device 200>
The charging device 200 includes an AC input unit 201, a power supply circuit 202, a current detection unit 203, a voltage detection unit 204, a charge control unit 205, a charge detection unit 206, a timer 207, and a display unit 208. When the battery pack 100 is attached, the charging device 200 can charge the battery pack 100 by a constant current constant voltage charging method.

  The charging device 200 has a terminal for mounting the battery pack 100. The + (plus) terminal 209 and the-(minus) terminal 210 are respectively connected to the + terminal 104 and the-terminal of the battery pack 100. By being connected to 105, the battery pack 100 is mounted.

  The AC input unit 201 is connected to a commercial AC power source, rectifies the power of the supplied commercial AC power source, and converts it into power suitable for the charging device 200. DC power converted from AC power by the AC input unit 201 is supplied to the power supply circuit 202.

  The power supply circuit 202 can limit the direct current power supplied from the AC input unit 201 and generate power for charging the battery pack 100. A constant current is supplied to the battery pack 100 according to control by the charge control unit 205. Or a constant voltage is output.

  The current detection unit 203 detects the current flowing through the + terminal 209 and outputs the current to the charge control unit 205 and the charge detection unit 206. When battery pack 100 is attached to charging device 200, the current flowing through positive terminal 209 is detected as the charging current flowing through secondary battery cells 101A and 101B of battery pack 100 charged by charging device 200. be able to.

  The voltage detection unit 204 detects a terminal voltage between the + terminal 209 and the − terminal 210 and outputs it to the charge control unit 205. When battery pack 100 is attached to charging device 200, the terminal voltage between + terminal 209 and − terminal 210 can be detected as the charging voltage of battery pack 100 charged by charging device 200.

  The charging control unit 205 sets a current value and a voltage value output from the power supply circuit 202 to the battery pack 100 so that each battery voltage applied to the secondary battery cells 101A and 101B does not exceed a predetermined voltage. In addition, the charging control unit 205 monitors the charging current detected by the current detecting unit 203 and the charging voltage detected by the voltage detecting unit 204, and charges the battery pack 100 by a constant current constant voltage charging method. The circuit 202 is controlled.

  In addition, the charging control unit 205 can issue an instruction to the charging detection unit 206, the timer 207, and the display unit 208 to control the operation of each unit. Further, each unit of the charging device 200 supplies information obtained by each operation to the charging control unit 205.

The charge detection unit 206 performs a detection process for detecting the state of charge of the battery pack 100 during charging according to the charging current detected by the current detection unit 203. There are three states of the battery pack 100: a charged state, a fully charged state, and a blocked state. When the detected charging current value is as follows, the state of the battery pack 100 is determined according to the charging current. To do.
Charging state: Charging current ≧ 80 mA
Fully charged state: 80 mA> charging current ≧ 10 mA
Blocking state: 10 mA> charging current The charging state is a state of the battery pack 100 when each battery voltage applied to the secondary battery cells 101A and 101B does not reach the predetermined voltage “4.22V ± 0.03V”.

  The fully charged state is a state of the battery pack 100 when the battery voltage of at least one of the secondary battery cells 101A and 101B reaches a predetermined voltage “4.22V ± 0.03V”. In the charged state and the fully charged state, the charging current flowing in the secondary battery cells 101A and 101B is not blocked by the blocking circuit 103. The shut-off state is a state of the battery pack 100 when the battery voltage of at least one of the secondary battery cells 101A and 101B exceeds a predetermined voltage “4.22V ± 0.03V”. In the cut-off state, the charge current flowing through the secondary battery cells 101A and 101B is cut off by the cut-off circuit 103.

  Further, the charge detection unit 206 outputs information indicating the detected state of the battery pack 100 to the charge control unit 205. The battery pack 100 detected by the charge detection unit 206 has three states, that is, a charged state, a fully charged state, and a blocked state. However, the present invention is not limited to this, and the battery pack 100 may be charged. It may be changed accordingly. In the first embodiment, the value of the charging current is set as described above as the determination of the state of the battery pack 100. However, the value is not limited to this, and may be changed according to the setting of the battery pack 100 or the charging device 200. Also good.

  Further, the charge detection unit 206 also controls charging of the battery pack 100 according to the charge voltage detected by the voltage detection unit 204.

  The timer 207 measures an operation time, a pause time, an elapsed time, and the like of each unit in the charging device 200 in accordance with an instruction from the charge control unit 205.

  The display unit 208 is configured by a display device such as an LED or an LCD, and displays the charge state of the battery pack 100 in accordance with an instruction from the charge control unit 205. In addition to the charging state of the battery pack 100, information such as a charging current value and a charging voltage value, and a predetermined icon may be displayed.

The + terminal 209 and the − terminal 210 are external connection terminals for connecting the charging device 200 to the battery pack 100. When the battery pack 100 is charged, the + terminal 209 and the − terminal 210 are connected to the connection terminal of the charging device 200 and supply power from the charging device 200 to the secondary battery 101 via the connection terminal of the battery pack 100. .
<Charging Process for Charging Battery Pack 100 Mounted on Charging Device 200>
Next, a charging process in the charging system according to the first embodiment will be described with reference to FIGS. 1, 2, and 3. FIG. 3 is a flowchart illustrating an example of a charging process performed when the charging device 200 according to the first embodiment charges the battery pack 100 attached to the charging device 200. The process shown in the flowchart of FIG. 3 is a process that is executed when the battery pack 100 and the charging device 200 are connected to each other through the terminals. In this flowchart, it is assumed that the secondary battery 101 and the negative terminal 105 of the battery pack 100 are connected by the cutoff circuit 103.

  In step S <b> 301, the charging control unit 205 sets the current value of the power supply circuit 202 to “700 mA ± 50 mA”. The power supply circuit 202 limits and outputs DC power according to the set value, and starts charging by constant current control. Along with the start of charging, the current detection unit 203 starts detection of the charging current, and the voltage detection unit 204 starts detection of the charging voltage. The charging control unit 205 constantly monitors so that the charging current detected by the current detection unit 203 does not exceed the current value of the power supply circuit 202 set by the charging control unit 205. In this case, the flowchart proceeds from step S301 to step S302.

  In step S301, the charging control unit 205 sets a current output to the battery pack 100 in order to charge the battery pack 100 so that the charging voltage of the battery pack 100 does not exceed “8.4V ± 0.1V”. There is a need to. Since the charging voltage of the battery pack 100 is the total voltage of the battery voltages of the secondary battery cells 101A and 101B, when the upper limit value of each battery voltage is “4.25V”, the charging voltage is the upper limit value “8”. .5V "must be controlled with a constant current so as not to exceed.

  The current value set by the charging control unit 205 is a current value “if the charging voltage of the battery pack 100 can be controlled so that the charging voltage of the battery pack 100 does not exceed the total voltage of the upper limit values of the battery voltages. It is not limited to “700 mA ± 50 mA”.

  In step S <b> 302, the charge detection unit 206 determines whether or not the charge voltage of the battery pack 100 detected by the voltage detection unit 204 has reached “8.4 V ± 0.1 V”. When it is determined by the charge detection unit 206 that the charging voltage of the battery pack 100 has reached “8.4 V ± 0.1 V”, the flowchart proceeds from step S302 to step S303. When it is determined by the charge detection unit 206 that the charging voltage of the battery pack 100 has not reached “8.4 V ± 0.1 V”, the flowchart returns from step S302 to step S301.

  In step S <b> 303, the charge control unit 205 switches the battery pack 100 from charging by constant current control to charging by constant voltage control, and controls the power supply circuit 202 to perform constant voltage charging processing of the battery pack 100. After executing the constant voltage charging process, when the charge detection unit 206 determines that the state of the battery pack 100 is a fully charged state, the charging control unit 205 ends the constant voltage charging process and controls the power supply circuit 202. Then, charging of the battery pack 100 is stopped. In this case, the flowchart ends and the charging process ends. The constant voltage charging process is a process in which the charging device 200 performs charging while outputting a constant voltage to the battery pack 100.

<Constant Voltage Charging Process of Battery Pack 100 Mounted on Charging Device 200>
Next, the constant voltage charging process in the charging system according to the first embodiment will be described with reference to FIGS. 1, 2, and 4. FIG. 4 is a flowchart illustrating an example of a constant voltage charging process performed when the charging device 200 according to the first embodiment charges the battery pack 100 attached to the charging device 200.

  The process shown in the flowchart of FIG. 4 is a process that is executed when the battery pack 100 and the charging device 200 are connected to each other through the terminals. In this flowchart, it is assumed that the secondary battery 101 and the negative terminal 105 of the battery pack 100 are connected by the cutoff circuit 103. Further, it is assumed that the charging current is detected by the current detection unit 203 and the charging voltage is detected by the voltage detection unit 204.

  In step S <b> 401, the charge control unit 205 sets the voltage value (output voltage) of the power supply circuit 202 to “8.4 V ± 0.1 V”. The power supply circuit 202 limits and outputs DC power according to the set value, and starts charging by constant voltage control. In this case, the flowchart proceeds from step S401 to step S402. In the first embodiment, since the upper limit value of the charging voltage of the battery pack 100 is “8.5 V”, the voltage value set by the charging control unit 205 is set to “8.4 V ± 0.1 V” in step S401. To do.

  In step S <b> 402, the charge detection unit 206 detects the state of the battery pack 100 based on the charging current detected by the current detection unit 203. When the charge detection unit 206 determines that the state of the battery pack 100 is the charged state, the flowchart returns from step S402 to step S401. When the charge detection unit 206 determines that the state of the battery pack 100 is a fully charged state, the flowchart proceeds from step S402 to step S411. When the charge detection unit 206 determines that the state of the battery pack 100 is the cut-off state, the flowchart proceeds from step S402 to step S403.

  In step S <b> 403, the charging control unit 205 sets the voltage value of the power supply circuit 202 to “0 V”, and causes the power supply circuit 202 to stop outputting to the battery pack 100. The power supply circuit 202 restricts the voltage to the set voltage value “0 V” and stops charging the battery pack 100. In this way, the charging control unit 205 causes the power supply circuit 202 to stop the output to the battery pack 100 and stop the charging of the battery pack 100 as a charging stop process. In addition, the charging control unit 205 instructs the timer 207 to measure the time elapsed since the charging of the battery pack 100 was stopped. In this case, the flowchart proceeds from step S403 to step S404.

  In step S404, the charging control unit 205 receives information on the elapsed time T measured by the timer 207, and determines whether or not the elapsed time T has reached 5 minutes. When the charging control unit 205 determines that the elapsed time T has reached 5 minutes, the charging control unit 205 cancels the charging stop process. In this case, the flowchart proceeds from step S404 to step S405.

  If the charging control unit 205 determines that the elapsed time T has not reached 5 minutes, the flowchart returns from step S404 to step S404. Until the elapsed time T reaches 5 minutes, the charging control unit 205 continues the charging stop process.

  As described above, the charging stop process is continued until the elapsed time T reaches 5 minutes. In order to charge the battery pack 100 again, the battery voltages of the secondary battery cells 101A and 101B are set to a predetermined value. This is because it was necessary to lower the voltage below. In addition, after the charging of the battery pack 100 is stopped, the battery voltage does not instantaneously change to the discharge voltage, but the voltage value gradually decreases, so that the charge detection unit 206 erroneously determines the state of the battery pack 100. Therefore, it is necessary to provide sufficient charging stop time. The charging stop process was executed until the elapsed time T reached 5 minutes as the predetermined time, but the elapsed time T may be a time for the battery voltage to fall to such an extent that the charge detection unit 206 does not erroneously determine the state of the battery pack 100. This is not limited to this.

  In step S <b> 405, the charging control unit 205 sets the voltage value of the power supply circuit 202 to “8.3 V ± 0.1 V” by lowering the predetermined value by 0.1 V from “8.4 V ± 0.1 V”. The power supply circuit 202 limits the DC power according to the set value and starts charging. In this case, the flowchart proceeds from step S405 to step S406.

  In step S406, the charge detection unit 206 detects the state of the battery pack 100. When the charge detection unit 206 determines that the state of the battery pack 100 is the charged state, the flowchart returns from step S406 to step S405. When the charge detection unit 206 determines that the state of the battery pack 100 is a fully charged state, the flowchart proceeds from step S406 to step S411. When the charge detection unit 206 determines that the state of the battery pack 100 is the cut-off state, the flowchart proceeds from step S406 to step S407.

  In step S <b> 407, the charging control unit 205 performs a charging stop process, issues an instruction to the timer 207, and measures the time elapsed since the battery pack 100 stopped charging. In this case, the flowchart proceeds from step S407 to step S408.

  In step S408, the charging control unit 205 determines whether or not the elapsed time T measured by the timer 207 has reached 5 minutes. When the charging control unit 205 determines that the elapsed time T has reached 5 minutes, the charging control unit 205 cancels the charging stop process. In this case, the flowchart proceeds from step S408 to step S409. When the charging control unit 205 determines that the elapsed time T has not reached 5 minutes, the flowchart returns from step S408 to step S408.

  In step S409, the charging control unit 205 lowers the voltage value of the power supply circuit 202 by 0.1V from “8.3V ± 0.1V” and sets it to “8.2V ± 0.1V”. The power supply circuit 202 starts charging according to the set value. In this case, the flowchart proceeds from step S409 to step S410.

  In step S <b> 410, the charge detection unit 206 detects the state of the battery pack 100. When the charge detection unit 206 determines that the state of the battery pack 100 is the charged state, the flowchart returns from step S410 to step S409. When the charge detection unit 206 determines that the state of the battery pack 100 is a fully charged state, the flowchart proceeds from step S410 to step S411. When the charge detection unit 206 determines that the state of the battery pack 100 is a cut-off state, the charge control unit 205 displays character data, an icon, or the like indicating that the battery pack 100 has been cut off on the display unit 208. Let In this case, the flowchart proceeds from step S410 to step S412.

  In step S411, the charging control unit 205 causes the display unit 208 to display character data, an icon, or the like indicating that the battery pack 100 has been charged. In this case, the flowchart proceeds from step S411 to step S412.

  In step S412, the charging control unit 205 instructs the power supply circuit 202 to stop outputting power and ends the constant voltage charging process. In this case, this flowchart ends.

  As described above, even when the charging current is interrupted by the protection circuit 102, the charging device 200 stops the voltage output to the battery pack 100 for a predetermined time, and then reduces the voltage output to the battery pack 100. The secondary battery cells 101A and 101B can be charged again. Therefore, when the charging device 200 detects that the charging current has been interrupted, the charging device 200 charges the secondary battery cells 101A and 101B without excessively decreasing the charging voltage by repeatedly reducing the charging voltage by a predetermined value and repeating the charging process again. It is possible to set a voltage suitable for the operation.

  Therefore, the charging device 200 can charge the secondary battery cells 101A and 101B with the maximum voltage that can be charged.

  In addition, when the charging current is interrupted, the charging device 200 prevents the battery pack 100 from repeatedly detecting the determined charging state of the battery pack 100 by not outputting to the battery pack 100 for a predetermined time. be able to.

  In addition, when the charging device 200 stops the output to the battery pack 100 for a predetermined time and then starts the charging process again, the charging device 200 lowers the voltage value by a predetermined value 0.1 V and resets the predetermined value. It is also possible to use a value of.

  In the first embodiment, this value is set to “4.22V ± 0.03V” as the predetermined voltage of the battery voltage. However, the value of the predetermined voltage is not limited to this value, and the secondary battery can be charged safely. Any value can be used.

  In the first embodiment, when it is detected that the charging current is cut off, the process of reducing the charging voltage and restarting charging is repeated twice. However, the present invention is not limited to this, and the charging apparatus 200 may repeatedly perform the process of reducing the charging voltage n times (n is an integer of 1 or more) and restarting the charging.

  In this case, it is possible to charge with a more optimal charging voltage as the value of the predetermined value to be lowered at the time of resetting is smaller. On the other hand, when the variation between cells is large, it is conceivable that the number of times of resetting the charging voltage increases before the protection circuit stops operating.

  Further, when performing the constant voltage charging process, the voltages set by the charging control unit 205 are “8.4 V ± 0.1 V”, “8.3 V ± 0.1 V”, “8.2 V ± 0.1 V”. Not limited to. The voltage value set by the charging control unit 205 may be set to a voltage that can be charged so that the battery voltages of the secondary battery cells 101A and 101B do not exceed the predetermined voltage, and change according to the value of the predetermined voltage. You may do it.

[Embodiment 2]
Next, a constant voltage charging process in the charging system according to the second embodiment will be described with reference to FIGS. 1, 2, and 5. In the second embodiment, description of parts common to the first embodiment will be omitted, and parts different from the first embodiment will be described.

<Constant Voltage Charging Process of Battery Pack 100 Mounted on Charging Device 200>
FIG. 5 is a flowchart illustrating an example of a constant voltage charging process performed when the charging device 200 according to the second embodiment charges the battery pack 100 attached to the charging device 200. The process shown in the flowchart of FIG. 5 is a process that is executed when the charging device 200 and the battery pack 100 are connected to each other through the terminals. In this flowchart, it is assumed that the secondary battery 101 and the negative terminal 105 of the battery pack 100 are connected by the cutoff circuit 103. Further, it is assumed that the charging current is detected by the current detection unit 203 and the charging voltage is detected by the voltage detection unit 204.

  In step S501, the charging control unit 205 sets the voltage value of the power supply circuit 202 to “8.4 V ± 0.1 V”. The power supply circuit 202 limits the DC power according to the set value and starts charging by constant voltage control. In this case, the flowchart proceeds from step S501 to step S502. Since the upper limit value of the charging voltage of the battery pack 100 is “8.5 V” in the second embodiment as well as the first embodiment, the voltage value set by the charging control unit 205 is “8.4 V ± in step S501. Set to 0.1V ".

  In step S502, the charge detection unit 206 detects the state of the battery pack 100 based on the charging current detected by the charge detection unit 206. When the charge detection unit 206 determines that the state of the battery pack 100 is the charged state, the flowchart returns from step S502 to step S501. When the charge detection unit 206 determines that the state of the battery pack 100 is a fully charged state, the process proceeds from step S502 to step S511. When the charge detection unit 206 determines that the state of the battery pack 100 is the cutoff state, the flowchart proceeds from step S502 to step S503.

  In step S503, when the charge detection unit 206 determines that the state of the battery pack 100 is the cutoff state, the charge control unit 205 instructs the charge detection unit 206 to stop the operation of detecting the state of the battery pack 100. The charge detection unit 206 is stopped. A process in which the charge control unit 205 performs detection control of the charge detection unit 206 so as to stop the charge detection unit 206 is referred to as a detection stop process. In addition, the charging control unit 205 instructs the timer 207 to measure the time that has elapsed since it was determined that the state of the battery pack 100 is the cutoff state. In this case, the flowchart proceeds from step S503 to step S504.

In step S <b> 504, the charging control unit 205 lowers the voltage value of the power supply circuit 202 by 0.1 V from “8.4 V ± 0.1 V” and sets it to “8.3 V ± 0.1 V”.
The power supply circuit 202 limits and outputs DC power according to the set voltage value, and starts charging. In this case, the flowchart proceeds from step S504 to step S505.

  In step S505, the charging control unit 205 receives information on the elapsed time T measured by the timer 207, and determines whether or not the elapsed time T has reached 5 minutes as a predetermined time. When the charging control unit 205 determines that the elapsed time T has reached 5 minutes, the charging control unit 205 cancels the detection stop process and starts the operation of the charging detection unit 206. In this case, the flowchart proceeds from step S505 to step S506. If the charging control unit 205 determines that the elapsed time T has not reached 5 minutes, the process returns from step S505 to step S505. Until the elapsed time T reaches 5 minutes, the charge detection unit 206 continues to execute the detection stop process.

  In step S506, the charging detection unit 206 detects the state of the battery pack 100 based on the charging current detected by the current detection unit 203. When the charge detection unit 206 determines that the state of the battery pack 100 is the charged state, the flowchart returns from step S506 to step S504. When the charge detection unit 206 determines that the state of the battery pack 100 is a fully charged state, the flowchart proceeds from step S506 to step S511. When the charge detection unit 206 determines that the state of the battery pack 100 is the cut-off state, the flowchart proceeds from step S506 to step S507.

  In step S507, when the charge detection unit 206 determines that the state of the battery pack 100 is the cut-off state, the charge control unit 205 performs a detection stop process. In addition, the charging control unit 205 instructs the timer 207 to measure the time after it is determined that the state of the battery pack 100 is the cutoff state. In this case, the flowchart proceeds from step S507 to step S508.

  In step S508, the charging control unit 205 sets the voltage value of the power supply circuit 202 to “8.2V ± 0.1V” by reducing it by 0.1V from “8.3V ± 0.1V”. The power supply circuit 202 limits the DC power according to the set value and starts charging. In this case, the flowchart proceeds from step S508 to step S509.

  In step S509, the charging control unit 205 receives information on the elapsed time T measured by the timer 207, and determines whether or not the elapsed time T has reached 5 minutes. When the charging control unit 205 determines that the elapsed time T has reached 5 minutes, the charging control unit 205 cancels the detection stop process and starts the operation of the charging detection unit 206. In this case, the flowchart proceeds from step S509 to step S510. When the charging control unit 205 determines that the elapsed time T has not reached 5 minutes, the flowchart returns from step S509 to step S509.

  In step S510, the charge detection unit 206 detects the state of the battery pack 100. When the charge detection unit 206 determines that the state of the battery pack 100 is the charged state, the flowchart returns from step S510 to step S510. When the charge detection unit 206 determines that the state of the battery pack 100 is a fully charged state, the process proceeds from step S510 to step S511. When the charge detection unit 206 determines that the state of the battery pack 100 is a cut-off state, the charge control unit 205 displays character data, an icon, or the like indicating that the battery pack 100 has been cut off on the display unit 208. Let In this case, the flowchart proceeds from step S510 to step S512.

  In step S511, the charging control unit 205 causes the display unit 208 to display character data, an icon, or the like indicating that the battery pack 100 has been charged. In this case, the flowchart proceeds from step S511 to step S512.

  In step S <b> 512, the charging control unit 205 instructs the power supply circuit 202 to stop outputting power and ends the constant voltage charging process. In this case, this flowchart ends.

  As described above, even when the charging current is interrupted by the protection circuit 102, the charging device 200 stops the state detection of the battery pack 100 for a predetermined time, and then lowers the voltage output to the battery pack 100, and again The secondary battery cells 101A and 101B can be charged. Therefore, when the charging device 200 detects that the charging current is cut off, the charging voltage is decreased by a predetermined value and the charging process is repeated again, thereby charging the secondary battery cells 101A and 101B without excessively decreasing the charging voltage. It can be set to a voltage suitable for.

  Therefore, the charging device 200 can charge the secondary battery cells 101A and 101B with the maximum voltage that can be charged.

  In addition, when the charging current is interrupted, the charging device 200 does not detect the charging state of the battery pack for a predetermined time, so that the charging state of the battery pack 100 once determined can be detected repeatedly or erroneously. Judgment can be prevented.

  In addition, when the charging apparatus 200 stops the detection of the charging state of the battery pack 100 for a predetermined time and then starts the charging process again, the charging device 200 resets the voltage value by reducing the predetermined value by 0.1 V. Other values are possible.

  In the second embodiment, this value is set to “4.22V ± 0.03V” as the predetermined voltage of the battery voltage. However, the value of the predetermined voltage is not limited to this value, and the secondary battery can be charged safely. Any value can be used.

  In the second embodiment, similarly to the first embodiment, when it is detected that the charging current is interrupted, the process of reducing the charging voltage and restarting charging is repeated twice. However, the present invention is not limited to this, and the charging apparatus 200 may repeatedly perform the process of reducing the charging voltage n times (n is an integer of 1 or more) and restarting the charging.

  In this case, it becomes possible to charge with a more optimal charging voltage, so that the predetermined value lowered at the time of resetting is small. On the other hand, when the variation between cells is large, it is conceivable that the number of times of resetting the charging voltage increases before the protection circuit stops operating.

  Further, when performing the constant voltage charging process, the voltages set by the charging control unit 205 are “8.4 V ± 0.1 V”, “8.3 V ± 0.1 V”, “8.2 V ± 0.1 V”. Not limited to. The voltage value set by the charging control unit 205 may be set to a voltage that can be charged so that the battery voltages of the secondary battery cells 101A and 101B do not exceed the predetermined voltage, and change according to the value of the predetermined voltage. You may do it.

[Other Embodiments]
The charging device 200 according to the present invention is not limited to the charging device 200 described in the first and second embodiments. For example, the charging device 200 according to the present invention can be realized by a system including a plurality of devices.

  The various processes and functions described in the first and second embodiments can also be realized by a computer program. In this case, the computer program according to the present invention is executed by a computer (including a CPU and the like), and realizes various functions described in the first and second embodiments.

  It goes without saying that the computer program according to the present invention may realize various processes and functions described in the first and second embodiments by using an OS (Operating System) running on the computer.

  The computer program according to the present invention is read from a computer-readable recording medium and executed by the computer. As the computer-readable recording medium, a hard disk device, an optical disk, a CD-ROM, a CD-R, a memory card, a ROM, or the like can be used. The computer program according to the present invention may be provided from an external device to a computer via a communication interface and executed by the computer.

It is a figure which shows an example of the charging system which concerns on Embodiment 1 and 2 of this invention. It is a block diagram which shows an example of schematic structure of the charging system which concerns on Embodiment 1 and 2 of this invention. It is a flowchart which shows an example of the charging process in the charging system which concerns on Embodiment 1 and 2 of this invention. It is a flowchart which shows an example of the constant voltage charging process in the charging system which concerns on Embodiment 1 of this invention. It is a flowchart which shows an example of the constant voltage charging process in the charging system which concerns on Embodiment 2 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Battery pack 101 Secondary battery 101A Secondary battery cell 101B Secondary battery cell 102 Protection circuit 103 Cutoff circuit 104 + terminal 105-terminal 200 Charging device 201 AC input part 202 Power supply circuit 203 Current detection part 204 Voltage detection part 205 Charge control Section 206 Charge detection section 207 Timer 208 Display section 209 + terminal 210-terminal

Claims (8)

Power supply means for generating power for charging a battery including a plurality of cells;
Current detection means for detecting current flowing in the battery;
Detecting means for detecting whether or not the current flowing through the plurality of cells is interrupted according to the current detected by the current detecting means;
Control means for controlling charging of the battery according to the result detected by the detection means,
The control unit controls the charging voltage for charging the battery to be lowered when the detection unit detects that the current flowing through the plurality of cells is interrupted. . The control unit controls the charging voltage not to be supplied to the battery until a predetermined time elapses when the detection unit detects that the current flowing through the plurality of cells is interrupted. And
The charging device according to claim 1, wherein the control unit controls the charging voltage to be lowered after the predetermined time has elapsed.   3. The control unit according to claim 1, wherein when the detection unit detects again that the current flowing through the plurality of cells is cut off, the control unit performs control again to reduce the charging voltage. 4. Communication equipment. The control means controls to limit the operation of the detection means until a predetermined time elapses when the detection means detects that the current flowing through the plurality of cells is interrupted,
4. The charging device according to claim 1, wherein the control unit performs control so that the operation of the detection unit is started after the predetermined time has elapsed. 5.   The control means controls the charge voltage to be lowered even before the predetermined time has elapsed when the detection means detects that the current flowing through the plurality of cells is interrupted. The charging device according to claim 4. Voltage detecting means for detecting the voltage of the battery;
The control means is for charging the battery so that the voltage detected by the voltage detection means does not exceed the predetermined voltage until the voltage detected by the voltage detection means reaches a predetermined voltage. Perform processing to control the charging current,
6. The control unit according to claim 1, wherein the control unit starts a process of controlling the charging voltage in response to the voltage detected by the voltage detection unit reaching the predetermined voltage. The charging device according to Item 1. Generating power for charging a battery including a plurality of cells;
Detecting a current flowing through the battery;
Detecting whether or not the current flowing through the plurality of cells is interrupted according to the detected current;
Controlling charging of the battery according to whether or not current flowing in the plurality of cells is interrupted;
And a step of controlling to lower a charging voltage for charging the battery when it is detected that currents flowing through the plurality of cells are cut off. Generating power for charging a battery including a plurality of cells;
Detecting a current flowing through the battery;
Detecting whether or not the current flowing through the plurality of cells is interrupted according to the detected current;
Controlling charging of the battery according to whether or not current flowing in the plurality of cells is interrupted;
A program for causing a computer to execute a step of controlling to lower a charging voltage for charging the battery when it is detected that currents flowing through the plurality of cells are interrupted.

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