JP5082677B2 - Battery identification method and battery identification device - Google Patents

Description

  The present invention relates to a battery identification method and a battery identification device, and more particularly to a battery identification method and a battery identification device suitable for identifying a battery manufacturer, product name, rated capacity, and the like.

Conventionally, a technique for identifying a cell type of a battery by applying a charging current to the battery and monitoring a terminal voltage of the battery is known (see, for example, Patent Document 1). In this technique, the terminal voltage of the battery is monitored during charging to which a charging current is applied, and the cell type of the battery is identified based on the terminal voltage during charging.
JP-A-6-249930

  However, in the technology for identifying the battery based on the terminal voltage during charging as described in Patent Document 1 described above, the state of charge of the battery (for example, the charge amount SOC) when the charging current is applied to the identification is considered. Therefore, the terminal voltage to be monitored may change depending on the state of charge of the battery, and as a result, it may be difficult to stably identify the battery.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a battery identification method and a battery identification device capable of realizing appropriate identification of a battery.

The object is to charge the battery with a predetermined charging state, to apply a predetermined voltage to the battery with the predetermined charging state in the charging step, and to the battery with the voltage applying step. comprising a current detection step of detecting a current flowing in the battery when a predetermined voltage is applied, and a battery identification step of identifying the battery based on the detected current in the current detection step, the charge predetermined charging state to be given to the battery in step, the predetermined value or less of the charging current is achieved by der Ru cell identification method that continues for a predetermined time by application of a predetermined charging voltage.

Further, the above object is achieved by charging means for giving a predetermined charging state to the battery, voltage applying means for applying a predetermined voltage to the battery given a predetermined charging state by the charging means, and the voltage applying means by the voltage applying means. A current detection means for detecting a current flowing through the battery when a predetermined voltage is applied to the battery; and a battery identification means for identifying the battery based on the current detected by the current detection means , It said charging means is a predetermined state of charge to the battery, a predetermined value or less of the charging current is achieved by the battery identification device you apply a predetermined charging voltage until continues for a predetermined time.

  In the inventions of these aspects, a predetermined voltage is applied to a battery given a predetermined state of charge, and a current flowing through the battery at that time is detected. Then, the battery is identified based on the detected current. According to this configuration, the battery can be identified based on the current that flows after the battery is given a predetermined state of charge. For this reason, according to this invention, it becomes possible to implement | achieve appropriate identification of a battery.

Incidentally, it is possible to create a common state of charge as a prerequisite for performing the identification of the O lever, each battery in the battery identification method described above.

  In the battery identification method described above, if the predetermined voltage applied to the battery in the voltage application step is a specified voltage higher than the predetermined charging voltage applied in the charging step, the above-described In the battery identification device, if the voltage applying unit applies a specified voltage higher than a predetermined charging voltage applied by the charging unit as a predetermined voltage to the battery, the voltage is applied to the battery of the specified voltage. Since a large charging current flows through the battery at the time of application, it becomes easy to appropriately identify the battery based on the charging current at that time.

  In the battery identification method described above, if the battery identification in the battery identification step is performed based on the time waveform of the current detected in the current detection step, The current detection means detects a time waveform of a current flowing through the battery when a predetermined voltage is applied to the battery by the voltage application means, and the battery identification means is detected by the current detection means. If the battery is identified based on the time waveform of the current, the battery identification accuracy can be improved.

  Furthermore, in the battery identification method described above, the amount of discharge or unit time of the battery after the predetermined charging state is given to the battery in the charging step and before the predetermined voltage is applied to the battery in the voltage applying step. If the amount of discharge per unit is greater than or equal to a predetermined amount, if the battery identification in the battery identification step is stopped, and in the battery identification device described above, a predetermined charging state is given to the battery by the charging means. If the amount of discharge of the battery or the amount of discharge per unit time is greater than or equal to a predetermined amount before the voltage is applied to the battery by the voltage applying means, the battery identifying means identifies the battery. If the battery is stopped, the battery identification accuracy decreases due to the discharge of the battery between the time when the predetermined charge state is given and the time when the predetermined voltage is applied. It is possible to prevent the.

A charging step for giving a predetermined charging state to the battery, a voltage applying step for applying a predetermined voltage to the battery given a predetermined charging state in the charging step, and a predetermined voltage for the battery in the voltage applying step A current detecting step for detecting a current flowing through the battery when a voltage is applied, and a battery identifying step for identifying the battery based on the current detected in the current detecting step. If the amount of discharge of the battery or the amount of discharge per unit time is greater than or equal to a predetermined amount from when the predetermined state of charge is given to the time when the predetermined voltage is applied to the battery in the voltage application step, According to the battery identification method for stopping the identification of the battery in the battery identification step, the charging means for giving the battery a predetermined charge state, A voltage applying means for applying a predetermined voltage to the battery given a predetermined state of charge by the charging means; and a current for detecting a current flowing through the battery when the predetermined voltage is applied to the battery by the voltage applying means. A battery identification unit configured to identify a battery based on the current detected by the current detection unit, and the voltage application unit after a predetermined charging state is given to the battery by the charging unit. If the discharge amount of the battery or the discharge amount per unit time exceeds a predetermined amount before a predetermined voltage is applied to the battery by the battery identification device, the battery identification device stops the identification of the battery by the battery identification means. For example, it is possible to prevent the battery identification accuracy from being lowered due to the discharge of the battery after the predetermined charging state is applied until the predetermined voltage is applied.
By the way, in the battery identification device described above, a battery temperature detecting means for detecting the temperature of the battery, and a predetermined charging state, a predetermined voltage, a predetermined value, and a predetermined time according to the temperature detected by the battery temperature detecting means. And a parameter changing means for changing a predetermined charging voltage, a battery identification value, or a predetermined amount, the battery identification accuracy is reduced due to a temperature change. Can be prevented.

  According to the present invention, appropriate identification of a battery can be realized.

  Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a configuration diagram of a system including a battery identification device 10 according to an embodiment of the present invention. The battery identification device 10 of the present embodiment is a device that automatically identifies the battery 12 mounted on the vehicle by mainly distinguishing the manufacturer, product name, rated capacity, and the like.

  As shown in FIG. 1, the vehicle of this embodiment includes a battery 12, an alternator 14, and an electric load 16. The battery 12, the alternator 14, and the electric load 16 are connected in parallel to each other.

  The battery 12 is a chargeable / dischargeable lead battery, a nickel metal hydride battery, a lithium ion battery, or the like that outputs a voltage of about 12 volts, and is a battery of a predetermined type according to the vehicle on which it is mounted. The battery 12 can discharge and supply electric power to the electric load 16. The alternator 14 can generate electric power by driving an engine that is vehicle power, and supply the generated electric power to the electric load 16 and the battery 12. The alternator 14 is a generator that can vary the generated voltage.

  The electric load 16 is, for example, a navigation device, an audio device, various lights of a vehicle, an air conditioner, an engine ignition device, a fuel injection device, a brake device, various sensors, various electronic control units, and the like. Operation and non-operation are switched according to operation requests such as supply. The electric load 16 can operate by being supplied with power from the battery 12 or the alternator 14.

  As shown in FIG. 1, the battery identification device 10 of this embodiment includes a controller 20 mainly composed of a computer. The controller 20 is a control device that identifies the battery 12.

  A current sensor 22 and a temperature sensor 24 are electrically connected to the controller 20. The current sensor 22 outputs a signal corresponding to the current flowing through the battery 12 toward the controller 20. The temperature sensor 24 outputs a signal corresponding to the temperature generated in the battery 12 to the controller 20. The controller 20 detects the current I flowing through the battery 12 based on the signal from the current sensor 22 and detects the temperature TH generated in the battery 12 based on the signal from the temperature sensor 24.

  The above-described alternator 14 is electrically connected to the controller 20. The controller 20 can vary the power generation voltage of the alternator 14 according to the running state of the vehicle. For example, when the vehicle accelerates, the power generation voltage of the alternator 14 is decreased to reduce the load on the engine. Is decelerated, the power generation voltage of the alternator 14 is increased to increase the amount of power generated by regenerative energy (charge / discharge control). The controller 20 supplies a command signal to the alternator 14 so as to output the set power generation voltage. The alternator 14 adjusts the generated voltage in accordance with a command from the controller 20.

  A storage device 26 is also electrically connected to the controller 20. The storage device 26 stores data necessary for battery identification. The data stored in the storage device 26 includes data representing the state of charge given to the battery 12 as a precondition for battery identification, identification determination values for battery identification, their temperature characteristics, and identification determination values and batteries. There are relationships with types.

  Next, with reference to FIG. 2 thru | or FIG. 4, operation | movement of the battery identification apparatus 10 of a present Example is demonstrated. FIG. 2 shows a flowchart of an example of a control routine executed by the controller 20 in the battery identification device 10 of the present embodiment. FIG. 3 shows an operation time chart of an example for performing battery identification in the battery identification device 10 of the present embodiment. FIG. 4 is a diagram showing the relationship between the current waveform at the time of battery identification stored in the storage device 26 and the type of the battery 12 in the battery identification apparatus 10 of this embodiment.

  In the present embodiment, the controller 20 gives a predetermined charging state to the battery 12 in a state where the vehicle engine capable of generating the alternator 14 is driven (step 100). When the battery 12 is thus given a predetermined state of charge, the battery 12 is charged to a state close to a predetermined full charge.

  Specifically, the controller 20 supplies a command signal to the alternator 14 so as to output a predetermined generated voltage (for example, 13.5 volts), whereby a predetermined charging voltage Vsh1 equal to the generated voltage is supplied to the battery 12. In the state where the charging voltage Vsh1 is applied, it is determined whether or not the state in which the charging current to the battery 12 is equal to or less than a predetermined value (for example, 5 amperes) Ish1 continues for a predetermined time (for example, 5 minutes) Tsh1.

  As a result, for example, when the vehicle suddenly accelerates and the generated voltage of the alternator 14 cannot be maintained at the predetermined generated voltage described above, the charging voltage of the battery 12 cannot be maintained at the predetermined charging voltage Vsh1. When the charging current has not yet decreased below the predetermined value Ish1, or when the state where the charging current is below the predetermined value Ish1 has not yet continued for the predetermined time Tsh1, a negative determination is made, but when the above condition is satisfied, an affirmative determination is made. To determine that the battery 12 has been given a predetermined state of charge (step 100).

  After determining that the battery 12 has been given the predetermined charging state, the controller 20 applies a charging voltage of a specified voltage (for example, 14.5 volts) Vsh2 higher than the predetermined charging voltage Vsh1 to the battery 12. It is determined whether or not it is in a state. This determination is affirmed when the power generation voltage of the alternator 14 becomes a specified voltage (for example, 14.5 volts) set when the vehicle to be regenerated is recovered by the battery 12 by charge / discharge control.

  The controller 20 also detects using the current sensor 22 until it is determined that the charging voltage of the specified voltage Vsh2 is applied to the battery 12 after determining that the predetermined charging state is applied to the battery 12. The amount of electricity discharged from the battery 12 (time integration value of discharge current) is calculated by integrating the current I. Then, it is determined whether or not the calculated amount of discharge electricity is larger than a predetermined amount and whether or not the amount of discharge electricity per unit time is larger than a predetermined amount.

  Then, when it is determined that the discharge electricity amount of the battery 12 is larger than a predetermined amount before the charging voltage of the specified voltage Vsh2 is applied to the battery 12, and when the discharge electricity amount per unit time is larger than the predetermined amount. If it is determined, it is determined that the amount of electricity or discharge polarization taken out (discharged) from the battery 12 is relatively large, and the state of charge of the battery 12 is far from the predetermined state of charge described above. The battery 12 identification process is stopped.

  The predetermined amount of discharge electricity and discharge electricity per unit time is set to a value that does not affect the battery identification because the discharge of the battery 12 affects the battery identification described later. Yes.

  On the other hand, when it is not determined that the amount of discharge electricity of the battery 12 is larger than a predetermined amount before the charging voltage of the specified voltage Vsh2 is applied to the battery 12, the amount of discharge electricity per unit time is larger than the predetermined amount. If it is not determined that the amount of electricity or discharge polarization taken out (discharged) from the battery 12 is not so large, it is determined that the state of charge of the battery 12 is maintained at the predetermined state of charge described above. When the charging voltage of the specified voltage Vsh2 is applied to the battery 12 (step 102), the battery 12 is identified.

  Specifically, the controller 20 first measures the time waveform of the current I flowing through the battery 12 based on the signal from the current sensor 22 when the charging voltage of the specified voltage Vsh2 is applied to the battery 12 ( Step 104). The charging current value of the battery 12 and its change over time refer to the relationship shown in FIG. 4 showing the identification determination value for identifying the battery stored in the storage device 26, and the current of any battery type It is determined whether or not the waveform matches, and the battery 12 is identified (step 106). As shown in FIG. 4, the above-described identification determination values (current threshold value Ish2 and time threshold value Tsh2) are determined in advance for each battery type (A, B, C).

  As a result, for example, when the state where the charging current value is 30 amperes or more and less than 55 amperes continues for 100 ms, it is determined that the type of the battery 12 to be mounted is “A”, and the charging current value is 55 amperes or more. When the state of less than 65 amperes continues for 100 ms, it is determined that the type of the mounted battery 12 is “B”, and the state where the charging current value is 65 amperes or more and less than 75 amperes continues for 100 ms. In such a case, it is determined that the type of the battery 12 to be mounted is “C”.

  Thus, in the battery identification device 10 of the present embodiment, a predetermined charging state is obtained by applying a predetermined charging voltage Vsh1 to the battery 12 to be mounted until a charging current equal to or lower than the predetermined value Ish1 continues for a predetermined time Tsh1. Thereafter, the waveform of the charging current that flows when the prescribed charging voltage Vsh2 is applied to the battery 12 can be measured, and the battery 12 can be identified based on the current waveform.

  If the battery 12 is given a predetermined state of charge, a common state of charge is created for the battery 12, so that the preconditions for battery identification can be made uniform for each battery. For this reason, the waveform of the charging current that flows when the specified voltage Vsh2 is applied to the battery 12 to which the predetermined charging state is given does not change according to the charging state of the battery 12, and Since only the type is used, the battery 12 can be appropriately and stably identified according to the current waveform. Therefore, according to the present embodiment, appropriate identification of the battery 12 can be realized.

  Further, in the battery identification device 10 of the present embodiment, at the time of battery identification, a specified voltage Vsh2 higher than the charging voltage Vsh1 applied at the time of setting the above preconditions is applied to the battery 12, so that a relatively large charging current is applied to the battery. 12 flows. In this case, the charging current at the time of applying the specified voltage Vsh2 can be greatly varied between battery types. Therefore, according to this embodiment, it is easy to appropriately identify the battery 12 based on the charging current when the specified voltage Vsh2 is applied.

  Further, in the battery identification device 10 of the present embodiment, the battery identification is performed based on the time waveform of the charging current, not based on the magnitude of the charging current itself when the specified voltage Vsh2 is applied. Even if a noisy charging current rises or falls, battery identification is not performed based on the charging current. Therefore, according to the present embodiment, the identification accuracy of the battery 12 can be improved.

  Furthermore, in the battery identification device 10 of the present embodiment, the amount of discharged electricity of the battery 12 is a predetermined amount from when a predetermined charging state is given to the battery 12 until the charging voltage of the specified voltage Vsh2 is applied to the battery 12. It is determined whether or not it is larger than this and whether or not the amount of discharge electricity per unit time is larger than a predetermined amount. In the meantime, when the amount of discharged electricity or the amount of discharged electricity per unit time does not exceed a predetermined amount, the battery 12 is identified based on the charging current when the specified voltage Vsh2 is applied as usual. If the amount of discharged electricity or the amount of discharged electricity per unit time exceeds a predetermined amount, the identification of the battery 12 is stopped.

  Although the discharge of the battery 12 greatly affects the charging current that flows thereafter, that is, the charging current of the battery 12 varies depending on the amount of discharge of the battery 12 that occurred before, but according to the configuration described above, the battery When the battery 12 is discharged in a large amount between the time when the predetermined charging state is given to the battery 12 and the time when the charging voltage of the specified voltage Vsh2 is applied to the battery 12, the battery identification based on the time waveform of the charging current is stopped. Is done. Therefore, according to the present embodiment, the battery 12 is identified due to the discharge of the battery 12 from when the predetermined charge state is given to the battery 12 until the charge voltage of the specified voltage Vsh2 is applied to the battery 12. It is possible to prevent the accuracy from deteriorating.

  It should be noted that the amount of electricity discharged from the battery 12 or the amount of electricity discharged per unit time after the predetermined charging state is given to the battery 12 until the charging voltage of the specified voltage Vsh2 is applied to the battery 12. When the identification of the battery 12 is stopped due to the occurrence of the battery, immediately after that or after a predetermined time (for example, 2 hours), the battery 12 is again given a predetermined charging state, and when the specified voltage Vsh2 is applied. The battery 12 may be identified based on the charging current.

  From the above, according to the battery identification method of the present embodiment, it is possible to realize appropriate identification of the battery 12, and thus, the battery 12 mounted on the vehicle is temporarily replaced. Even in this case, after the identification, it is possible to execute control related to the battery such as charge / discharge control and engine start control in accordance with the charge acceptance characteristic and internal resistance characteristic of the battery 12 actually mounted on the vehicle. It is possible to set a control constant (for example, charging voltage) that matches the characteristics of the battery 12 to be mounted.

  In this regard, according to the present embodiment, it is not necessary to limit the battery 12 mounted on the vehicle to one type of a specific manufacturer. Therefore, a plurality of types of batteries 12 by a plurality of manufacturers are mounted on the vehicle at random. It is possible to make it. In addition, all the characteristics data of all the batteries that may be mounted are stored in the memory in the vehicle, or all the characteristics data of the batteries that are stored in the memory in the vehicle may be mounted. It is not necessary to include the difference in characteristics of the batteries, so that the memory capacity can be reduced and the optimal control over the performance of the on-board battery 12 can be prevented. be able to. Therefore, according to the present embodiment, it is possible to appropriately execute the control related to the battery with a simple configuration and the optimal control constant corresponding to the battery 12 to be mounted.

  In the above-described embodiment, the specified charging voltage Vsh2 is the “predetermined voltage” described in the claims, and the predetermined charging voltage Vsh1 is the “predetermined charging voltage” described in the claims. The predetermined current value Ish1 of the charging current is the “predetermined value” described in the claims and the predetermined time Tsh1 is the “predetermined time” described in the claims. The value Ish2 and the time threshold value Tsh2 correspond to the “determination value for battery identification” described in the claims.

  Further, in the above embodiment, the controller 20 executes the process of step 100 in the routine shown in FIG. 2 so that the “charging step” and “charging means” described in the claims are processed in step 102. The “voltage application step” and the “voltage application means” described in the claims by executing the step 104 perform the processing of the step 104 to execute the “current detection step” and “current detection” described in the claims. By executing the processing of step 106, the “means” realizes the “battery identification step” and the “battery identification means” recited in the claims.

  By the way, in the above embodiment, the battery 12 mounted on the vehicle is identified. However, the present invention is not limited to this, and is mounted on another moving body such as a railroad or fixed. It is good also as applying to what installs the battery which can be charged / discharged.

  Further, in the above embodiment, the battery is identified among three types as shown in FIG. 4, but may be identified between two or more types.

  Further, in the above embodiment, after a predetermined charging state is given to the battery 12, the specified charging voltage Vsh2 is applied to the battery 12, and the battery is identified based on the waveform of the charging current flowing at that time. However, the present invention is not limited to this until the alternator 14 is decelerated so that the alternator 14 can generate power at the specified voltage Vsh2. However, the present invention is not limited to this. Immediately and forcibly, the specified charging voltage Vsh2 may be applied, and battery identification may be performed based on the waveform of the charging current flowing at that time.

  Further, in the above embodiment, the parameters necessary for identifying the battery 12 of the charging voltage Vsh1, the charging current Ish1, the predetermined time Tsh1, the specified voltage Vsh2, the current threshold value Ish2, and the time threshold value Tsh2, In addition, although the predetermined amount related to the amount of discharged electricity necessary for determining whether or not to stop the identification of the battery 12 is not changed according to the temperature of the battery 12, the temperature of the battery 12 as shown in FIG. It is good also as changing according to. FIG. 5 shows a relationship between the battery temperature and various determination parameters in the battery identification device 10 of the present modification.

  In general, the battery 12 changes its characteristics such as its charge acceptance characteristics according to the battery temperature. For example, the higher the battery temperature, the better the current acceptance, and quick charging is performed even under the same charging voltage. In this regard, in order to keep the battery identification accuracy uniform regardless of the battery temperature, the higher the battery temperature, the higher the thresholds Ish1 and Ish2 related to the current, and the lower the thresholds Vsh1 and Vsh2 related to the voltage. Alternatively, it is appropriate to shorten the threshold values Tsh1 and Tsh2 related to time or to increase the threshold value related to the amount of discharge electricity.

  Therefore, in the configuration of this modification, the controller 20 detects the temperature TH of the battery 12 based on a signal from the temperature sensor 24, and changes the various parameters described above according to the temperature TH. According to the configuration of such a modified example, it is possible to equalize a predetermined charging state given to the battery 12 as a precondition for battery identification regardless of the battery temperature, and to uniformize the accuracy of battery identification. Therefore, it is possible to prevent the identification accuracy from being lowered due to the temperature change of the battery. Moreover, since the determination accuracy of whether or not to stop battery identification can be made uniform regardless of the battery temperature, it is possible to prevent the determination accuracy of whether or not to stop battery identification due to a change in battery temperature. It becomes possible.

  In this modification, the controller 20 detects the temperature TH of the battery 12 on the basis of the signal from the temperature sensor 24, so that the “battery temperature detecting means” described in the appended claims has the battery temperature TH. Accordingly, the above-described charging voltage Vsh1, charging current Ish1, predetermined time Tsh1, specified voltage Vsh2, current threshold value Ish2, time threshold value Tsh2, or a predetermined amount related to the discharge electric quantity is changed. Each of the “parameter changing means” described in 1 is realized.

It is a lineblock diagram of a system provided with a battery identification device which is one example of the present invention. It is a flowchart of an example of the control routine performed in the battery identification apparatus of a present Example. It is an operation | movement time chart of an example in the battery identification device of a present Example. It is a figure showing the relationship between the electric current waveform at the time of battery identification in the battery identification device of a present Example, and the kind of battery. It is a figure showing the relationship between the battery temperature in the battery identification device which is a modification of this invention, and various determination parameters.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Battery identification device 12 Battery 14 Alternator 20 Controller 22 Current sensor 24 Temperature sensor

Claims (13)

A charging step for providing the battery with a predetermined state of charge;
A voltage applying step of applying a predetermined voltage to the battery given a predetermined state of charge in the charging step;
A current detection step of detecting a current flowing through the battery when a predetermined voltage is applied to the battery in the voltage application step;
A battery identification step for identifying a battery based on the current detected in the current detection step;
Equipped with a,
Wherein the predetermined state of charge to be supplied to the battery in the charging step, a battery identification method prescribed value below the charging current by applying a predetermined charging voltage, wherein the der Rukoto that continues for a predetermined time. Predetermined voltage, the battery identification method according to claim 1, characterized in that a higher specified voltage than a predetermined charging voltage to be applied in the charging step to be applied to the battery in the voltage application step. The amount of discharge of the battery or the amount of discharge per unit time is greater than or equal to a predetermined amount after the predetermined charging state is given to the battery in the charging step and before the predetermined voltage is applied to the battery in the voltage applying step. 3. The battery identification method according to claim 1, wherein the battery identification is stopped in the battery identification step.   A charging step for providing the battery with a predetermined state of charge;
  A voltage applying step of applying a predetermined voltage to the battery given a predetermined state of charge in the charging step;
  A current detection step of detecting a current flowing through the battery when a predetermined voltage is applied to the battery in the voltage application step;
  A battery identification step for identifying a battery based on the current detected in the current detection step;
  With
  The amount of discharge of the battery or the amount of discharge per unit time is greater than or equal to a predetermined amount after the predetermined charging state is given to the battery in the charging step and before the predetermined voltage is applied to the battery in the voltage applying step. If so, the battery identification method is characterized in that the battery identification in the battery identification step is stopped. The identification of the battery in the battery identification step, cell identification method according to any one of claims 1 to 4, characterized in that is carried out based on the time waveform of the current detected in the current detecting step. A charging means for giving a predetermined charging state to the battery;
Voltage application means for applying a predetermined voltage to the battery given a predetermined state of charge by the charging means;
Current detecting means for detecting a current flowing through the battery when a predetermined voltage is applied to the battery by the voltage applying means;
Battery identification means for identifying a battery based on the current detected by the current detection means;
Equipped with a,
It said charging means is a predetermined state of charge in the battery, the battery identification device a predetermined value or less of the charging current is characterized that you apply a predetermined charging voltage until continues for a predetermined time. The battery identification device according to claim 6 , wherein the voltage applying unit applies a specified voltage higher than a predetermined charging voltage applied by the charging unit as a predetermined voltage to the battery. The amount of discharge of the battery or the amount of discharge per unit time after the predetermined charging state is given to the battery by the charging means until the predetermined voltage is applied to the battery by the voltage applying means is a predetermined amount or more. The battery identification device according to claim 6 or 7 , wherein the battery identification unit stops the identification of the battery.   A charging means for giving a predetermined charging state to the battery;
  Voltage application means for applying a predetermined voltage to the battery given a predetermined state of charge by the charging means;
  Current detecting means for detecting a current flowing through the battery when a predetermined voltage is applied to the battery by the voltage applying means;
  Battery identification means for identifying a battery based on the current detected by the current detection means;
  With
  The amount of discharge of the battery or the amount of discharge per unit time after the predetermined charging state is given to the battery by the charging means until the predetermined voltage is applied to the battery by the voltage applying means is a predetermined amount or more. In this case, the battery identification device stops the identification of the battery by the battery identification means. Battery temperature detecting means for detecting the temperature of the battery;
A parameter for changing a predetermined charging state, a predetermined voltage, a predetermined value, a predetermined time, a predetermined charging voltage, or a determination value for identifying a battery according to the temperature detected by the battery temperature detecting means. Change means,
The battery identification device according to claim 6 or 7, further comprising:   Battery temperature detecting means for detecting the temperature of the battery;
  According to the temperature detected by the battery temperature detecting means, a predetermined charging state, a predetermined voltage, a predetermined value, a predetermined time, a predetermined charging voltage, a determination value for identifying a battery, or a predetermined amount Parameter changing means to be changed;
  The battery identification device according to claim 8, comprising:   Battery temperature detecting means for detecting the temperature of the battery;
  In accordance with the temperature detected by the battery temperature detecting means, a predetermined charging state, a predetermined voltage, a judgment value for identifying a battery, or a parameter changing means for changing a predetermined amount;
  The battery identification device according to claim 9, comprising: The current detection means detects a time waveform of a current flowing through the battery when a predetermined voltage is applied to the battery by the voltage application means,
The battery identification means, battery identification device of any one of claims 6 to 12, characterized in that the identification of the battery based on the time waveform of the current detected by said current detecting means.

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