JP2010086746A - Pack battery and its control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pack battery and its control method capable of reliably appealing to its user deterioration of a battery performance and capable of securing safety by prohibiting its usage without feelings of unpleasantness or incongruity. <P>SOLUTION: When deterioration of a secondary battery is detected, the user is informed of the same and usage of the pack battery is prohibited after passing of a predetermined grace period. In the grace period, a charge voltage of the secondary battery is lowered compared with a specified battery voltage and prohibition of usage is conducted by shutting down a charge/discharge electric passage of the secondary battery on condition that the secondary battery is not under discharging. Furthermore, in the grace period, a decreasing rate of a residual quantity of the secondary battery outputted outside while time elapses is enlarged in appearance. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a battery pack having a function of prohibiting its use when battery performance deteriorates and a control method thereof.

  A battery pack composed mainly of a secondary battery such as a lithium ion battery is detachably mounted on various electronic devices and electric motors, and used as a power source. However, this type of battery pack has a potential problem such that the battery performance of the secondary battery gradually deteriorates with long-term use, and the thermal stability thereof decreases. For this reason, it is recommended that a function for outputting some kind of deterioration warning, use prohibition message or the like be incorporated in the battery pack when used for a long period of time.

Incidentally, the performance deterioration and the life of the secondary battery can be determined by comparing the initial full charge amount and the current full charge amount as disclosed in, for example, Patent Document 1 below, As disclosed, it is determined by monitoring the change over time of the time required for constant voltage charging, and further as determined by the change over time in the internal resistance of the secondary battery during charging as disclosed in Patent Document 3. It has been proposed to do.
JP 2005-195388 A JP 2007-78506 A JP 2006-153663 A

  However, simply detecting the performance deterioration of the secondary battery and outputting an alarm such as a deterioration warning or prohibition of use and prohibiting the use of the battery pack along with this will cause an alarm to be issued without notice and sudden use. Prohibition processing can cause dissatisfaction and upset to the user. In this regard, it is conceivable to alert the user by detecting the degree of performance deterioration of the secondary battery and displaying this as the battery deterioration rate. However, if the battery deterioration rate or the like is constantly output (displayed), the appeal effect (appealability) to the user may become poor, for example, it may be mistaken for the remaining capacity display (charge warning) of the secondary battery. can not deny.

  The present invention has been made in consideration of such circumstances, and its purpose is to reliably appeal the user to the deterioration of the battery performance and prompt the user to replace it, and to use it without feeling of resistance or discomfort. It is an object of the present invention to provide a battery pack that can be prohibited and ensure safety and a control method thereof.

In order to achieve the above-described object, the battery pack control method according to the present invention manages the expiration date of the battery pack including the secondary battery and the charge / discharge control unit of the secondary battery.
Compare the characteristics or charge / discharge performance of the secondary battery with a predetermined deterioration determination condition to determine whether or not the secondary battery has deteriorated, and notify that when the deterioration of the secondary battery is detected. The use of the battery pack is prohibited after a predetermined grace period.

  Incidentally, the use prohibition of the battery pack is preferably executed by blocking the charge / discharge path of the secondary battery on condition that the secondary battery is not discharging. In addition, what is necessary is just to manage the said grace period as the usage time of the said battery pack, the total use integrated capacity, or the number of charge / discharge cycles, for example. In this grace period, for example, it is desirable to lower the charging voltage of the secondary battery below a specified battery voltage.

  The battery pack is provided with means for externally outputting the remaining capacity of the secondary battery, which is obtained on the basis of the full charge capacity of the secondary battery. Decreasing the remaining capacity of the secondary battery that is output externally by increasing the apparent decrease in the remaining capacity of the secondary battery during discharge during the grace period until the use is prohibited. It is also useful to increase the rate apparently.

Further, the battery pack according to the present invention includes a secondary battery, a control element that is inserted in a charge / discharge path of the secondary battery and can prohibit charging / discharging of the secondary battery, characteristics of the secondary battery, and / or Or a charge / discharge control unit that controls the charge / discharge of the secondary battery according to the monitoring result while monitoring the charge / discharge performance,
The charge / discharge control unit determines the presence or absence of deterioration of the secondary battery by comparing characteristics or charge / discharge results of the secondary battery with a predetermined deterioration determination condition, and the deterioration of the secondary battery is detected. A deterioration determining means for informing the fact sometimes,
And use prohibiting means for operating the control element after a predetermined grace period and prohibiting use of the battery pack when deterioration of the secondary battery is detected by the deterioration determining means. It is said.

  In addition, it is useful to provide the charging / discharging control unit with a limiting unit that lowers the charging voltage of the secondary battery below a specified battery voltage during the grace period. Further, the charge / discharge control unit further obtains the remaining capacity of the secondary battery with reference to the full charge capacity of the secondary battery, and outputs the remaining capacity to the outside, and the apparent appearance during discharge during the grace period It is also useful to provide output control means for controlling the remaining capacity of the secondary battery obtained by the remaining capacity output means by increasing the decrease in the remaining capacity of the secondary battery.

That is, the battery pack control method according to the present invention compares the deterioration of the secondary battery with a predetermined deterioration determination condition to determine whether or not the secondary battery has deteriorated, and the deterioration of the secondary battery is detected. Set a predetermined grace period,
The battery pack including the secondary battery includes means for externally outputting the remaining capacity of the secondary battery obtained based on the full charge capacity of the secondary battery, and after detecting deterioration of the secondary battery. In this grace period, the apparent decrease in the remaining capacity of the secondary battery during discharge is increased as time elapses.

  According to the battery pack of the above configuration and its control method, when the deterioration of the secondary battery is detected, the fact is notified, and the use of the battery pack is prohibited after a predetermined grace period. The user who has received the above-mentioned grace period replaces the battery pack before using the battery pack is forcibly prohibited, or stops the operation of the equipment powered by the battery pack. Can be taken with a margin.

  Also, if the secondary battery charging voltage is lowered below the specified battery voltage when secondary battery deterioration is detected, the secondary battery with degraded performance will not be overcharged. Problems caused by a decrease in thermal stability can be reduced. Furthermore, if the remaining capacity of the secondary battery determined by the remaining capacity output means is controlled by gradually decreasing the learning capacity during the grace period, the rate of decrease of the remaining capacity of the secondary battery output by this Since it can be apparently increased, it is possible to enhance the appeal effect (appealability) of battery performance degradation to the user.

Hereinafter, a battery pack and a control method thereof according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic configuration diagram of a main part of a battery pack 10 according to the present invention. The battery pack 10 is used by being mounted on an electronic device 30 such as a notebook personal computer, and is basically connected to a control / power supply unit (charger) 31 built in the electronic device 30. A secondary battery 1 to be charged is provided. A commercial power supply is supplied to the control / power supply unit (charger) 31 of the electronic device 30, and the secondary battery 1 is charged with energy obtained from the commercial power supply. The battery pack 10 is used as a power source for the electronic device 30 when the electronic device 30 does not use a commercial power source. That is, the power energy accumulated in the secondary battery 1 by charging is supplied to the load 32 such as a CPU or a memory that is the main body of the electronic device 30 via the control / power supply unit 31. .

  Incidentally, the secondary battery 1 is composed of a lithium ion battery, a nickel hydrogen battery, or the like, and is realized as a battery group in which a plurality of battery cells 2 are connected in series and parallel to ensure a predetermined battery voltage and battery capacity. Specifically, when the secondary battery 1 uses a battery cell 2 that is 4.2 V in a fully charged state, for example, a lithium ion battery, the battery cell 2 is connected in three stages in series. Is realized as having a battery voltage of 12.6V. Moreover, the required electric capacity is ensured by making the battery cell 2 of each step | paragraph connect the some battery cell in parallel, respectively.

  The plurality of battery cells 2 are connected in parallel and in series using, for example, a connection tab 3 made of a metal plate or a lead wire, and the secondary battery 1 is packaged by grouping these battery cells into one. Is realized. The number of battery cells 2 connected in parallel and the number of battery cells 2 connected in series are determined according to the specifications (battery voltage and battery capacity) required for the secondary battery 1 according to the load 2. Needless to say, the secondary battery 1 is not limited to the three parallel / three-stage series configuration illustrated in FIG. Also, in such a secondary battery 1, a temperature sensor 4 such as a thermistor for detecting the battery temperature T is integrally incorporated.

  On the other hand, the battery pack 10 includes a current detection unit (current detection means) 5 that is provided in the charge / discharge path of the secondary battery 1 and detects the charge / discharge current I of the secondary battery 1. The current detection unit 5 includes, for example, a shunt resistor inserted in series in the charge / discharge path, and a sensing amplifier that detects the charge / discharge current I of the secondary battery 1 from the voltage generated between both ends of the shunt resistor. Consists of. Whether the current flowing in the charge / discharge path of the secondary battery 1 is a charge current or a discharge current is determined from the polarity of the voltage generated across the shunt resistor depending on the direction of the current. Needless to say.

  The charging / discharging path of the secondary battery 1 includes a charge control switch (charge prohibiting means) 6 for preventing overcharge of the secondary battery 1 and a discharge for preventing overdischarge of the secondary battery 1. A control switch (discharge prohibiting means) 7 is provided. These control switches 6, 7 are composed of, for example, two P-channel MOS-FETs inserted in series in the charge / discharge path. The operation of these control switches (FETs) 6 and 7 is controlled by a control / arithmetic unit 20 described later. For example, the control switches (FETs) 7 and 7 are turned off when a high level (H) control signal is applied to their gates. (Off) Operates to cut off the charging current or discharging current for the secondary battery 1 respectively. That is, the control switches (FETs) 6 and 7 serve as charge / discharge prohibiting means for prohibiting charging and discharging of the secondary battery 1.

  The control / calculation unit 20 described above is realized by a microprocessor, for example. The control / calculation unit 20 basically detects the terminal voltage Vbat of the secondary battery 1 and the terminal voltage Vcell of each of the battery cells 2 constituting the secondary battery 1, and also controls the temperature sensor 4. The battery temperature T detected by the temperature detector 8 is input, and the charging / discharging current I of the secondary battery 1 detected by the current detector 5 is further input to charge and discharge the secondary battery 1. To control each.

  Incidentally, the control / calculation unit 20 illustrated in FIG. 1 includes the positive-side voltages V1, V2, V3 and negative-voltage V0 and the temperature detection unit 8 in the plurality of battery cells 2 connected in series in three stages. The detected battery temperature T is selectively input via the multiplexer 21 and is digitally converted via the A / D converter 22 and captured. In addition, the control / calculation unit 20 takes in the charge / discharge current I detected by the current detection unit 4 through digital conversion via the A / D converter 23. The voltages V1, V2, V3, V0 and the temperature information T are input cyclically in a predetermined cycle in synchronization with the sampling cycle of the multiplexer 21 and the A / D converter 22. The control / calculation unit 20 calculates the terminal voltage Vbat (= V1-V0) of the secondary battery 1 described above from the positive voltages V1, V2, V3 and the negative voltage V0 of the plurality of battery cells 2, and The terminal voltages Vcell1 (= V1-V2), Vcell2 (= V2-V3), and Vcell3 (= V3-V0) of each battery cell 2 are detected.

  Thus, the control / calculation unit 20 that detects the terminal voltage Vbat and the charge / discharge current I of the secondary battery 1 basically controls the operation of the control / power supply unit 30 via the communication processing unit 24. In addition to controlling the charging of the secondary battery 1 (full charge control), the charge control switch 6 described above is controlled to be off to prevent the secondary battery 1 from being overcharged (overcharge protection), and further to the discharge The control switch 7 is turned off to prevent overcharge of the secondary battery 1 (overdischarge protection). Further, as will be described later, the control / calculation unit 20 determines the degree (life) of the performance deterioration of the secondary battery 1, and when the performance deterioration is detected, outputs that effect. A function of urging the user of the attached electronic device 30 to replace the secondary battery 1 is provided.

  In the above-described full charge control for the secondary battery 1, in a nickel metal hydride battery or the like, for example, when the secondary battery 1 is charged, the terminal voltage Vbat of the secondary battery 1 gradually increases, and the terminal is fully charged. After the voltage Vbat reaches the peak, the state of full charge (100% charge) is determined using the phenomenon that the voltage Vbat decreases by a constant voltage (ΔV) (−ΔV method), and the charging of the secondary battery 1 is stopped. Done. Also, in constant current / constant voltage charging where the current value is limited to a predetermined value or less and the voltage value is limited to a predetermined value or less as in charging a lithium ion battery, during constant voltage charging after constant current charging When the charging current value becomes a predetermined value or less, this may be determined as full charge. In addition, it goes without saying that various charge control methods conventionally proposed, such as detecting a fully charged state from changes in the battery temperature T and changes in the charging current I, can be adopted as appropriate. In addition, since the present invention is not directly related to the full charge control of the secondary battery 1, further description of the full charge control is omitted.

  Further, the overcharge protection described above is performed when, for example, the terminal voltage Vbat of the secondary battery 1 exceeds a preset overcharge protection voltage as the secondary battery 1 or a plurality of battery cells 2 constituting the secondary battery 1. When the individual terminal voltage Vcell exceeds the overcharge protection voltage specific to each battery cell 2, the above charging control switch 6 is operated to forcibly cut off the charging path, thereby further charging ( It plays a role to prevent overcharge). Note that the terminal voltage (charge voltage) Vbat of the secondary battery 1 is managed by the full charge voltage in the above-described charge control in this embodiment, so that overcharge prevention by the operation of the charge control switch 6 is exclusively performed. When the terminal voltage Vcell of each battery cell 2 exceeds the overcharge protection voltage, the battery cell 2 operates.

  Further, overdischarge protection is performed when, for example, the terminal voltage Vbat of the secondary battery 1 approaches the preset overdischarge protection voltage of the secondary battery 1 or when the individual terminal voltages Vcell of the battery cells 2 in a plurality of stages are When the overdischarge protection voltage specific to the battery cell 2 approaches or reaches the overdischarge protection voltage, the discharge control switch 7 described above is operated to forcibly cut off the charging path, and the secondary battery 1 It plays a role to prevent deep discharge (overdischarge). In addition to such a protective function, the control / calculation unit 20 may, for example, detect the charging control switch 6 and / or the abnormal charging / discharging current for the secondary battery 1 from the charging / discharging current I. Or the discharge control switch 7 is operated, the charge / discharge path is interrupted, and the function etc. which protect not only the secondary battery 1 but the load 32 grade | etc., Are provided.

  Basically, in the battery pack (secondary battery device) configured as described above, the present invention is characterized in that the control / calculation unit 20 detects deterioration of characteristics of the secondary battery 1. 20a, and when the deterioration determination means 20a detects the deterioration of the characteristics of the secondary battery 1, the fact is notified, and after a predetermined grace period, the secondary battery 1, and thus the battery pack itself It is in the point provided with the use prohibition means 20b which prohibits use.

  Incidentally, the detection of the deterioration of the characteristics of the secondary battery 1 is performed, for example, by determining the change in the internal resistance of the secondary battery 1 or measuring the elapsed time (use time / standby time) from the start of use of the battery pack, as will be described later Or by comparing the integrated capacity (charge amount / discharge amount) from the start of use with a predetermined threshold. Further, the notification that the characteristics of the secondary battery 1 have deteriorated displays, for example, the remaining capacity or the remaining capacity rate of the secondary battery 1 and a warning message prompting the replacement of the battery pack via the communication processing unit 24. Is done by doing. The use of the battery pack after the predetermined grace period is prohibited, for example, by forcibly turning off the charge control switch 6 and the discharge control switch 7, respectively.

  When the battery pack has a configuration in which a resistance heating type fuse 26 is inserted in series in the charge / discharge path of the secondary battery 1 as shown in FIG. 2, for example, the resistance heating type fuse 26 is blown out. Thus, it is possible to disconnect the secondary battery 1 itself as a circuit, and thereby set the battery pack to be permanently prohibited. Incidentally, it is desirable to perform the process of prohibiting use of the battery pack by fusing the resistance heating type fuse 26 or controlling the discharge control switch 7 to be turned off on the condition that the secondary battery 1 is not discharged.

  In addition, the control / calculation unit 20 further includes a charging voltage limiting unit 20c that lowers the charging voltage for the secondary battery 1 below the specified battery voltage of the secondary battery 1 during the grace period until the use prohibition. The limitation of the charging voltage of the secondary battery 1 by the charging voltage limiting means 20c decreases the thermal stability of the secondary battery 1 whose characteristics have deteriorated. The purpose is to suppress heat generation. For this charging voltage control, for example, as shown in FIG. 2, an auxiliary charging control switch 6a is provided in parallel with the above-described charging control switch 6, and instead of the charging control switch 6, the auxiliary charging control switch 6a is used. The secondary battery 1 is charged. And you may make it reduce the charging voltage with respect to the said secondary battery 1 by the resistance 6b inserted in series by this auxiliary charge control switch 6a.

  Further, the control / calculation unit 20 apparently reduces the remaining capacity (or remaining capacity rate) of the secondary battery 1 output to the outside via the communication processing unit 24 in the grace period, apparently less than the actual remaining capacity. Thus, the remaining capacity output control means 20d for emphasizing the degree of deterioration of the battery performance is provided. That is, the remaining capacity output control means 20d increases the degree of change in the remaining capacity display in order to emphasize the degree of battery performance deterioration. Play a role in encouraging exchanges.

  This remaining capacity output control means 20d determines the maximum charge amount (total capacity) of the secondary battery 1 determined in accordance with, for example, the number of repetitions of charging / discharging (so-called cycle number) of the secondary battery 1, etc. When the capacity obtained by subtracting the discharge amount from the learning capacity is obtained as the remaining capacity of the secondary battery 1, the learning capacity is gradually reduced during the grace period. Incidentally, the learning capacity is obtained, for example, as a cumulative discharge capacity until the secondary battery 1 is completely discharged from the fully charged state, or as a cumulative charge capacity from the fully discharged state to full charge. For example, the learning capacity described above may be obtained by multiplying the charging current of the secondary battery 1 by a predetermined charging efficiency, or by calculating the discharging current in consideration of the predetermined discharging efficiency.

  FIG. 3 shows an example of the battery performance deterioration detection process in the battery pack configured as described above and the use prohibition process of the battery pack whose battery performance has deteriorated. This processing is executed when the secondary battery 1 is discharged. For example, first, information on the discharge time measured by a timer (not shown; built in the control / calculation unit 20) provided in the battery pack 10 and the second time. The process starts from obtaining the total use time and the total use integrated capacity from the discharge current per unit time of the secondary battery 1 <Step S1>. Specifically, the discharge time of the secondary battery 1 that is repeatedly charged and discharged is measured by a timer, and the total use time is obtained by sequentially integrating the discharge time. Further, the used capacity (discharge amount) is obtained as the product of the discharge current I per unit time from the secondary battery 1 and the discharge time, and the used capacity obtained as described above is integrated every time charging / discharging is repeated. Obtain the total accumulated capacity. The total use time may be a time measured by a timer built in the control / calculation unit 20 from the time when the battery pack is manufactured or the specification start time of the battery pack. Further, the total accumulated usage capacity may be a usage capacity obtained by adding the discharge amount and the charge amount, or may be the number of charge / discharge cycles as described later.

  After that, by comparing the total use time and the total use accumulated capacity obtained as described above with the prescribed values 1 and 2 set in advance, whether or not the total use time has exceeded the predetermined value 1, and the total It is determined whether or not the accumulated usage capacity exceeds a predetermined value <steps S2 and S3>. The determination as to whether or not the total usage time has exceeded the predetermined value 1 is based on the usage time of the battery pack 10, and the usage time of the battery pack 10 for functioning the secondary battery 1 safely and stably as a power source. It is determined whether (total discharge time) has reached a presumed usable time (for example, 5 years). The determination of whether or not the total used integrated capacity has reached the predetermined value 2 is based on the fact that the battery performance of the secondary battery 1 gradually deteriorates due to repeated charge / discharge, and the secondary battery 1 that has been repeatedly charged / discharged. It is determined whether or not the total discharge amount (the integrated value of the discharge amount) has reached the battery performance assumed in advance (lifetime capacity until the secondary battery undergoes cycle deterioration; for example, discharge capacity for 800 cycles). is there.

  By these determination processes, it is determined whether or not the battery pack 10 has been used for a presumed usable time (long-term use determination). If the total use time exceeds the predetermined value 1 or the total use accumulated capacity exceeds the predetermined value 2, the battery pack 10 is used for a period of guaranteeing its stable operation, and the replacement is performed. Judge as having reached the time. In this case, it is determined whether or not a preset grace period is left until the next use of the battery pack 10 is prohibited. Even if it is detected that the battery pack 10 has reached the replacement time by the above-described long-term determination process, this grace period determination process is performed immediately after a predetermined grace period is anticipated without prohibiting its use. This is a consideration for preventing the user of the battery pack 10 from feeling dissatisfied or shaking by prohibiting the use of the battery 10.

  In this grace period determination process, the total use time and the total use capacity obtained as described above are respectively compared with predetermined values 3 and 4 to determine whether the total use time has exceeded the predetermined value 3 or not. This is performed by determining whether or not the total accumulated capacity used exceeds a predetermined value 4 (steps S4 and S5). Specifically, whether or not the total use time has exceeded the predetermined value 3 is determined by determining whether or not the use time (total discharge time) has reached a presumed use limit time (for example, 5 years and 2 months). Is. Further, whether or not the total accumulated capacity has reached the predetermined value 4 is determined based on the battery performance (the secondary battery is completely cycled) that the total discharge amount (the accumulated value of the discharge amount) of the secondary battery 1 is assumed in advance. It is determined whether or not a lifetime capacity until deterioration; for example, a discharge capacity of 800 cycles + 40 cycles) has been reached. Incidentally, the grace period is set in anticipation of a period during which a new battery pack 10 as a service part is available.

  By the above determination process <steps S2, S3, S4, and S5>, <1> whether the battery pack 10 is still used for a short time, or <2> Whether the battery 10 has been used for a sufficiently long time and it is time to replace the battery pack 10 in order to stably use the electronic device 30 with the battery pack 10 mounted thereon. <3> Has reached the limit, and three states that the use of the battery pack 10 should be prohibited in order to guarantee its safety.

Here, processing when it is determined that the battery pack 10 can be continuously used as it is will be described. In this case, in order to manage the performance of the secondary battery 10, the remaining capacity RC (Remaining Capacity) is obtained and the relative remaining capacity RSOC (Relative State Of Capacity) is obtained <step S6>. Specifically, by subtracting the discharge capacity ΔI [Amsec] obtained by multiplying the discharge current at that time by the measurement unit time from the remaining capacity oldRC [Amsec] obtained previously, the remaining capacity updated at the present time is subtracted. Capacity newRC [Amsec]
newRC = oldRC−ΔI
Asking. Further, the newly obtained remaining capacity newRC [Amsec] is divided by the previously obtained full charge capacity FCC [Amsec] of the secondary battery 1 to obtain the relative remaining capacity RSOC of the secondary battery 1 at that time. RSOC = newRC / FCC
Asking. The relative remaining capacity RSOC indicates the ratio of the remaining capacity RC to the full charge capacity FCC of the secondary battery 1 and corresponds to a so-called remaining capacity ratio displayed as [Remaining Capacity%] or the like.

  Thereafter, it is determined whether or not the remaining capacity newRC obtained as described above has become negative, that is, whether or not all of the charge energy charged in the secondary battery 1 has been discharged, and the discharge has been completed. The remaining capacity newRC is initialized as [0]. Then, the secondary battery 1 is recharged under the above-described charging control, the end voltage is determined and it is detected that the battery has reached full charge, and then the above-described full charge capacity FCC is updated <step S7>. After this processing, the processing from step S1 described above is repeatedly executed.

  On the other hand, when the usage period of the secondary battery 1 is sufficiently long and it is time to replace the battery pack 10, and the above-described grace period in which the deterioration is detected remains, the secondary battery is firstly replaced. 1 to reduce the charging voltage of the secondary battery 1 in order to ensure safety (step S8). The charge voltage reduction control may be performed under the control / control of the control / power supply unit 31 by giving an instruction to the control / power supply unit 31 as shown in FIG. When the auxiliary charging control switch 6a is provided, the charging voltage is suppressed by charging the secondary battery 1 from the auxiliary charging control switch 6a through the resistor 6b in a state where the charging control switch 6 is cut off. Anyway. In this case, the charging voltage of the secondary battery 1 can be reduced and the operation safety can be ensured only by control by the control / calculation unit 20 provided in the battery pack 10 without imposing a burden on the electronic device 30 side. Is possible.

Thereafter, the full charge capacity newFCC of the secondary battery 1 in a state where the usage period of the secondary battery 1 extends for a long time is obtained. The full charge capacity newFCC is obtained by, for example, multiplying the original full charge capacity FCC of the secondary battery 1 obtained in advance by a predetermined coefficient, for example, [0.9].
newFCC = FCC × 0.9
Is calculated as <Step S9>. In other words, in this example, the charging voltage is lowered so that the full charge capacity FCC is reduced by about 10%, and the original charge capacity FCC of the secondary battery 1 is multiplied by the coefficient [0.9]. Find the full charge capacity newFCC.

Thereafter, the remaining capacity newRC of the secondary battery 1 at this time is obtained, the relative remaining capacity RSOC of the apparent secondary battery to be output to the outside, and the remaining capacity RC for actually managing the performance of the secondary battery 1 and Relative remaining capacity RSOC is obtained <step S10>. Specifically, as a parameter for evaluating the performance deterioration of the secondary battery 1, the parameter α focusing on the total use time is α = (total use time−default value 1) / (default value 3−default value 1).
And the parameter β focusing on the total accumulated capacity used is β = (total accumulated capacity−default value 2) / (default value−default value 2)
Asking. That is, the ratio of the usage period of the secondary battery 1 to the grace period after the time when the secondary battery 1 is determined to have been used for a preset period in steps S2 and S3 described above is obtained. Here, the parameter α is a value that rises from [0] when the total usage time exceeds the predetermined value [1], and approaches [1] when the total usage time approaches the default value [3]. When the capacity exceeds the predetermined value [2], it rises from [0], and when the capacity approaches the default value [4], the capacity approaches [1].

Of these parameters α and β, a parameter having a larger ratio of the usage period to the grace period is set as a new parameter γ, and the apparent remaining capacity newRC [Amsec] at that time is, for example, (apparent) newRC = oldRC -ΔI (1 + 0.5γ)
Calculate as Further, by dividing the newly obtained remaining capacity newRC by the full charge capacity newFCC obtained as described above of the secondary battery 1, the apparent relative remaining capacity of the secondary battery 1 at that time is obtained. RSOC (Fake) RSOC = newRC / newFCC
Asking. These remaining capacity newRC and relative remaining capacity RSOC are output to the electronic device 30 and presented (displayed) to the user.

  The process shown in steps S8 to S10 described above limits the amount of discharge from the secondary battery 1 by reducing the battery voltage itself of the secondary battery 1 during the grace period as shown in FIG. Thus, the role of ensuring the operational safety of the secondary battery 1 and the change (decrease) in the apparent remaining capacity RC of the secondary battery 1 at the time of discharging are increased to increase the relative remaining capacity RSOC associated with the discharging. It plays a role of apparently increasing the rate of change in Incidentally, in FIG. 4, the horizontal axis is time. And the amount of discharge corresponding to this is shown.

As described above, the remaining capacity RC and relative remaining capacity for actually managing and controlling the charging / discharging of the secondary battery 1 are performed in parallel with the determination of the remaining capacity newRC and relative remaining capacity RSOC for display output. The capacity RSOC is the same as the processing in step S6 described above (actually) newRC = oldRC−ΔI
(Actual) RSOC = newRC / FCC
As required. Then, after performing the process of step S7 described above according to the obtained remaining capacity RC and relative remaining capacity RSOC, the process from step S1 described above is repeatedly executed.

  On the other hand, when the secondary battery 1 is used after the grace period described above, an indication (notification) that the battery life has been exhausted is made to prompt prompt replacement of the battery pack 10. <Step S11>. At the same time, in order to prohibit the use of the battery pack 10, for example, the next charging prohibition control is performed <step S12>. This charge prohibition control is performed by shutting off the auxiliary charge control switch 6a in addition to the above-described shutoff of the charge control switch 6. As a result, the discharge from the secondary battery 1 is performed until charging energy remains in the secondary battery 1, that is, until the remaining capacity RC becomes [0]. Since subsequent charging is prohibited, the use of the battery pack 10 itself becomes impossible.

  In the case where the charging / discharging path of the secondary battery 1 is forcibly cut off using the temperature fuse 26 described above, if the secondary battery 1 is being discharged, the temperature fuse is discharged after the discharge is completed. It is desirable to melt 26. In this way, even when the electronic device 30 is in use even though the replacement of the battery pack 10 has been instructed, the use of the battery pack 10 can be prohibited with a slight margin. Therefore, the user of the electronic device 30 instructed to prohibit the use of the battery pack 10 can quickly finish the work using the margin period. In addition, for the battery pack 10, since all (most) of the remaining charge capacity remaining in the secondary battery 1 is discharged and discarded, it is possible to ensure safety as a used battery pack. Become.

  According to the battery pack configured to have such a function, when the deterioration of the characteristics of the secondary battery 1 is detected, the user of the electronic device 30 wearing the battery pack 10 as a power source is informed of the battery pack 10. In addition to notifying a message that prompts replacement, and prohibiting the use of the battery pack 10 after a predetermined grace period, the user can use the grace period after receiving the message to recharge the secondary battery. 1 characteristic degradation (life) can be dealt with with a margin. Specifically, even if a warning message about characteristic deterioration is received, the use of the battery pack 10 is not immediately prohibited, so that the user does not need to stop using (interrupting) the electronic device 30. Then, for example, the user can replace the electronic device 30 with a new battery pack 10 after completing the electronic device 30 through a predetermined procedure using the above-described grace period.

Further, as described above, during the grace period, the apparent remaining capacity newRC is set using ΔI (1 + 0.5γ) larger than the actual ΔI.
newRC = oldRC−ΔI (1 + 0.5γ)
Therefore, for example, the apparent rate of change (reduction rate) of the remaining capacity RC of the secondary battery 1 presented to the user can be made faster than that during normal use, thereby paying attention to the user. It becomes possible to evoke effectively. Therefore, in combination with the above-described warning message, it is possible to sufficiently enhance the appeal effect of battery performance degradation to the user in the grace period until the use of the battery pack is prohibited.

Here, the battery performance deterioration determination by the deterioration determination means 20a described above will be described in a little more detail.
The deterioration of the battery performance may be caused by, for example, detecting the internal resistance of the secondary battery 1 or detecting the maximum capacity that can be charged in the secondary battery 1 or the number of charge / discharge cycles of the secondary battery 1 (repetitive charge / discharge cycles). The number of times can be determined. Of course, it is possible to detect deterioration of battery performance by a conventionally known method other than these methods, and the deterioration in the degree of deterioration of the battery performance detected by using these plural types of methods. It is also possible to adopt the one with the most advanced as the deterioration detection result.

The technique for detecting the deterioration of the battery performance from the internal resistance of the secondary battery 1 focuses on the property that the internal resistance increases with the deterioration of the battery performance. That is, the internal resistance R of the secondary battery 1 is determined from the terminal voltage Eocv of the secondary battery 1 at no load and the voltage Vccv of the secondary battery 1 when the current I flows through the secondary battery 1.
R = (Eocv−Eccv) / I
Can be obtained as Accordingly, the internal resistance R obtained in advance according to the degree of deterioration (degradation level) of the secondary battery 1 is given as a function or a table, and the degree of characteristic deterioration at that time is calculated from the internal resistance R calculated as described above. Should be asked.

  Specifically, the minimum internal resistance Rmin of the new secondary battery 1 and the maximum internal resistance Rmax of the secondary battery 1 whose life has expired are measured in advance, and the internal resistance R of the secondary battery 1 is the maximum internal resistance Rmax. The state in which the internal resistance R of the secondary battery 1 is in the state of the minimum internal resistance Rmin is determined as the deterioration degree 0%. For example, if a change in resistance value from the minimum internal resistance Rmin to the maximum internal resistance Rmax is associated with the degree of deterioration and the relationship is defined as a table or function, the deterioration is determined from the internal resistance R of the secondary battery 1. Can be determined. The characteristic of the change in internal resistance with respect to the degree of deterioration is not necessarily defined linearly, but is preferably defined as a monotonically increasing function. Then, when the internal resistance R of the secondary battery 1 calculated as described above exceeds a preset determination threshold value Rth, this may be detected as “the battery performance of the secondary battery 1 has deteriorated”. .

  On the other hand, when detecting the characteristic deterioration of the secondary battery 1 by paying attention to the fact that the capacity (full charge capacity) that can be charged to the secondary battery 1 decreases as the characteristic of the secondary battery 1 deteriorates, The capacity that can be charged to the new secondary battery 1 is obtained in advance as the maximum charge capacity, and the maximum charge capacity that can be charged to the secondary battery 1 whose life has expired is obtained. Then, based on these maximum charging capacities, the actual charging capacity of the secondary battery 1 and the degree of performance deterioration are associated with each other and registered as a table or a function. This function is not necessarily defined linearly. Thereafter, a substantial amount of charge from the fully discharged state of the secondary battery 1 to full charge is measured as a substantial capacity, and the performance deterioration degree of the secondary battery 1 is determined with reference to the above table or function. Just do it. Based on the above-mentioned maximum charge capacity, a charge capacity that can be regarded as having deteriorated battery performance is set in advance as a determination threshold, and when the actual capacity measured as described above falls below the determination threshold, It may be detected that the battery performance has deteriorated.

  Furthermore, when determining the deterioration of the battery performance based on the number of charge / discharge cycles of the secondary battery 1 (the number of charge / discharge cycles), the following may be performed. The charge / discharge cycle of the secondary battery 1 is defined as one cycle when the fully discharged secondary battery 1 (remaining capacity is 0%) is fully charged and then fully discharged. . Since the battery performance of the secondary battery 1 gradually deteriorates every time the charge / discharge cycle is repeated, the above-described charge / discharge cycles are accumulated, and when the number of cycles reaches a preset determination threshold, You may make it detect as the performance of the battery 1 having deteriorated.

  In addition, instead of counting the charge / discharge cycle described above only when the secondary battery 1 is fully discharged from the fully discharged state, the charge capacity or discharge capacity is integrated. It is also possible to count. That is, in this case, the charge capacity of the secondary battery 1 that is repeatedly charged and discharged is accumulated (accumulated), and each time the accumulated value (accumulated value) reaches the substantial capacity of the secondary battery 1, this is counted as one cycle. It is also possible to do. Specifically, the secondary battery 1 having a real capacity of 1000 mAh is charged 500 mAh for the first time, 200 mAh for the second time, and 300 mAh for the third time. May be counted as one cycle. Of course, it is possible to discharge the secondary battery 1 during the period of charging the secondary battery 1 over a plurality of times. Alternatively, the secondary battery 1 can be fully charged to stop charging. Town theory is possible.

  It is also possible to count the charge / discharge cycles by paying attention to the discharge amount of the secondary battery 1 instead of the charge amount described above. That is, in this case, the discharge capacity of the secondary battery 1 that is repeatedly charged and discharged is accumulated (accumulated), and each time the accumulated value (accumulated value) reaches the substantial capacity of the secondary battery 1, this is counted as one cycle. Just do it. Even in this case, it is of course possible to charge the secondary battery 1 in the middle thereof.

  As another method, it is also possible to determine the characteristic deterioration of the secondary battery 1 by measuring the usage time of the battery pack. Specifically, using a real time clock (timer) built in the battery pack, the usage time of the battery pack is monitored from the start of use. That is, the actual working time (charging time + discharging time) during which the secondary battery 1 is charged / discharged is counted, and the so-called standby time during which the charging / discharging of the secondary battery 1 is stopped is counted. Then, an actual working time obtained by multiplying the standby time by a predetermined coefficient is added to the actual working time to obtain a usage time of the secondary battery 1, and the performance guarantee time of the secondary battery 1 set in advance is used. Can be determined as the battery performance of the secondary battery 1 has deteriorated. The performance guarantee period (expiration date) in this case may be set as 3 to 15 years, for example, 7 years or 10 years.

  By the way, when the overcharge of the secondary battery 1 is detected and the battery pack 10 is shut down, there is a possibility that information on the usage time measured by the timer operating with the secondary battery 1 as a power source may be lost. There is. Therefore, in such a case, when the information on the usage time measured by the timer is stored in the nonvolatile memory, and the secondary battery 1 is recharged and the timer becomes operable, The information on the usage time stored in the memory can be read out, and the subsequent timing operation can be resumed. It is of course possible to manage the usage time while acquiring the absolute time by using a radio clock as a real time clock or by using an information communication function with the electronic device 30.

  In the above description, it has been described that the performance deterioration accompanying the repeated charging / discharging of the secondary battery 1 is detected and the use of the battery pack 10 is prohibited. However, the voltage of the voltage cell detected as described above is used. Even when abnormality of the secondary battery 1 itself is detected based on the battery temperature or the like, the use of the battery pack 10 can be prohibited in the same manner. Specifically, when the voltage of the battery cell exceeds the predetermined value, or even when the charging capacity obtained from the charging current and the charging time when the secondary battery 1 is charged exceeds the predetermined value, it is not When charging is not detected, or when the battery temperature is higher than this, it is possible to detect this as an abnormality of the secondary battery 1 and prohibit use of the battery pack 10.

  Furthermore, when the voltage of the battery cell changes in a state where no charge / discharge current is detected, specifically, when the change of the cell voltage exceeds a predetermined value (for example, 20 mV) for a predetermined time (for example, 30 minutes). Of course, it is possible to detect the occurrence of a short circuit or micro short circuit in the secondary battery 1 and prohibit the use of the battery pack as a battery failure. Furthermore, in the secondary battery 1 in which a plurality of battery cells are connected in parallel, when the voltage change within a predetermined time during charging / discharging is abnormally large, this is detected as a tab disconnection abnormality between the plurality of battery cells, and as a battery failure It is of course possible to prohibit the use of the battery pack.

  In short, the control method of the battery pack according to the present invention detects the deterioration of the secondary battery characteristics due to the abnormality or the life and prohibits the use of the battery pack, and notifies that the battery characteristics have deteriorated. Since the use of the battery pack is prohibited after a predetermined grace period from the time when the characteristic deterioration is detected, the user (user) of the battery pack can deal with the characteristic deterioration of the secondary battery with a margin. Further, during the grace period, information indicating the degree of deterioration of the battery characteristics is emphasized and output, so that, for example, the change in the remaining battery capacity due to the use of the battery pack 10 becomes faster than the normal time. Such as being able to call attention to a person (user) effectively.

  Needless to say, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention.

The principal part schematic block diagram of the battery pack which concerns on one Embodiment of this invention. The figure which shows the structural example of the use prohibition means in a pack battery, and a charging voltage limiting means. The figure which shows an example of the process sequence for demonstrating the control method of the battery pack which concerns on one Embodiment of this invention. The figure for demonstrating the effect by the battery voltage control in a grace period, and the output control of remaining capacity.

Explanation of symbols

1 Secondary battery 5 Current detector 6, 7 Control switch (charge / discharge prohibition means)
DESCRIPTION OF SYMBOLS 8 Temperature detection part 10 Pack battery 20 Control / calculation part 20a Degradation determination means 20b Use prohibition means 20c Charge voltage limiting means 20d Remaining capacity output control means 26 Resistance heating type fuse 30 Electronic device

Claims (10)

A battery pack control method for managing the expiration date of a battery pack comprising a secondary battery and a charge / discharge controller for the secondary battery,
Compare the characteristics or charge / discharge performance of the secondary battery with a predetermined deterioration determination condition to determine whether or not the secondary battery has deteriorated, and notify that when the deterioration of the secondary battery is detected. A method of controlling a battery pack, wherein use of the battery pack is prohibited after a predetermined grace period.   2. The method of controlling a battery pack according to claim 1, wherein the use prohibition of the battery pack is executed by blocking a charge / discharge path of the secondary battery on condition that the secondary battery is not being discharged. .   The method for controlling a battery pack according to claim 1, wherein the charging voltage of the secondary battery is lowered below a specified battery voltage during the grace period.   The method of controlling a battery pack according to claim 1, wherein the grace period is managed as a use time, a total use accumulated capacity, or a charge / discharge cycle number of the battery pack. The method for controlling a battery pack according to claim 1,
The battery pack includes means for externally outputting the remaining capacity of the secondary battery, which is obtained based on the full charge capacity of the secondary battery,
Increasing the apparent decrease in the remaining capacity of the secondary battery at the time of discharge over time during the grace period until the use of the battery pack is prohibited after the deterioration of the secondary battery is detected. A battery pack control method characterized by the above. A secondary battery, a control element that can be inserted into a charge / discharge path of the secondary battery and prohibit the charge / discharge of the secondary battery, and monitor the characteristics and / or charge / discharge performance of the secondary battery. A charge / discharge control unit for controlling charge / discharge of the secondary battery according to a monitoring result,
The charge / discharge control unit determines the presence or absence of deterioration of the secondary battery by comparing characteristics or charge / discharge results of the secondary battery with a predetermined deterioration determination condition, and the deterioration of the secondary battery is detected. A deterioration determining means for informing the fact sometimes,
And use prohibiting means for operating the control element after a predetermined grace period and prohibiting use of the battery pack when deterioration of the secondary battery is detected by the deterioration determining means. Pack battery.   The battery pack according to claim 6, wherein the grace period is managed as a use time, a total use accumulated capacity, or a charge / discharge cycle number of the battery pack. The battery pack according to claim 6, wherein
The charge / discharge control unit further includes a limiting unit that lowers a charging voltage of the secondary battery below a specified battery voltage during the grace period. The battery pack according to claim 6 or 8,
The charge / discharge control unit further obtains a remaining capacity of the secondary battery based on a full charge capacity of the secondary battery and outputs the remaining capacity to the outside, and
Output control means for controlling the remaining capacity of the secondary battery required by the remaining capacity output means so as to increase the apparent decrease in the remaining capacity of the secondary battery during discharge during the grace period. Pack battery. Determining whether or not the secondary battery has deteriorated by comparing the deterioration of the secondary battery with a predetermined deterioration determination condition, and providing a predetermined grace period when the deterioration of the secondary battery is detected,
The battery pack including the secondary battery includes means for externally outputting the remaining capacity of the secondary battery obtained based on the full charge capacity of the secondary battery, and after detecting deterioration of the secondary battery. A control method for a battery pack, wherein the apparent decrease in the remaining capacity of the secondary battery at the time of discharging is increased as time elapses during the grace period.

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