JP2006101699A - Battery pack arrangement - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress overdischarging and overcharging of a module battery that constitutes the battery pack. <P>SOLUTION: The battery pack arrangement 20 has the battery pack 21 formed by connecting in series a plurality of module batteries 24a to 24n constituted by at least one cell 22. The battery pack arrangement 20 is provided with an abnormality detecting device of the battery pack, comprising a module voltage detection means for detecting each voltage of a plurality of the module batteries 24a to 24n, an equalization means for equalizing the voltage of each module battery based on the voltage of the detected each module battery, and an abnormality decision means for deciding abnormality of the module voltage detection means. In addition, the battery pack arrangement 20 is provided with an equalization regulating means for regulating the equalization by the equalization means, when abnormality is detected by the abnormality detection device. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an assembled battery device, and more particularly, to an assembled battery device including an assembled battery formed by connecting a plurality of module batteries configured by at least one unit cell in series.

  Conventionally, as this type of assembled battery device, a device that detects a charge / discharge voltage for each module battery and suppresses overcharge, overdischarge, or failure during charge / discharge has been proposed (for example, Patent Document 1, 2). In this device, a plurality of module batteries composed of a plurality of single cells are connected in series to form an assembled battery, and the voltage at the time of charging / discharging is detected for each module battery at the time of charging / discharging of the assembled battery. .

JP-A-5-64377 JP-A-8-140204

  However, in such an assembled battery device, an abnormality occurring in the voltage detection system cannot be detected, and charge / discharge cannot be properly managed when an abnormality occurs in the voltage detection system. In an assembled battery device that performs voltage equalization for each module battery, even if an abnormality occurs in the voltage detection system, the voltage of the module battery is equalized, so the module battery may be overdischarged or overcharged. Arise.

  Then, this invention provides the assembled battery apparatus which can suppress the overdischarge and overcharge of a module battery.

  In addition, the applicant has proposed what detects abnormality of a module battery as this kind of assembled battery apparatus (Japanese Patent Application No. 9-339123). In this apparatus, the voltage of the module battery is detected, and the abnormality of the module battery is determined based on whether or not the detected voltage is within an allowable range.

  An assembled battery device according to the present invention is an assembled battery device having an assembled battery formed by connecting a plurality of module batteries configured by at least one single battery in series, and each of the plurality of module batteries of the assembled battery. Module voltage detection means for detecting voltage, equalization means for equalizing the voltage of each module battery based on the detected voltage of each module battery, and abnormality determination means for determining abnormality of the module voltage detection means And an equalization regulation means for regulating equalization by the equalization means when an abnormality is detected by the abnormality detection apparatus.

  In this assembled battery device according to the present invention, when an abnormality is detected by the abnormality detection device, the equalization regulation means regulates the equalization of the voltage of the module battery, so the module based on the voltage detected by the abnormal voltage detection means The equalization of the battery voltage can be suppressed. As a result, overdischarge or overcharge of the module battery can be suppressed.

  Next, embodiments of the present invention will be described using examples. FIG. 1 is a configuration diagram showing an outline of the configuration of an assembled battery device 20 according to an embodiment of the present invention. As illustrated, the assembled battery device 20 of the embodiment includes an assembled battery 21 whose output terminal is connected to the load 10 by a power line, and an electronic control unit 40 that manages the assembled battery 21.

  The assembled battery 21 is configured by connecting a plurality of module batteries 24a to 24n formed by connecting a plurality of unit cells 22 such as lithium ion batteries in series. Cell equalization circuits 28a to 28n for equalizing the voltages of the unit cells 22 using the voltage detection lines 26a to 26n for detecting the voltages of the unit cells 22 are attached to the module batteries 24a to 24n. . Hereinafter, the numerals of the parts corresponding to the n module batteries 24a to 24n are displayed using numerals and subscripts of alphabets a to n.

  The electronic control unit 40 is configured as a microprocessor centered on a CPU 42 and includes a ROM 44 that stores a processing program and a RAM 46 that temporarily stores data. The electronic control unit 40 is connected to conductive lines 32a to 32n + 1 connected to the connection ends of the module batteries 24a to 24n, and each module battery is detected by detecting a potential difference between the conductive lines 32a to 32n + 1. The voltages 24a to 24n can be detected. In the electronic control unit 40, the remaining capacities Sa to Sn of the module batteries 24a to 24n are calculated based on the detected voltages of the module batteries 24a to 24n. Since the calculation of the remaining capacity (SOC) based on the voltage is well known, its description is omitted. Further, resistors 34a to 34n and transistors 36a to 36n are connected in series between the conductive lines 32a to 32n + 1, and the bases of the transistors 36a to 36n are connected to the electronic control unit 40 by signal lines 38a to 38n. It is connected. Therefore, the electronic control unit 40 can turn on and off the transistors 36a to 36n by outputting on / off signals to the signal lines 38a to 38n. The electronic control unit 40 also outputs a lighting signal to the indicator 48 that lights when the voltage detection system of the assembled battery 21 or the module batteries 24a to 24n is abnormal.

  Next, the operation of the assembled battery device 20 of the embodiment configured as described above, particularly the operation for detecting the abnormality of the voltage detection system of the module batteries 24a to 24n and the operation when this abnormality is detected will be described. FIG. 2 is a flowchart illustrating an example of an abnormality detection processing routine executed by the electronic control unit 40 of the assembled battery device 20 according to the embodiment. This routine is repeatedly executed every predetermined time (for example, every hour).

  When the abnormality detection processing routine is executed, the CPU 42 of the electronic control unit 40 first detects a potential difference between the conductive lines 32a to 32n + 1 to detect voltages Va to Vn of the module batteries 24a to 24n. Execute (Step S100). Subsequently, the remaining capacity Sa to Sn of each module battery 24a to 24n is calculated based on the detected voltage Va to Vn of each module battery 24a to 24n (step S102), and the calculated remaining capacity Sa to Sn and the previous time The remaining capacity time change rates DSa to DSn are calculated using the remaining capacity Sa to Sn calculated when the routine is executed (step S104). Specifically, this is performed by dividing the deviation between the current remaining capacity Sa to Sn and the previous remaining capacity Sa to Sn by the time interval at which the abnormality detection processing routine is executed.

  Then, an average value A of the remaining capacity time change rates DSa to DSn is calculated (step S106), and the calculated average value A is multiplied by a predetermined coefficient a, the average value A is multiplied by a predetermined coefficient b, and each The time change rates DSa to DSn of the remaining capacity are compared (step S108). Here, the predetermined coefficient a and the predetermined coefficient b are coefficients that determine an upper limit and a lower limit of the allowable variation from the average value A of the time change rates DSa to DSn of the remaining capacity, and the single battery 22 and the module batteries 24a to 24n. It is determined by the characteristics and specifications. When any of the remaining capacity time change rates DSa to DSn is smaller than the average value A multiplied by the predetermined coefficient a and larger than the average value A multiplied by the predetermined coefficient b, an abnormality has occurred in all voltage detection systems. If it is determined that there is no, this routine is terminated. On the other hand, when the time change rate DS of any remaining capacity is larger than the average value A multiplied by the predetermined coefficient a or smaller than the average value A multiplied by the predetermined coefficient b, the time change rate of the remaining capacity It is determined that an abnormality has occurred in the voltage detection system of the module battery 24 related to DS, and the indicator 48 is turned on (step S110), and this routine ends. Here, the abnormality of the voltage detection system can be determined based on the time change rate DS of the remaining capacity for the following reason.

  FIG. 3 is an explanatory diagram showing an example of the relationship between the remaining capacity and voltage of the module battery by the normal voltage detection system and the relationship between the remaining capacity and voltage of the module battery by the abnormal voltage detection system. The abnormal voltage detection system in FIG. 3 detects a high voltage. In the equalization process as the process of step S204 of the equalization process routine of FIG. 4 described later, the transistor 36 is connected to the module battery having a high voltage so that the remaining capacities Sa to Sn of the module batteries 24a to 24n are equalized. It is turned on and power is consumed by the resistor 34. Therefore, a module battery in which the voltage is detected by an abnormal voltage detection system that detects a high voltage is discharged more than necessary, so even if it is detected as the same voltage, the module can detect the voltage by a normal voltage detection system The remaining capacity (SOC) is smaller than that of the battery. As shown in the figure, the rate of change between the remaining capacity (SOC) and the voltage is large in a region where the remaining capacity (SOC) is small and a large region. For this reason, in the region where the remaining capacity (SOC) of the module battery in which the voltage is detected by the abnormal voltage detection system is small, the time change rate of the remaining capacity is the remaining capacity of the module battery in which the voltage is detected by the normal voltage detection system. In the region where the remaining capacity (SOC) is large, the time changing rate of the remaining capacity is compared with the time changing rate of the remaining capacity of the module battery whose voltage is detected by the normal voltage detection system. And get smaller.

  On the contrary, the module battery in which the voltage is detected by the abnormal voltage detection system in which the voltage is detected at a low voltage does not discharge by the equalization process. Therefore, even if it is detected as the same voltage, the voltage is detected by the normal voltage detection system. The remaining capacity (SOC) becomes larger than the detected module battery. For this reason, in the region where the remaining capacity (SOC) of the module battery in which the voltage is detected by the abnormal voltage detection system is small, the time change rate of the remaining capacity is the remaining capacity of the module battery in which the voltage is detected by the normal voltage detection system. In the region where the remaining capacity (SOC) is large, the time change rate of the remaining capacity is compared with the time change ratio of the remaining capacity of the module battery whose voltage is detected by the normal voltage detection system. And get bigger. Using this idea, in the embodiment, the abnormality of the voltage detection system of the module battery having the time change rate DS exceeding the allowable range including the average value A of the time change rates DSa to DSn of the remaining capacity is determined.

  In the assembled battery device 20 of the embodiment, in addition to such abnormality detection processing, processing for equalizing the module batteries 24a to 24n is also performed. FIG. 4 is a flowchart illustrating an example of an equalization processing routine executed by the electronic control unit 40 of the assembled battery device 20 according to the embodiment. This routine is repeatedly executed every predetermined time (for example, every 30 minutes).

  When the equalization processing routine is executed, the CPU 42 of the electronic control unit 40 first detects a potential difference between the conductive lines 32a to 32n + 1 to detect voltages Va to Vn of the module batteries 24a to 24n. Execute (Step S200). Subsequently, it is checked whether or not an abnormality of the voltage detection system has been determined (step S202). When the abnormality has not been determined, an equalization process is performed so that the remaining capacities Sa to Sn of the module batteries 24a to 24n are equalized. Is executed (step S204), and this routine is terminated. This equalization processing is performed by turning on the transistor 36 and consuming power by the resistor 34 with respect to the module battery having a high voltage so that the remaining capacities Sa to Sn of the module batteries 24 a to 24 n are equalized.

  On the other hand, when the abnormality of the voltage detection system is determined, the voltage of the module battery whose voltage is detected by the voltage detection system where the abnormality is determined is corrected based on the time change of the remaining capacity (step S206), and each module Adjustment is made so that the voltages of the batteries 24a to 24n approach the corrected voltage (step S208), and this routine ends. As illustrated in FIG. 3, the voltage correction can estimate the remaining capacity of the module battery from the voltage detected by the abnormal voltage detection system from the relationship between the voltage of the module battery and the remaining capacity. Is applied to the relationship between the voltage detected by the normal voltage detection system and the remaining capacity to estimate the voltage. In the case of an abnormal voltage detection system in which the voltage of each module battery 24a to 24n is approximated to the corrected voltage, in the case of an abnormal voltage detection system that detects the voltage higher, each module battery whose voltage is detected by the normal voltage detection system 24, the transistor 36 is turned on and power is consumed by the resistor 34. However, unlike the equalization process, the discharge is not performed until the corrected voltage is reached, and the discharge is terminated at a voltage higher than the corrected voltage. Is done. On the other hand, in the case of an abnormal voltage detection system that detects a voltage at a low level, the module battery 24 whose voltage is detected by the abnormal voltage detection system is turned on and the power is consumed by the resistor 34 by turning on the transistor 36. . Also in this case, the discharge is not finished until the corrected voltage becomes a voltage detected by a normal voltage detection system, but the discharge is terminated at a slightly higher voltage.

  According to the assembled battery device 20 of the embodiment described above, the abnormality of the voltage detection system of the module batteries 24a to 24n can be detected. As a result, overdischarge and overcharge of the module battery 24 based on abnormality of the voltage detection system can be prevented. Further, according to the assembled battery device 20 of the embodiment, when the abnormality of the voltage detection system is detected, the voltage of the module battery 24 related to the abnormality is corrected and the voltages of the other module batteries 24a to 24n approach the corrected voltage. Thus, the module battery 24 can be further prevented from being overdischarged or overcharged due to an abnormality in the voltage detection system, and can be used for subsequent use.

  In the assembled battery device 20 according to the embodiment, when the time change rate DS of the remaining capacity falls outside the allowable range set by the average value A multiplied by the predetermined coefficient a and the predetermined coefficient b. Although the voltage detection system related to the time change rate DS of the capacity is determined to be abnormal, the time change rate DS of the remaining capacity is set based on a value obtained by subtracting the predetermined value c from the average value A and a value obtained by adding the predetermined value d. The voltage detection system related to the time change rate DS of the remaining capacity may be determined to be abnormal when it falls outside the allowable range. Here, the predetermined value c and the predetermined value d are constants that define an upper limit and a lower limit of an allowable variation from the average value A of the time change rates DSa to DSn of the remaining capacity, and the single battery 22 and the module batteries 24a to 24n. It is determined by the characteristics and specifications.

  In the assembled battery device 20 of the embodiment, when the abnormality of the voltage detection system is detected, the voltage of the module battery 24 related to the abnormality is corrected and the voltage of the other module battery 24 is adjusted. When an abnormality is detected, the equalization process is not performed, and the voltage of the module battery 24 related to the abnormality or the voltage of another module battery 24 may not be adjusted.

  In the assembled battery device 20 of the embodiment, the abnormality detection processing routine and the equalization processing routine are executed by the electronic control unit 40 as separate routines, but the abnormality detection processing is performed before step S202 of the equalization processing routine. It is good also as what detects abnormality of a voltage detection system in an equalization processing routine as what performs processing of Steps S102-S110 of a routine.

  In the assembled battery device 20 of the embodiment, the remaining capacities Sa to Sn of the module batteries 24a to 24n are obtained by calculation based on the voltages Va to Vn of the module batteries 24a to 24n, but the module batteries 24a to 24n are calculated. The remaining capacities Sa to Sn may be directly detected, or those calculated using state values other than the voltages Va to Vn may be used.

  In the assembled battery device 20 of the embodiment, the plurality of unit cells 22 are connected in series to form the module batteries 24a to 24n. However, the single unit cell 22 may constitute the module batteries 24a to 24n. In this case, the cell equalization circuits 28a to 28n are not necessary.

  The embodiments of the present invention have been described using the embodiments. However, the present invention is not limited to these embodiments, and can be implemented in various forms without departing from the gist of the present invention. Of course you get.

It is a block diagram which shows the outline of a structure of the assembled battery apparatus 20 which is one Example of this invention. It is a flowchart which shows an example of the abnormality detection process routine performed by the electronic control unit 40 of the assembled battery apparatus 20 of an Example. It is explanatory drawing which shows an example of the relationship between the remaining capacity and voltage of a module battery by a normal voltage detection system, and the relationship between the remaining capacity and voltage of a module battery by an abnormal voltage detection system. It is a flowchart which shows an example of the equalization process routine performed by the electronic control unit 40 of the assembled battery apparatus 20 of an Example.

Explanation of symbols

  10 load, 20 assembled battery device, 21 assembled battery, 22 single battery, 24a-24n module battery, 26a-26n voltage detection line, 28a-28n cell equalization circuit, 32a-32n + 1 conductive line, 34a-34n resistance, 36a- 36n transistor, 38a-38n signal line, 40 electronic control unit, 42 CPU, 44 ROM, 46 RAM, 48 indicator.

Claims (1)

An assembled battery device having an assembled battery formed by connecting a plurality of module batteries constituted by at least one single battery in series,
Module voltage detection means for detecting the voltage of each of the plurality of module batteries of the assembled battery, equalization means for equalizing the voltage of each module battery based on the detected voltage of each module battery, and A battery pack abnormality detection device comprising abnormality determination means for determining abnormality of the module voltage detection means;
Equalization regulation means for regulating equalization by the equalization means when an abnormality is detected by the abnormality detection device;
An assembled battery device comprising:

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