JP2021026879A - Battery control system - Google Patents

Abstract

Suppressing Lithium Deposition A battery control system 10 includes a lithium ion secondary battery 12 and a control device 14. The control device 14 includes a storage unit 14a and a processing unit 14b. The storage unit 14a stores map data 30 that stores the relationship between the usage status information 40 of the lithium ion secondary battery 12 and the metal elution derived from the lithium transition metal oxide. The processing unit 14b is the negative electrode active material when the metal elution derived from the lithium transition metal oxide is estimated based on the usage status information 40 acquired from the lithium ion secondary battery 12 and the map data 30. It is configured to reduce the battery voltage to a predetermined battery voltage so that the metal derived from the lithium transition metal oxide adhering to the layer becomes an oxide. [Selection diagram] Fig. 3

Description

The disclosure herein relates to a battery control system.

Japanese Unexamined Patent Publication No. 2013-196820 proposes to provide a system for accurately determining the precipitation of lithium metal at the negative electrode. In the same publication, the control unit charges the lithium ion secondary battery with a current value of 10 C or more for a predetermined time, and after charging, the lithium ion secondary battery has the same current value as the current value at the time of charging for the predetermined time. Is being discharged. Then, when the first potential difference, which is the difference between the negative electrode potential before charging and the negative electrode potential after charging, is larger than the second potential difference, which is the difference between the negative electrode potential after discharging and the negative electrode potential before discharging. It is determined that lithium metal is deposited on the negative electrode.

Further, Japanese Patent Application Laid-Open No. 2018-163806 describes an event in which a transition metal is eluted from a positive electrode active material.

Japanese Unexamined Patent Publication No. 2013-196820 JP-A-2018-163806

By the way, according to the knowledge of the present inventor, as charging progresses, an event in which lithium is deposited on the negative electrode can be seen. Such an event also causes a decrease in capacity. Therefore, it is desirable to suppress the phenomenon of lithium precipitation on the negative electrode.

The battery control system proposed here includes a lithium ion secondary battery and a control device. The lithium ion secondary battery includes a battery case, an electrode body housed in the battery case, and a non-aqueous electrolyte solution. The electrode body is a negative electrode sheet composed of a positive electrode collector having a positive electrode active material layer containing positive electrode active material particles and a negative electrode current collector having a negative electrode active material layer containing negative electrode active material particles. And have. The positive electrode active material layer and the negative electrode active material layer face each other with a separator interposed therebetween. The positive electrode active material particles contain a lithium transition metal oxide.
The control device includes a storage unit and a processing unit. The storage unit stores map data that stores information on the usage status of the lithium ion secondary battery and the relationship between metal elution derived from the lithium transition metal oxide. The processing unit adhered to the negative electrode active material layer when metal elution derived from the lithium transition metal oxide was estimated based on the usage status information acquired from the lithium ion secondary battery and the map data. The process of lowering the battery voltage of the lithium ion secondary battery is executed up to a predetermined battery voltage so that the metal derived from the lithium transition metal oxide becomes an oxide.

According to such a battery control system, when metal elution derived from the lithium transition metal oxide is estimated, the metal derived from the lithium transition metal oxide adhering to the negative electrode active material layer becomes an oxide in advance. The process of lowering the battery voltage of the lithium ion secondary battery to the specified battery voltage is executed. Therefore, the negative electrode active material layer is maintained in a state in which lithium is difficult to precipitate, and the precipitation of lithium on the negative electrode active material layer is suppressed.

FIG. 1 is a schematic view of the surface of the negative electrode active material layer 20 of the lithium ion secondary battery. FIG. 2 is a schematic view of the surface of the negative electrode active material layer 20 of the lithium ion secondary battery. FIG. 3 is a schematic configuration diagram of the battery control system 10. FIG. 4 is a schematic view of the surface of the negative electrode active material layer 20 of the lithium ion secondary battery. FIG. 5 is a flowchart showing an example of the control flow of the battery control system 10.

Hereinafter, an embodiment of the battery control system disclosed here will be described. The embodiments described herein are, of course, not intended to specifically limit the present invention. The present invention is not limited to the embodiments described herein, unless otherwise specified.

The battery to be controlled is a lithium ion secondary battery. In the lithium ion secondary battery, it is preferable that the electrode body and the electrolytic solution are housed in the battery case. The electrode body is a negative electrode sheet composed of a positive electrode collector having a positive electrode active material layer containing positive electrode active material particles and a negative electrode current collector having a negative electrode active material layer containing negative electrode active material particles. And have. The positive electrode active material layer and the negative electrode active material layer face each other with a separator interposed therebetween.

The positive electrode active material particles can be, for example, lithium transition metal oxides. The lithium transition metal oxide may contain, for example, at least one Ni, Co, and Mn as a transition metal. Examples of such lithium transition metal oxides include lithium nickel cobalt manganese composite oxide (eg, LiNi _1/3 Co _1/3 Mn _1/3 O ₂ ), lithium nickel composite oxide (eg LiNiO ₂ ), and lithium. Cobalt composite oxides (eg LiCoO ₂ ), lithium manganese composite oxides (eg LiMn ₂ O ₄ ), lithium nickel manganese composite oxides (eg LiNi _0.5 Mn _1.5 O ₄ ) and the like can be mentioned. The ratio of transition metals is not particularly limited. The positive electrode active material particles contained in the positive electrode active material layer may contain at least a part of lithium transition metal oxide. The positive electrode active material layer may contain positive electrode active material particles other than the lithium transition metal oxide.

Examples of the negative electrode active material particles include natural graphite and hard carbon. The negative electrode active material particles may have a potential of around ^{1 V (vsLi + / Li), for example.}

The lithium ion secondary battery may contain a non-aqueous electrolytic solution using a non-aqueous solvent. As the non-aqueous solvent, for example, a so-called carbonate-based solvent may be used. The non-aqueous electrolyte solution is a lithium ion secondary battery, which is described in detail in the prior art document, and there are various proposals in addition to the prior art document. Here, a detailed description of the lithium ion secondary battery will be omitted.

FIG. 1 is a schematic view of the surface of the negative electrode active material layer 20 of the lithium ion secondary battery. As shown in FIG. 1, a coating film 21 is formed on the surface of the negative electrode active material layer 20. The coating film 21 has high electrical resistance and is unlikely to become a resistance when lithium ions are incorporated into the negative electrode active material during charging. Therefore, due to the action of the coating film 21, lithium ions in the electrolytic solution are unlikely to precipitate on the surface of the negative electrode active material layer 20. Further, due to the action of the coating film 21, the lithium ions in the electrolytic solution react with the surface of the negative electrode active material layer 20 substantially uniformly during charging.

FIG. 2 is a schematic view of the surface of the negative electrode active material layer 20 of the lithium ion secondary battery. FIG. 2 shows a state in which the transition metal 22 derived from the lithium transition metal oxide contained in the positive electrode is deposited on the coating film 21 on the surface of the negative electrode active material layer 20. According to the knowledge of the present inventor, the positive electrode becomes high potential as the lithium ion secondary battery 12 is charged. When the positive electrode has a high potential, the transition metal may be ionized from the lithium transition metal oxide contained in the positive electrode and eluted into the electrolytic solution. A part of the metal eluted in the electrolytic solution may move in the electrolytic solution, adhere to the coating film 21 on the surface of the negative electrode active material layer 20, and precipitate.

As shown in FIG. 2, in the portion where the transition metal 22 is deposited on the coating film 21 on the surface of the negative electrode active material layer 20, lithium ions in the electrolytic solution are negative electrode as compared with other portions of the coating film 21 during charging. It is difficult to enter the active material layer 20. On the other hand, the portion where the transition metal 22 is deposited has a small electrical resistance. Therefore, in or around the portion where the transition metal 22 is precipitated, electrons are likely to act locally on the lithium ions, the lithium ions are easily reduced, and lithium is likely to be precipitated. According to the findings of the present inventor, as shown in FIG. 2, when the transition metal 22 derived from the lithium transition metal oxide is deposited on the coating film 21 on the surface of the negative electrode active material layer 20, the transition metal 22 is formed. As a result, lithium in the electrolytic solution tends to precipitate.

Examples of the transition metal 22 precipitated by such an event include Co (cobalt) and Mn (manganese). Co has a low electrical resistance. Therefore, in the portion where Co is deposited on the coating film 21 on the surface of the negative electrode active material layer 20, electrons are likely to act and Li ions are easily reduced, so that lithium is easily deposited. Mn has a high reaction resistance. Therefore, in the portion where Mn is precipitated on the coating film 21 on the surface of the negative electrode active material layer 20, Li is difficult to precipitate, but the reaction tends to concentrate around the portion where Mn is precipitated. Therefore, Li is likely to be precipitated around the portion where Mn is precipitated. When a transition metal such as Co or Mn is deposited on the surface of the negative electrode active material layer 20 in this way, lithium is likely to be locally deposited in or around the portion. When Ni is also deposited on the surface of the negative electrode active material layer 20, lithium is likely to be locally deposited in or around the portion.

Lithium precipitation also causes a decrease in capacity. Therefore, it is desirable to suppress the phenomenon of lithium precipitation on the negative electrode due to the metal derived from the lithium transition metal oxide contained in the positive electrode. FIG. 3 is a schematic configuration diagram of the battery control system 10. As shown in FIG. 3, the battery control system 10 includes a lithium ion secondary battery 12, a control device 14, and a sensor unit 16. In FIG. 3, the lithium ion secondary battery 12 is schematically shown without detailed illustration.

The control device 14 is a device that performs various processes of the battery control system 10. The control device 14 can be embodied by, for example, a computer driven according to a predetermined program. The control device 14 may be a computer incorporated in a vehicle in which the lithium ion secondary battery 12 is mounted. Each function of the control device 14 includes an arithmetic unit (also called a processor, a CPU (Central Processing Unit), an MPU (Micro-processing unit)) or a storage device (memory, hard disk, etc.) of each computer constituting the control device 14. And processed in collaboration with the software. The processing of the control device 14 may be executed by one computer. Further, the processing of the control device 14 may be executed by a plurality of computers. Further, the processing of the control device 14 may be executed in collaboration with an external computer. For example, an external computer may store information or a part of the information stored in the control device 14. Further, an external computer may execute a process or a part of the process executed by the control device 14.

The control device 14 includes a storage unit 14a and a processing unit 14b. The storage unit 14a stores the map data 30. The map data 30 stores the relationship between the usage status information 40 of the lithium ion secondary battery 12 to be controlled and the metal elution derived from the lithium transition metal oxide.

The sensor unit 16 is a sensor for acquiring information 40 on the usage status of the lithium ion secondary battery 12. In this embodiment, for example, a current value, a voltage value, a temperature, and the like are acquired as information on the usage status of the lithium ion secondary battery 12. The sensor unit 16 includes an ammeter, a voltmeter, a temperature sensor, and the like.

In this embodiment, the usage status information 40 of the lithium ion secondary battery is measured, for example, through a sensor unit 16 at a predetermined cycle. The measured information 40 on the usage status of the lithium ion secondary battery may be stored in a predetermined storage area of the control device 14. In this embodiment, as shown in FIG. 3, the control device 14 includes a storage unit 14c that stores information 40 on the usage status of the lithium ion secondary battery 12. The usage status information 40 of the lithium ion secondary battery 12 may include information such as a voltage value, a current value, and a temperature.

For example, according to the findings of the present inventor, even if the battery voltage of the lithium ion secondary battery 12 is the same, the higher the temperature, the easier it is for the transition metal to elute from the positive electrode. Therefore, the battery voltage at which the transition metal elution from the positive electrode is estimated differs depending on the temperature. The relationship between the usage status information 40 of the lithium ion secondary battery 12 to be controlled and the metal elution derived from the lithium transition metal oxide is, for example, tested in advance for the lithium ion secondary battery to be controlled. And so on. For example, a test battery that imitates a lithium ion secondary battery to be controlled is prepared, and it is observed whether or not metal is deposited on the negative electrode surface of the test battery under a predetermined usage condition. By such a test, it is preferable to obtain the relationship between the information on the usage status of the lithium ion secondary battery to be controlled and the metal elution derived from the lithium transition metal oxide of the positive electrode.

The relationship between the usage status information of the lithium ion secondary battery and the metal elution derived from the lithium transition metal oxide of the positive electrode may be summarized as map data 30. The map data 30 may include, for example, the presence or absence of metal elution recorded on an n-dimensional map whose variable is the usage status of the lithium ion secondary battery. In the map data 30, for example, the presence or absence of metal elution may be recorded in relation to the temperature and the battery voltage. Such map data 30 is electronic information and may be stored in advance in the storage unit 14a of the control device 14.

The processing unit 14b is the negative electrode active material when the metal elution derived from the lithium transition metal oxide is estimated based on the usage status information 40 acquired from the lithium ion secondary battery 12 and the map data 30. The battery voltage of the lithium ion secondary battery 12 is reduced to a predetermined battery voltage so that the metal derived from the lithium transition metal oxide deposited on the layer 20 (see FIG. 1) becomes an oxide. Has been done.

Here, when the battery voltage of the lithium ion secondary battery 12 decreases, the potential of the negative electrode increases. When the potential of the negative electrode becomes high, the transition metal derived from the positive electrode deposited on the coating film 21 on the surface of the negative electrode active material layer 20 is oxidized. At this time, the oxygen source when the transition metal is oxidized may be, for example, oxygen contained in a non-aqueous solvent in the electrolytic solution, for example, a carbonate-based solvent. The battery voltage of the lithium ion secondary battery 12 is lowered to a predetermined battery voltage so that the transition metal derived from the lithium transition metal oxide deposited on the negative electrode active material layer 20 (see FIG. 1) becomes an oxide. The process of causing the battery 12 may be, for example, a process of discharging the lithium ion secondary battery 12.

FIG. 4 is a schematic view of the surface of the negative electrode active material layer 20 of the lithium ion secondary battery. FIG. 4 shows a state in which the metal oxide 23 is attached to the coating film 21 on the surface of the negative electrode active material layer 20. The metal oxide 23 has a higher electrical resistance than the coating film 21. Further, the metal oxide 23 adhering to the coating film 21 on the surface of the negative electrode active material layer 20 is unlikely to become a resistance when lithium ions are incorporated into the negative electrode active material. Therefore, even if the metal oxide 23 is attached to the coating film 21, the lithium ions in the electrolytic solution react with the surface of the negative electrode active material layer 20 substantially uniformly during charging. Therefore, the precipitation of lithium on the surface of the negative electrode active material layer 20 is suppressed. In other words, even if the metal oxide 23 of the transition metal is attached to the surface of the negative electrode active material layer 20, lithium is deposited on the surface of the negative electrode active material layer 20 at or around the portion where the metal oxide 23 is attached. The state that is difficult to do is maintained.

For example, according to the findings of the present inventor, when CoO (cobalt oxide (II)) is attached as compared with the case where Co (cobalt) is attached to the coating film 21 on the surface of the negative electrode active material layer 20. , The amount of lithium precipitation can be kept low. Further, the amount of lithium precipitated is suppressed to be lower when _{Mn 2} O ₃ (magnesium oxide) is attached than when Mn (manganese) is attached to the film 21 on the surface of the negative electrode active material layer 20. Be done. As described above, the amount of lithium precipitated is larger when the transition metal derived from the positive electrode is attached to the coating film 21 on the surface of the negative electrode active material layer 20 in the oxide state than when it is attached in the metal state. It can be kept low.

In the battery control system 10 proposed here, metal elution derived from the lithium transition metal oxide is estimated based on the usage status information 40 of the lithium ion secondary battery 12 and the map data 30. Then, when the metal elution derived from the lithium transition metal oxide is estimated, the metal derived from the lithium transition metal oxide adhering to the negative electrode active material layer becomes an oxide up to a predetermined battery voltage. , The process of lowering the battery voltage is executed. When such a treatment is executed, as shown in FIG. 4, the metal derived from the lithium transition metal oxide adhering to the negative electrode active material layer 20 is oxidized to become the metal oxide 23. Therefore, the surface of the negative electrode active material layer 20 is kept in a state in which lithium is difficult to precipitate, and the precipitation of lithium on the surface of the negative electrode active material layer 20 is suppressed. As described above, when the elution of the metal derived from the lithium transition metal oxide is estimated, the process of lowering the battery voltage of the lithium ion secondary battery 12 is executed. As a result, the so-called lithium precipitation resistance of the surface of the negative electrode active material layer 20 can be maintained in a good state.

FIG. 5 is a flowchart showing an example of a control flow of the battery control system 10 (see FIG. 3). The control flow of the battery control system 10 is not limited to that shown in FIG. Here, the lithium ion secondary battery 12 (see FIG. 3) to be controlled is used as a power source for driving an electric vehicle such as a hybrid vehicle or an EV vehicle. During traveling, the lithium ion secondary battery 12 is charged by obtaining regenerative energy. Further, in a hybrid vehicle, the vehicle is charged by the electric power generated by the motor generator driven by the engine.

In this battery control system 10, as shown in FIG. 5, it is determined whether or not the battery is running (S1). If it is not running (No), no special processing is required. Whether or not the vehicle is traveling can be determined based on, for example, whether or not the shift lever is in the range that allows the vehicle to travel. For example, when it is in the drive range (so-called D range) or the battery running range (so-called B range), it is determined that the vehicle is running.

When the vehicle is running (Yes), it is determined whether or not the battery voltage Vx at that time is larger than the predetermined threshold value V1 (t) (Vx> V1 (t)) (S2). In the determination process S2, the threshold value V1 (t) changes based on the usage status information acquired from the lithium ion secondary battery 12 and the map data. That is, the higher the temperature, the easier it is for the transition metal to elute at the positive electrode. Therefore, an appropriate threshold value is appropriately set for the threshold value V1 (t) according to the temperature of the lithium ion secondary battery. For example, in the determination process S2, it is preferable that the map is appropriately referred to and an appropriate threshold value V1 (t) is set each time.

Here, in the determination process S2, it is determined whether or not metal elution from the positive electrode is estimated. In the determination process S2, if Vx> V1 (t) is not (No), the start is returned and the control of the battery control system 10 may be repeated.

When it is determined (Yes) that Vx> V1 (t) in the determination process S2, the predetermined discharge process S3 is executed. Here, in the discharge treatment S3, it is preferable that the negative electrode potential is increased so that the transition metal derived from the positive electrode adhering on the negative electrode becomes an oxide. It is preferable that the battery voltage of the lithium ion secondary battery 12 is reduced to a predetermined battery voltage at which such a negative electrode potential is realized. When a metal derived from the lithium transition metal oxide is attached to the negative electrode active material layer 20 by the discharge treatment S3, the metal is oxidized and the metal oxide 23 is oxidized as shown in FIG. become. As a result, the coating film 21 on the surface of the negative electrode active material layer 20 can be kept in a state in which lithium is unlikely to be deposited.

Here, the determination process S2 may be configured to count the number of times it is determined that Vx> V1 (t). Then, in the control cycle of the control device 14, when Vx> V1 (t) is continuously determined for a predetermined number of times, the determination process S2 is configured to determine Vx> V1 (t). You may be. In this case, if it is temporarily determined that Vx> V1 (t), metal elution from the positive electrode is not estimated. When it is determined that Vx> V1 (t) is continuously determined for a predetermined number of times, metal elution from the positive electrode is estimated. In this case, the discharge process S3 can be configured not to be executed only by temporarily setting Vx> V1 (t) based on the erroneous determination. In the determination process S2, Vx> V1 (t) may be simply determined.

According to the findings of the present inventor, the negative electrode potential for the transition metal derived from the positive electrode adhering to the coating film 21 on the surface of the negative electrode active material layer 20 to become an oxide is ^{defined by, for example, 1 V (VsLi +} / Li). To. 1V (VsLi ⁺ / Li) is a potential at which it was confirmed that transition metals such as manganese and cobalt become oxides. That is, in the discharge process S3, for example, the lithium ion secondary battery 12 may be discharged to a battery voltage at which the ^{negative electrode potential becomes 1 V (VsLi + / Li).}

Here, in the discharge process S3, it is not necessary to discharge the lithium ion secondary battery 12 at once with a large current, and it is preferable to slowly discharge the lithium ion secondary battery 12. For example, in a hybrid vehicle, in the discharge process S3, the EV mode, that is, the discharge of the lithium ion secondary battery 12 is controlled to run as the main drive source up to the battery voltage ^{at which the negative electrode potential becomes 1 V (VsLi + / Li).} May be done. Further, the lithium ion secondary battery 12 may be charged by regenerative energy in the middle of the discharge process S3. When charging is performed by regenerative energy in the middle of the discharge process S3, the charging current may be suppressed to a small extent so that lithium precipitation is suppressed. The charging current may be limited to, for example, 2C rate or less. The conditions for such discharge and the limit value of the charging current during the discharge process may be determined by the use of the lithium ion secondary battery 12. Further, the discharge condition and the limit value of the charging current during the discharge process may be determined by a separately prepared control map in relation to the usage status information 40 of the lithium ion secondary battery 12.

The discharge treatment S3 lowers the battery voltage to a predetermined battery voltage so that the transition metal derived from the lithium transition metal oxide adhering to the negative electrode active material layer 20 becomes an oxide as described above. Then, when the battery voltage of the lithium ion secondary battery 12 drops to a predetermined battery voltage, the discharge process S3 ends. In the flowchart shown in FIG. 4, after the discharge process S3 is completed, the control of the battery control system 10 is repeated again (S4).

According to the battery control system 10, when the metal elution derived from the lithium transition metal oxide is estimated, the metal derived from the lithium transition metal oxide adhering to the negative electrode active material layer becomes an oxide. A process of lowering the battery voltage of the lithium ion secondary battery 12 to a predetermined battery voltage is executed. Therefore, the negative electrode active material layer is maintained in a state in which lithium is difficult to precipitate, and the precipitation of lithium on the negative electrode active material layer is suppressed.

The battery control system disclosed here has been described in various ways. Unless otherwise specified, the embodiments of the battery control system mentioned here do not limit the present invention. Further, the battery control system disclosed herein can be variously modified, and each component and each process referred to here may be appropriately omitted or combined as appropriate, unless a particular problem occurs.

10 Battery control system 12 Lithium-ion secondary battery 14 Control device 14a Storage unit 14b Processing unit 14c Storage unit 16 Sensor unit 20 Negative electrode active material layer 21 Coating 22 Transition metal 23 Metal oxide 30 Map data 40 Lithium-ion secondary battery 12 Usage information

Claims (1)

Equipped with a lithium-ion secondary battery and a control device,
The lithium ion secondary battery is
A battery case, an electrode body housed in the battery case, and a non-aqueous electrolyte solution are provided.
The electrode body is a negative electrode composed of a positive electrode sheet formed of a positive electrode current collector on which a positive electrode active material layer containing positive electrode active material particles is formed and a negative electrode current collector formed of a negative electrode active material layer containing negative electrode active material particles. It has a seat and
The positive electrode active material layer and the negative electrode active material layer face each other with a separator interposed therebetween.
The positive electrode active material particles contain a lithium transition metal oxide and contain.
The control device is
A storage unit that stores map data that stores the relationship between the usage status information of the lithium ion secondary battery and the metal elution derived from the lithium transition metal oxide.
When the metal elution derived from the lithium transition metal oxide was estimated based on the usage status information acquired from the lithium ion secondary battery and the map data, it adhered to the negative electrode active material layer. A battery provided with a processing unit configured to reduce the battery voltage of the lithium ion secondary battery to a predetermined battery voltage so that the metal derived from the lithium transition metal oxide becomes an oxide. Control system.

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