Patent Description:
Recently, research and development on a secondary battery are being actively conducted. Here, the secondary battery is a battery capable of charging and discharging, and is meant to include all of a conventional Ni/Cd battery, Ni/MH battery, etc. and a recent lithium ion battery. Among the secondary batteries, the lithium ion battery has an advantage of having much higher energy density compared to the conventional Ni/Cd battery, Ni/MH battery, etc. In addition, the lithium ion battery can be manufactured in a small size and light weight, and thus the lithium ion battery is used as a power source for a mobile device. In addition, the lithium ion battery is attracting attention as a next-generation energy storage medium as its range of use has been expanded to a power source for an electric vehicle.

In addition, the secondary battery is generally used as a battery pack including a battery module in which a plurality of battery cells are connected in series and/or in parallel. In addition, a state and operation of the battery pack are managed and controlled by a battery management system (BMS).

A plurality of battery modules are connected in series/in parallel to configure a battery rack, and a plurality of battery racks are connected in parallel to configure a battery bank. Such a battery bank can be used as an energy storage system (ESS). Each battery module is monitored and controlled by a corresponding slave BMS. A master BMS, which is the upper-most level controller in each battery rack, monitors and controls each slave BMS, and monitors and controls the entire battery rack state based on information obtained from the slave BMS.

In this case, in the battery management system for ESS, data transmission and reception between the upper-level battery management system and a lower-level battery management system are mostly made in a tree structure. In such a tree structure, when communication cannot be performed because an abnormality occurs in an intermediate path, there was a problem that communication performance between the lower-level battery management system and the upper-level controller becomes disabled.

In addition, in order to prevent such disabling of communication, a communication structure between the upper-level and lower-level battery management systems should be equipped with an additional interface to perform communication in a mesh structure rather than the tree structure, which has problems such as laying, managing, etc. of additional cables during installation as well as development.

<CIT> describes further the background art.

An object of the present invention is to provide a battery management system and a battery management method that maintain continuity of communication without additional configuration even if a communication abnormality occurs when performing communication in the tree structure between the upper-level and lower-level battery management systems.

A system for managing a battery described herein includes a wireless communication unit that communicates with a first upper-level battery management system performing communication using a first communication channel, a communication abnormality detection unit that detects a communication abnormality of the first upper-level battery management system performing communication using the first communication channel, and a channel change unit that changes the communication channel of the wireless communication unit to a second communication channel different from the first communication channel when the communication abnormality of the first upper-level battery management system is detected by the communication abnormality detection unit.

In this system for managing the battery, the communication abnormality detection unit detects a communication abnormality if a signal is not received from the first upper-level battery management system through the first communication channel for a preset time, and the second communication channel is a preset communication channel.

In the system for managing the battery according to the embodiment of the present invention, through the second communication channel, a plurality of upper-level battery management systems different from the first upper-level battery management system are alternately and periodically connected to and communicate with each other.

This system for managing the battery further includes a control unit that allows the wireless communication unit to communicate with a second upper-level battery management system connected to the second communication channel when performing communication by changing to the second communication channel and allows a communication abnormality signal of the first upper-level battery management system to be transmitted, through the wireless communication unit, to the second upper-level battery management system through the second communication channel.

This system for managing the battery further includes a battery state measuring unit that measures a state of the battery, in which the control unit allows measured state-related data of the battery to be transmitted to the second upper-level battery management system through the wireless communication unit.

A system for managing a battery according to the present invention includes a wireless communication unit that communicates using a plurality of associated lower-level battery management systems disposed in the same battery rack through a third communication channel, a channel change unit that allows the wireless communication unit to communicate using a second communication channel different from the third communication channel for a preset time at a preset period, and a communication unit that transmits and receives data with an upper-level control unit.

The system for managing the battery according to the present invention further includes a control unit that allows a communication abnormality signal to the upper-level control unit if the wireless communication unit receives the communication abnormality signal of an upper-level battery management system of a non-associated lower-level battery management system is received from the corresponding non-associated lower-level battery management system not disposed in the same battery rack when the wireless communication unit wirelessly performs wireless communication using the second communication channel.

In the system for managing the battery according to the present invention, if the communication abnormality signal of the upper-level battery management system is received from the non-associated lower-level battery management system through the second communication channel, the control unit allows a command signal received from the upper-level control unit from before a preset time to be transmitted to the non-associated lower-level battery management system.

In the system for managing the battery according to the present invention, when the wireless communication unit performs wireless communication using, the wireless communication unit receives battery measurement data measured by the lower-level battery management system from the non-associated lower-level battery management system, and transmits the battery measurement data to the upper-level system.

A method for managing a battery described herein includes detecting a communication abnormality of a first upper-level battery management system performing communication using a first communication channel and changing the first communication channel of a wireless communication unit to a second communication channel different from the first communication channel to perform communication when the communication abnormality of the first upper-level battery management system is detected in the detecting the communication abnormality.

In this method for managing the battery, the communication abnormality is detected if a signal is not received from the first upper-level battery management system through the first communication channel for a preset time, and the second communication channel is a preset communication channel.

In this method for managing the battery, through the second communication channel, a plurality of upper-level battery management systems different from the first upper-level battery management system are alternately and periodically connected to and communicate with each other.

This method for managing the battery further includes communicating with a second upper-level battery management system connected to the second communication channel when performing communication by changing to the second communication channel and transmitting a communication abnormality signal of the first upper-level battery management system to the second upper-level battery management system through the second communication channel.

In this method for managing the battery, measured battery state related data is transmitted to the second upper-level battery management system through the second communication channel, or a command received from the upper-level controller is received from the second upper-level battery management system through the second communication channel.

The present invention has an effect of maintaining continuity of communication without additional configuration even if a communication abnormality occurs when performing communication in a tree structure between upper-level and lower-level battery management systems.

The terms used in this document are only used to describe a specific embodiment, and may not be intended to limit the scope of other embodiments. Singular expressions may include plural expressions unless the context clearly indicates otherwise. All terms used herein, including technical or scientific terms, may have the same meaning as generally understood by a person of ordinary skill in the art. Terms defined in a generally used dictionary may be interpreted as having the same or similar meaning as the meaning in the context of the related technology, and are not to be interpreted as an ideal or excessively formal meaning unless explicitly defined in this document. In some cases, even terms defined in this document cannot be interpreted to exclude embodiments of the present invention.

In addition, in describing the constituent elements of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the constituent element from other constituent elements, and the nature, sequence, or order of the component is not limited by the term. When a certain constituent element is described as being "connected", "coupled" or "linked" to another constituent element, but it should be understood that the constituent element may be directly connected or linked to the other component, but another component may be "connected", "coupled" or "linked" between the components.

<FIG> schematically illustrates a configuration of a plurality of battery racks in an ESS.

An ESS <NUM> includes a plurality of battery racks <NUM>, <NUM>, and <NUM>. Each battery rack includes a plurality of battery modules <NUM> to <NUM> connected in series or in parallel.

Each of the battery module <NUM> to <NUM> includes a battery management system (BMS) that controls and monitors the battery module. In the BMS, there is an MBMS (module BMS) that controls and monitors each of the battery modules, and there is an RBMS (rack BMS) that controls a plurality of MBMS and transfers data received from the MBMS to an upper-level system. In addition, the RBMS may transmit a command received from the upper-level system to each battery module or a corresponding battery module. Here, the MBMS is a lower-level battery management system of RBMS, and the RBMS is an upper-level battery management system of MBMS.

Each MBMS monitors the battery status by sensing the temperature, voltage, and current of each battery module or battery cell, and transmits monitored information data to the RBMS in a wireless or wired manner.

The RBMS that has received battery status information or status information data of the battery module from each MBMS can transmit this data directly to the upper-level controller, or can transmit information data obtained by determining a status of the battery module based on this data to the upper-level controller.

<FIG> schematically illustrates a communication connection between the upper-level battery management system and the lower-level battery management system.

The battery pack <NUM> includes a battery module <NUM> composed of one or more battery cells and capable of charging and discharging, a switching unit <NUM> connected in series to the +terminal side or the - terminal side of the battery module <NUM> to control a charge/discharge current flow of the battery module <NUM>, and the MBMS <NUM> that monitors the voltage, current, temperature, etc. of the battery module <NUM> and controls and manages to prevent overcharging and overdischarging.

Here, the switching unit <NUM> is a semiconductor switching element for controlling the current flow for charging or discharging the battery module <NUM>, and, for example, at least one MOSFET may be used.

In addition, the MBMS <NUM> can measure or calculate a voltage and current of a gate, source, drain, etc. of the semiconductor switching element in order to monitor a voltage, current, temperature, etc. of the battery module <NUM>, and can also measure the current, voltage, temperature, etc. of the battery module by using a sensor <NUM> provided adjacent to the semiconductor switching element. The MBMS <NUM> is an interface that receives values obtained by measuring the various parameters described above, and may include a plurality of terminals and a circuit connected to these terminals to perform processing of input values.

In addition, the MBMS <NUM> can control ON/OFF of the MOSFET, and may be connected to the battery module <NUM> to monitor the state of the battery module <NUM>.

Since the configuration of the battery pack <NUM> and the configuration of the MBMS <NUM> are known configurations, a more detailed description will be omitted.

Meanwhile, the MBMS <NUM> according to the embodiments of the present invention is connected to an upper-level RBMS <NUM>, and the operation thereof may be controlled based on a signal applied from the upper-level BMS. In addition, the upper-level RBMS <NUM> may be connected to the upper-level controller <NUM>. The operation of the upper-level RBMS <NUM> may also be controlled based on a signal applied from the upper-level controller <NUM>.

Hereinafter, a configuration and method in which communication between the MBMS <NUM> and the upper-level controller <NUM> is performed when a communication abnormality occurs in the upper-level RBMS <NUM> will be described in detail.

<FIG> is a configuration diagram of a battery module management system.

A battery module management system <NUM> corresponding to the MBMS <NUM> includes a wireless communication unit <NUM>, a communication abnormality detection unit <NUM>, a battery state measurement unit <NUM>, a channel change unit <NUM>, and a control unit <NUM>.

The wireless communication unit <NUM> wirelessly communicates with a battery rack management system (corresponding to the RBMS <NUM>), which is an upper-level battery management system that is located in the same rack as the battery module and controls by receiving various data from the battery module and transmitting the data to the upper-level controller and receiving commands from the upper-level controller and transmitting the commands to the battery module, through a preset first communication channel. Typically, the wireless communication unit <NUM> may receive a battery state measurement command or a battery SOC calculation command, etc. from the battery rack management system. Or, the wireless communication unit <NUM> may wirelessly transmit data related to the battery state, for example, battery voltage, current, or temperature data to the battery rack management system. Or, the wireless communication unit <NUM> transmits a battery abnormal signal to the battery rack management system through the first communication channel when it is determined that there is an abnormality in the battery. When there is an abnormality in the battery, it is necessary to take prompt action, and thus it is important that the battery abnormal signal is quickly transmitted to the upper-level controller through the battery rack management system. However, if a communication abnormality of the battery rack management system (hereinafter referred to as a 'first battery rack management system'), which is an intermediate communication node, occurs and battery status data cannot be transferred to the upper-level controller or the command received from the upper-level controller cannot be received, the battery cannot be used efficiently and effectively. Therefore, when it is determined that a communication abnormality has occurred on the battery rack management system located in the same rack, the wireless communication unit <NUM> attempts communication through a second communication channel different from the first communication channel that has been used to communicate with the first battery rack management system.

When the communication abnormality occurs in the first battery rack management system, the battery module management systems attempt communication through the second communication channel with any other battery rack management system located in another rack in order to maintain communication continuity. Here, each of the battery rack management systems in the plurality of battery racks communicates with the battery module management system in the same rack through a predetermined channel, but periodically performs communication through the second communication channel for a predetermined time. Each of the plurality of battery rack management systems alternately performs communication through a second communication channel in each period. When the wireless communication unit <NUM> performs communication through the second communication channel due to a communication abnormality of the first battery rack management system while the plurality of battery rack management systems alternately performing communication through the second communication channel, the wireless communication unit <NUM> performs communication with a battery rack management system (hereinafter referred to as a 'second battery rack management system') performing communication through the second communication channel.

The wireless communication unit <NUM> transmits the communication abnormality signal of the first battery rack management system to the second battery rack management system through the second communication channel. In addition, the wireless communication unit <NUM> transmits the battery status data to the second battery rack management system through the second communication channel.

In addition, the wireless communication unit <NUM> receives various commands received from the upper-level controller from the second battery rack management system through the second communication channel.

The communication abnormality detection unit <NUM> determines a communication abnormality of the battery rack management system in the same rack. All methods of determining communication abnormalities are included. For example, when a communication confirmation signal is periodically transmitted to the battery rack management system in the same rack, and a response signal to the corresponding communication confirmation signal is received, it is determined that there is no communication abnormality of the battery rack management system, and when the response signal is not received, it is determined that there is the communication abnormality of the corresponding battery rack management system.

Or, for example, the wireless communication unit <NUM> periodically receives a command from the battery rack management system, and if no signal is received from the corresponding battery rack management system for a predetermined time, the communication abnormality detection unit <NUM> determines that there is a communication abnormality of the corresponding battery rack management system.

The battery state measurement unit <NUM> is a configuration for measuring the state of the battery, and may include a configuration that measures the voltage, current, or temperature of the battery. In general, there are methods of measuring the battery voltage, for example, a method of using an operational amplifier and a method of using a relay and a capacitor. In addition, in general, battery current measurement may be performed using a current sensor corresponding to at least one of a current transformer method, a hall element method, and a fuse method. Also, in general, the battery temperature measurement can be measured by, for example, a thermistor. Thermistor is a semiconductor element obtained by combining oxides such as manganese, nickel, copper, cobalt, chromium, and iron to be mixed and sintered, and is an element having a characteristic that an electrical resistance value changes according to temperature. For example, the thermistor may be a positive temperature coefficient thermistor (PTC) having temperature and resistance values having a proportional characteristic, a negative temperature coefficient thermistor (NTC) having temperature and resistance values having an inverse proportional characteristic, and a critical temperature resistor in which a resistance value rapidly changes at a specific temperature.

The voltage, current, or temperature data of the battery measured by the battery state measurement unit <NUM> may be transmitted to a battery rack management system, which is an upper-level battery management system. In addition, a battery SOC may be calculated using the battery voltage, current, or temperature data measured by the battery state measurement unit <NUM>, and battery abnormality determination may be performed using the calculated battery SOC information. The battery SOC or a battery abnormality signal determined based on the battery SOC is transmitted to the battery rack management system, which is the upper-level battery management system.

The channel change unit <NUM> allows the wireless communication unit <NUM> to perform communication through a preset second communication channel when the communication abnormality of the battery rack management system in the same battery rack is detected by the communication abnormality detection unit <NUM>. When the corresponding battery rack management system has a communication abnormality, the channel change unit <NUM> stores second communication channel information so that the wireless communication unit <NUM> can perform communication through the second communication channel.

When the communication abnormality detection unit <NUM> detects the communication abnormality of the corresponding battery rack management system, the control unit <NUM> receives the communication abnormality signal of the corresponding battery rack management system from the communication abnormality detection unit <NUM>. When the control unit <NUM> receives the communication abnormality signal from the corresponding battery rack management system from the communication abnormality detection unit <NUM>, the control unit <NUM> causes the wireless communication unit <NUM> to transmit data including information that a communication abnormality of the corresponding battery rack management system has occurred to the battery rack management system of another rack through the second communication channel.

<FIG> is a configuration diagram of a battery rack management system according to the present invention.

The battery rack management system <NUM> includes a wireless communication unit <NUM>, a channel change unit <NUM>, a communication unit <NUM>, and a control unit <NUM>.

The wireless communication unit <NUM> basically performs wireless communication with the battery module management system in the same rack through a preset communication channel, for example, a third communication channel. The wireless communication unit <NUM> transmits commands received from the upper-level controller to a battery module in the same battery rack through the third communication channel.

The wireless communication unit <NUM> performs communication through the second communication channel, which is the preset communication channel, for a predetermined time at a preset period. The wireless communication unit <NUM> can perform communication with the battery module management system <NUM> disposed in another rack through the second communication channel. In this case, as described above, when a communication abnormality occurs in the battery rack management system in the same rack, the battery module management system <NUM> disposed in another rack attempts communication by changing a channel to a preset communication channel, for example, the second communication channel. In this case, through the preset second communication channel, each of the battery rack management systems disposed in a plurality of other racks alternately performs communication by changing to the second communication channel for a preset time at a preset period. When the battery module management system <NUM> for which a communication abnormality occurs in the upper-level battery management system changes to the second communication channel to perform communication, the battery module management system <NUM> may perform communication with a battery rack management system, which is in communication through the second communication channel, among other plurality of battery rack management systems.

That is, when the communication abnormality occurs in the battery rack management system of another rack, the wireless communication unit <NUM> can perform communication with the battery module management system <NUM> in the corresponding rack, and receive a communication abnormality signal of the battery rack management system in the corresponding rack from the battery module management system <NUM> through the second communication channel. In addition, the wireless communication unit <NUM> can receive battery status information data from the battery module management system <NUM> in the rack, in which the communication abnormality has occurred, through the second communication channel. In addition, if there is a command, which is received from the upper-level controller <NUM> for a certain time before the communication connection is established through the second communication channel to the battery module management system <NUM>, in the rack in which a communication abnormality has occurred, the wireless communication unit <NUM> transmits the corresponding commands to the battery module management system <NUM> through the second communication channel.

The channel change unit <NUM> changes the communication channel of the wireless communication unit <NUM>. The wireless communication unit <NUM> usually performs communication with battery module management systems in the same rack through a third communication channel. However, when the communication abnormality occurs in the battery module management system in another specific rack and communication with the corresponding battery rack management system is impossible, communication continuity can be maintained by changing to a specific channel, for example, the second communication channel, and attempting communication with a battery rack management system of another rack. In this time, in order to perform communication with the battery module management system disposed in another rack that attempts communication by changing to the second communication channel, the battery rack management systems in a rack other than a rack, in which the communication abnormality has occurred, perform communication by alternately and periodically changing to the second communication channel.

Accordingly, the channel change unit <NUM> changes the communication channel of the wireless communication unit <NUM> to perform communication through a preset communication channel for a preset time at a preset period.

The communication unit <NUM> performs communication with the upper-level controller <NUM>. The communication unit <NUM> may be a wireless communication unit or a wired communication unit. In the case of the wireless communication unit, it may be used by being integrated with the wireless communication unit <NUM>.

The communication unit <NUM> transmits battery status information received from the battery module management system in the same rack received by the wireless communication unit <NUM> to the upper-level controller <NUM>.

In addition, the communication unit <NUM> receives control commands from the upper-level controller <NUM>.

In addition, the communication unit <NUM> transmits the communication abnormality signal and battery status data of the battery rack management system received from the battery module management system <NUM> in another rack by the wireless communication unit <NUM> to the upper-level controller <NUM> through the second communication channel.

When the communication abnormality signal of the battery rack management system is received from the non-associated battery module management system through the second communication channel, the control unit <NUM> causes the wireless communication unit <NUM> to transmit a command signal, which has been received from the upper-control unit from before a preset time, to a battery module management system which is not associated by being disposed in another rack.

<FIG> illustrates an example of a communication channel between the systems for managing a battery.

BBMS (BANK BMS) is communicatively connected to RBMS_A, RBMS_B, and RBMS_C through CAN communication. In this case, a wired connection through CAN communication is established, but it may be wirelessly connected.

Each RBMS performs wireless communication with a plurality of MBMSs disposed in each rack. Each RBMS wirelessly communicates with each of the plurality of MBMSs disposed in each rack through each set communication channel.

For example, RBMS_A communicates wirelessly through channel A (ch A) with the plurality of MBMSs in the same rack. RBMS_A can transmit various command signals, such as a control command or a monitoring command, etc. received from BBMS which is an upper-level controller, to MBMS, a lower-level battery management system, respectively, through channel A. In addition, each MBMS can also transmit battery status information or battery abnormality information, etc. to RBMS_A through channel A.

However, MBMSs in the same rack as RBMS_A basically transmit and receive signals to and from BBMS, which is an upper-level controller, through only RBMS_A, through channel A. However, if a communication abnormality occurs in RBMS_A, MBMSs that performed communication with BBMS through RBMS_A become in a communication disabled state.

Therefore, in order to eliminate the communication disabled state of these MBMSs, a separate channel is formed to communicate by changing the channel to, for example, channel E (ch E), so that MBMSs can communicate with the battery rack management system of another battery rack.

Specifically, each of the plurality of RBMSs performs communication by periodically connecting to a preset emergency channel, for example, channel E (ch E) as the second communication channel described above, while basically performing communication with the MBMS in the corresponding battery rack through a set communication channel. A plurality of RBMSs alternately perform communication through channel E. MBMSs whose communication is disabled due to a communication abnormality of RBMS_A can detect the communication abnormality of RBMS_A and changes the communication channel to channel E, and can perform communication with RBMS_B of another rack which is in communication through channel E at that time.

Through channel E, the plurality of MBMSs in a communication disabled state can receive a command from BBMS, which is an upper-level controller, or transmit battery status information or battery abnormality information through RBMS_B of another rack without a communication short circuit.

<FIG> is a flowchart of a method for managing a battery.

The battery module management system <NUM>, which is a lower-level battery management system, detects a communication abnormality of a battery rack management system, which is a first upper-level battery management system that wirelessly performs communication through a first communication channel (S500). The battery rack management system in the same rack as the battery module management system <NUM> is a system associated with the battery module management system, and the battery rack management system in another rack is a system not associated with the battery module management system.

For example, a communication confirmation signal is periodically transmitted to the battery rack management system in the same rack, and when a response signal to the communication confirmation signal is received, it is determined that there is no communication abnormality of the corresponding battery rack management system, and when the response signal is not received, it is determined that there is a communication abnormality in the corresponding battery rack management system.

Or, for example, the wireless communication unit <NUM> periodically receives a command from the corresponding battery rack management system, and when no signal is received from the corresponding battery rack management system for a predetermined time, the abnormality detection unit <NUM> determines that there is a communication abnormality in the corresponding battery rack management system.

The battery module management system <NUM> starts wireless communication using a second communication channel different from the first communication channel (S502).

The second communication channel is a preset channel, and is a channel through which battery rack management systems of other racks periodically change channels to perform wireless communication.

Accordingly, when the battery module management system <NUM> start communication using the second communication channel, the battery module management system <NUM> transmits a communication abnormality signal of the first upper-level battery management system to the second upper-level battery management system performing communication using the second communication channel (S504).

The second upper-level battery management system is a battery rack management system which is performing communication through the second communication channel when the battery module management system <NUM> performs communication using the second communication channel.

The battery module management system <NUM> communicates with the second upper-level battery management system through the second communication channel (S506).

The wireless communication unit <NUM> transmits the battery status data to the second battery rack management system through the second communication channel. In addition, the wireless communication unit <NUM> receives various commands received from the upper-level controller from the second battery rack management system through the second communication channel.

<FIG> is a flowchart of a method for managing a battery according to the present invention.

The battery rack management system <NUM> communicates with a lower-level battery management system, which is a battery module management system in the same rack, through a third communication channel (S600).

The wireless communication unit <NUM> of the battery rack management system typically performs wireless communication with the battery module management system in the same rack through a preset communication channel, for example, a third communication channel. The wireless communication unit <NUM> transmits commands received from an upper-level controller to a battery module in the same battery rack through the third communication channel.

In addition, the battery rack management system <NUM> performs communication through a preset second communication channel for a preset time at a preset period (S602).

The wireless communication unit <NUM> of the battery rack management system <NUM> performs communication through the second communication channel which is the preset communication channel for a predetermined time at a preset period.

If the battery rack management system <NUM> receives a communication abnormality signal of the first upper-level battery management system from a lower-level battery system in another rack while performing communication through the second communication channel, the communication abnormality signal is transmitted to the upper-level controller (S604).

That is, when a communication abnormality of the battery rack management system of another rack occurs, the wireless communication unit <NUM> can perform communication with the battery module management system <NUM> in the corresponding rack and receives the communication abnormality signal of the battery rack management system in the corresponding rack from the battery module management system <NUM> through the second communication channel.

The battery rack management system <NUM> transmits the battery status data received from the lower-level battery management system to the upper-level controller through the second communication channel (S606).

Specifically, the wireless communication unit <NUM> of the battery rack management system <NUM> can receive battery status information data from the battery module management system <NUM> in the rack in which the communication abnormality has occurred through the second communication channel.

In addition, the battery rack management system <NUM> transmits the command received from the upper-level controller from before a predetermined time to the battery module management system, which is a lower-level battery management system, through the second communication channel (S608).

If there is the command received from the upper-level controller <NUM> for a predetermined time before the communication connection is established through the second communication channel to the battery module management system <NUM> in the rack where a communication abnormality has occurred, the wireless communication unit <NUM> of the battery rack management system <NUM> transmits corresponding commands to the battery module management system <NUM> through the second communication channel.

<FIG> is a block diagram illustrating a hardware configuration of the system for managing the battery.

A system <NUM> for managing a battery may include a microcontroller (MCU) <NUM> that controls various processes and configurations, a memory <NUM> in which an operating system program and various programs (e.g., a battery pack abnormality diagnosis program or a battery pack temperature estimation program), etc. are recorded, an input and output interface <NUM> that provides an input interface and an output interface between the battery cell module and/or the semiconductor switching element, and a communication interface <NUM> capable of performing communication with the outside through a wired or wireless communication network. In this way, the computer program according to the present invention is recorded in the memory <NUM> and processed by the microcontroller <NUM>, thereby capable of being implemented as a module that performs the respective functional blocks illustrated in <FIG> and <FIG>.

In this specification, reference to 'one embodiment' of the principles of the present invention and various modifications of such expression, in connection with this embodiment, means that a particular feature, structure, characteristic, etc. are included in at least one embodiment of the principles of the present invention. Accordingly, the expression 'in one embodiment' and any other modified examples disclosed throughout this specification are not necessarily all referring to the same embodiment.

Claim 1:
A system (<NUM>) for managing a battery, the system comprising:
a wireless communication unit (<NUM>) configured to communicate using a plurality of associated lower-level battery management systems disposed in the same battery rack through a first communication channel; and
a communication unit (<NUM>) configured to transmit and receive data with an upper-level control unit (<NUM>);
characterized in that the system further comprises a channel change unit (<NUM>) configured to allow the wireless communication unit to communicate with a non-associated lower-level battery management system in a different battery rack using a second communication channel different from the first communication channel for a preset time at a preset period when a communication abnormality occurs in the non-associated lower-level battery management system in the different battery rack.