KR101441761B1 - Battery Energy Storage System - Google Patents

Abstract

A battery energy storage system according to one aspect of the present invention which can improve a data transfer rate includes a battery management device that charges electric power of a system or discharges power to a system; And an integrated controller for controlling charging and discharging of the battery management apparatus, wherein the battery management apparatus includes at least one of voltage, current, and temperature of the battery module from a plurality of trays composed of one or more battery modules A BMS (Battery Management System) for acquiring battery module data including the analog type and converting the battery module data of the analog type into digital battery module data; And a remote input / output unit connected to the tray BMS by a hard wire and transmitting the analog type battery module data received via the hard wire to the integrated controller according to a predetermined first communication protocol .

Description

[0001] Battery Energy Storage System [0002]

The present invention relates to an energy storage system, and more particularly to a battery energy storage system.

With the development of the industry, the demand for electric power is increasing, and the gap of electricity use between day and night, season, and day is increasing.

Recently, many techniques for reducing the peak load by utilizing surplus power of the system have been developed rapidly. For example, among these technologies, a battery which stores surplus power of the system in the battery, It is a battery energy storage system.

The battery energy storage system stores surplus power generated at night or surplus power generated from renewable energy sources such as wind power and sunlight, and supplies the power stored in the battery to the system during a peak load or system accident. This will stabilize the system power unstably fluctuating by the renewable energy source and achieve maximum load reduction and load leveling.

In particular, such a battery energy storage device can be used in an intelligent power grid (Smart Grid) and a micro power grid (Micro Grid), which are emerging due to the emergence of various new and renewable energy sources.

The battery energy storage system includes a battery management system (BCS) having a configuration as shown in FIG. The battery management apparatus 100 includes a tray BMS 120 for controlling a tray composed of a plurality of battery modules, a rack BMS 130 for controlling a plurality of tray BMSs 120, a plurality of rack BMSs 130 And a battery management device controller 150 for interfacing the system BMS 140 with an upper controller (not shown).

As shown in FIG. 1, the battery management apparatus 100 provides power stored in a plurality of battery modules to the system or charges the plurality of batteries with power of the system.

However, in the case of the battery energy storage system including the battery management apparatus 100 having the above-described configuration, since the respective components 120 to 150 are configured in a hierarchical structure, There is a problem that significant delay occurs in transferring the module related data to the host controller and real-time monitoring of the battery management apparatus 100 is restricted due to such delay.

SUMMARY OF THE INVENTION The present invention is directed to a battery energy storage system capable of improving data transfer speed.

Another object of the present invention is to provide a battery energy storage system with improved reliability.

According to an aspect of the present invention, there is provided a battery energy storage system including: a battery management device for charging a system power or discharging power to a system; And an integrated controller for controlling charging and discharging of the battery management apparatus, wherein the battery management apparatus includes at least one of voltage, current, and temperature of the battery module from a plurality of trays composed of one or more battery modules A BMS (Battery Management System) for acquiring battery module data including the analog type and converting the battery module data of the analog type into digital battery module data; And a remote input / output unit connected to the tray BMS by a hard wire and transmitting the analog type battery module data received via the hard wire to the integrated controller according to a predetermined first communication protocol .

According to another aspect of the present invention, there is provided a battery energy storage system including: a battery management device charging a system power or discharging power to a system; A power management device that charges the battery management device using the power of the system or discharges power of the battery management device to supply the power to the system; And an integrated controller for determining charging and discharging of the battery management apparatus and controlling operations of the battery management apparatus and the power management apparatus according to whether the battery management apparatus is charged or discharged, A power management apparatus controller for controlling an operation of the power management apparatus according to an operation control command transmitted from a controller; A first master Ethernet switch for mediating a connection between the power management unit controller and the integrated controller; And a first backup Ethernet switch duplicated with the first master Ethernet switch.

According to the present invention, since the battery module data acquired by the tray BMS is directly transmitted in analog form from the tray BMS to the remote input / output unit without passing through other BMSs, and the remote input / output unit transmits battery module data to the integrated controller, There is an effect that the transmission speed of module data can be improved.

In addition, according to the present invention, since the battery management apparatus controller, the power management apparatus controller, and the remote input / output unit interface with the integrated controller using the IEC 61850 communication protocol, the communication speed can be maximized.

In addition, according to the present invention, the reliability of the battery energy storage system can be improved because the Ethernet switch connecting each controller constituting the battery energy storage system is duplicated.

In addition, according to the present invention, since each controller constituting the battery energy storage system is duplicated, the reliability improvement of the battery energy storage system can be maximized.

1 is a block diagram schematically showing a configuration of a general battery management device.
2 is a block diagram illustrating a network environment to which a battery energy storage system according to an embodiment of the present invention is applied.
3 is a block diagram schematically illustrating the configuration of the battery energy storage system shown in FIG. 2. FIG.
FIG. 4 is a block diagram schematically showing the configuration of the battery management apparatus shown in FIG. 3; FIG.
5 is a block diagram schematically showing the configuration of the power management apparatus shown in FIG. 3;
6 is a block diagram showing the network connections of the controllers that make up the battery energy storage system;

The meaning of the terms described herein should be understood as follows.

The word " first, "" second," and the like, used to distinguish one element from another, are to be understood to include plural representations unless the context clearly dictates otherwise. The scope of the right should not be limited by these terms.

It should be understood that the terms "comprises" or "having" does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

It should be understood that the term "at least one" includes all possible combinations from one or more related items. For example, the meaning of "at least one of the first item, the second item and the third item" means not only the first item, the second item or the third item, but also the second item and the second item among the first item, Means any combination of items that can be presented from more than one.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a schematic diagram of a network configuration to which a battery energy storage system according to an embodiment of the present invention is applied.

2, a battery energy storage system (BESS) 200 according to the present invention includes a global monitoring system (GMS) 210 and an energy management system (EMS) 220). At this time, the global monitoring system 210 may be connected to the battery energy storage system 200 and the energy management system 220 via the Internet.

First, the global monitoring system 210 is connected to a plurality of battery energy storage systems 200 through an energy management system 220. The global monitoring system 210 includes a global integrated management system 200, a plurality of battery energy storage systems 200, (E.g., battery life prediction or checking), a plurality of battery energy storage < RTI ID = 0.0 > Performs operational optimization management of the system 200, and manages investment / facility efficiency.

The energy management system 220 is connected to a plurality of battery energy storage systems 200 to perform operation schedule control of a plurality of battery energy storage systems 200, Various data are reported to the global monitoring system 210, integrated management of the power of the plurality of battery energy storage systems 200, and prediction of demand or generation amount of the system (not shown).

In addition, the energy management system 220 performs functions such as power transaction history management or optimal power generation planning.

The battery energy storage system 200 receives surplus power generated from wind power, sunlight, etc. from the system and charges the battery power storage system 200. In case of a peak load or a system failure, And discharges the charged power to the system to supply power to the system.

Hereinafter, such a battery energy storage system 200 will be described in more detail with reference to FIGS. 3 to 5. FIG.

3 is a block diagram schematically illustrating the configuration of a battery energy storage system according to an embodiment of the present invention. 2, the battery energy storage system 200 includes a battery conditioner system 300, a power conditioning system 310, and an integrated controller 320 (BESS Controller 320) .

Although the integrated controller 320 is illustrated as being connected to one battery management device 300 and one power management device 310 for ease of explanation in FIG. 3, in an alternative embodiment, the integrated controller 320 A plurality of battery management devices, and a plurality of power management devices.

First, the battery management device 300 receives power supplied from the power management device 310, charges one or more battery modules included in the battery management device 300 using the supplied power, charges the one or more battery modules And supplies the power to the system through the power management device 310. [

The configuration of the battery management apparatus 300 will be described in more detail with reference to FIG.

4 is a block diagram schematically illustrating the configuration of a battery management apparatus according to an embodiment of the present invention. 4, the battery management apparatus 300 includes a tray BMS 410, a remote input / output unit 420, a rack BMS 430, and a battery management apparatus controller 440. [ 4, the battery management apparatus 300 according to an embodiment of the present invention may further include an air conditioning management unit 450 and a fire control unit 460.

First, the tray BMS 410 controls a tray (not shown) composed of one or more battery modules. Specifically, the tray BMS 410 senses the voltage of the battery modules included in the tray, the current flowing in the battery modules, and the temperature of the battery modules, and outputs the analog signals including at least one of voltage, current, Lt; / RTI >

The tray BMS 410 is connected to an analog type battery module 420 using an analog-digital converter (ADC) (not shown) to transmit battery module data to the rack BMS 430 through a CAN (Controller Area Network) Converts the data into digital form battery module data, and transmits digital form battery module data to the rack BMS 430.

4, the tray BMS 410 is connected to the remote input / output unit 420 through a hard wire 412. The tray BMS 410 is connected to the remote I / To the remote input / output unit 420 through the hard wire.

That is, in order to eliminate the time delay occurring in the process of transmitting the battery module data such as the voltage, current, and temperature of the battery module to the integrated controller 320 of FIG. 3 as the host controller, 410 and the remote input / output unit 420 via the hard wire 412. When the battery module data is generated from the battery module, the battery module data is directly transmitted to the remote input / output unit 420 in analog form.

In addition, the tray BMS 410 performs functions such as voltage unbalance control between the battery modules, prevention of overcharge or overdischarge of the battery module, and the like.

The remote input / output unit 420 is connected to a plurality of tray BMSs 410 via a hard wire 412 to directly receive battery module data from a plurality of tray BMSs 410 in analog form. The remote input / output unit 420 transmits the battery module data received from the plurality of tray BMSs 410 to the integrated controller 320 using a predetermined communication protocol.

In one embodiment, the remote input / output unit 420 may transmit battery module data to the integrated controller 320 using an International Electro-technical Commission (IEC) 61850 communication protocol.

Here, the IEC 61850 communication protocol means a substation automation communication protocol for converting an existing complex copper wire communication method into an open type Ethernet based optical cable digital method for communication and control of the substation system.

To this end, the remote input / output unit 420 includes an analog to digital converter (not shown) for converting the analog form of battery module data received from the tray BMS 410 via the hard wire 412 into digital form, (Not shown) for converting the battery module data to the IEC 61850 communication protocol.

In one embodiment, the protocol converter may convert the battery module data into a Generic Object-Oriented Substation Event (GOOSE) message or a Manufacturing Message Specification (MMS) message format according to the IEC 61850 communication protocol and transmit the data to the integrated controller 320 .

Next, the rack BMS 430 is configured to link a plurality of tray BMSs 410 with the battery management device controller 440, and receives digital type battery module data from the plurality of tray BMSs 410 via CAN communication , And estimates SOC (State Of Charge) of each battery rack formed of a plurality of trays by using the received digital form battery module data.

In addition, the rack BMS 430 transmits the digital battery module data and the SOC of each battery rack to the battery management unit controller 440 according to the Modbus / TCP communication protocol.

That is, in the present invention, the rack BMS 430 transmits / receives data through the CAM communication with the tray BMS 410, but transmits / receives data to / from the battery management device controller 440 according to the Modbus / TCP communication protocol. 430 and the battery management device controller 440 can be improved.

The battery management unit controller 440 is a unit for interfacing a plurality of rack BMSs 430 with the integrated controller 320 and is configured to receive battery module data and battery power data from a plurality of rack BMSs 430 in accordance with the Modbus / Receives the SOC of the rack and transfers the received battery module data or the SOC of each battery rack to the integrated controller 320 according to the IEC 61850 communication protocol.

That is, the battery management unit controller 440 also transmits and receives data using the IEC 61850 communication protocol with the integrated controller 320 in the same manner as the remote input / output unit 420 in order to improve the communication speed.

In addition, the battery management device controller 440 receives information on the charge / discharge status of the battery management device 300 from the integrated controller 320, and determines whether the battery management device 300 is included in each battery rack The battery management device 300 can perform charging or discharging by turning on / off a rack switch (not shown).

The battery management device controller 440 may further control an initial charge switch (not shown) included in each battery rack to prevent an inrush current in each battery rack. Specifically, the battery management apparatus controller 440 turns on the initial charge switch for a time period before the battery management apparatus 300 reaches a normal state, and after the battery management apparatus 300 reaches a normal state, Turn off the charging switch.

In addition, the battery management device controller 440 controls the operation of the air conditioning management unit 450 and the fire management unit 460. [

Specifically, when the internal temperature of the battery management device controller 440 is equal to or greater than the first threshold value, the air conditioning management unit 450 controls the cooling function to be performed. When the internal temperature of the battery management device controller 440 is lower than the second threshold value The air conditioning management unit 450 performs a heating function.

In addition, the battery management device controller 440 operates the fire control unit 460 to detect the occurrence of a fire in the battery management device 300 so that the generated fire is extinguished.

Next, the air conditioning management unit 450 operates under the control of the battery management device controller 440 to cool or heat the battery management device 300 or to control the humidity inside the battery management device 300 do.

The fire control unit 460 operates under the control of the battery control unit controller 440 to extinguish a fire generated when a fire occurs in the battery management unit 300. [

Although the air conditioning management unit 450 and the fire control unit 460 are included in the battery management unit 300 in the embodiment described above, May be implemented as an external device physically separated from the battery management device 300, and thus may not be included in the battery management device 300.

3, the power management apparatus 310 may use one or more battery modules included in the battery management apparatus 300 using the power provided from the system according to the operation control information transmitted from the integrated controller 320 Or discharges the electric power charged in one or more battery modules and supplies the electric power to the system.

Although not shown in FIG. 3, the power management device 310 may be connected to the plurality of battery management devices 300. As described above, when a plurality of battery management apparatuses 300 are connected to one power management apparatus 310, power can be supplied to the system for a long time.

Hereinafter, the configuration of such a power management apparatus will be described with reference to FIG.

5 is a block diagram schematically illustrating the configuration of a power management apparatus according to an embodiment of the present invention. 5, the power management apparatus 310 according to an exemplary embodiment of the present invention includes a power management apparatus controller 510, at least one power conversion unit 520, a switchgear 530, and a transformer 540 ).

First, the power management apparatus controller 510 receives operation control information of the power management apparatus 310 from the integrated controller 320 and transmits the received operation control information to the at least one power conversion unit 520.

In one embodiment, the operation control information of power management device 310 may include a converting instruction and an inverting instruction. Here, the converting instruction means converting the AC voltage provided from the system into a DC voltage and providing it to the battery management apparatus 300, which means a charge command of the battery management apparatus 300. Also, the inverting instruction means converting the DC voltage supplied from the battery management device 300 into an AC voltage and providing it to the system, which means a discharge command of the battery management device 300.

Meanwhile, the power management unit controller 510 collects the data transmitted from the at least one power conversion unit 520 and transmits the collected data to the integrated controller 320. In one embodiment, the data provided from the one or more power conversion units 520 include the amount of output power (active power and reactive power), the output frequency, the on / off operation state, the power factor, the efficiency, Output voltage, and output current.

In one embodiment, the power management unit controller 510 may send and receive data in accordance with one or more power converters 520 and Modbus / TCP communication protocols and may receive data from the integrated controller 320 and the IEC 61850 communication protocol Lt; / RTI > As a result, the data transmission speed can be improved between the power management apparatus 310 and the integrated controller 320 as well as within the power management apparatus 310.

In addition, the power management apparatus controller 510 monitors whether or not an error has occurred in the power management apparatus 310 or the system. If it is determined that an error has occurred, the power management apparatus controller 510 turns off the switch gear 530, The system is disconnected or the transformer 540 is controlled so that the AC voltage is stepped up or reduced.

Next, at least one power conversion unit (PCU) 520 converts the AC voltage to a DC voltage or converts the DC voltage to an AC voltage according to operation control information transmitted from the power management unit controller 510 .

That is, the power conversion unit 520 converts the AC voltage provided from the system into the DC voltage according to the converting instruction received from the power management unit controller 510, and outputs the DC voltage to the battery management device 300 Converts the supplied DC voltage into an AC voltage and outputs it.

In addition, the power conversion unit 520 may compensate the active power of the system using the power provided through discharging of one or more battery modules included in the battery management device 300, The reactive power of the system can be compensated by changing the frequency and phase of the power output through discharging of the batteries.

Next, the switch gear 530 connects the system and the power conversion unit 520. This switchgear 530 is turned on and off by the power management apparatus controller 510. Specifically, when an error occurs in the power management apparatus 310 or the system, the switchgear 530 is turned off by the power management apparatus controller 510, Thereby disconnecting the device 310 from the system.

Next, the transformer 540 reduces the AC voltage input from the system to the power conversion unit 520 to an AC voltage that can be operated by the power conversion unit 520, or converts the AC voltage output from the power conversion unit 520 into a system To the AC voltage that can be operated by the inverter.

Referring again to FIG. 3, the integrated controller 320 determines whether the one or more battery modules included in the battery management device 300 are charged or discharged, and determines whether the battery management device 300 and the power management device 300 310 and transmits the generated operation control information to the battery management device 300 and the power management device 310. Here, the operation control information may include any one of a converting instruction and an inverting instruction.

The integrated controller 320 receives the battery module data from the remote input / output unit 420 included in the battery management device 300 and receives the battery module data and the SOC of each battery rack from the battery management device controller 440 do. At this time, as described above, the integrated controller 320 directly receives the battery module data from the remote input / output unit 420, so that it can receive the battery module data generated by the tray BMS 410 in a shorter time .

The integrated controller 320 receives the output power amount (active power and reactive power) of the power conversion units 520 from the power management unit controller 510 included in the power management apparatus 310, the output frequency, the on / , Power factor, efficiency, output voltage, and output current.

In one embodiment, the integrated controller 320 interfaces with the remote input / output unit 420, the battery management unit controller 440, and the power management unit controller 510 using the IEC 61850 communication protocol, Can transmit and receive data to / from the remote input / output unit 420, the battery management device controller 440, and the power management device controller 510 at a higher speed.

The integrated controller 320 transfers the data transmitted from the battery management device 300 and the power management device 310 to the energy management system 220 shown in FIG. And transfers the operation schedule and the like of the battery energy storage system 200 to the battery management device 300 or the power management device 310.

At this time, the integrated controller 320 can transmit / receive data to / from the energy management system 220 at a higher speed by interfacing with the energy management system 220 using the IEC 61850 communication protocol.

Meanwhile, the integrated controller 320 according to the present invention may further include a soft PLC (not shown) to additionally implement various control algorithms required in the field. By configuring various control algorithms required in the field through such soft PLC, it is possible to reflect various environmental changes occurring in the field in the control logic.

Although the battery energy storage system 200 is described as an interface only with the energy management system 220 in the above-described embodiment, the battery energy storage system 200 according to the present invention may be linked to various systems. For example, the battery energy storage system 200 may also interface with a SCADA system or a human interface (HMI) system.

In this case, the battery energy storage system 200 can interface with the Scada system using the DNP 3.0 communication protocol, and can interface with the human interface system using the OPC communication protocol. The integrated controller 320 of the battery energy storage system 200 for interfacing with these various systems includes a remote input / output unit 420, a battery management unit controller 440, and a power management unit controller 510 according to the IEC 61850 communication protocol And a plurality of protocol mapping units (not shown) for mapping the data received from the other system to the promised communication protocol with other systems.

Hereinafter, the network connection of the battery energy storage system having the above-described configuration with reference to FIG. 6 will be briefly described.

6 is a block diagram illustrating a network connection of each controller constituting a battery energy storage system according to an embodiment of the present invention.

6, the power management apparatus 310 of the energy storage system 200 according to an exemplary embodiment of the present invention includes a first power management apparatus 310 that mediates a connection between the power management apparatus controller 510 and the integrated controller 320, And an Ethernet switch 610. The battery management apparatus 300 includes a battery management apparatus controller 440 and a second Ethernet switch 620 for mediating a connection between the remote input / output unit 420 and the integrated controller 320 .

At this time, the second Ethernet switch 620 connects the battery management device controller 440 and the remote input / output unit 420 to the integrated controller 320 using the first Ethernet switch 610 as a backbone switch.

In one embodiment, the first Ethernet switch 610 is duplicated as a first master Ethernet switch 610a and a first backup Ethernet switch 610b as shown in FIG. 6, and the second Ethernet switch 620, Is duplicated as a second master Ethernet switch 620a and a second backup Ethernet switch 620b.

To this end, the power management apparatus controller 510 and the integrated controller 320 connected to the first Ethernet switch 610 are connected to the Ethernet port for connection to the first master Ethernet switch 610a and the first backup Ethernet switch 610b And an Ethernet port to be connected.

The battery management unit controller 440 and the remote input / output unit 420 connected to the second Ethernet switch 620 are connected to the Ethernet port for connecting to the second master Ethernet switch 620a and the second backup Ethernet switch 620b, Lt; RTI ID = 0.0 > Ethernet < / RTI >

According to this embodiment, the first and second Ethernet switches 610 and 620 can prevent RSTP (Rapid Spanning Tree Protocol) in order to prevent a collision between each of the dual connected devices and to switch a connection path at a high speed when an error occurs. It is set to support.

6, the battery energy storage system 200 according to the present invention includes an integrated controller 320, a battery management device controller 440, and a power management device controller 510 ) Can be implemented by duplicating at least one of them.

6, the integrated controller 320 may be configured to be duplicated in the master integrated controller 320a and the backup integrated controller 320b, or the battery management device controller 440 may be configured in the master battery management unit controller 440a, And the backup battery management unit controller 440b or the power management unit controller 510 may be configured to be redundant to the master power management unit controller 510a and the backup power management unit controller 510b.

At this time, the redundant controllers 320, 440 and 510 are operated in parallel according to the hot standby mode.

Although the first Ethernet switch 610 is included in the power management device 310 and the second Ethernet switch 620 is included in the battery management device 300 in the above embodiment, The first Ethernet switch 610 may be configured separately from the power management apparatus 310 and the second Ethernet switch 620 may be configured separately from the battery management apparatus 300. [

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof.

It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

200: Battery Energy Storage System 210: Global Monitoring System
220: Energy management system 300: Battery management device
310: power management device 320: integrated controller
410: Tray BMS 420: Remote I / O unit
430: Rack BMS 440: Battery management device controller
450: HVAC management unit 460:
510: Power Management Device Controller 520: Power Conversion Unit
530: Switching gear 540: Transformer
610a: first master Ethernet switch 610b: first backup Ethernet switch
620a: second master Ethernet switch 620b: second backup Ethernet switch

Claims (11)

A battery management device for charging the power of the system or discharging power to the system; And
And an integrated controller for controlling charging and discharging of the battery management device,
The battery management device includes:
A method of controlling a battery module, comprising: acquiring battery module data of an analog type including at least one of voltage, current, and temperature of the battery module from a plurality of trays constituted by one or more battery modules; A tray BMS (Battery Management System) for converting into battery module data; And
And a remote input / output unit connected to the tray BMS by a hard wire and transmitting the analog type battery module data received via the hard wire to the integrated controller according to a predetermined first communication protocol,
Wherein the integrated controller includes a master integrated controller and a backup integrated controller that operate in a redundant manner. The method according to claim 1,
The battery management device includes:
A rack BMS for receiving the digital type battery module data from the tray BMS and estimating a state of charge (SOC) of a battery rack composed of the plurality of trays; And
A battery management module that receives the digital type battery module data and the SOC of the battery rack from the rack BMS and transmits the digital battery module data and the SOC of the battery rack to the integrated controller in accordance with the first communication protocol Further comprising a device controller. 3. The method of claim 2,
Wherein the battery management device controller comprises a master battery management device controller and a backup battery management device controller that are operated in a redundant manner. The method according to claim 1,
Further comprising a power management device for charging the battery management device by using power of the system or for discharging power of the battery management device to supply the power to the system,
The power management apparatus includes:
At least one power conversion unit converting an AC voltage provided from the system into a DC voltage or converting a DC voltage provided from the battery management device into an AC voltage; And
And a power management unit controller for receiving an operation control command of the power conversion unit from the integrated controller according to the first communication protocol or transmitting data transmitted from the at least one power conversion unit to the integrated controller. Energy storage system. 5. The method of claim 4,
Wherein the power management device controller comprises a master power management device controller and a backup power management device controller that are operated in a redundant manner. The method according to claim 1,
The first communication protocol is IEC 61850,
Wherein the remote input / output unit converts the analog battery module data into digital data and transmits the data to the integrated controller using a Generic Object-Oriented Substation Event (GOOSE) message or a Manufacturing Message Specification (MMS) message. Storage system. delete A battery management device for charging the power of the system or discharging power to the system;
A power management device that charges the battery management device using the power of the system or discharges power of the battery management device to supply the power to the system; And
And an integrated controller for determining charging and discharging of the battery management apparatus and controlling operations of the battery management apparatus and the power management apparatus according to charging / discharging of the battery management apparatus,
The power management apparatus includes:
A power management apparatus controller for controlling an operation of the power management apparatus according to an operation control command transmitted from the integrated controller;
A first master Ethernet switch for mediating a connection between the power management unit controller and the integrated controller; And
And a first backup Ethernet switch duplicated with the first master Ethernet switch,
Wherein the integrated controller includes a master integrated controller and a backup integrated controller that operate in a redundant manner. 9. The method of claim 8,
The battery management device includes:
A battery management device controller for transmitting SOC of a battery rack composed of a plurality of trays and battery module data obtained from at least one battery module to the integrated controller;
A second master Ethernet switch for connecting the battery management device controller to the integrated controller through the first master Ethernet switch and the first backup Ethernet switch; And
And a second backup Ethernet switch that is redundant with the second master Ethernet switch. 9. The method of claim 8,
The battery management device includes:
A remote input / output unit for receiving analog type battery module data from the tray BMS via a hard wire and transmitting the data to the integrated controller; And
A second master Ethernet switch for connecting the remote input / output unit to the integrated controller via the first master Ethernet switch and the first backup Ethernet switch; And
And a second backup Ethernet switch that is redundant with the second master Ethernet switch. 11. The method of claim 10,
The remote I / O unit and the integrated controller are interfaces using an IEC 61850 communication protocol,
Wherein the remote input / output unit converts the analog battery module data into digital data and transmits the data to the integrated controller using a Generic Object-Oriented Substation Event (GOOSE) message or a Manufacturing Message Specification (MMS) message. Storage system.

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