KR102236346B1 - Dual power supply for energy storage system and method for controlling the same - Google Patents

Abstract

A dual power supply device for an energy storage system according to an embodiment of the present invention includes: a battery management system for managing a battery; A DC-DC converter stepping down the output voltage of the battery; And when power is supplied from an external power source and the DC-DC converter, the battery management system and the energy storage by receiving power for operation of the energy storage system from the battery and from the external power source through the DC-DC converter. The battery management system and the energy storage by receiving power for the operation of the energy storage system from the battery through the DC-DC converter when it is provided to an electric device inside the system and power is not supplied from the external power source. It is provided to an electric device inside the system, and when power is not supplied from the DC-DC converter, power for the operation of the energy storage system is supplied from the external power source, and electricity inside the battery management system and the energy storage system Including the load share unit provided to the device, it is possible to monitor the immediate inoperative state of external power and converters, and to stably supply power to electrical devices such as the battery management system inside the energy storage system without fear of inoperability in an emergency. It can ensure a long life of the switching mode power supply and DC-DC converter, and keep the usable capacity of the battery high.

Description

Dual power supply for energy storage system and method for controlling the same}

The present invention relates to a dual power supply for an energy storage system and a control method thereof.

The Energy Storage System (ESS) is a system that can stably supply power according to a demand pattern by storing generated power.It stores excess power produced by a power plant and supplies it when power is temporarily insufficient. Say.

The energy storage system includes a battery system including a plurality of battery racks and a battery management system (BMS), a power conversion system (PCS), and an energy management system (EMS). .

The plurality of battery racks are for charging and storing energy and discharging and outputting energy when necessary, and the battery management system is for managing the plurality of battery racks, and the power conversion system connects to the grid, which is a power grid, to convert direct current It is for converting to or converting AC into DC and charging and discharging the battery, and the energy management system is for controlling the battery management system and the power conversion system in consideration of loads and battery conditions.

Each of the plurality of battery racks included in the battery system includes a plurality of battery trays and a rack battery management system for managing the plurality of battery trays, wherein each battery tray includes a tray battery including a plurality of battery cells, and the It includes a tray battery management system for managing the tray battery.

Typically, the battery management systems and electric devices for the operation of the energy storage system, such as a fan for temperature control inside the energy storage system, are a switching mode power supply (SMPS) that converts external AC power, which is a constant power, into DC power. It operates by receiving power through.

However, when the supply of power is interrupted or the switching mode power supply is in an inoperative state, the supply of power required for the operation of the battery management systems and electric devices of the energy storage system is interrupted, making it impossible to control the energy storage system. Do.

Therefore, in order to solve this problem in the related art, a separate uninterruptible power supply is installed inside the energy storage system in preparation for the interruption of the supply of power at all times, or a separate auxiliary power supply inside the energy storage system in preparation for the inability of the switching mode power supply Is installing. However, when a separate uninterruptible power supply is installed or a separate auxiliary power is installed inside the energy storage system, there is a problem that the installation cost and space are increased.

The patent documents described in the following prior art documents relate to a power storage system and a control method capable of stably operating the battery management unit even when the supply of external power is interrupted, and when external power is applied, external power is supplied to the battery. It is supplied as the operating power of the management unit 50, and when external power is not applied, the power from the battery 40 is started to be supplied as the operating power of the battery management unit 50. However, the following patent document discloses that external power is used as the main operating power source of the battery management unit 50 and the power from the battery 40 is used as an emergency power source, but the battery 40 is used as an emergency power source. When the converter 62 to be converted is not constantly monitored and the converter 62 is in an inoperable state in an emergency, no power is supplied to the battery management unit 50 and thus the control of the energy storage system is impossible.

Therefore, it is possible to monitor the external power and the state of the converter at all times, so that the supply of external power can be stopped and the immediate monitoring of the converter's inoperative state is possible, and electrical devices such as battery management systems inside the energy storage system without fear of inoperative in an emergency There is a need for a dual power supply device and a control method thereof for an energy storage system capable of stably supplying power to fields.

KR 10-1193168 B1

The problem to be solved by the present invention is that it is possible to monitor the external power and the state of the converter at all times, so that the supply of external power and the immediate monitoring of the inoperative state of the converter are possible, and the battery inside the energy storage system is It is to provide a dual power supply for an energy storage system capable of stably supplying power to electrical devices such as management systems.

Another problem to be solved by the present invention is that it is possible to monitor the external power and the state of the converter at all times, so that the supply of external power can be stopped and the immediate monitoring of the inoperative state of the converter is possible. It is to provide a control method of a dual power supply for an energy storage system capable of stably supplying power to electric devices such as battery management systems.

A dual power supply device for an energy storage system according to an embodiment of the present invention for solving the above problem,

A battery management system for managing the battery;

A DC-DC converter stepping down the output voltage of the battery; And

AC-DC converter for converting external AC power into DC power and when power is supplied from the DC-DC converter, for operation of an energy storage system from the battery and from the AC-DC converter through the DC-DC converter Operation of the energy storage system from the battery through the DC-DC converter when power is supplied and provided to the battery management system and an electric device inside the energy storage system, and power is not supplied from the AC-DC converter Power is supplied to the battery management system and the electric device inside the energy storage system, and when power is not supplied from the DC-DC converter, for operation of the energy storage system from the AC-DC converter And a load share unit that receives power and provides it to the battery management system and an electric device inside the energy storage system.

In the dual power supply device for an energy storage system according to an embodiment of the present invention, the battery includes at least one battery rack, and the battery management system includes a master battery management system for managing the at least one battery rack. Can include.

In addition, in the dual power supply device for an energy storage system according to an embodiment of the present invention, the DC-DC converter may receive power from a battery rack having a highest charge state among the at least one battery rack.

In addition, in the dual power supply device for an energy storage system according to an embodiment of the present invention, the DC-DC converter may receive power from a preset battery rack among the at least one battery rack.

In addition, in the dual power supply device for an energy storage system according to an embodiment of the present invention, the battery includes at least one battery tray, and the battery management system is a rack battery for managing the at least one battery tray. It may include a management system.

In addition, in the dual power supply device for an energy storage system according to an embodiment of the present invention, the DC-DC converter may receive power from a battery tray having a highest charge state among the at least one battery tray.

In addition, in the dual power supply device for an energy storage system according to an embodiment of the present invention, the DC-DC converter may receive power from a preset battery tray among the at least one battery tray.

In addition, in the dual power supply device for an energy storage system according to an embodiment of the present invention, the DC-DC converter can step down the output voltage of the battery to a voltage having the same magnitude as the output voltage of the AC-DC converter. have.

In addition, in the dual power supply device for an energy storage system according to an embodiment of the present invention, the DC-DC converter may step down the output voltage of the battery to a voltage equal to the operating voltage of the battery management system. .

In addition, in the dual power supply device for an energy storage system according to an embodiment of the present invention, the load share unit, when power is supplied from the AC-DC converter and the DC-DC converter, the DC-DC converter Through the battery and from the AC-DC converter, each half of the power for the operation of the energy storage system may be supplied to the battery management system and the electric device inside the energy storage system.

A method of controlling a dual power supply device for an energy storage system according to an embodiment of the present invention,

(A) determining whether power supply from an AC-DC converter or DC-DC converter for converting external AC power into DC power is stopped;

(B) when it is determined that power is supplied from the AC-DC converter and the DC-DC converter in step (A), the energy storage system from the battery and from the AC-DC converter through the DC-DC converter Receiving power required for the operation of the battery and providing it to the battery management system and an electric device inside the energy storage system;

(C) When it is determined that power supply from the AC-DC converter is stopped in step (A), power required for the operation of the energy storage system is supplied from the battery of the energy storage system through the DC-DC converter. Providing the battery management system and an electric device inside the energy storage system; And

(D) When it is determined that power supply from the DC-DC converter is stopped in step (A), power required for the operation of the energy storage system is supplied from the AC-DC converter, and the battery management system and the energy And providing it to an electrical device inside the storage system.

In the control method of a dual power supply device for an energy storage system according to an embodiment of the present invention, the battery includes at least one battery rack, and the battery management system is a master battery that manages the at least one battery rack. It may include a management system.

In addition, in the control method of a dual power supply device for an energy storage system according to an embodiment of the present invention, the step (C) is determined that the power supply from the AC-DC converter is stopped in the step (A). In this case, power required for the operation of the energy storage system is supplied from the battery rack having the highest charge state among the at least one battery rack through the DC-DC converter, and the battery management system and the electric device inside the energy storage system It may include the step of providing to.

In addition, in the control method of a dual power supply device for an energy storage system according to an embodiment of the present invention, the step (C) is determined that the power supply from the AC-DC converter is stopped in the step (A). In this case, power required for the operation of the energy storage system is supplied from a preset battery rack among the at least one battery rack through the DC-DC converter and provided to the battery management system and an electric device inside the energy storage system. It may include steps.

In addition, in the control method of a dual power supply device for an energy storage system according to an embodiment of the present invention, the battery includes at least one battery tray, and the battery management system manages the at least one battery tray. It may include a rack battery management system for.

In addition, in the control method of a dual power supply device for an energy storage system according to an embodiment of the present invention, the step (C) is determined that the power supply from the AC-DC converter is stopped in the step (A). In this case, power required for the operation of the energy storage system is supplied from the battery tray having the highest charge state among the at least one battery tray through the DC-DC converter, and the battery management system and the electric device inside the energy storage system It may include the step of providing to.

In addition, in the control method of a dual power supply device for an energy storage system according to an embodiment of the present invention, the step (C) is determined that the power supply from the AC-DC converter is stopped in the step (A). In this case, power required for the operation of the energy storage system is supplied from a preset battery tray among the at least one battery tray through the DC-DC converter and provided to the battery management system and an electric device inside the energy storage system. It may include steps.

In addition, in the control method of a dual power supply for an energy storage system according to an embodiment of the present invention, the DC-DC converter converts the output voltage of the battery to a voltage having the same magnitude as the output voltage of the AC-DC converter. You can coerce.

In addition, in the control method of a dual power supply for an energy storage system according to an embodiment of the present invention, the DC-DC converter steps down the output voltage of the battery to a voltage having the same magnitude as the operating voltage of the battery management system. can do.

In addition, in the control method of a dual power supply device for an energy storage system according to an embodiment of the present invention, the step (B),

When it is determined in step (A) that power is supplied from the AC-DC converter and the DC-DC converter, each of the energy storage system from the battery and from the AC-DC converter through the DC-DC converter 50% of the power required for operation may be supplied and provided to the battery management system and an electric device inside the energy storage system.

Features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to this, terms or words used in the present specification and claims should not be interpreted in a conventional and dictionary meaning, and the inventors should appropriately define the concept of terms in order to explain their own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that it can be.

According to an embodiment of the present invention, it is possible to monitor the external power and the state of the converter at all times, so that the supply of external power can be stopped and the immediate monitoring of the converter's inoperative state is possible. Electric devices such as systems can be reliably supplied with power. In addition, compared to the method of using an external power source as the main power source and an internal battery as an emergency power source, the switching mode power supply that converts external AC power into DC power can guarantee a longer life, and the internal battery is used as the main power source. Compared to the method, the usable capacity of the battery can be maintained higher, and the long life of the DC-DC converter that steps down the voltage of the battery can be guaranteed.

1 is a block diagram of a dual power supply device for an energy storage system according to an embodiment of the present invention.
2 is a block diagram of a dual power supply device for an energy storage system according to another embodiment of the present invention.
3 is a flowchart of a method for controlling a dual power supply device for an energy storage system according to an embodiment of the present invention.

Objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments associated with the accompanying drawings.

In adding reference numerals to elements of each drawing in the present specification, it should be noted that, even though they are indicated on different drawings, only the same elements are to have the same number as possible.

In addition, terms such as "first", "second", "one end", and "the other end" are used to distinguish one component from another component, and the component is limited by the terms no.

Hereinafter, in describing the present invention, detailed descriptions of related known technologies that may unnecessarily obscure the subject matter of the present invention will be omitted.

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

1 is a block diagram of a dual power supply device for an energy storage system according to an embodiment of the present invention.

Hereinafter, with reference to FIG. 1, a description will be given of a dual power supply device for an energy storage system according to an embodiment of the present invention.

The dual power supply device for an energy storage system according to an embodiment of the present invention shown in FIG. 1 includes a battery management system 108 for managing the battery 110, and a DC voltage reducing the output voltage of the battery 110. -When power is supplied from the DC converter 104 and the switching mode power supply 100, which is an AC-DC converter that converts external AC power into DC power, and the DC-DC converter 104, the DC-DC 50% of the power for the operation of the energy storage system is supplied from the battery 110 and the switching mode power supply 100 through the converter 104, respectively, and the battery management system 108 and a plurality of battery racks ( BR1 to BRn) provided to rack battery management systems (not shown) and other electric devices 106, and when power is not supplied from the switching mode power supply 100, the DC-DC converter 104 ) To receive all of the power for the operation of the energy storage system from the battery 110 through the battery management system 108, the rack battery management systems included in the plurality of battery racks BR1 to BRn, and other electricity Provided to the device 106, and when power is not supplied from the DC-DC converter 104, the battery management by receiving all of the power for the operation of the energy storage system from the switching mode power supply 100 The system 108 includes a load share module 102 provided to the rack battery management systems and other electric devices 106 included in the plurality of battery racks BR1 to BRn.

The battery 110 includes a plurality of battery racks BR1 to BRn, and the battery management system 108 is a master battery management system for managing the plurality of battery racks BR1 to BRn. In the above, n is an integer of 2 or more.

The DC-DC converter 104 step-down the output voltage of the battery 110 to a voltage having the same magnitude as the output voltage of the switching mode power supply 100, or the master battery management system 108 and the plurality of batteries It is a step-down converter that steps down to a voltage equal to the operating voltage of the rack battery management systems included in the racks BR1 to BRn.

The other electrical devices 106 include electrical devices for the operation of the energy storage system, such as a fan for controlling the temperature inside the energy storage system.

The operation of the dual power supply device for the energy storage system according to an embodiment of the present invention configured as described above will be described below.

First, a case where external AC power is normally supplied, DC power is supplied from the switching mode power supply 100, and power is supplied from the battery 110 through the DC-DC converter 104 will be described.

When the load share unit 102 is supplied with DC power from the switching mode power supply 100 and the power is supplied from the battery 110 through the DC-DC converter 104, the battery management system 108, the Each of 50% of the power required for the operation of the rack battery management systems (not shown) and other electric devices 106 included in the plurality of battery racks BR1 to BRn is transferred to the battery through the DC-DC converter 104, respectively. Received from 110 and from the switching mode power supply 100, the battery management system 108, rack battery management systems (not shown) included in the plurality of battery racks (BR1 to BRn), and other electricity It is provided to the device 106.

On the other hand, when the supply of external AC power is interrupted or power is not supplied from the switching mode power supply 100 due to the inability of the switching mode power supply 100 to operate, the load share unit 102 may provide the battery management system ( 108), 100% of the power required for the operation of the rack battery management systems and other electric devices 106 included in the plurality of battery racks BR1 to BRn is transferred to the battery 110 through the DC-DC converter 104 It is supplied from the battery management system 108, and provides to the rack battery management systems included in the plurality of battery racks (BR1 to BRn), and other electric devices 106.

In addition, when the power is not supplied from the DC-DC converter 104 due to the inoperability of the DC-DC converter 104, the load share unit 102, the battery management system 108, the plurality of battery racks 100% of the power required for the operation of the rack battery management systems and other electric devices 106 included in (BR1 to BRn) is supplied from the switching mode power supply 100, and the battery management system 108, the plurality of It provides to the rack battery management systems and other electric devices 106 included in the battery racks (BR1 to BRn) of.

In an embodiment of the present invention, the DC-DC converter 104 is supplied with power from the battery 110 and stepped down, but the present invention is not limited thereto, and the charging state among the plurality of battery racks BR1 to BRn is The voltage may be stepped down by receiving power from the highest battery rack, or may be stepped down by receiving power from a preset battery rack among the plurality of battery racks BR1 to BRn.

According to an embodiment of the present invention, it is possible to monitor the external power, the switching mode power supply 100, and the DC-DC converter 104 at all times in the load share unit 102, so that the supply of external power is stopped and the switching mode. It is possible to immediately monitor the inoperative state of the power supply 100 and the DC-DC converter 104, and stably supply power to electric devices such as the battery management system inside the energy storage system without fear of inoperability in an emergency. have.

In addition, in an embodiment of the present invention, when external power is normally supplied, the switching mode power supply 100 and the battery 110 are related to the electric device required for the operation of the energy storage system through the load share unit 102. Since half of the load is charged, in the case of the switching mode power supply 100 and the DC-DC converter 104, a long life is guaranteed as the load is reduced by half.

In addition, according to an embodiment of the present invention, compared to a method of using an external power source as a main power source and using an internal battery as an emergency power source, the switching mode power supply 100 that converts external AC power into DC power is reduced. It can be guaranteed, and the usable capacity of the battery 110 can be maintained higher than that of using the internal battery as a main power source, and a long lifespan of the DC-DC converter 104 for stepping down the voltage of the battery 110 can be guaranteed. have.

2 is a block diagram of a dual power supply device for an energy storage system according to another embodiment of the present invention.

Hereinafter, a dual power supply device for an energy storage system according to another embodiment of the present invention will be described with reference to FIG. 2.

The dual power supply device for an energy storage system according to an embodiment of the present invention shown in FIG. 2 includes a rack battery management system 208 for managing the rack battery 210, and an output voltage of the rack battery 210. When power is supplied from the DC-DC converter 204 to step-down, the switching mode power supply 200 for converting external AC power to DC power, and the DC-DC converter 204, the DC-DC converter ( 50% of the power for the operation of the energy storage system is supplied from the rack battery 210 and the switching mode power supply 200 through 204, and the rack battery management system 208 and a plurality of tray batteries are managed. Provided to the system (TBMS1 to TBMSn) and other electrical devices 206, and when power is not supplied from the switching mode power supply 200, energy from the rack battery 210 through the DC-DC converter 204 It receives all of the power for the operation of the storage system and provides it to the rack battery management system 208, a plurality of tray battery management systems (TBMS1 to TBMSn), and other electric devices 206, and the DC-DC converter 204 ), when power is not supplied from the switching mode power supply 200, the rack battery management system 208 and a plurality of tray battery management systems (TBMS1 to TBMS1) are supplied with all of the power for the operation of the energy storage system. TBMSn) and other electrical devices (206).

In FIG. 2, the rack battery 210 includes a plurality of battery trays BT1 to BTn, and the rack battery management system 208 is a battery management system for managing the plurality of battery trays BT1 to BTn. In addition, the plurality of battery trays BT1 to BTn is a battery management system for managing a plurality of battery cells (not shown) included in the plurality of tray batteries BT1 to BTn, respectively.

The DC-DC converter 204 step-down the output voltage of the rack battery 210 to a voltage having the same magnitude as the output voltage of the switching mode power supply 200, or the rack battery management system 208 and the plurality of It is a step-down converter that steps down to a voltage having the same size as the operating voltage of the tray battery management system (TBMS1 to TBMSn).

The other electric devices 206 include electric devices for the operation of the energy storage system, such as a fan for controlling the temperature inside the energy storage system.

The operation of the dual power supply device for the energy storage system according to another embodiment of the present invention configured as described above will be described below.

First, a case where external AC power is normally supplied, DC power is supplied from the switching mode power supply 200, and power is supplied from the rack battery 210 through the DC-DC converter 204 will be described.

When the load share unit 202 is supplied with DC power from the switching mode power supply 200 and is supplied with power from the rack battery 210 through the DC-DC converter 204, the rack battery management system 208 , 50% of the power required for the operation of the plurality of tray battery management systems (TBMS1 to TBMSn) and other electric devices 206, respectively, from the rack battery 210 through the DC-DC converter 204 and the switching mode It is supplied from the power supply 200, and is provided to the rack battery management system 208, a plurality of tray battery management systems TBMS1 to TBMSn, and other electric devices 206.

On the other hand, when the supply of external AC power is interrupted or power is not supplied from the switching mode power supply 200 due to the inability of the switching mode power supply 200 to operate, the load share unit 202 may provide the rack battery management system. (208), 100% of the power required for the operation of the plurality of tray battery management systems (TBMS1 to TBMSn) and other electric devices 206 is supplied from the rack battery 210 through the DC-DC converter 204, the A rack battery management system 208, a plurality of tray battery management systems (TBMS1 to TBMSn), and other electrical devices 206 are provided.

In addition, when power is not supplied from the DC-DC converter 204 due to the inoperability of the DC-DC converter 204, the load share unit 202 includes the rack battery management system 208 and a plurality of tray batteries. 100% of the power required for the operation of the management systems (TBMS1 to TBMSn) and other electric devices 206 is supplied from the switching mode power supply 200, and the rack battery management system 208, a plurality of tray battery management systems ( TBMS1 to TBMSn) and other electrical devices 206.

In another embodiment of the present invention, the DC-DC converter 204 receives power from the rack battery 210 and is depressurized, but the present invention is not limited thereto, and the charging state among the plurality of tray batteries TB1 to TBn is The pressure may be stepped down by receiving power from the highest tray battery, or may be stepped down by receiving power from a preset tray battery among the plurality of tray batteries TB1 to TBn.

According to another embodiment of the present invention, external power, switching mode power supply 200, and DC-DC converter 204 can be monitored at all times in the load share unit 202 to stop supply of external power, switching mode. It is possible to immediately monitor the inoperative state of the power supply 200 and the DC-DC converter 204, and stably supply power to electric devices such as the battery management system inside the energy storage system without fear of inoperability in an emergency. have.

Further, in another embodiment of the present invention, when external power is normally supplied, the switching mode power supply 200 and the rack battery 210 are provided with electrical devices required for the operation of the energy storage system through the load share unit 202. Since it bears half of the load associated with the switching mode power supply 200 and the DC-DC converter 204, a long life is guaranteed as the load is reduced by half.

In addition, according to another embodiment of the present invention, compared to a method of using an external power source as a main power source and an internal battery as an emergency power source, a longer life of the switching mode power supply 200 that converts external AC power into DC power. It can be guaranteed, and the usable capacity of the rack battery 210 can be maintained higher than that of using the internal battery as the main power source, and a long life of the DC-DC converter 204 that step-down the voltage of the rack battery 210 is guaranteed. can do.

3 is a flowchart of a method for controlling a dual power supply device for an energy storage system according to an embodiment of the present invention.

In the control method of a dual power supply device for an energy storage system according to an embodiment of the present invention shown in FIG. 3, it is determined whether the power supply from the switching mode power supply 100 or the DC-DC converter 104 is stopped. When it is determined that power is supplied from the switching mode power supply 100 and the DC-DC converter 104 in step S300, the battery 110 through the DC-DC converter 104 And operation of the battery management system 108, rack battery management systems (not shown) and other electric devices 106 included in the plurality of battery racks BR1 to BRn, respectively, from the switching mode power supply 100 50% of the power required for each is supplied to the battery management system 108, the rack battery management systems included in the plurality of battery racks BR1 to BRn, and other electric devices 106 (S302). , When it is determined that the power supply from the switching mode power supply 100 is stopped in step S300, the battery management system 108 of the energy storage system from the battery 110 through the DC-DC converter 104, a plurality of The battery management system receives 100% of the power required for the operation of the rack battery management systems (not shown) included in the battery racks BR1 to BRn and other electric devices 106 including a fan for temperature control, etc. (108), providing to rack battery management systems (not shown) and other electric devices 106 included in the plurality of battery racks BR1 to BRn (S304), the DC-DC converter in the step S300 When it is determined that power supply from 104 is interrupted, the battery management system 108 from the switching mode power supply 100, and rack battery management systems included in the plurality of battery racks BR1 to BRn ( Not shown) and other electric devices 106 And providing to the battery management system 108, rack battery management systems included in the plurality of battery racks BR1 to BRn, and other electric devices 106 (S306).

In step S300, the load share unit 102 determines whether the power supply through the switching mode power supply 100 or the DC-DC converter 104 is stopped.

When it is determined that power is supplied from the switching mode power supply 100 and the DC-DC converter 104 in step S300, the load share unit 102 in step S302 comprises the DC-DC converter 104 From the battery 110 and the switching mode power supply 100 through the battery management system 108, rack battery management systems (not shown) included in the plurality of battery racks BR1 to BRn, respectively, and others By receiving 50% of the power required for the operation of the electric device 106, the battery management system 108, the rack battery management systems included in the plurality of battery racks BR1 to BRn, and other electric devices 106 To provide.

When it is determined in step S300 that the power supply from the switching mode power supply 100 is stopped, in step S304, the load share unit 102, the energy storage system from the battery 110 through the DC-DC converter 104 Of the battery management system 108, the rack battery management systems (not shown) included in the plurality of battery racks BR1 to BRn, and 100% of the power required for the operation of the other electric devices 106 A battery management system 108, rack battery management systems included in the plurality of battery racks BR1 to BRn, and other electric devices 106 are provided.

When it is determined in step S300 that the power supply from the DC-DC converter 104 is stopped, in step S306, the load share unit 102 receives the battery management system 108 from the switching mode power supply 100. , The battery management system 108, the plurality of battery racks by receiving 100% of power required for the operation of the rack battery management systems and other electric devices 106 included in the plurality of battery racks BR1 to BRn It is provided to the rack battery management systems and other electric devices 106 included in (BR1 to BRn).

According to an embodiment of the present invention, it is possible to monitor the external power, the switching mode power supply 100, and the DC-DC converter 104 at all times in the load share unit 102, so that the supply of external power is stopped and the switching mode. Electrical devices such as battery management systems inside the energy storage system, fans for temperature control, etc., enabling immediate monitoring of the inoperative state of the power supply 100 and the DC-DC converter 104, and without fear of inoperability in an emergency Power can be supplied stably.

In addition, in an embodiment of the present invention, when external power is normally supplied, since the switching mode power supply 100 and the rack battery 110 bear half of the total load of the rack through the load share unit 102, In the case of the switching mode power supply 100 and the DC-DC converter 104, a long life is guaranteed as the load is reduced by half.

In addition, according to an embodiment of the present invention, compared to a method of using an external power source as a main power source and using an internal battery as an emergency power source, the switching mode power supply 100 that converts external AC power into DC power is reduced. It can be guaranteed, and the usable capacity of the battery 110 can be maintained higher than that of using the internal battery as a main power source, and a long lifespan of the DC-DC converter 104 for stepping down the voltage of the battery 110 can be guaranteed. have.

Although the present invention has been described in detail through specific examples, this is for describing the present invention in detail, and the present invention is not limited thereto, and those of ordinary skill in the art within the technical scope of the present invention It would be clear that the transformation or improvement is possible.

All simple modifications to changes of the present invention belong to the scope of the present invention, and the specific scope of protection of the present invention will become apparent by the appended claims.

100, 200: switching mode power supply
102, 202: Road share section
104, 204: DC-DC converter
106, 206: other electric devices
108: Master Battery Management System
110: battery
208: Rack battery management system
210: rack battery
BR1 to BRn: the first battery rack to the nth battery rack
TBMS1 to TBMSn: first tray BMS to nth tray BMS
TB1 to TBn: first tray battery to nth tray battery
BT1 to BTn: first battery tray to nth battery tray

Claims (20)

AC-DC converter for converting external AC power into DC power;
A battery management system for managing the battery;
A DC-DC converter stepping down the output voltage of the battery; And
It includes a load share unit connected to the AC-DC converter and DC-DC converter,
The load share unit;
When DC power is supplied from the AC-DC converter and power is supplied from the battery through the DC-DC converter, the battery management system, a rack battery management system included in a plurality of battery racks, and an energy storage system 50% of the power required for the operation of the electric device is supplied from the battery and the AC-DC converter through the DC-DC converter, respectively, and the battery management system, the rack battery management system included in the plurality of battery racks, and Provided to an electric device inside the energy storage system,
When the supply of external AC power is interrupted or power is not supplied from the AC-DC converter due to an inoperable AC-DC converter, the battery management system and rack battery management systems included in the plurality of battery racks And a rack battery management system included in the battery management system and the plurality of battery racks by receiving 100% of the power required for the operation of the electric device inside the energy storage system from the battery through the DC-DC converter. Provides to electrical devices inside the energy storage system,
When power is not supplied from the DC-DC converter due to the inoperability of the DC-DC converter, the battery management system, the rack battery management system included in the plurality of battery racks, and the electric device inside the energy storage system An energy storage system that receives 100% of power required for operation from the AC-DC converter and provides it to the battery management system, a rack battery management system included in the plurality of battery racks, and an electric device inside the energy storage system. Dual power supply for the device. The method according to claim 1,
The battery includes at least one battery rack, and the battery management system includes a master battery management system for managing the at least one battery rack. The method according to claim 2,
The DC-DC converter is a dual power supply device for an energy storage system receiving power from a battery rack having a highest charge state among the at least one battery rack. The method according to claim 2,
The DC-DC converter is a dual power supply device for an energy storage system receiving power from a preset battery rack among the at least one battery rack. The method according to claim 1,
The battery includes at least one battery tray, and the battery management system includes a rack battery management system for managing the at least one battery tray. The method of claim 5,
The DC-DC converter is a dual power supply device for an energy storage system receiving power from a battery tray having a highest charge state among the at least one battery tray. The method of claim 5,
The DC-DC converter is a dual power supply device for an energy storage system receiving power from a preset battery tray among the at least one battery tray. The method according to claim 1,
The DC-DC converter steps down the output voltage of the battery to a voltage having the same magnitude as the output voltage of the AC-DC converter. The method according to claim 1,
The DC-DC converter steps down the output voltage of the battery to a voltage equal to the operating voltage of the battery management system. delete (A) determining whether power supply from the battery is stopped through an AC-DC converter or DC-DC converter that converts external AC power into DC power;
(B) When it is determined that power is supplied from the battery through the AC-DC converter and the DC-DC converter in step (A), the load share unit -A battery management system, a rack battery management system included in a plurality of battery racks, and 50% of power required for the operation of an electric device inside an energy storage system are supplied from the DC converter, respectively, and the battery management system, the plurality of battery racks Providing the rack battery management system included in and an electric device inside the energy storage system;
(C) When it is determined that the power supply from the AC-DC converter is stopped in step (A), the load share unit is from the battery to the battery management system and the plurality of battery racks through the DC-DC converter. Receiving 100% of the power required for the operation of the included rack battery management system and the electric device inside the energy storage system, the battery management system, the rack battery management system included in the plurality of battery racks, and the energy storage system interior Providing to the electrical device of the; And
(D) When it is determined in step (A) that power supply from the battery is stopped through the DC-DC converter, the load share unit is transferred from the AC-DC converter to the battery management system and the plurality of battery racks. Receiving 100% of the power required for the operation of the included rack battery management system and the electric device inside the energy storage system, the battery management system, the rack battery management system included in the plurality of battery racks, and the energy storage system interior A method of controlling a dual power supply for an energy storage system comprising the step of providing an electric device of the The method of claim 11,
The battery includes at least one battery rack, and the battery management system includes a master battery management system for managing the at least one battery rack. The method of claim 12,
In the step (C), when it is determined that power supply from the AC-DC converter is stopped in the step (A), the battery rack having the highest charge state among the at least one battery rack through the DC-DC converter And supplying power required for the operation of the energy storage system to the battery management system and an electric device inside the energy storage system. The method of claim 12,
In the step (C), when it is determined that the power supply from the AC-DC converter is stopped in the step (A), the energy from the preset battery rack among the at least one battery rack through the DC-DC converter A method of controlling a dual power supply device for an energy storage system, comprising the step of receiving power required for operation of a storage system and providing it to the battery management system and an electric device inside the energy storage system. The method of claim 11,
The battery includes at least one battery tray, and the battery management system includes a rack battery management system for managing the at least one battery tray. The method of claim 15,
In the step (C), when it is determined that the power supply from the AC-DC converter is stopped in the step (A), the battery tray having the highest charge state among the at least one battery tray through the DC-DC converter And supplying power required for the operation of the energy storage system from the battery management system and the electric device inside the energy storage system. The method of claim 15,
In the step (C), when it is determined that the power supply from the AC-DC converter is stopped in the step (A), the energy from the preset battery tray among the at least one battery tray through the DC-DC converter A method of controlling a dual power supply device for an energy storage system, comprising the step of receiving power required for operation of a storage system and providing it to the battery management system and an electric device inside the energy storage system. The method of claim 11,
The DC-DC converter steps down the output voltage of the battery to a voltage equal to the output voltage of the AC-DC converter. The method of claim 11,
The DC-DC converter steps down the output voltage of the battery to a voltage equal to the operating voltage of the battery management system. delete

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