KR20160007739A - Tray balancing apparatus, tray balancing method, and rack balancing apparatus using fan - Google Patents

Abstract

A tray balancing apparatus using a fan according to an embodiment of the present invention comprises: the fan for adjusting a temperature in a battery tray; a selection unit that provides an output voltage of an exterior power source outside a tray or a voltage of the tray battery to the fan; and a tray battery management system that senses a voltage of the tray battery, provides the sensed voltage of the tray battery to a rack battery management system outside the tray, controls an operation of the selection unit and provides a voltage of the tray battery to the fan if a tray balancing signal is received from the rack battery management system, wherein the rack battery management system determines whether a voltage variation between voltages of the tray battery is over or equal to a reference value based on the voltages of the tray battery received from the battery trays, provides the tray balancing signal to the tray battery management system of the battery tray comprising a tray battery subject to a discharge target and having a voltage higher than a reference voltage if the voltage variation between voltages of the tray battery is over or equal to the reference value and thus has no burden on the generation of heat despite of consuming a large amount of energy, relatively easily implements a technology, improves efficiency of balancing with a minimum cost and also, reduces a time spent in balancing greatly.

Description

Technical Field [0001] The present invention relates to a tray balancing apparatus, a tray balancing apparatus, and a rack balancing apparatus using a fan,

The present invention relates to a tray balancing apparatus using a fan, a tray balancing method, and a rack balancing apparatus.

Energy Storage System (ESS) is a system that can store generated power and supply power in a stable manner according to demand pattern. It is a system that stores excess power generated by a power plant and temporarily supplies power when the power is insufficient. It says.

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 battery management system is for managing the plurality of battery racks. The power conversion system is connected to a grid, which is a power grid, And converts the alternating current into direct current and controls charge and discharge of the battery. The energy management system is for controlling the battery management system and the power conversion system in consideration of the load, the battery condition, and the like.

Each of the plurality of battery racks included in the battery system includes a plurality of battery trays, and each battery tray includes a plurality of battery cells.

In general, each of the plurality of battery cells included in the battery tray may be dangerous when charged significantly higher than the rated charging range, and the battery life may be shortened when discharging is lower than the rated charging range. The state of charge of the battery cells is in an unbalanced state due to various factors. An imbalance occurs in the state of charge of the battery cell during the manufacture or repetitively charging / discharging the battery. In the case of a lithium-ion cell, the fabrication of the cell in the factory is strictly controlled to minimize the difference in state of charge between the battery cells. However, the state of charge of the battery cell, which is almost the same within the error range in the factory, varies depending on various factors, resulting in imbalance in the state of charge among the battery cells.

In addition, a voltage deviation may occur in the same battery tray in accordance with the parallel-serial structure between the battery cells. When a voltage deviation occurs, an inter-cell voltage imbalance occurs and the available state of charge (SOC) is reduced.

In addition, a voltage deviation may occur in the same battery rack in accordance with the serial-to-parallel structure of the tray batteries. When a voltage deviation occurs, a voltage unbalance occurs between the tray batteries and the available state of charge (SOC) is reduced.

In addition, a voltage deviation may occur according to the serial-parallel structure between the rack batteries in the battery system, and when a voltage deviation occurs, a voltage unbalance occurs between the rack batteries and the available state of charge (SOC) is reduced.

Factors affecting the unbalanced charge state of the battery cell, the tray battery, and the rack battery include, for example, the chemical reaction of each battery cell, the tray battery, and the rack battery, the impedance of the cell, And a variation in operating temperature.

Inconsistencies in the temperature of the battery cell, the tray battery, and the rack battery are important factors in the imbalance of charge state. For example, battery cells, tray batteries, and rack batteries have a "self discharge" which is a function of battery temperature, and a high temperature battery typically exhibits a higher self discharge rate than a low temperature battery. As a result, a battery with a higher temperature exhibits a lower charge over time than a battery with a lower temperature.

In addition, the battery cell, the tray battery, and the rack battery are subject to voltage imbalance between the battery cells, between the tray batteries and the rack battery when repeated charging and discharging, and voltage imbalance between the battery cells, between the tray batteries, The life of the battery is shortened and the energy efficiency of the battery is deteriorated due to the inefficient use of the battery. Accordingly, the battery management system (BMS) included in the battery system performs a balancing function for balancing the voltage based on the sensed voltages of the batteries, thereby extending the life of the battery, I will.

Conventional battery balancing includes passive balancing and active balancing. The passive balancing method lowers the voltage of a high-voltage battery by using a balancing resistor. Since the energy of a high-voltage battery is consumed as heat through a balancing resistor, energy efficiency is low and a large amount of energy It is difficult to consume. However, there is an advantage that the technology is relatively easy to implement.

On the other hand, the active balancing method is a method of moving the energy of a high voltage battery to a low voltage battery, which is energy efficient and can transfer a large amount of energy compared with a passive balancing method. However, there is a disadvantage that the technology implementation is relatively difficult.

The patent documents described in the following prior art documents disclose a battery balancing system and a battery balancing method for reusing energy by supplying electricity consumed in the balancing process of the battery to energy corresponding to the charging voltage of the connected external electronic device. However, since the energy consumed in the cell balancing process is separately stored for each power capacity, the following patent document requires a separate energy storage unit, has a complicated configuration, and can not consume a large amount of energy in a short time.

Therefore, a battery balancing device which can consume a large amount of energy, does not have a burden of heat generation, is relatively easy to implement, can improve the balancing efficiency at a minimum cost, and can greatly shorten the time required for balancing And methods are required.

KR 10-2013-0101235 A

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems of the prior art in that a large amount of energy is consumed and no burden is imposed on heat generation and the technology is relatively easy to implement and the balancing efficiency can be improved with a minimum cost, The present invention provides a tray balancing apparatus using a fan capable of making a tray.

Another problem to be solved by the present invention is to solve the problems of the present invention, which is to solve the problems of the prior art, And to provide a tray balancing method using a fan that can shorten the time required for balancing.

Another problem to be solved by the present invention is to provide a method and an apparatus for measuring the amount of energy consumed, without burdening heat generation, relatively easy to implement the technology, capable of improving the balancing efficiency at a minimum cost, And to provide a rack balancing apparatus using a fan that can be shortened.

According to an aspect of the present invention, there is provided a tray balancing apparatus using a fan,

A fan for temperature control within the battery tray;

A selector for supplying an output voltage of an external power source outside the tray or a voltage of the tray battery to the fan; And

A controller for sensing a voltage of the tray battery and providing a voltage of the sensed tray battery to a rack battery management system external to the tray, and when a tray balancing signal is received from the rack battery management system, And a tray battery management system for supplying a voltage of the tray battery to the fan,

Wherein the rack battery management system determines whether a voltage deviation between the tray battery voltages is equal to or greater than a reference value based on tray battery voltages received from the plurality of battery trays and if the voltage deviation between the tray battery voltages is equal to or greater than a reference value And provides the tray balancing signal to a tray battery management system of a battery tray including a tray battery to be discharged having a voltage higher than a reference voltage.

In the tray balancing apparatus using a fan according to an embodiment of the present invention, when the voltage of the tray battery to be discharged is balanced up to the target tray voltage, the balancing stop signal is transmitted to the tray To a tray battery management system of a battery tray including a battery.

Further, in the tray balancing apparatus using a fan according to an embodiment of the present invention, the tray battery management system may further include: when the tray balancing signal is not received from the rack battery management system, When the balancing stop signal is received, the output voltage of the external power supply can be supplied to the fan by controlling the operation of the selection unit.

In addition, the tray balancing apparatus using a fan according to an embodiment of the present invention may further include a DC-DC converter for converting the voltage of the tray battery into a driving voltage of the fan and providing the voltage to the selecting unit.

In the tray balancing apparatus using a fan according to an embodiment of the present invention, the reference voltage = the average voltage of the plurality of tray batteries + the reference value.

According to an embodiment of the present invention, there is provided a tray balancing apparatus using a fan,

A tray balancing device for each of the plurality of battery trays, for a battery rack including an ac-to-dc conversion section for converting AC to DC, a plurality of battery trays, and a rack battery management system for managing the plurality of battery trays, In this case,

Wherein each of the plurality of battery trays includes a tray battery and a fan for controlling the temperature in the battery tray,

The tray balancing device includes:

A selector for supplying an output voltage of the AC-DC converter or a voltage of the tray battery to the fan; And

A controller for sensing a voltage of the tray battery and providing a voltage of the sensed tray battery to the rack battery management system external to the tray, and when a tray balancing signal is received from the rack battery management system, And a tray battery management system for supplying a voltage of the tray battery to the fan,

Wherein the rack battery management system determines whether a voltage deviation between the tray battery voltages is equal to or greater than a reference value based on tray battery voltages received from the plurality of battery trays and if the voltage deviation between the tray battery voltages is equal to or greater than a reference value And provides the tray balancing signal to a tray battery management system of a battery tray including a tray battery to be discharged having a voltage higher than a reference voltage.

In the tray balancing apparatus using a fan according to an embodiment of the present invention, when the voltage of the tray battery to be discharged is balanced up to the target tray voltage, To the tray battery management system of the battery tray including the tray battery of the tray.

Further, in the tray balancing apparatus using a fan according to an embodiment of the present invention, the tray battery management system may further include: when the tray balancing signal is not received from the rack battery management system, When the balancing stop signal is received, the output voltage of the AC-DC converting unit can be supplied to the fan by controlling the operation of the selecting unit.

In addition, the tray balancing apparatus using a fan according to an embodiment of the present invention may further include a DC-DC converter for converting the voltage of the tray battery into a driving voltage of the fan and providing the voltage to the selecting unit.

In the tray balancing apparatus using a fan according to an embodiment of the present invention, the reference voltage = the average voltage of the plurality of tray batteries + the reference value.

According to another aspect of the present invention, there is provided a method of balancing a tray using a fan,

(A) determining whether a voltage deviation between the plurality of trays is equal to or greater than a reference value; And

(B) performing a tray balancing by supplying a voltage of a tray battery to be discharged having a voltage higher than a reference voltage to the fan when the voltage deviation between the plurality of trays is equal to or greater than a reference value in the step (A).

A method of balancing a tray using a fan according to an embodiment of the present invention includes: (C) when a plurality of tray battery voltage deviations are less than a reference value or the tray balancing of the step (B) is completed in the step (A) And supplying an output voltage of an external power source outside the tray to the fans in the plurality of battery trays.

In the tray balancing method using a fan according to an embodiment of the present invention, the step (B)

(B1) lowering the voltage of the tray battery to be discharged to the driving voltage of the fan; And

(B2) performing the tray balancing by supplying the voltage of the coercive force-converted tray battery to the fan until the voltage of the tray battery to be discharged becomes the target tray voltage.

In the tray balancing method using a fan according to an embodiment of the present invention, the reference voltage = the average voltage of the plurality of tray batteries + the reference value.

According to another aspect of the present invention, there is provided a rack balancing apparatus using a fan,

A rack balancing apparatus included in each of the plurality of battery racks for a battery system including a plurality of battery racks and a master battery management system for managing the plurality of battery racks,

Wherein each of the plurality of battery racks includes an AC-DC conversion unit for converting AC into DC, a rack battery, and a fan for temperature control in the battery rack,

The rack balancing apparatus includes:

A selector for supplying an output voltage of the AC-DC converter or a voltage of the rack battery to the fan; And

The method comprising: sensing a voltage of the rack battery; providing a voltage of the sensed rack battery to the master battery management system outside the rack; and when a rack balancing signal is received from the master battery management system, And a rack battery management system for supplying a voltage of the rack battery to the fan,

Wherein the master battery management system determines whether a voltage deviation between the rack battery voltages is equal to or greater than a reference value based on rack battery voltages received from the plurality of battery racks and if the voltage deviation between the rack battery voltages is equal to or greater than a reference value And provides the rack balancing signal to a rack battery management system in a battery rack that includes a rack battery to be discharged having a voltage higher than a reference voltage.

In a rack balancing apparatus using a fan according to an embodiment of the present invention, when the voltage of the rack battery to be discharged is balanced up to the target rack voltage, the master battery management system sets the balancing stop signal to the rack And can be provided to a rack battery management system of a battery rack containing a battery.

Further, in the rack balancing apparatus using a fan according to an embodiment of the present invention, the rack battery management system may be configured such that when the rack balancing signal is not received from the master battery management system, When the balancing stop signal is received, the output voltage of the AC-DC converting unit can be supplied to the fan by controlling the operation of the selecting unit.

The rack balancing apparatus using a fan according to an embodiment of the present invention may further include a DC-DC converter for converting the voltage of the rack battery into a driving voltage of the fan and providing the voltage to the selecting unit.

In the rack balancing apparatus using a fan according to an embodiment of the present invention, the reference voltage = the average voltage of the plurality of rack batteries + the reference value.

The 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 and words used in the present specification and claims should not be construed in a conventional and dictionary sense, and the inventor may appropriately define the concept of a term in order to best describe its invention The present invention should be construed in accordance with the spirit and scope of the present invention.

According to the embodiment of the present invention, there is no burden on heat generation while consuming a large amount of energy, the technique is relatively easy to implement, the balancing efficiency can be improved at a minimum cost, and the time required for balancing is greatly shortened .

1 is a block diagram of a battery rack including a tray balancing apparatus using a fan according to an embodiment of the present invention;
2 is a flowchart of a method of balancing a tray using a fan according to an embodiment of the present invention.
3 is a block diagram of a battery system including a rack balancing device using a fan according to one embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The objectives, specific advantages and novel features of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

It should be noted that, in the present specification, the reference numerals are added to the constituent elements of the drawings, and the same constituent elements are assigned the same number as much as possible even if they are displayed on different drawings.

Also, the terms "first", "second", "once", "other end", and the like are used to distinguish one component from another, and the fact that the component is limited by the terms no.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, detailed description of related arts which may unnecessarily obscure the gist 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 battery rack including a tray balancing apparatus using a fan according to an embodiment of the present invention.

Hereinafter, a tray balancing apparatus using a fan according to an embodiment of the present invention will be described with reference to FIG.

1, a battery rack including a tray balancing apparatus using a fan according to an embodiment of the present invention includes a switching mode power supply 100, which is an AC-DC converting unit for converting AC into DC, a plurality of battery trays And a rack battery management system (BMS) 102 for managing the plurality of battery trays (Tray_1 to Tray_n). In the above, n is an integer of 2 or more.

The plurality of battery trays Tray_1 to Tray_n include tray batteries TB1 to TBn and fans CF1 to CFn for temperature control in the battery trays Tray_1 to Tray_n.

A tray balancing apparatus using a fan according to an embodiment of the present invention is included in each of the plurality of battery trays (Tray_1 to Tray_n).

The tray balancing apparatus using a fan according to an embodiment of the present invention includes DC-DC converters DCC1 to DCCn for down converting the voltages of the tray batteries TB1 to TBn into driving voltages of the fans CF1 to CFn, A selection unit SEL1 to SELn for supplying the output voltage of the switching mode power supply 100 or the voltages of the tray batteries TB1 to TBn transformed through the DC-DC converters DCC1 to DCCn to the fan, Sensing the voltage of the tray batteries TB1 to TBn and providing the voltage of the sensed tray batteries TB1 to TBn to the rack battery management system 102 outside the tray, Which feeds the voltages of the tray batteries TB1 to TBn to the fans CF1 to CFn by controlling the operation of the selection units SEL1 to SELn when a tray balancing signal is received from the tray 102, And a battery management system (TBMS1 to TBMSn), wherein the rack battery management system (102) is configured to control the battery management system (TBMS1 to TBMSn) based on voltages of the tray batteries (TB1 to TBn) received from the plurality of battery trays (Tray_1 to Tray_n) And determines whether a voltage deviation between the voltages of the batteries TB1 to TBn is equal to or greater than a reference value. If the voltage deviation between the voltages of the tray batteries TB1 to TBn is equal to or greater than the reference value, Balancing signals to the tray battery management systems TBMS1 to TBMSn of battery trays (Tray_1 to Tray_n) including the battery tray trains (TB1 to TBn).

The first battery tray Tray_1 includes a first fan CF1 for controlling the temperature in the first battery tray Tray_1 and a second fan FC1 for controlling the voltage of the first tray battery TB1 up to the driving voltage of the first fan CF1 A first DC-DC converter DCC1 that performs a step-down conversion, a voltage of the switching mode power supply 100 that is an external power source external to the first battery tray Tray_1, or a voltage of the first DC-DC converter DCC1 (SEL1) for supplying a voltage of the first tray battery (TB1) to the first fan (CF1) through a step-down transformer through which the voltage of the first tray battery (TB1) The first battery tray TB1 supplies the voltage of the first tray battery TB1 to the rack battery management system 102 outside the first battery tray Tray_1 and when the tray balancing signal is received from the rack battery management system 102, 1 selection unit SEL1 to control the operation of the first DC-DC converter DCC1, And a first tray battery management system (TBMS1) for supplying the first tray CF1 with the voltage of the first tray battery TB1, which is down-converted through the first tray battery TB1.

The first tray battery TB1 includes a plurality of battery cells (not shown).

The nth battery tray Tray_n supplies the voltage of the nth fan CFn and the nth tray battery TBn for controlling the temperature in the nth battery tray Tray_n to the driving voltage of the nth fan CFn The voltage of the switching mode power supply 100 or the voltage of the n-th DC-DC converter DCCn, which is an external power source external to the n-th battery tray Tray_n, An n-th selection unit SELn for supplying a voltage of the n-th tray battery TBn to the n-th fan CFn via the n-th tray battery TBn, (Tbn) to the rack battery management system (102) outside the nth battery tray (Tray_n), and when a tray balancing signal is received from the rack battery management system (102) n converter (DCCn) by controlling the operation of the nth selection unit (SELn) And an nth tray battery management system (TBMSn) for supplying the voltage of the nth tray battery TBn to the nth fan CFn.

The nth tray battery TBn includes a plurality of battery cells (not shown).

The rack battery management system 102 determines whether the voltage deviation between the voltages of the tray batteries TB1 to TBn is equal to or greater than a reference value based on the tray battery voltages received from the plurality of battery trays Tray_1 to Tray_n And provides the tray balancing signal to the tray battery management system of the battery tray to be discharged having a voltage higher than the reference voltage when the voltage deviation between the voltages of the tray batteries TB1 to TBn is equal to or greater than the reference value.

In the embodiment of the present invention, the reference voltage may be a voltage obtained by adding the voltage deviation reference value to the average voltage of the plurality of tray batteries TB1 to TBn, but the embodiment of the present invention is not limited thereto.

The first through n-th fans CF1 through CFn are fans installed in the first through n-th battery trays Tray_1 through Tray_n, respectively. The first through n-th fans CF1 through CFn are respectively connected to the first through nth battery trays Tray_1 through Tray_n It is a device for regulation.

The operation of the tray balancing apparatus using the fan according to an embodiment of the present invention will be described below.

Illustratively, in one embodiment of the present invention, it is assumed that the voltage of the first tray battery TB1 is higher than the reference voltage.

In one embodiment of the present invention, the rack battery management system 102 operates using the output voltage of the switched mode power supply 100 as a driving power source.

The rack battery management system 102 determines whether a voltage deviation between the tray battery voltages is equal to or greater than a reference value based on tray battery voltages received from a plurality of battery trays Tray_1 to Tray_n.

The rack battery management system 102 determines that the voltage of the first tray battery TB1 received from the first battery tray Tray_1 is higher than the reference voltage, It is judged that the voltage deviation between the voltages of the tray batteries TB2 to nth tray batteries TBn is equal to or higher than the reference value.

In the embodiment of the present invention, the reference voltage may be a voltage obtained by adding a reference value of the voltage deviation to an average voltage of the plurality of tray batteries TB1 to TBn, but the embodiment of the present invention is not limited thereto.

The rack battery management system 102 provides a tray balancing signal to a first tray battery management system (TBMS1) of a first battery tray (Tray_1) to be discharged having a voltage higher than a reference voltage via a communication line.

When the tray balancing signal is received from the rack battery management system 102, the first tray battery management system TBMS1 applies a first control signal CS1 to the first selector SEL1, The voltage of the first tray battery TB1 is supplied to the first fan CF1 through the first DC-DC converter DCC1 by controlling the operation of the first tray battery TB1 Perform tray balancing for

In an embodiment of the present invention, the first fan CF1 for temperature control in the first tray Tray_1 uses an operating voltage of 24 V, and the first tray battery TB1 generally has a voltage of about 60 V The first fan CF1 can be operated only by reducing the voltage of the first tray battery TB1 to the operating voltage of the first fan CF1.

Accordingly, in an embodiment of the present invention, the voltage of the first tray battery TB1 to be discharged, which has a voltage higher than the reference voltage, is supplied to the first fan CF1 using the first DC- Down to the operating voltage.

The first tray battery management system TBMS1 controls the operation of the first selection unit SEL1 until the balancing stop signal is received from the rack battery management system 102, The voltage of the first tray battery TB1 is supplied to the first fan CF1 and the first tray battery TB1 is turned on until the voltage of the first tray battery TB1 becomes the target tray voltage. Is consumed through the first fan CF1.

On the other hand, when the voltage of the first tray battery TB1 drops to the target tray voltage, the rack battery management system 102 continuously monitors the voltage of the first tray battery TB1, Determines that the balancing is completed, and provides a balancing stop signal to the first tray battery management system (TBMS1).

The target tray voltage may include an average voltage of the plurality of tray batteries TB1 to TBn, but the embodiment of the present invention is not limited thereto.

When the first tray battery management system TBMS1 receives the balancing stop signal from the rack battery management system 102, the first tray battery management system TBMS1 receives the first stop signal SEL1 The first control signal CS1 is applied to the first fan CF1 so that the voltage of the first tray battery TB1 is no longer supplied to the first fan CF1 to stop the tray balancing and the switching control of the switching mode power supply 100 The output voltage is supplied to the first fan CF1 so that the first fan CF1 normally performs the temperature control function.

Since the second to nth tray battery management systems TBMS2 to TBMNSn do not receive the tray balancing signal from the rack battery management system 102, the second to nth selection units SEL2 to SELn ) By supplying the voltage of the switching mode power supply 100 to the second to the n-th fans CF2 to CFn so that the second to the n-th fans CF2 to CFn are in the switching mode To operate with the voltage of the power supply 100.

In the embodiment of the present invention, when there is one fan in the battery tray, the tray balancing is performed by using one fan inside the battery tray. However, the present invention is not limited to this, The tray balancing may be performed using a plurality of fans in the battery tray.

Also, in the embodiment of the present invention, tray balancing is performed using a fan. However, the present invention is not limited to this, and the tray balancing may be performed by using a temperature control means such as a thermoelectric element instead of the fan.

The tray balancing apparatus using a fan according to an embodiment of the present invention can be used for tray balancing of a plurality of tray batteries included in a rack of an energy storage system. However, the present invention is not limited to this, It can also be used for tray balancing of tray batteries included in any type of device or system.

In the above-described embodiment, the rack battery management system 102 receives each tray battery voltage from the plurality of tray battery management systems TBMS1 to TBMSn and supplies a tray balancing control signal to each tray battery management system TBMS1 to TBMSn, To balance the tray battery of the discharge target with a high reference voltage.

However, the present invention is not limited to this, and each tray battery management system (TBMS1 to TBMSn) individually compares the voltage of each tray battery with a set reference voltage, and balances each tray battery TB1 to TBn Control.

In this case, for example, the first tray battery management system TBMS1 senses the voltage of the first tray battery TB1, and when the voltage of the first tray battery TB1 is higher than the set reference voltage, Controls the operation of the first selection unit SEL1 until the voltage of the first tray battery TB1 of the first tray battery TB1 becomes the target tray voltage and controls the operation of the first tray battery TB1 through the first DC- Can be supplied to the first fan CF1 inside the first battery tray Tray_1 to perform balancing of the first tray battery TB1.

When the voltage of the first tray battery TB1 is equal to or lower than the reference voltage or the voltage of the first tray battery TB1 of the discharge object is balanced to the target tray voltage, The voltage of the switching mode power supply 100, which is an external power supply, can be supplied to the first fan CF1 by controlling the operation of the first selection unit SEL1.

In one embodiment of the present invention, the tray balancing of one tray battery is performed. However, the present invention is not limited to this, and the tray balancing of a plurality of tray batteries may be performed at the same time.

2 is a flowchart of a tray balancing method using a fan according to an embodiment of the present invention.

The method of balancing a tray using a fan according to an embodiment of the present invention shown in FIG. 2 includes the steps of: determining whether a voltage deviation between a plurality of tray batteries TB1 to TBn in a rack battery management system 102 is equal to or greater than a reference value If it is determined in step S200 that the voltage deviation between the plurality of tray batteries TB1 to TBn is equal to or greater than the reference value, the voltage of the tray battery to be discharged having a voltage higher than the reference voltage is supplied to the corresponding fan, When the voltage deviation between the plurality of tray batteries TB1 to TBn is less than the reference value or the tray balancing in step S230 is completed in step S200, And supplying the voltage of the supply 100 to the corresponding fan (step S212).

The step S230 includes a step of issuing a balancing command to the tray battery to be discharged having a voltage higher than the reference voltage (step S202), a step of converting the voltage of the tray battery of the balancing object into the fan driving voltage (Step S206), the voltage of the tray battery to be balanced is supplied to the target tray voltage (step S206) (Step S208), and terminating the tray balancing (step S210).

In step S202, the rack battery management system 102 provides a tray balancing signal to the tray battery to be discharged to start tray balancing.

The step S204 is a step of converting the voltage of the tray battery to be discharged to the driving voltage of the fan by using the DC-DC converter of the battery tray including the tray battery to be discharged.

In step S206, the tray battery management system of the battery tray including the tray battery to be discharged applies the first control signal CS1 to the corresponding selection unit to control the operation of the selection unit, And supplying the voltage of the battery to the corresponding fan to perform balancing of the tray battery to be discharged.

In step S208, the rack battery management system 102 compares the voltage of the tray battery to be discharged with the target tray voltage to determine whether the voltage of the tray battery to be discharged is balanced to the target tray voltage.

If it is determined in step S208 that the voltage of the tray battery to be balanced is not balanced to the target tray voltage, the flow returns to step S206, where the voltage of the tray battery to be discharged is supplied to the corresponding fan so that tray balancing is continued.

If it is determined in step S208 that the voltage of the tray battery to be balanced is balanced to the target tray voltage, the rack battery management system 102 determines whether the tray battery is to be discharged Determines that the tray balancing is completed, and provides a balancing stop signal to the tray battery management system of the battery tray including the tray battery to be discharged.

When receiving a balancing stop signal from the rack battery management system 102, the tray battery management system of the battery tray including the tray battery to be discharged applies a control signal to the selection unit so that the voltage of the tray battery is no longer DC- It is not supplied to the converter, the balancing of the tray battery is stopped, and the balancing of the tray is terminated.

In step S212, when it is determined that the voltage deviation between the plurality of tray batteries TB1 to TBn is less than the reference value or the tray balancing is terminated in step S210, the voltage of the switching mode power supply 100 To the fans.

In the embodiment of the present invention, when there is one fan in the battery tray, the tray balancing is performed by using one fan inside the battery tray. However, the present invention is not limited to this, The tray balancing may be performed using a plurality of fans in the battery tray.

Also, in the embodiment of the present invention, tray balancing is performed using a fan. However, the present invention is not limited to this, and the tray balancing may be performed by using a temperature control means such as a thermoelectric element instead of the fan.

The tray balancing method using a fan according to an embodiment of the present invention can be used for tray balancing of a plurality of tray batteries included in a rack of an energy storage system. However, the present invention is not limited to this, It can also be used for tray balancing of tray batteries included in any type of device or system.

3 is a block diagram of a battery system including a rack balancing apparatus using a fan according to an embodiment of the present invention.

A rack balancing apparatus using a fan according to an embodiment of the present invention will now be described with reference to FIG.

3, a battery system including a fan-based rack balancing apparatus according to an embodiment of the present invention includes a plurality of battery racks Rack_1 to Rack_n and a plurality of battery racks Rack_1 to Rack_n for managing the plurality of battery racks Rack_1 to Rack_n And a master battery management system (BMS: Battery Management System) 300. In the above, n is an integer of 2 or more.

Each of the plurality of battery racks Rack_1 to Rack_n includes switching mode power supplies SMPS1 to SMPSn for converting AC to DC and fans CFR1 to CFRn for temperature control in battery racks Rack_1 to Rack_n .

The rack balancing apparatus using a fan according to an embodiment of the present invention is included in each of the plurality of battery racks Rack_1 to Rack_n.

DC converter DCCR1 to DCCRn for down-converting the voltages of the rack batteries RB1 to RBn to the driving voltages of the fans CFR1 to CFRn, respectively, according to an embodiment of the present invention. And supplies the voltages of the rack batteries RB1 to RBn that have undergone the down-conversion through the DC-DC converters DCCR1 to DCCRn to the fans CFR1 to CFRn, respectively, as the output voltages of the switching mode power supplies SMPS1 to SMPSn, And the voltages of the sensed battery packs RB1 to RBn are sensed by the master battery management system in the racks Rack_1 to Rack_n, And controls the operation of the selection units SELR1 to SELRn when the rack balancing signal is received from the master battery management system 300 so as to supply the voltages of the rack batteries RB1 to RBn to the fan CFR1 to CFR1 Wherein the master battery management system 300 includes a battery management system RBMS1 to RBMSn for supplying power to the battery cells RB1 to RBn received from the plurality of battery racks Rack_1 to Rack_n, Determines whether a voltage deviation between the voltages of the rack batteries RB1 to RBn is equal to or greater than a reference value based on the voltage values of the rack batteries RB1 to RBn and if the voltage deviation between the voltages of the rack batteries RB1 to RBn is equal to or greater than a reference value, Balancing signal to the rack battery management systems RBMS1 to RBMSn of the battery racks Rack_1 to Rack_n including the rack batteries RB1 to RBn to be discharged.

The first battery rack Rack_1 includes a first switching mode power supply SMPS1 as an AC-DC converting unit for converting AC into DC, a first fan CFR1 for controlling the temperature in the first battery rack Rack_1, A first DC-DC converter DCCR1 for converting the voltage of the first rack battery RB1 to a driving voltage of the first fan CFR1, a second DC-DC converter DCCR2 for converting the voltage of the first switching mode power supply SMPS1 or the first A first selector SELR1 for supplying a voltage output from the DC-DC converter DCCR1 to the first fan CFR1; and a second selector SELR2 for sensing a voltage of the first battery RB1, The voltage of the battery RB1 is supplied to the master battery management system 300 outside the first rack Rack_1 and when the rack balancing signal is received from the master battery management system 300, SELR1) to control the operation of the first rack-and-pin And a first rack battery management system (RBMS1) for supplying a voltage of the battery RB1 to the first fan CFR1.

The first rack battery RB1 includes a plurality of tray batteries (not shown).

The n-th battery rack Rack_n includes an n-th switching-mode power supply SMPSn, which is an AC-DC converting unit for converting AC into DC, an n-th fan CFRn for temperature control in the n-th battery rack Rack_n, An n-th DC-DC converter DCCRn for converting the voltage of the n-th rack battery RBn into a driving voltage of the n-th fan CFRn, a voltage of the n-th switching mode power supply SMPSn, An n-th selection unit SELRn for supplying a voltage output from the DC-DC converter DCCRn to the n-th fan CFRn, and a n-th selection unit SELRn for sensing the voltage of the n-th rack battery RBn, The voltage of the battery RBn is supplied to the master battery management system 300 outside the nth rack Rack_n and when the rack balancing signal is received from the master battery management system 300, N) of the n-th DC-DC converter (DCCRn) by controlling the operation of the n-th DC-DC converter And an nth rack battery management system (RBMSn) for supplying a voltage of the battery RBn to the nth fan CFRn.

The n-th rack battery RBn includes a plurality of tray batteries (not shown).

The master battery management system 300 determines whether the voltage deviation between the voltages of the rack batteries RB1 to RBn is equal to or greater than a reference value based on the rack battery voltages received from the plurality of battery racks Rack_1 to Rack_n And provides the rack balancing signal to the rack battery management system of the battery rack to be discharged having a voltage higher than the reference voltage when the voltage deviation between the voltages of the rack batteries RB1 to RBn is equal to or greater than the reference value.

In the embodiment of the present invention, the reference voltage may be a voltage obtained by adding the voltage deviation reference value to the average voltage of the plurality of rack batteries RB1 to RBn, but the embodiment of the present invention is not limited thereto.

The first through n-th fans CFR1 through CFn are fans installed in the first through n-th battery racks Rack_1 through Rack_n, respectively. It is a device for regulation.

When the balancing stop signal is received from the master battery management system 300, or when the rack balancing signal is not received from the master battery management system 300, the rack battery management systems RBMS1 to RBMSn may select And supplies the voltages of the switching mode power supplies SMPS1 to SMPSn to the fans CFR1 to CFRn by controlling the operation of the switches SELR1 to SELRn.

The master battery management system 300 provides a balancing stop signal to the rack battery management system of the battery rack to be discharged when the voltage of the rack battery to be discharged is balanced to the target rack voltage.

The operation of the rack balancing apparatus using the fan according to one embodiment of the present invention will be described below.

Illustratively, in an embodiment of the present invention, it is assumed that the voltage of the first rack battery RB1 is higher than the reference voltage.

The master battery management system 300 determines whether the voltage deviation between the rack battery voltages is equal to or greater than a reference value based on rack battery voltages received from the plurality of battery racks Rack_1 to Rack_n.

The master battery management system 300 determines that the voltage of the first rack battery RB1 received from the first battery rack Rack_1 is higher than the reference voltage, It is judged that the voltage deviation between the voltages of the rack batteries RB2 to nB rack batteries RBn is equal to or higher than the reference value.

In an embodiment of the present invention, the reference voltage may be a voltage obtained by adding a reference value of the voltage deviation to an average voltage of the plurality of rack batteries RB1 to RBn, but the embodiment of the present invention is not limited thereto.

The master battery management system 300 provides a rack balancing signal to the first rack battery management system RBMS1 of the first battery rack Rack_1 including the first rack battery RB1 having a voltage higher than the reference voltage.

The first rack battery management system RBMS1 applies a first control signal CSR1 to the first selector SELR1 when the rack balancing signal is received from the master battery management system 300, The voltage of the first rack battery RB1 transformed through the first DC-DC converter DCCR1 is supplied to the first fan CFR1 by controlling the operation of the first battery RB1 by controlling the operation of the first battery RB1, Lt; RTI ID = 0.0 > Rack < / RTI >

In an embodiment of the present invention, the first fan CFR1 for controlling the temperature in the first battery rack Rack_1 uses a driving voltage of 24V, and the first battery RB1 generally has a voltage of about 1000V The first fan CFR1 can be driven only when the voltage of the first rack battery RB1 is lowered to the driving voltage of the first fan CFR1.

Therefore, in an embodiment of the present invention, the voltage of the first battery RB1 to be discharged, which has a voltage higher than the reference voltage, is applied to the first fan CFR1 using the first DC-DC converter DCCR1 Down to the driving voltage.

The first rack battery management system RBMS1 controls the operation of the first selection unit SELR1 until the balancing stop signal is received from the master rack battery management system 300, DCR1 to the first fan CFR1 and supplies the voltage of the first rack battery RB1 to the first rack battery RB1 until the voltage of the first rack battery RB1 becomes the target rack voltage RB1 through the first fan CFR1.

The target rack voltage may include an average voltage of the plurality of rack batteries RB1 to RBn, but the embodiment of the present invention is not limited thereto.

When the voltage of the first rack battery RB1 falls to the target rack voltage, the master battery management system 300 continuously monitors the voltage of the first rack battery RB1, It is determined that the balancing is completed, and a balancing stop signal is provided to the first rack battery management system (RBMS1).

When the first rack battery management system RBMS1 receives the balancing stop signal from the master battery management system 300, the first rack battery management system RBMS1 receives the balancing stop signal from the first selection unit SELR1 of the first battery rack Rack_1 The first control signal CSR1 is applied to stop the voltage of the first rack battery RB1 from being supplied to the first fan CFR1 to stop the balancing of the racks and the first switching mode power supply SMPS1 Is supplied to the first fan CFR1 so that the first fan CFR1 normally performs the temperature control function.

Meanwhile, since the second to n-th rack battery management systems (RBMS2 to RBMSn) do not receive the rack balancing signal from the master battery management system 300, the second to the n-th selection units SELR2- And supplies the voltages of the second to the n-th switching mode power supplies SMPS2 to SMPSn to the second to the n-th fans CFR2 to CFRn, CFR2 to CFRn are operated with voltages of the second to n < th > switching mode power supplies SMPS2 to SMPSn.

In the embodiment of the present invention, when there is one fan inside the battery rack, balancing of the rack is performed by using one fan inside the battery rack. However, the present invention is not limited to this, The rack balancing may be performed using a plurality of fans in the battery rack.

In the embodiment of the present invention, rack balancing is performed using a fan. However, the present invention is not limited to this, and the rack balancing may be performed by using a temperature adjusting means such as a thermoelectric element instead of the fan.

The fan balancing apparatus using the fan according to the embodiment of the present invention can be used for balancing racks of a plurality of rack batteries included in the battery system of the energy storage system. However, the present invention is not limited to this, Can be used for rack balancing of rack batteries included in any type of device or system.

According to the embodiment of the present invention, since tray balancing or rack balancing is performed using a conventional battery tray or a fan installed inside a battery rack, the additional hardware cost is reduced, and the heat generated by the passive balancing using the balancing resistance The balance can be solved through balancing through fan.

Therefore, according to the embodiment of the present invention, since the tray balancing or the rack balancing is performed through the fan, the problem of heat generation at the time of balancing can be solved, and the configuration of the balancing circuit can be simplified because no balancing resistance is required.

In addition, since the conventional passive balancing performs balancing with a low current of several tens to several hundreds of amperes (mA), the fan or the thermoelectric element operates with a high current of a few amperes (A) The balancing efficiency can be improved, and the time required for balancing can be greatly shortened.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be modified or improved.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

100: Switching mode power supply
102: Rack Battery Management System
300: Master Battery Management System
Tray_1, ... Tray_n: first battery tray to nth battery tray
TBMS1, ..., TBMSn: first tray BMS to nth tray BMS
SEL1, ..., SELn: the first to n < th >
CF1, ..., CFn: first to nth fans
DCC1, ..., DCCn: the first DC-DC converter to the nth DC-DC converter
TB1, ..., TBn: first tray battery to nth tray battery
Rack_1, ... Rack_n: first battery rack to nth battery rack
SMPS1, ..., SMPSn: first SMPS to nth SMPS
RBMS1, ..., RBMSn: first rack BMS to nth rack BMS
SELR1, ..., SELRn: the first to n < th >
CFR1, ..., CFRn: first to nth fans
DCCR1, ..., DCCRn: the first DC-DC converter to the nth DC-DC converter
RB1, ..., RBn: first rack battery to nth rack battery

Claims (19)

A fan for temperature control within the battery tray;
A selector for supplying an output voltage of an external power source outside the tray or a voltage of the tray battery to the fan; And
A controller for sensing a voltage of the tray battery and providing a voltage of the sensed tray battery to a rack battery management system external to the tray, and when a tray balancing signal is received from the rack battery management system, And a tray battery management system for supplying a voltage of the tray battery to the fan,
Wherein the rack battery management system determines whether a voltage deviation between the tray battery voltages is equal to or greater than a reference value based on tray battery voltages received from the plurality of battery trays and if the voltage deviation between the tray battery voltages is equal to or greater than a reference value A tray balancing apparatus using a fan to provide the tray balancing signal to a tray battery management system of a battery tray including a tray battery to be discharged having a voltage higher than a reference voltage. The method according to claim 1,
The rack battery management system includes a fan for providing a balancing stop signal to the tray battery management system of the battery tray including the tray battery to be discharged when the voltage of the tray battery to be discharged is balanced to the target tray voltage Tray balancing device. The method of claim 2,
Wherein the tray battery management system is further configured to control the operation of the selection unit when the tray balancing signal is not received from the rack battery management system or when the balancing stop signal is received from the rack battery management system, And a fan for supplying an output voltage to the fan. The method of claim 3,
And a DC-DC converter for converting the voltage of the tray battery to a driving voltage of the fan and providing the voltage to the selecting unit. The method according to claim 1,
Wherein the reference voltage = the average voltage of the plurality of tray batteries + the reference value. A tray balancing device for each of the plurality of battery trays, for a battery rack including an ac-to-dc conversion section for converting AC to DC, a plurality of battery trays, and a rack battery management system for managing the plurality of battery trays, In this case,
Wherein each of the plurality of battery trays includes a tray battery and a fan for controlling the temperature in the battery tray,
The tray balancing device includes:
A selector for supplying an output voltage of the AC-DC converter or a voltage of the tray battery to the fan; And
A controller for sensing a voltage of the tray battery and providing a voltage of the sensed tray battery to the rack battery management system external to the tray, and when a tray balancing signal is received from the rack battery management system, And a tray battery management system for supplying a voltage of the tray battery to the fan,
Wherein the rack battery management system determines whether a voltage deviation between the tray battery voltages is equal to or greater than a reference value based on tray battery voltages received from the plurality of battery trays and if the voltage deviation between the tray battery voltages is equal to or greater than a reference value A tray balancing apparatus using a fan to provide the tray balancing signal to a tray battery management system of a battery tray including a tray battery to be discharged having a voltage higher than a reference voltage. The method of claim 6,
The rack battery management system includes a fan for providing a balancing stop signal to the tray battery management system of the battery tray including the tray battery to be discharged when the voltage of the tray battery to be discharged is balanced to the target tray voltage Tray balancing device. The method of claim 7,
Wherein the tray battery management system controls the operation of the selection unit when the tray balancing signal is not received from the rack battery management system or when the balancing stop signal is received from the rack battery management system, And a fan for supplying an output voltage of the converting unit to the fan. The method of claim 8,
And a DC-DC converter for converting the voltage of the tray battery to a driving voltage of the fan and providing the voltage to the selecting unit. The method of claim 6,
Wherein the reference voltage = the average voltage of the plurality of tray batteries + the reference value. (A) determining whether a voltage deviation between the plurality of trays is equal to or greater than a reference value; And
(B) supplying a voltage of a tray battery to be discharged having a voltage higher than a reference voltage to the fan to perform tray balancing when the voltage deviation between the plurality of trays is equal to or greater than a reference value in the step (A) . The method of claim 11,
(C) When the voltage deviation between the plurality of trays is judged to be less than the reference value or the tray balancing in the step (B) is completed in the step (A), the output voltage of the external power source, To a fan in the tray. The method of claim 11,
The step (B)
(B1) lowering the voltage of the tray battery to be discharged to the driving voltage of the fan; And
(B2) performing tray balancing by supplying the voltage of the coercive force-converted tray battery to the fan until the voltage of the tray battery to be discharged becomes the target tray voltage. The method of claim 11,
Wherein the reference voltage = the average voltage of the plurality of tray batteries + the reference value. A rack balancing apparatus included in each of the plurality of battery racks for a battery system including a plurality of battery racks and a master battery management system for managing the plurality of battery racks,
Wherein each of the plurality of battery racks includes an AC-DC conversion unit for converting AC into DC, a rack battery, and a fan for temperature control in the battery rack,
The rack balancing apparatus includes:
A selector for supplying an output voltage of the AC-DC converter or a voltage of the rack battery to the fan; And
The method comprising: sensing a voltage of the rack battery; providing a voltage of the sensed rack battery to the master battery management system outside the rack; and when a rack balancing signal is received from the master battery management system, And a rack battery management system for supplying a voltage of the rack battery to the fan,
Wherein the master battery management system determines whether a voltage deviation between the rack battery voltages is equal to or greater than a reference value based on rack battery voltages received from the plurality of battery racks and if the voltage deviation between the rack battery voltages is equal to or greater than a reference value A rack balancing apparatus using a fan that provides said rack balancing signal to a rack battery management system of a battery rack that includes a rack battery to be discharged having a voltage higher than a reference voltage. 16. The method of claim 15,
Wherein the master battery management system includes a fan for providing a balancing stop signal to the rack battery management system of the battery rack including the rack battery to be discharged when the voltage of the rack battery to be discharged is balanced to the target rack voltage Used rack balancing device. 18. The method of claim 16,
The rack battery management system may further include a controller for controlling the operation of the selection unit when the rack balancing signal is not received from the master battery management system or when the balancing stop signal is received from the master battery management system, And a fan for supplying an output voltage of the converting unit to the fan. 18. The method of claim 17,
And a DC-DC converter for converting the voltage of the rack battery to a driving voltage of the fan and providing the voltage to the selecting unit. 16. The method of claim 15,
Wherein the reference voltage = the average voltage of the plurality of rack batteries + the reference value.

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