KR101465179B1 - An energy storage system using bidirectional pwm inverter - Google Patents

Abstract

A bidirectional PWM inverter capable of solving the problem of cell imbalance without employing a cell balancing circuit of the battery cell, easily auditing the failure of the battery cell, improving the usable life of the battery, and reducing the battery maintenance cost An energy storage device is disclosed. The energy storage device using the bidirectional PWM inverter includes a plurality of battery packs each including a predetermined number of battery cells connected in series to each other; A plurality of bidirectional PWM inverters each connected to each of the battery packs to convert DC power of the battery pack into AC power and convert AC power into DC power to provide the DC power to the battery pack; And a plurality of bidirectional PWM inverters, which are supplied with AC power and convert the magnitude of the voltage to provide a system or a load, and receive AC power from the system to convert the magnitude of the voltage and provide the AC voltage to the plurality of bidirectional PWM inverters Matching transformer.

Description

TECHNICAL FIELD [0001] The present invention relates to an energy storage device using a bidirectional PWM inverter,

The present invention relates to an energy storage device, and more particularly, to an energy storage device, and more particularly, to an energy storage device that can reduce the problem of cell imbalance without separately providing a cell balancing circuit for battery cells connected in series. Storage device.

Generally, an energy storage system (ESS) using PWM (Pulse Width Modulation) inverter stores electric energy in the battery while the power of the system is supplied, and the power supply of the system can not be supplied It is a device that supplies stable power to load through inverter.

Bidirectional PWM inverter used in the energy storage device is a power conditioner (PCS) that enables charging and discharging of the battery through power flow in both directions between the AC side and the DC side.

These energy storage devices are mainly operated in two modes.

One of the two operation modes is a voltage control operation, which is a mode for supplying stable power to the load when no power is supplied from the system. In the voltage control operation mode, the switch for the connection to the system is turned off for independent operation, and the DC power stored in the battery is converted into AC and supplied to the load side by using a bi-directional PWM inverter which is a power converter (PCS). In the voltage controlled operation mode, the load side AC voltage of the bidirectional PWM inverter that converts the DC power of the battery to AC and provides it to the load is compared with the preset reference voltage to provide a stable AC voltage on the load side, And controls the PWM inverter to be provided to this load.

The other operation mode is a current control operation, which is applied to a case where power is supplied to the system in a state where the system power is normally supplied and the battery is charged, or conversely, current is supplied to the system to sell the power . In the current controlled operation mode, the battery side current of the bidirectional PWM inverter is compared with the predetermined reference direct current so as to provide a stable DC current for the battery to charge the battery, so that a DC current of a predetermined magnitude can be supplied as a battery, And controls the inverter.

Such an energy storage device using a conventional bidirectional PWM inverter is disclosed in Korean Patent Laid-Open No. 10-2011-0054041, which is a prior art document.

On the other hand, a rechargeable battery applied to an energy storage device is one of the important parts of an energy storage device and manages the DC voltage of a bidirectional PWM inverter which is a power converter (PCS).

Generally, a rechargeable battery applied to an energy storage device may include a plurality of battery cells connected in series. A battery including a plurality of battery cells connected in series is generally referred to as a battery pack.

The battery cells connected in series in the battery pack are liable to cause variations in internal resistance, charge / discharge capacity, and the like over time, causing problems. For example, if some cells with reduced charge capacity during charging are overcharged early due to overcharging, the entire battery pack will be in danger of fire and explosion. In addition, if the internal resistance of some of the cells is increased, the voltage of the entire battery pack may increase due to a rise in the voltage of the battery pack even though the battery pack is not fully charged.

To solve such a problem, a cell balancing circuit is usually applied to a battery cell. The cell balancing circuit is a circuit that detects voltages of a plurality of battery cells, compares them, and controls the voltages of all the battery cells to be equal to each other. The cell balancing technique applied to the cell balancing circuit is a passive method and an active method. In the passive cell balancing method, the charge of the overcharged cells is consumed through the resistor to balance the cells. The active cell balancing method supplies more current to the undercharged cells to balance the cells It is a way of giving.

When a battery having a relatively large capacity such as an energy storage device is used, it is preferable to adopt an active type, but the volume and weight of the power converter increase and the price rises.

Korean Patent Publication No. 10-2011-0054041

It is an object of the present invention to solve the problem of cell imbalance without employing a cell balancing circuit of a battery cell, to provide a bi-directional battery capable of easily monitoring the failure of the battery cell, improving the usable life of the battery, And to provide an energy storage device using a PWM inverter.

According to an aspect of the present invention,

A plurality of battery packs each including a predetermined number of battery cells mutually connected in series;

A plurality of bidirectional PWM inverters each connected to each of the battery packs to convert DC power of the battery pack into AC power and convert AC power into DC power to provide the DC power to the battery pack; And

Wherein the plurality of bidirectional PWM inverters are supplied with alternating current power to convert the magnitude of the voltage to provide a system or a load, and the alternating current power is supplied from the system to convert the magnitude of the voltage, Transformer

And an energy storage device using the bidirectional PWM inverter.

In an embodiment of the present invention, the number of battery cells may be a number that does not cause a cell imbalance phenomenon between battery cells connected in series.

In one embodiment of the present invention, the matching transformer includes: a plurality of low voltage side coils respectively connected to the AC input and output terminals of the plurality of bidirectional PWM inverters; And a plurality of high-voltage side coils each of which is electromagnetically inductively coupled with the plurality of low-voltage side coils, wherein the plurality of high-voltage side coils are connected to each other in series, and the series connection structure of the high- have.

In one embodiment of the present invention, the matching transformer includes: a plurality of low voltage side coils respectively connected to the AC input and output terminals of the plurality of bidirectional PWM inverters; And a single high voltage side coil which is electromagnetic inductively coupled in common with the plurality of low voltage side coils, and the single high voltage side coil can be connected to the system or the load.

In one embodiment of the present invention, the matching transformer includes: a plurality of low voltage side coils respectively connected to the AC input and output terminals of the plurality of bidirectional PWM inverters; And a plurality of high-voltage side coils connected to each other in parallel by electromagnetic induction coupling with the plurality of low-voltage side coils, wherein each of the plurality of high-voltage side coils can be connected to the system or the load.

In one embodiment of the present invention, an LC filter including an inductor series-connected between each of the plurality of bidirectional PWM inverters and the matching transformer, and a capacitor shunted to each other may be further included.

In an embodiment of the present invention, it may further comprise an LC filter implemented with a capacitor shunt-connected to the leakage inductance of the matching transformer and the high-voltage side coil of the matching transformer.

According to another aspect of the present invention,

The battery pack includes a battery pack including a plurality of battery cells each of which is connected in series to each other. The battery pack receives DC power from the battery pack and converts the DC power into AC power and outputs AC power. A plurality of energy storage modules including bidirectional PWM inverters; And

And a power supply unit for converting a magnitude of a voltage received from the plurality of energy storage modules to provide a grid or a load to the grid and providing AC power to the plurality of energy storage modules Matching transformer

And an energy storage device using the bidirectional PWM inverter.

In an embodiment of the present invention, the number of battery cells may be a number that does not cause a cell imbalance phenomenon between battery cells connected in series.

In an embodiment of the present invention, the matching transformer may include: a plurality of low voltage side coils respectively connected to the input and output ends of the plurality of energy storage modules; And a plurality of high-voltage side coils each of which is electromagnetically inductively coupled with the plurality of low-voltage side coils, wherein the plurality of high-voltage side coils are connected to each other in series, and the series connection structure of the high- have.

In an embodiment of the present invention, the matching transformer may include: a plurality of low voltage side coils respectively connected to the input and output ends of the plurality of energy storage modules; And a single high voltage side coil which is electromagnetic inductively coupled in common with the plurality of low voltage side coils, and the single high voltage side coil can be connected to the system or the load.

In an embodiment of the present invention, the matching transformer may include: a plurality of low voltage side coils respectively connected to the input and output ends of the plurality of energy storage modules; And a plurality of high-voltage side coils connected to each other in parallel by electromagnetic induction coupling with the plurality of low-voltage side coils, wherein each of the plurality of high-voltage side coils can be connected to the system or the load.

In an embodiment of the present invention, the LC filter may further include an inductor connected in series between each of the plurality of energy storage modules and the matching transformer, and a capacitor shunted to each other.

In an embodiment of the present invention, it may further comprise an LC filter implemented with a capacitor shunt-connected to the leakage inductance of the matching transformer and the high-voltage side coil of the matching transformer.

According to the present invention, the number of battery cells connected in series to store energy in the energy storage device is reduced compared to the prior art, thereby significantly reducing the probability of battery failure.

Further, according to the present invention, it is much easier and more accurate to monitor the battery cells since the number of battery cells connected in series to store energy in the energy storage device is reduced.

Also, according to the present invention, since the battery cell and the bidirectional PWM inverter are modularly implemented, only the battery pack or the energy storage module having the failed battery cell can be replaced, so that the battery replacement cost is reduced and the replacement process is simple Maintenance cost can be reduced. In addition, if a standardized energy storage module is used, the failed energy storage module can be simply replaced by a hot-swap method during operation.

Further, according to the present invention, since the cell equilibrium circuit is not required separately, the energy efficiency of the entire system is increased, and the weight, size, and manufacturing cost of the product are reduced.

According to the present invention, when one battery cell fails, the energy storage module using the corresponding battery cell is stopped and the AC side is bypassed, thereby enabling continuous operation even in the event of a failure, so that the failure tolerance (FRT) ) Operation is possible.

1 is a block diagram of an energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention.
2 to 7 are circuit diagrams of an energy storage device using bidirectional PWM inverter according to various embodiments of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. In addition, in describing the present invention, the defined terms are defined in consideration of the functions of the present invention, and they may be changed depending on the intention or custom of the technician working in the field, so that the technical components of the present invention are limited It will not be understood as meaning.

1 is a block diagram of an energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention.

Referring to FIG. 1, an energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention includes a plurality of battery packs 11, a plurality of bidirectional PWM inverters 12, and a matching transformer 13 Lt; / RTI >

Each of the plurality of battery packs 11 is an element for storing electric energy, and may include a predetermined number of mutually serially connected battery cells. Each of the plurality of battery packs 11 is supplied with DC power from the bidirectional PWM inverter 12 or supplies DC power to the bidirectional PWM inverter 12 to provide power to the system 14 or the load 15 can do.

In one embodiment of the present invention, the battery is not in the form of a single battery pack including a plurality of mutually serially connected battery cells requiring a cell balancing circuit, . ≪ / RTI > The battery pack 11 according to an embodiment of the present invention includes a single battery cell or a plurality of battery cells. When the battery pack 11 includes a plurality of battery cells, (E.g., two to three) battery cells that do not require the application of the technique and that do not cause the problem of cell imbalance.

As described above, according to the embodiment of the present invention, since the entire battery is implemented by a plurality of battery packs 11 including a very small number of battery cells, the problem of cell imbalance hardly occurs and one battery pack 11 Even if a problem occurs in one of the two or three battery cells in the battery, it is possible to simply prevent the accident from being deteriorated by monitoring the DC link side voltage in real time. In addition, since each battery pack 11 operates independently, when a failure occurs in the battery, only the problematic battery pack is replaced during operation, thereby eliminating the need to replace the entire battery, thereby simplifying maintenance and reducing the maintenance cost can do.

Each of the plurality of bidirectional PWM inverters 12 is an element for converting a DC power input to an AC power output and converting an AC power output to a DC power output and includes a DC input / output stage in which DC power is input / output and an AC input / Lt; / RTI >

Each of the plurality of bidirectional PWM inverters 12 may form a one-to-one connection to each of the plurality of battery packs 11, and a plurality of battery packs 11 may be connected to the DC input / output terminals. The plurality of bidirectional PWM inverters 12 are supplied with DC power from the connected battery pack 11 and convert the AC power into AC power and supply the AC power to the system 14 or the load 15, Converted into DC power, and supplied to the connected battery pack 11 so that the battery pack 11 can be charged.

The DC-AC conversion or the AC-DC conversion of the bidirectional PWM inverter 12 can be performed by the conventional PWM control of the voltage control mode and the current control mode described in the background art, And thus will be omitted for the sake of clarity of the present invention.

In one embodiment of the present invention, one battery pack 11 and one bi-directional PWM inverter 12 connected thereto can form one energy storage module 10. [ That is, one battery pack 11 including a number of battery cells in which the problem of cell unbalance does not occur and one bidirectional PWM inverter 12 connected thereto may be provided in the form of modules in the entire energy storage device. In the form of this energy storage module 10, the input / output terminals of each energy storage module 10 may be AC input / output terminals of the bidirectional PWM inverter 12 therein. Thus, when the energy storage module 10 is implemented in the form of the energy storage module 10, since the energy storage module 10 operates independently, only the energy storage module, which is a problem when a problem occurs in the battery, It is possible to maintain the operation of the energy storage system in a maintenance operation as well as to reduce the maintenance cost and the cost.

The matching transformer 13 receives AC power from a plurality of bidirectional PWM inverters 12 and converts the magnitude of the voltage to supply the system 14 or the load 15. The matching transformer 13 receives AC power from the system power supply, It is possible to convert the magnitude and provide it to each of the plurality of bidirectional PWM inverters 12. The matching transformer 13 is provided not only for the mutual impedance matching between the bidirectional PWM inverter 12 and the system 14 or the load 15 but also converts AC power output from each energy storage module 10 into a system 14 and the load 15 and convert the AC power supplied from the system 14 to provide an AC voltage of an appropriate magnitude to each of the plurality of bidirectional PWM inverters 12.

2 to 7 are circuit diagrams of an energy storage device using bidirectional PWM inverter according to various embodiments of the present invention.

Referring to FIG. 2, an energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention includes a plurality of bidirectional PWM inverters 12 each having a series of input / output stages and a matching transformer 13 And an LC filter 16 including a capacitor coupled to the shunt via a connected inductor.

2, the matching transformer 13 includes a plurality of low-voltage side coils (hereinafter referred to as " low-side coils ") connected to the AC input and output terminals (input and output terminals of the energy storage module 10) And a plurality of high voltage side coils 131 that are inductively coupled to the plurality of low voltage side coils 132 by electromagnetic induction. The plurality of high voltage side coils 131 are connected in series and the series connection structure of the high voltage side coil 131 can be connected to the system 14 or the load 15.

In the embodiment shown in Fig. 2, a plurality of high voltage side coils 131 connected in series with each other in the matching transformer 13 are provided from each energy storage module 10 to the system 14 or the load 15 finally The capacity of the alternating voltage and the alternating current becomes the same as that of the conventional energy storage device including the cell equilibrium circuit including a plurality of battery cells. For example, instead of an energy storage device having a single battery pack conventionally composed of 60 battery cells and one bidirectional PWM inverter connected thereto, as shown in FIG. 2, 20 energy storage modules 10 ), The number of battery cells connected in series to each of the energy storage modules 10 becomes three. Thus, when the voltage allocated to one energy storage module 10 is reduced to 1/20, the magnitude of the AC voltage output from each energy storage module 10 is also reduced by 1/20. However, when the high voltage side coil 131 of the matching transformer 13 is connected in series as shown in FIG. 2, an AC voltage of the same magnitude as that of the conventional energy storage device using 60 DC side series battery cells can be secured. In other words, in terms of power conversion, instead of an energy storage device employing a conventional single battery pack and a single bidirectional PWM inverter, a series of 20 modular energy storage modules 10 can be combined in terms of volume, weight and cost There is no big difference.

Next, an energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention shown in Fig. 3 has a matching transformer 13 having the same structure as the embodiment shown in Fig. In the embodiment shown in FIG. 3, the LC inductor is not connected to the input / output terminals of each energy storage module 10 but is used as a filter inductor by utilizing the leakage inductance of the matching transformer 13, The filter can be constituted by shunt connection commonly to the series connection structure of the high-voltage side coil of the transformer 13. Such a filter structure is advantageous in that the connection of the filter capacitor is easy and the fabrication is simple and the filter capacitor is easily managed.

Next, an energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention shown in FIG. 4 is realized by winding a high-voltage side coil of a matching transformer 13 around a common iron core and winding a low- . 4, the matching transformer 13 includes a plurality of low-voltage side coils 132 connected to the AC input and output terminals (input and output terminals of the energy storage module 10) side of each bidirectional PWM inverter 12, And a common single high-voltage side coil 133 which is inductively coupled with the plurality of low-voltage side coils 132 by electromagnetic induction. The single high voltage side coil 133 may be connected to the system 14 or the load 15. This matching transformer 13 structure has the advantage of simplifying the connection of the high voltage side power line of the matching transformer.

In the embodiment of Fig. 4, the LC filter 16 may be implemented with the same structure as that shown in Fig.

Next, an energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention shown in Fig. 5 includes a matching transformer 13 having the same structure as that shown in Fig. 4, ≪ / RTI >

6, an energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention includes a matching transformer 13 for connecting an energy storage module 10 in series and in parallel, As shown in Fig. In the embodiment shown in Figure 6, the battery or energy storage modules are connected in parallel at the high voltage side of the matching transformer 13 rather than directly connected in parallel to increase the overall capacity of the energy storage device. 6, the matching transformer 13 includes a plurality of low-voltage side coils 132 connected to the AC input and output terminals (input and output terminals of the energy storage module 10) side of each bidirectional PWM inverter 12, And a plurality of high-voltage side coils 131, which are electromagnetic inductively coupled to the plurality of low-voltage side coils 132 and are connected in parallel to each other. In this structure, each of the high-voltage side coils 131 has a form connected to the system 14 and the load 15 individually.

 The parallel connection technique using the matching transformer 13 has an advantage of avoiding the circulation current problem in the switching period occurring between the AC input and output stages of the bidirectional PWM inverter operated in parallel. Further, since the DC side battery pack 11 of the energy storage module 10 is independently operated and managed, problems caused by parallel connection of the battery can be avoided.

In the embodiment of Fig. 6, the LC filter 16 can be implemented with the same structure as that shown in Fig.

Next, an energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention shown in Fig. 7 is provided with a matching transformer 13 having the same structure as that shown in Fig. 6, ≪ / RTI >

As described above, the energy storage device using the bidirectional PWM inverter according to the embodiment of the present invention has a very good advantage in terms of the management of the battery.

First, when a conventional single power conversion structure is used, the probability of failure of one of a plurality of battery cells connected in series in one battery pack is very high compared to the case of dividing into a plurality of energy storage modules. That is, as the number of battery cells connected in series increases, the probability of failure increases. An energy storage device using a bidirectional PWM inverter according to an embodiment of the present invention can reduce the number of batteries connected in series to the DC link side of one bidirectional PWM inverter compared with the conventional one, thereby significantly reducing the probability of battery failure.

Second, an energy storage device using a bidirectional PWM inverter in an embodiment of the present invention is easy to monitor the failure of a battery cell. For example, it may be easier and more accurate to monitor two or three small-scale, cascaded battery cells than to monitor 60 cascaded battery cells integrally.

Third, the energy storage device using the bidirectional PWM inverter according to an embodiment of the present invention is simple in maintenance and low in cost. In the conventional energy storage device, when one battery cell fails, the entire battery pack must be replaced. However, since the battery pack or the energy storage module having the battery cell in which the failure occurs can be replaced, The replacement process is simple and the maintenance cost is low. Furthermore, using a standardized energy storage module allows for a simple replacement of the failed energy storage module hot-swap during operation.

Fourth, since the energy storage device using the bidirectional PWM inverter according to an embodiment of the present invention does not require a cell balancing circuit, the energy efficiency of the entire system is increased, and the weight, size, and manufacturing cost of the product are reduced.

Finally, in an embodiment of the present invention, an energy storage device using a bidirectional PWM inverter can operate in a fault ride through (FRT). For example, when one of the plurality of battery cells fails, the energy storage module using the corresponding battery cell is stopped and the AC side is bypassed, so that continuous operation is possible even during a failure. The failed energy storage module has time to spare and can be replaced later. As described above, the embodiment of the present invention can improve coping ability in an emergency situation.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited to the embodiments described, but should be determined by the scope of the following claims and equivalents thereof.

10: Energy storage module 11: Battery pack
12: Bidirectional PWM inverter 13: Matching transformer
131, 133: high-voltage side coil 132: low-voltage side coil
14: grid (grid power) 15: load

Claims (14)

delete delete A plurality of battery packs each including a predetermined number of battery cells mutually connected in series;
A plurality of bidirectional PWM inverters each connected to each of the battery packs to convert DC power of the battery pack into AC power and convert AC power into DC power to provide the DC power to the battery pack; And
Wherein the plurality of bidirectional PWM inverters are supplied with alternating current power to convert the magnitude of the voltage to provide a system or a load, and the alternating current power is supplied from the system to convert the magnitude of the voltage, Comprising a transformer,
The matching transformer includes: a plurality of low voltage side coils respectively connected to the AC input / output terminals of the plurality of bidirectional PWM inverters; And a plurality of high-voltage side coils each of which is electromagnetically inductively coupled with the plurality of low-voltage side coils, wherein the plurality of high-voltage side coils are connected in series and the series connection structure of the high-voltage side coil is connected to the system or the load Energy saving device using bidirectional PWM inverter. A plurality of battery packs each including a predetermined number of battery cells mutually connected in series;
A plurality of bidirectional PWM inverters each connected to each of the battery packs to convert DC power of the battery pack into AC power and convert AC power into DC power to provide the DC power to the battery pack; And
Wherein the plurality of bidirectional PWM inverters are supplied with alternating current power to convert the magnitude of the voltage to provide a system or a load, and the alternating current power is supplied from the system to convert the magnitude of the voltage, Comprising a transformer,
The matching transformer includes: a plurality of low voltage side coils respectively connected to the AC input / output terminals of the plurality of bidirectional PWM inverters; And a single high voltage side coil that is electromagnetic inductively coupled in common with the plurality of low voltage side coils, wherein the single high voltage side coil is connected to the system or the load. A plurality of battery packs each including a predetermined number of battery cells mutually connected in series;
A plurality of bidirectional PWM inverters each connected to each of the battery packs to convert DC power of the battery pack into AC power and convert AC power into DC power to provide the DC power to the battery pack; And
Wherein the plurality of bidirectional PWM inverters are supplied with alternating current power to convert the magnitude of the voltage to provide a system or a load, and the alternating current power is supplied from the system to convert the magnitude of the voltage, Comprising a transformer,
The matching transformer includes: a plurality of low voltage side coils respectively connected to the AC input / output terminals of the plurality of bidirectional PWM inverters; And a plurality of high voltage side coils connected in parallel to each other in electromagnetic induction coupling with the plurality of low voltage side coils, wherein each of the plurality of high voltage side coils is connected to the system or the load. Device. 6. The method according to any one of claims 3 to 5,
Further comprising an LC filter including an inductor connected in series between each of the plurality of bi-directional PWM inverters and the matching transformer, and a capacitor shunted to each other. 6. The method according to any one of claims 3 to 5,
Further comprising an LC filter implemented by a leakage inductance of the matching transformer and a capacitor shunted to a high voltage side coil of the matching transformer. delete delete The battery pack includes a battery pack including a plurality of battery cells each of which is connected in series to each other. The battery pack receives DC power from the battery pack and converts the DC power into AC power and outputs AC power. A plurality of energy storage modules including bidirectional PWM inverters; And
And a power supply unit for converting a magnitude of a voltage received from the plurality of energy storage modules to provide a grid or a load to the grid and providing AC power to the plurality of energy storage modules A matching transformer,
The matching transformer includes a plurality of low voltage side coils connected to the input and output ends of the plurality of energy storage modules, respectively; And a plurality of high-voltage side coils each of which is electromagnetically inductively coupled with the plurality of low-voltage side coils, wherein the plurality of high-voltage side coils are connected in series and the series connection structure of the high-voltage side coil is connected to the system or the load Energy saving device using bidirectional PWM inverter. The battery pack includes a battery pack including a plurality of battery cells each of which is connected in series to each other. The battery pack receives DC power from the battery pack and converts the DC power into AC power and outputs AC power. A plurality of energy storage modules including bidirectional PWM inverters; And
And a power supply unit for converting a magnitude of a voltage received from the plurality of energy storage modules to provide a grid or a load to the grid and providing AC power to the plurality of energy storage modules A matching transformer,
The matching transformer includes a plurality of low voltage side coils connected to the input and output ends of the plurality of energy storage modules, respectively; And a single high voltage side coil that is electromagnetic inductively coupled in common with the plurality of low voltage side coils, wherein the single high voltage side coil is connected to the system or the load. The battery pack includes a battery pack including a plurality of battery cells each of which is connected in series to each other. The battery pack receives DC power from the battery pack and converts the DC power into AC power and outputs AC power. A plurality of energy storage modules including bidirectional PWM inverters; And
And a power supply unit for converting a magnitude of a voltage received from the plurality of energy storage modules to provide a grid or a load to the grid and providing AC power to the plurality of energy storage modules A matching transformer,
The matching transformer includes a plurality of low voltage side coils connected to the input and output ends of the plurality of energy storage modules, respectively; And a plurality of high voltage side coils connected in parallel to each other in electromagnetic induction coupling with the plurality of low voltage side coils, wherein each of the plurality of high voltage side coils is connected to the system or the load. Device. 13. The method according to any one of claims 10 to 12,
Further comprising an LC filter including an inductor connected in series between each of the plurality of energy storage modules and the matching transformer and a capacitor shunted to each other. 13. The method according to any one of claims 10 to 12,
Further comprising an LC filter implemented by a leakage inductance of the matching transformer and a capacitor shunted to a high voltage side coil of the matching transformer.

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