KR20150079211A - Power Conditioning System for Battery Energy Storage System and Method for Controlling Power Conditioning System - Google Patents

Abstract

The present invention relates to a power management apparatus for a battery energy storage system and a controlling method of a power management apparatus, comprising: a first power conversion unit for managing a power of batteries; a second power conversion unit installed spacing apart from the first power conversion unit; a control unit for supplying cold air for cooling an interior of the first power conversion unit and an interior of the second power conversion unit and for recovering a heat generated by the first power conversion unit and the second power conversion unit; a first supply fan for moving cold air supplied from the control unit into an interior of the first power conversion unit; a second supply fan for moving cold air supplied from the control unit into an interior of the second power conversion unit; and a separation unit installed between the first power conversion unit and the second power conversion unit to separate a movement path of the cold air supplied from the first supply fan, a movement path of the heat generated from the first power conversion unit, a movement path of the cold air supplied by the second supply fan and a movement path of the heat generated from the second power conversion unit. According to the present invention, it is possible to increase use hours of batteries installed in the management apparatus by reducing a power consumption and possible to contribute to reducing material costs and operation costs by reducing an installed capacity of installed batteries.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power management apparatus for a battery energy storage system,

The present invention relates to a power management apparatus and a control method used in a battery energy storage system.

With the development of the industry, the demand for electric power is increasing, and the gap of electricity use between day and night, season, and day is increasing. Recently, for this reason, a number of techniques are rapidly being developed for reducing the peak load by utilizing surplus power of the system. Among these technologies, a typical example is a battery energy storage system (BESS) that stores surplus power of the system in the battery or supplies the system with the insufficient power of the system.

The battery energy storage system stores surplus power generated at night or surplus power generated from renewable energy sources such as wind power and sunlight, and supplies the power stored in the battery to the system during a peak load or system accident. This will stabilize the system power unstably fluctuating by the renewable energy source and achieve maximum load reduction and load leveling. In particular, such a battery energy storage system can be used in an intelligent grid (Smart Grid), which has recently been emerging due to the emergence of various renewable energy sources.

Such a battery energy storage system includes a battery conditioner system (BCS), and a power conditioner system (PCS). The batteries installed in the battery management apparatus are charged (charged) using electric power supplied from the system or discharged to supply power to the system. The power management apparatus has a function of managing the power of the batteries installed in the battery management apparatus, such as performing power conversion (AC / DC) between the system and the battery management apparatus.

Such a power management apparatus generates heat in the process of operating to manage the power of the batteries. The heat generated in this manner deteriorates the performance of the power management apparatus and can damage or destroy the power management apparatus in the case of high temperature. Therefore, it is required to develop a technique capable of eliminating the heat generated in the power management apparatus.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a power management apparatus and a control method of a power management apparatus capable of eliminating heat generated during operation for managing power of batteries.

In order to solve the above-described problems, the present invention can include the following configuration.

A power management apparatus according to the present invention includes: a first power conversion unit for managing power of batteries; A second power conversion unit installed apart from the first power conversion unit; A second power converter for converting the heat generated by the first power converter and the heat generated by the second power converter into a heat to cool the inside of the first power converter and the inside of the second power converter; And A first supply fan for moving the cool air supplied from the regulator into the first power converter; A second supply fan for moving the cool air supplied from the controller to the inside of the second power converter; And a movement route of the cool air supplied by the first supply fan and a movement path of the heat generated by the first power conversion unit and a movement path of the cool air supplied by the second supply fan, And a separator provided between the first power conversion unit and the second power conversion unit to separate the heat transfer path generated by the first power conversion unit.

A power management apparatus control method according to the present invention includes: selecting a power conversion unit to be operated according to an output command value among a plurality of power conversion units; Measuring a temperature of the selected power conversion unit; Determining whether the measured temperature exceeds a predetermined reference temperature; If the measured temperature is higher than the reference temperature, activating a regulator for generating cold air and a supply fan for moving the generated cold air to forcibly air-cool the selected power converter; And stopping the regulator and operating the supply fan to naturally cool the selected power switching unit if the measured temperature is below the reference temperature.

According to the present invention, the following effects can be obtained.

The present invention is designed to solve the heat generated during the operation for managing the power of the batteries, thereby improving the performance for managing the power of the batteries and reducing the maintenance work due to damage or breakage The operating rate can be improved.

The present invention can contribute to the reduction of the material cost and the operating cost by reducing the power consumption by increasing the use time of the batteries installed in the battery management apparatus and by decreasing the installation capacity of the batteries installed in the battery management apparatus.

1 is a schematic perspective view of a power management apparatus according to the present invention;
2 is a schematic plan view showing the power management apparatus according to the present invention with reference to the line I-I in FIG.
3 is a schematic side sectional view of the power management apparatus according to the present invention, taken along the line II-II in FIG. 2;
4 is a schematic side cross-sectional view illustrating the first power conversion unit according to the present invention with reference to line II-II in FIG. 2
5 is a schematic plan sectional view of the power management apparatus according to the present invention taken along the line III-III in FIG. 3;
FIG. 6 is a schematic front sectional view of the power management apparatus according to the present invention, taken on line IV-IV of FIG. 5;
7 is a schematic side cross-sectional view showing the power management apparatus according to the present invention with reference to the line V-V in FIG. 5
8 is a schematic block diagram for explaining a control unit according to the present invention.
9 is a schematic flowchart of a control method of the power management apparatus according to the present invention

Hereinafter, embodiments of a power management apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, the power management apparatus 1 according to the present invention is used in a battery energy storage system (BESS). The power management device 1 according to the present invention performs power conversion (AC / DC) between the system and the battery management device in the battery energy storage system, and manages the power of the batteries installed in the battery management device.

The power management apparatus 1 according to the present invention includes a first power conversion unit 100 for managing the power of the batteries. The power management apparatus 1 according to the present invention may cool the inside of the first power conversion unit 100 using cool air and may heat the inside of the first power conversion unit 100 To regulate the internal temperature of the first power conversion unit 100. [ Accordingly, the power management apparatus 1 according to the present invention can eliminate the heat generated during the operation for managing the power of the batteries. Accordingly, the power management apparatus 1 according to the present invention can improve the performance for managing the power of the batteries, and can reduce the maintenance work due to damage or breakage, thereby improving the operation rate. The heat generated inside the first power conversion unit 100 may be formed as the cool air is heated while cooling the inside of the first power conversion unit 100.

1 to 3, a power management apparatus 1 according to the present invention includes a main body 2, a support portion 3, a vent portion 4, a control portion 5, and the first power conversion portion 100).

The main body 2 supports the first power conversion portion 100, the support portion 3, the vent portion 4, and the regulating portion 5. The first power conversion unit 100, the support unit 3, the ventilation unit 4 and the control unit 5 are installed inside the main body 2.

The body 2 may include a first sidewall 21 (shown in Fig. 2) and a second sidewall 22 (shown in Fig. 2) facing each other.

The first side wall 21 is one of a plurality of side walls of the main body 2. The first side wall 21 is one of two sidewalls forming a long side when the main body 2 is formed in a rectangular shape. The first sidewall 21 may have a rectangular plate shape.

The second side wall 22 is one of a plurality of side walls of the main body 2. The second side wall 22 is one of two long side walls when the main body 2 is formed in a rectangular shape. The second sidewall 22 is spaced from the first sidewall 21 by a predetermined distance. The second side wall 22 may have a rectangular plate shape.

The body 2 may include a bottom 23 (shown in Fig. 3) coupled to the first sidewall 21 and the second sidewall 22, respectively.

The bottom (23) forms the lower part of the main body (2). One side of the bottom 23 is coupled to the first side wall 21 and the other side is coupled to the second side wall 22 to close the bottom of the main body 2. The bottom 23 may be formed in a rectangular plate shape.

The body 2 may include a ceiling 24 (shown in FIG. 3) coupled to the first sidewall 21 and the second sidewall 22, respectively.

The ceiling (24) forms the upper part of the main body (2). The ceiling 24 is connected to the first side wall 21 at one side and is coupled to the second side wall 22 at the other side to close the upper portion of the main body 2. [ The ceiling (24) is spaced a predetermined distance from the floor (23). The ceiling (24) is installed at a height higher than the floor (23). The ceiling 24 and the bottom 23 may be spaced apart from each other by a distance greater than the height of the first power conversion unit 100 and the second power conversion unit 200, respectively. The ceiling 24 may be formed in a rectangular plate shape.

The body 2 has a third side wall 25 (shown in Fig. 2) and a fourth side wall 26 (shown in Fig. 2) coupled to the first side wall 21 and the second side wall 22, . ≪ / RTI >

The third side wall 25 is one of a plurality of side walls of the main body 2. The third side wall 25 is one of two sidewalls forming a short side when the main body 2 is formed into a rectangular shape. The third side wall 25 may have a rectangular plate shape.

The fourth side wall 26 is one of a plurality of side walls of the main body 2. The fourth side wall 26 is one of two short side walls when the main body 2 is formed into a rectangular shape. The fourth side wall 26 is spaced from the third side wall 25 by a predetermined distance. The fourth side wall 26 may be formed in a rectangular plate shape.

The body 2 has a first side wall 21, a second side wall 22, a ceiling 24, a bottom 23, a third side wall 25 and a fourth side wall 26 By being joined to each other, the inside can be formed to be closed. In this case, the main body 2 may be formed in a rectangular shape.

The main body 2 may be implemented as a container for cargo transportation. Accordingly, the power management apparatus 1 according to the present invention can be unloaded to the transportation means by means of a transportation facility or the like that has been built to cargo-operate the transportation means such as a ship, an airplane, or the like. Therefore, the power management apparatus 1 according to the present invention does not need to newly provide a separate transportation facility, so that it is possible to reduce the construction cost for newly installing the transportation facility. Also, the power management apparatus 1 according to the present invention can be installed and used in a state of transportation, thereby improving the ease of transportation and installation. The body 2 may be a 20 FT container or a 40 FT container.

Referring to FIGS. 1 to 3, the support portion 3 (shown in FIG. 3) supports the first power conversion portion 100. The support part 3 is installed in the main body 2 so as to be spaced apart from the bottom 23 of the main body 2 (shown in Fig. 3). Accordingly, the support portion 3 is located at a height apart from the bottom 23 of the main body 2 by a predetermined distance. The first power conversion unit 100 is supported by the support unit 3 at a height spaced from the bottom 23 of the main body 2 by a predetermined distance. The supporting portion 3 may be formed in a rectangular plate shape.

The support portion (3) divides the inside of the main body (2). The interior of the main body 2 includes an installation space 2a (shown in Fig. 3) in which the first power conversion portion 100 is installed by the support portion 3, 2), and a floor passage 2b (shown in Fig. And the bottom passage 2b is connected to the regulating part 5. [ 3, the cold air supplied by the controller 5 moves along the bottom passage 2b under the first power converter 100, Can be supplied to the inside of the unit 100. In FIG. 3, arrows indicated by dashed lines indicate the paths of cool air.

1 to 4, the vent portion 4 (shown in FIG. 3) includes a passage for supplying cool air moving along the bottom passage 2b to the inside of the first power conversion portion 100 . The cool air moving along the bottom passage 2b may be supplied to the interior of the first power conversion unit 100 through the support unit 3 through the ventilation unit 4. [ The vent portion 4 may include a plurality of first vent holes 41 (shown in FIG. 4) through which cool air passes. The first ventilation holes 41 are formed through the ventilation part 4. The first vent holes 41 may be spaced apart from each other. The vent portion 4 may be coupled to the support portion 3. The vent portion 4 may be formed as a through hole penetrating the support portion 3.

The vent portion 4 is coupled to the support portion 3 under the first power conversion portion 100. Accordingly, the cool air supplied from the controller 5 is supplied to the inside of the first power converter 100 by passing through the support portion 3 through the vent portion 4. Therefore, the power management apparatus 1 according to the present invention is configured such that the cool air having passed through the ventilation unit 4 is directly supplied to the inside of the first power conversion unit 100, whereby the first power conversion unit 100 It is possible to improve the cooling efficiency for cooling the inside of the apparatus. Specifically, it is as follows.

First, when cool air having passed through the vent portion 4 is supplied to the interior of the first power conversion portion 100 through the installation space 2a, the cool air passing through the vent portion 4 flows into the first power conversion portion 100, 1 power converter 100 and then mixed with the heat discharged from the first power converter 100 to the installation space 2a. Accordingly, the cooling efficiency of cooling the interior of the first power conversion unit 100 may be lowered by increasing the temperature of the cool air passing through the vent portion 4. [

Next, when cool air having passed through the first ventilation hole 4 is directly supplied to the interior of the first power conversion unit 100, the cool air that has passed through the ventilation unit 4 passes through the first power conversion unit 100 As shown in Fig. Therefore, the power management apparatus 1 according to the present invention can improve the cooling efficiency for cooling the interior of the first power conversion unit 100. [

The power management apparatus 1 according to the present invention may include a plurality of the vent portions 4. The vent portions 4 may be coupled to the support portion 3 so as to be spaced apart from each other. 3 shows that two vent portions 4 are coupled to the support portion 3 but the present invention is not limited thereto and one or more vent portions 4 may be coupled to the support portion 3 . Although not shown, the power management apparatus 1 according to the present invention may be implemented such that the vent portions 4 form a matrix and are coupled to the support portion 3. [

Referring to FIGS. 1 to 4, the controller 5 supplies cold air for cooling the interior of the first power conversion unit 100. The regulator 5 recovers the heat generated in the first power converter 100. The regulating unit 5 may include a cooling device (not shown) that cools the recovered heat to cool again. The cooling device can cool the heat recovered by using the refrigerant. The regulator 5 may include an outdoor unit for dissipating heat absorbed by the refrigerant. The outdoor unit may be installed inside the main body 2. The outdoor unit may be installed outside the main body 2.

The controller 5 supplies cool air to the floor passage 2b. The cool air supplied to the bottom passage 2b is supplied to the inside of the first power converter 100 through the air passage 4 after moving along the bottom passage 2b. The cool air supplied to the inside of the first power conversion unit 100 cools the inside of the first power conversion unit 100 and generates heat as it is heated. This heat is discharged to the regulating portion 5 after being discharged to the ceiling 24 of the main body 2 and the first power converting portion 100. In FIG. 3, arrows denoted by solid lines indicate the paths of the openings. The heat recovered by the regulating unit 5 is cooled and changed to cool air, and then supplied to the bottom passage 2b again.

1 to 4, the first power conversion unit 100 converts the DC power supplied from the battery management device into AC power and supplies the AC power to the load. The first power conversion unit 100 converts AC power supplied from a renewable energy source into DC power and supplies the DC power to the battery management apparatus.

The first power conversion unit 100 is installed in the main body 2. The first power conversion parts 100 are installed between the first sidewall 21 and the second sidewall 22. The first power conversion units 100 may be installed at a predetermined distance from the first sidewall 21 and the second sidewall 22, respectively. The first power conversion unit 100 may be supported by the support unit 3. The first power conversion unit 100 is installed apart from the first sidewall 21 so that first sidewall passages 21a and 21b are formed between the first power conversion unit 100 and the first sidewall 21, 6) is formed. Accordingly, the control unit 5 can further recover the heat generated by the first power conversion unit 100 through the first sidewall passage 21a. Therefore, the power management apparatus 1 according to the present invention can improve the cooling performance by increasing the area for recovering the heat.

The first power conversion unit 100 includes a first support surface 110 contacting the support portion 3 and a first through hole 120 formed through the first support surface 110 .

The first support surface 110 is a lower surface of the first power conversion unit 100. The first support surface 110 forms the lower portion of the first power conversion unit 100. The first power conversion unit 100 may be supported by the support unit 3 such that the first support surface 110 is in close contact with the support unit 3. [ The first support surface 110 may have a rectangular plate shape.

The first passage hole 120 is formed in the first power conversion unit 100 so that the cool air supplied through the ventilation unit 4 passes through the first support surface 110 and is supplied to the inside of the first power conversion unit 100, 4). Accordingly, the battery management apparatus 1 according to the present invention can be implemented such that the cool air supplied from the controller 5 is directly supplied to the inside of the first power conversion unit 100. The first power conversion unit 100 may be supported by the support unit 3 such that the first passage hole 120 is connected to the first vent hole 41. The first power conversion unit 100 may include a plurality of the first holes 120. The first power conversion unit 100 may include the same number of first through holes 120 as the number of the first ventilation holes 41. The first through-holes 120 are formed at positions spaced apart from each other.

The first power conversion unit 100 may include a first discharge fan 130 (shown in FIG. 7).

The first discharge fan 130 is coupled to the upper surface 100a of the first power conversion unit 100. The first discharge fan 130 is disposed between the upper surface 100a of the first power conversion unit 100 and the ceiling 24 of the main body 2 and the upper surface 100a of the first power conversion unit 100 0.0 > 100a. ≪ / RTI > The first discharge fan 130 sucks the heat inside the first power conversion unit 100 and discharges the heat to the ceiling 24 of the main body 2. [ Therefore, the power management apparatus 1 according to the present invention can reduce the time required for the heat to stay inside the first power conversion unit 100, thereby reducing the time required for cooling the inside of the first power conversion unit 100 It is possible to improve the efficiency. The power management apparatus 1 according to the present invention may include a plurality of the first discharge fans 130. The first discharge fans 130 may be coupled to the upper surface 100a of the first power conversion unit 100 at positions spaced apart from each other.

The first power conversion unit 100 may include a first inverter 140 and a first filter 150 as shown in FIG.

The first inverter 140 converts the DC power supplied from the battery management device into AC power. The first inverter 140 may operate according to a gating reference voltage input from the voltage controller to output a constant voltage. The cool air supplied from the controller 5 is supplied into the first power converter 100 through the vent 4 and the first passage hole 120 so that the first inverter 140 Can be cooled. The vent portion 4 and the first passage hole 120 may be located below the first inverter 140. The heat generated by the first inverter 140 is transferred to the upper surface 100a of the first power conversion unit 100 and the ceiling 24 of the main body 2 by the first discharge fan 130 Can be discharged. The first discharge fan 130 may be positioned above the first inverter 140.

The first filter 150 reduces the harmonics of the AC voltage output from the first inverter 140. The cool air supplied from the controller 5 is supplied into the first power converter 100 through the vent 4 and the first passage hole 120 so that the first filter 150 Can be cooled. The vent portion 4 and the first passage hole 120 may be positioned below the first filter 150. The heat generated by the first filter 150 is blown by the first discharge fan 130 between the upper surface 100a of the first power conversion unit 100 and the ceiling 24 of the main body 2 Can be discharged. The first exhaust fan 130 may be positioned above the first filter 150. The first filter 150 and the first inverter 140 may be disposed in parallel in the first axis direction (X axis direction). The first axial direction (X-axis direction) is a direction parallel to the long side of the main body 2. [

The first filter 150 and the first inverter 140 may be installed in different spaces defined in the first power conversion unit 100. In this case, the power management apparatus 1 according to the present invention includes a first vent hole 41 located below the first filter 150, and a second vent hole 41 located below the first inverter 140. [ Pores 41 may be included. The first power conversion unit 100 includes a first discharge fan 130 positioned above the first filter 150 and a first discharge fan 130 positioned above the first inverter 140 can do.

1 to 5, the power management apparatus 1 according to the present invention may include a blocking unit 6 (shown in FIG. 3).

The shutoff unit 6 blocks the cold air supplied from the control unit 5 from moving toward the auxiliary equipment installed in the main body 2. [ The auxiliary equipment may be the fire fighting equipment 20, the control box 30, or the like. Accordingly, the shutoff unit 6 prevents the cool air supplied from the control unit 5 from being transmitted to the member facility, thereby preventing the cool air supplied from the control unit 5 from being lost. Therefore, the power management apparatus 1 according to the present invention can improve the cooling performance for cooling the interior of the first power conversion unit 100. [

The blocking portion 6 is coupled to the main body 2 so as to contact the bottom 23 of the main body 2 and the support portion 3 respectively. The blocking portion 6 may be formed in a rectangular plate shape. The blocking portion 6 may be formed of a material excellent in heat insulation performance and rigidity. For example, the blocking portion 6 may be formed of a fluororesin such as Teflon. The blocking portion 6 is coupled to the main body 2 to be in contact with the first side wall 21 and the second side wall 22, respectively.

Referring to FIGS. 1 to 7, the power management apparatus 1 according to the present invention may include a second power conversion unit 200.

The second power conversion unit 200 converts the DC power supplied from the battery management device into AC power and supplies the AC power to the load. The second power conversion unit 200 converts AC power supplied from a renewable energy source into DC power and supplies the DC power to the battery management apparatus.

The second power conversion unit 200 is installed in the main body 2. The second power conversion units 200 are installed between the first power conversion unit 100 and the second sidewall 22. The second power conversion units 200 may be installed at positions separated from the first power conversion unit 100 and the second side wall 22 by a predetermined distance in the second axis direction (Y axis direction). The second axial direction (Y-axis direction) is a direction parallel to the short side of the main body 2. The second power conversion unit 200 is installed apart from the second sidewall 22 so that the second sidewall passages 22a and 22b are formed between the second power conversion unit 200 and the second sidewall 200, 6) is formed. Accordingly, the control unit 5 can further increase the heat generated by at least one of the second power conversion unit 200 and the first power conversion unit 100 through the second side wall passage 22a Can be recovered. Therefore, the power management apparatus 1 according to the present invention can improve the cooling performance by increasing the area for recovering the heat.

The second power conversion unit 200 may be supported by the support unit 3.

The second power conversion unit 200 includes a second support surface 210 (shown in FIG. 7) contacting the support portion 3 and a second support surface 210 (220, shown in FIG. 7).

The second support surface 210 is a lower surface of the second power conversion unit 200. The second support surface 210 forms a lower portion of the second power conversion unit 200. The second power conversion unit 200 may be supported by the support unit 3 such that the second support surface 210 is in close contact with the support unit 3. [ The second support surface 210 may have a rectangular plate shape.

The second passage hole 220 is formed in the second passage 210 so that the cool air supplied from the controller 5 passes through the second support surface 210 and is supplied to the inside of the second power converter 200 As shown in FIG. Accordingly, the battery management apparatus 1 according to the present invention can be implemented such that the cool air supplied from the controller 5 is directly supplied to the inside of the second power converter 200. The second power converting part 200 may be supported by the support part 3 such that the second through hole 220 is connected to the second vent hole 42 of the vent part 4. [ The second power conversion unit 200 may include a plurality of the second through holes 220. The second power conversion unit 200 may include the same number of second through holes 220 as the number of the second air holes 42. The second through holes 220 are formed at positions spaced apart from each other.

The second power conversion unit 200 may include a second exhaust fan 230 (shown in FIG. 7).

The second discharge fan 230 is coupled to the upper surface 200a of the second power conversion unit 200. [ The second discharge fan 230 is disposed between the top surface 200a of the second power conversion unit 200 and the ceiling 24 of the main body 2 and the top surface of the second power conversion unit 200 200a. The second discharge fan 230 sucks the heat inside the second power conversion unit 200 and discharges the heat to the ceiling 24 of the main body 2. [ Therefore, the power management apparatus 1 according to the present invention can reduce the time required for the heat to stay inside the second power conversion unit 200, thereby cooling the inside of the second power conversion unit 200 It is possible to improve the efficiency. The power management apparatus 1 according to the present invention may include a plurality of the second discharge fans 230. The second discharge fans 230 may be coupled to the upper surface 200a of the second power conversion unit 200 at positions spaced apart from each other.

The second power conversion unit 200 may include a second inverter 240 and a second filter 250 as shown in FIG.

The second inverter 240 converts the DC power supplied from the battery management device into AC power. The second inverter 240 may operate according to a gating reference voltage input from the voltage controller to output a constant voltage. The cool air supplied from the controller 5 is supplied into the second power converter 200 through the vent 4 and the second passage hole 220 so that the second inverter 240 Can be cooled. The vent portion 4 and the second passage hole 220 may be positioned below the second inverter 240. The heat generated by the second inverter 240 is transferred to the upper surface 200a of the second power conversion unit 200 and the ceiling 24 of the main body 2 by the second discharge fan 230 Can be discharged. The second discharge fan 230 may be positioned above the second inverter 240.

The second filter 250 reduces the harmonics of the AC voltage output from the second inverter 240. The cool air supplied from the controller 5 is supplied into the second power converter 200 through the vent 4 and the second passage hole 220 so that the second filter 250 Can be cooled. The vent 4 and the second passage hole 220 may be located below the second filter 250. The heat generated by the second filter 250 is transferred to the upper surface 200a of the second power conversion unit 200 and the ceiling 24 of the main body 2 by the second discharge fan 230 Can be discharged. The second exhaust fan 230 may be positioned above the second filter 250.

The second filter 250 and the second inverter 240 may be installed in different spaces partitioned in the second power conversion unit 200. In this case, the power management apparatus 1 according to the present invention includes a second vent hole 42 positioned below the second filter 250, and a second vent hole 42 located below the second inverter 240. [ Pores 42 may be included. The second power conversion unit 200 includes a second exhaust fan 230 positioned above the second filter 250 and a second exhaust fan 230 positioned above the second inverter 240 can do.

When the power management apparatus 1 according to the present invention includes the first power conversion unit 100 and the second power conversion unit 200, the control unit 5 controls the ceiling passage 24a Heat can be further recovered through the heat exchanger (not shown). The ceiling passage 24a is formed between the first power conversion portion 100 and the ceiling 24 and between the second power conversion portion 200 and the ceiling 24. [ The ceiling passage 24a is also formed on the upper side between the first power conversion unit 100 and the second power conversion unit 200.

5 to 7, the power management apparatus 1 according to the present invention may include a first supply fan 71, and a second supply fan 72. As shown in FIG.

The first supply fan (71) moves the cool air supplied from the controller (5) into the first power supply fan (100). The first supply fan (71) generates a wind power for moving the cool air supplied from the controller (5). The heat discharged from the first power conversion unit 100 may be recovered to the regulating unit 5 by a negative pressure generated by the first supply fan 71. The first supply fan 71 may be coupled to the main body 2 so as to be positioned in the bottom passage 2b.

The second supply fan 72 moves the cool air supplied from the controller 5 into the second power supply fan 200. The second supply fan (72) generates a wind power for moving the cool air supplied from the controller (5). The heat discharged from the second power conversion unit 200 may be recovered to the control unit 5 by the negative pressure generated by the second supply fan 72.

The second supply fan 72 may be installed at a position spaced apart from the first supply fan 71 in the second axial direction (Y-axis direction). The second supply fan 72 may be installed at a position spaced apart from the second side wall 22 by a distance shorter than a distance from the first side wall 21. [ The first supply fan 71 may be installed at a position spaced apart from the first sidewall 21 by a distance shorter than a distance from the second sidewall 22. [

5 to 7, the power management apparatus 1 according to the present invention may include a separation unit 8. [

The separating unit 8 separates the moving path of the cool air supplied by the first supply fan 71 and the moving path of the heat generated by the first power converting unit 100 and the second supply fan 72 The first power converting unit 100 and the second power converting unit 200 may be configured to separate the moving path of the cool air supplied by the first power converting unit 200 and the moving path of the heat generated by the second power converting unit 200, Respectively.

The separating unit 8 separates the cool air to be transferred to the first supply fan 71 and the cool air to be transported by the second supply fan 72. Accordingly, as the cool air to be transferred to the first supply fan (71) and the cool air to which the second supply fan (22) to move are mixed with each other, the separator (8) It is possible to prevent a difference in the cooling efficiency of each of the second power conversion units 200 from occurring. In addition, the separator 8 may be configured to supply cold air of different flow rates to the first power conversion unit 100 and the second power conversion unit 200. The separating unit 8 may be configured to supply cold air of different temperatures to the first power converting unit 100 and the second power converting unit 200. That is, the first power conversion unit 100 and the second power conversion unit 200 can be independently controlled in temperature by the separation unit 8. When the second supply fan 72 is not operated and only the first supply fan 71 operates, the separator 8 is connected to the first power converter 100 (100) by the first supply fan 71, The cooling performance of the first power conversion unit 100 can be improved by blocking the loss of the cool air to the second power conversion unit 200 side. When the first supply fan 71 is not operated and only the second supply fan 72 operates, the separator 8 is connected to the second power converter 200 Can be prevented from being lost toward the first power conversion unit 100, thereby improving the cooling performance of the second power conversion unit 200. [

The separating portion 8 is formed to be spaced from the ceiling passage 24a so as not to block the ceiling passage 24a (shown in FIG. 6). Accordingly, when the second power conversion unit 200 is not operated and only the first power conversion unit 100 is operated, the second supply fan 72 is not operated and only the first supply fan 71 Even when operating, the regulating portion 5 can recover the heat from the entirety of the ceiling passage 24a. When only the second power supply unit 72 is operated without operating the first power supply unit 71 as the first power conversion unit 100 is not operated and only the second power conversion unit 200 is operated The regulating unit 5 can recover the heat from the entire ceiling passage 24a. Therefore, the power management apparatus 1 according to the present invention is capable of preventing the power consumption of the entire power supply unit from being lowered when the power is supplied from the entirety of the ceiling passage 24a even when one of the first power conversion unit 100 and the second power conversion unit 200 is operating. It is possible to improve the cooling performance.

The separating portion 8 may be coupled to the main body 2 so as to be in contact with the bottom 23 and the supporting portion 3 of the main body 2, respectively. The separating part 8 may be coupled to the main body 2 so as to be in contact with the blocking part 6 and the fourth side wall 26, respectively. Accordingly, the separating section 8 can divide the bottom passage 2b into a first bottom passage 21b (shown in Fig. 6) and a second bottom passage 22b (shown in Fig. 6). The separator 8 may be formed in a rectangular plate shape. The separator 8 may be formed of a material having excellent heat insulating performance and rigidity. For example, the separator 8 may be formed of a fluororesin such as Teflon.

Referring to FIGS. 1 to 8, the power management apparatus 1 according to the present invention may include a controller 9.

The control unit 9 controls the first supply fan 71 and the second supply fan 72. [ The controller 9 may be installed inside the main body 2. The controller 9 may be installed outside the main body 2.

The controller 9 controls the first supply fan 71 and the second supply fan 72 in accordance with the operation of the first power conversion unit 100 and the second power conversion unit 200, .

For example, when the first power conversion unit 100 is activated, the controller 9 can control the first supply fan 71 to operate only the first supply fan 71. In this case, the controller 9 may control the second supply fan 72 so that the second supply fan 72 stops. The controller 9 controls the first power converter 100 to operate only the first power converter 100 when the output command value received in the battery energy storage system is a value that can be satisfied even if only the first power converter 100 is operated, And may control the conversion unit 100.

For example, when the second power conversion unit 200 is activated, the controller 9 may control the second supply fan 72 to operate only the second supply fan 72. In this case, the controller 9 may control the first supply fan 71 so that the first supply fan 71 stops. The control unit 9 controls the second power conversion unit 200 to operate only the second power conversion unit 200 when the output command value is a value that can be satisfied even when the second power conversion unit 200 is operated only. Control.

Accordingly, the power management apparatus 1 according to the present invention can increase the use time of the batteries installed in the battery management apparatus by reducing power consumption. Further, the power management apparatus 1 according to the present invention can reduce the installation cost of the batteries installed in the battery management apparatus, thereby reducing the material cost and the operating cost. Specifically, it is as follows.

First, when the output command value is always distributed to the first power conversion unit 100 and the second power conversion unit 200, the first power conversion unit 100, the second power conversion unit 200, , The first supply fan (71) and the second supply fan (72) always operate together, so that the power consumption is increased. In addition, when power consumption is provided from the batteries installed in the battery management device, the installation capacity of the batteries installed in the battery management device must be increased, so that the material cost and the operation cost increase.

Next, when at least one of the first power conversion unit 100 and the second power conversion unit 200 is selectively operated according to the output command value, the power management apparatus 1 according to the present invention is configured to control the first Only a part of the power conversion unit 100, the second power conversion unit 200, the first supply fan 71, and the second supply fan 72 can operate, thereby reducing power consumption. Accordingly, even when the power management apparatus 1 according to the present invention receives power consumption from the batteries installed in the battery management apparatus, it reduces the installation capacity of the batteries installed in the battery management apparatus, thereby reducing the material cost and the operation cost .

The control unit 9 may include an identification module 91 (shown in FIG. 8) and a control module 92 (shown in FIG. 8).

The confirmation module 91 confirms whether the first power converter 100 is in operation. The confirmation module 91 can confirm whether the first power converter 100 is in operation by receiving the operation information about whether the first power converter 100 is in operation. The confirmation module 91 confirms whether the second power converter 200 is in operation. The confirmation module 91 can confirm whether or not the second power converter 200 is in operation by receiving the operation information regarding whether the second power converter 100 is in operation.

The control module 92 controls the first supply fan 71 and the second supply fan 72 according to whether the first power conversion unit 100 and the second power conversion unit 200 are operated, . The control module 92 can operate the first supply fan 71 when the confirmation module 91 confirms that the first power conversion part 100 is operating. The control module 92 can operate the second supply fan 72 when the confirmation module 91 confirms that the second power conversion part 200 is operating.

When the first power conversion section 100 is operated, the control module 92 controls the rotation speed of the first supply fan 71 and the rotation speed of the first power conversion section 100 according to the internal temperature of the first power conversion section 100, The temperature of the cold air discharged from the heat exchanger 5 can be adjusted. The internal temperature of the first power conversion unit 100 may be obtained by the first measurement unit 160 (shown in FIG. 8).

The first measurement unit 160 may measure the internal temperature of the first power conversion unit 100 and then provide the measured temperature value to the control unit 9. [ The first measuring unit 160 may be coupled to the first inverter 140. The first measurement unit 160 may indirectly measure the internal temperature of the first power conversion unit 100 by measuring the temperature of the first inverter 140. The first measuring unit 160 may be coupled to an IGBT heat sink, which is a heating element of the first inverter 140. The first measurement unit 160 may be coupled to the first filter 150. The first measurement unit 160 may indirectly measure the internal temperature of the first power conversion unit 100 by measuring the temperature of the first filter 150. The first measuring unit 160 may be coupled to the core of the filter reactor of the first filter 150. When the first inverter 140 and the first filter 150 are located in separate spaces, the first power conversion unit 100 may be provided with a plurality of first measurement units 160 .

The control module 92 controls at least one of the rotational speed of the first supply fan 71 and the temperature of the cool air discharged by the controller 5 according to the temperature measured by the first measuring unit 160 So that the internal temperature of the first power conversion unit 100 can be adjusted. The control module 92 adjusts the rotational speed of the first supply fan 71 to adjust the flow rate of cool air supplied to the first power converter 100 so that the first power converter 100 ) Can be adjusted. The control module 92 adjusts the temperature of the cool air discharged from the controller 5 to adjust the temperature of cool air supplied to the first power converter 100 so that the first power converter 100 can be adjusted.

Accordingly, the power management apparatus 1 according to the present invention is configured such that the interior of the first power conversion unit 100 is cooled down to a temperature lower than a predetermined reference temperature, thereby unnecessarily consuming power, Can be prevented. In addition, the control module 92 prevents the interior of the first power conversion unit 100 from being maintained at a temperature higher than the reference temperature, thereby preventing the performance of the first power conversion unit 100 from being deteriorated can do. The reference temperature may be preset by a user in a temperature range in which the first power converter 100 can operate normally. The control module 92 adjusts the internal temperature of the first power conversion unit 100 based on a temperature value that is much different from the reference temperature among the temperature values acquired by the first measurement units 160 .

The control module 92 controls the rotation speed of the second supply fan 72 and the rotation speed of the second supply fan 72 in accordance with the internal temperature of the second power conversion unit 200 when the second power conversion unit 200 is operated, The temperature of the cold air discharged from the heat exchanger 5 can be adjusted. The internal temperature of the second power conversion unit 200 may be obtained by the second measurement unit 260 (shown in FIG. 8).

The second measurement unit 260 may measure the internal temperature of the second power conversion unit 200 and then provide the measured temperature value to the control unit 9. [ The second measuring unit 260 may be coupled to the second inverter 240. The second measurement unit 260 may indirectly measure the internal temperature of the second power conversion unit 200 by measuring the temperature of the second inverter 240. The second measuring unit 260 may be coupled to an IGBT heat sink, which is a heating element of the second inverter 240. The second measuring unit 260 may be coupled to the second filter 250. The second measurement unit 260 can indirectly measure the internal temperature of the second power conversion unit 200 by measuring the temperature of the second filter 250. The second measuring unit 260 may be coupled to the core of the filter reactor of the second filter 250. When the second inverter 240 and the second filter 250 are located in different spaces, the second power converter 200 may be provided with a plurality of second measuring units 260 .

The control module 92 controls at least one of the rotational speed of the second supply fan 72 and the temperature of the cool air discharged by the controller 5 according to the temperature measured by the second measuring unit 260 So that the internal temperature of the second power conversion unit 200 can be adjusted. The control module 92 adjusts the rotational speed of the second supply fan 72 to adjust the flow rate of cool air supplied to the inside of the second power converter 200 so that the second power converter 200 ) Can be adjusted. The control module 92 adjusts the temperature of the cool air discharged from the controller 5 to adjust the temperature of cool air supplied to the inside of the second power converter 200, 200 can be adjusted.

Accordingly, the power management apparatus 1 according to the present invention is configured such that the interior of the second power conversion unit 200 is cooled to a temperature lower than a preset reference temperature, thereby unnecessarily consuming power, Can be prevented. In addition, the control module 92 prevents the interior of the second power converter 200 from being maintained at a temperature higher than the reference temperature, thereby preventing the performance of the second power converter 200 from degrading can do. The reference temperature may be set by a user in a temperature range in which the second power converter 200 can operate normally. The control module 92 adjusts the internal temperature of the second power conversion unit 200 based on a temperature value that is much different from the reference temperature among the temperature values acquired by the second measurement units 260 .

The control unit 9 may include a comparison module 93 (shown in FIG. 9).

The comparison module 93 compares the temperature measured by the first measuring unit 160 and the reference temperature. The comparison module 93 may provide a comparison result to the control module 92. The control module 92 stops the controller 5 and operates the first supply fan 71 when the temperature measured by the first measuring unit 160 is lower than the reference temperature. Accordingly, the power management apparatus 1 according to the present invention can adjust the internal temperature of the first power conversion unit 100 in a natural air cooling manner. The control module 92 operates the controller 5 and the first supply fan 71 when the temperature measured by the first measuring unit 160 exceeds the reference temperature. Accordingly, the power management apparatus 1 according to the present invention can adjust the internal temperature of the first power conversion unit 100 by the forced cooling method.

The comparison module 93 compares the temperature measured by the second measurement unit 260 and the reference temperature. The comparison module 93 may provide a comparison result to the control module 92. The control module 92 stops the controller 5 and operates the second supply fan 72 when the temperature measured by the second measuring unit 260 is lower than the reference temperature. Accordingly, the power management apparatus 1 according to the present invention can adjust the internal temperature of the second power conversion unit 200 in a natural air cooling manner. The control module 92 operates the controller 5 and the second supply fan 72 when the temperature measured by the second measuring unit 260 exceeds the reference temperature. Accordingly, the power management apparatus 1 according to the present invention can adjust the internal temperature of the second power conversion unit 200 by the forced air cooling method.

Hereinafter, a method of controlling a power management apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

9 is a schematic flowchart of a control method of the power management apparatus according to the present invention.

1 to 9, a control method of a power management apparatus according to the present invention is for controlling a power management apparatus used in a battery energy storage system. The control method of the power management apparatus according to the present invention can be performed using the power management apparatus 1 according to the present invention described above. The control method of the power management apparatus according to the present invention may include the following configuration.

First, a power conversion unit to be activated is selected (S100). This step (S200) can be performed by selecting a power conversion unit that operates in accordance with the output command value among the plurality of power conversion units 100 and 200. [ The step (S100) of selecting the power conversion section to be activated may be performed by the control section (9). The controller 9 may be a BCESS (BESS Control Unit). When the power management apparatus 1 includes the first power conversion unit 100 and the second power conversion unit 200, 9 may select at least one of the first power conversion unit 100 and the second power conversion unit 200 according to the output command value.

Next, the temperature of the selected power conversion unit is measured (S200). This step (S200) can be performed by measuring the temperature of the selected power conversion section by the measurement section. In the step S200 of measuring the temperature of the selected power conversion unit when the first power conversion unit 100 is selected in the step S100 of selecting the power conversion unit to be activated, And measuring the internal temperature of the first power conversion unit 100. [ When the second power conversion unit 200 is selected in the step S100 of selecting the power conversion unit to be activated, the step S200 of measuring the temperature of the selected power conversion unit is performed by the second measurement unit 260, And measuring the internal temperature of the second power converter 200. [

Next, it is determined whether the measured temperature exceeds the reference temperature (S300). The process (S300) may be performed by comparing the measured temperature and the reference temperature by the controller (9). The step of determining whether the measured temperature exceeds the reference temperature (S300) may be performed by the comparison module (93).

Next, if the measured temperature is higher than the reference temperature, the selected power conversion unit is forcibly cooled (S400). This step S400 may be performed by the control unit 9 operating both the control unit 5 and the supply fan to forcedly cool the selected power conversion unit. As the step S400 is performed, the cool air generated by the controller 5 may be supplied to the selected power converter by being moved by the supply fan.

The step S400 of forcibly cooling the selected power conversion section may include a step of selecting a supply fan, and a step of operating the selected supply fan and the regulating section.

The process of selecting the supply fan may be performed by the control unit 9 selecting a supply fan capable of forcibly cooling the power conversion unit selected from the plurality of supply fans. For example, when the first power conversion unit 100 is selected, the process of selecting the supply fan may be performed by selecting the first supply fan 71. For example, when the second power conversion unit 200 is selected, the process of selecting the supply fan may be performed by selecting the second supply fan 72.

The operation of operating the selected supply fan and the regulating unit may be performed by operating both the selected supply fan and the regulating unit 5 by the control unit 9. [

Next, if the measured temperature is lower than the reference temperature, the selected power conversion unit is air-cooled (S500). This step S500 may be performed by the control unit 9 stopping the control unit 5 and operating the supply fan. As the process (S400) is performed, the room temperature gas without the cool air generated by the controller (5) can be supplied to the selected power conversion unit by being moved by the supply fan.

Accordingly, the control method of the power management apparatus according to the present invention controls the power management apparatus 1 in a control mode capable of reducing power consumption when the measured temperature is equal to or lower than the reference temperature, The use time of the batteries can be increased. Further, the control method of the power management apparatus according to the present invention can reduce the installation cost of the batteries installed in the battery management apparatus, thereby reducing the material cost and the operating cost.

Referring to FIGS. 1 to 9, the step S100 of selecting the power converter to be operated may include the following configuration.

First, the first power converter is set (S110). The process (S110) may be performed by the control unit 9 setting the power conversion unit having the shortest operation time among the power conversion units as the first order. Accordingly, the power management self-control method according to the present invention can reduce the power consumption by activating only a part of the power conversion units, and reduce the difference in the operation time between the power conversion units.

Next, the rated output and the output command value of the power conversion unit set to the first order are compared (S120). This step (S120) may be performed by comparing the rated output and the output command value of the power conversion section set to the first order by the control section (9). The step of comparing the rated output and the output command value may be performed by the comparison module 93.

Next, if the rated output of the power conversion unit set to the first order is greater than or equal to the output command value, the power conversion unit set to the first order is selected as the power conversion unit to be operated (S130). The process (S130) may be performed by the control unit 9 selecting a power conversion unit to operate the power conversion unit set to the first rank according to the comparison result.

Next, when the rated output of the power conversion unit set to the first order is less than the output command value, the power conversion unit is selected as the power conversion unit to be operated (S140). The process (S140) may be performed by selecting the power conversion unit to be operated by the control unit 9 in such a manner that the sum of the rated outputs of the power conversion units according to the comparison result is equal to or greater than the output reference value.

A step (S200) of measuring a temperature of the selected power conversion unit when a plurality of power conversion units to be operated are selected; a step (S300) of determining whether the measured temperature exceeds the reference temperature (S300) The step of air cooling (S400) and the step of spontaneously cooling the selected power converter (S500) may be performed for each of the selected power converters.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It will be clear to those who have knowledge.

1: power management device 2: main body
3: Support part 4:
5: regulating part 6:
8: Separation unit 9: Control unit
100: first power conversion unit 200: second power conversion unit

Claims (12)

A first power conversion unit for managing the power of the batteries;
A second power conversion unit installed apart from the first power conversion unit;
A second power converter for converting the heat generated by the first power converter and the heat generated by the second power converter into a heat to cool the inside of the first power converter and the inside of the second power converter; And
A first supply fan for moving the cool air supplied from the regulator into the first power converter;
A second supply fan for moving the cool air supplied from the controller to the inside of the second power converter; And
A movement path of the cool air supplied by the first supply fan and a movement path of the heat generated by the first power conversion unit and a movement path of the cool air supplied by the second supply fan, And a separation unit provided between the first power conversion unit and the second power conversion unit to separate the movement path of the heat generated by the first power conversion unit and the second power conversion unit. The method according to claim 1,
And a main body provided with the first power conversion unit and the second power conversion unit,
Wherein the body includes a ceiling spaced apart from the first power conversion portion and the second power conversion portion, and a floor spaced from the ceiling,
Wherein the separating unit is installed on the floor so as not to block the ceiling passage formed between the first power conversion unit and the ceiling and between the second power conversion unit and the ceiling. . The method according to claim 1,
Wherein the first power conversion unit and the second power conversion unit are provided in the main body and the second power conversion unit, And a control unit for selectively activating the fan,
The control unit stops the second supply fan and operates the first supply fan when the second power conversion unit is stopped and the first power conversion unit is activated,
The control unit recovers the heat generated by the first power conversion unit through the ceiling passage formed between the first power conversion unit and the ceiling of the main body and between the second power conversion unit and the ceiling of the main body To the power management device. The method according to claim 1,
A main body provided with the first power conversion section and the second power conversion section, and a support part installed apart from the bottom of the main body,
Wherein the first supply fan moves the cool air along a first bottom passageway formed between the support and the bottom of the main body,
The second supply fan moves the cool air along a second bottom passage formed between the support and the bottom of the main body,
Wherein the separating portion is provided in contact with each of the bottom portion of the support portion and the main body to partition the first bottom passage and the second bottom passage. The method according to claim 1,
And a main body provided with the first power conversion unit and the second power conversion unit,
The body includes a first sidewall and a second sidewall facing each other,
Wherein the first power conversion unit is installed apart from the first sidewall and the second sidewall,
Wherein the second power conversion unit is installed apart from the first power conversion unit and the second sidewall,
And the regulator recovers the heat through a first side wall passage formed between the first power conversion portion and the first side wall, and a second side wall passage formed between the second power conversion portion and the second side wall. Power management device. The method according to claim 1,
A main body provided with the first power conversion portion, a support portion spaced from the bottom of the main body, and a vent portion provided in the support portion,
And the ventilation portion is installed to be connected to the inside of the first power conversion portion so that the cool air moving along the bottom passage formed between the support portion and the bottom of the main body passes through the support portion and is supplied into the first power conversion portion To the power management device. The method according to claim 1,
A main body provided with the first power conversion portion, a support portion spaced from the bottom of the main body, and a vent portion provided in the support portion,
Wherein the vent portion includes a first vent hole for passing cool air so that chilled air moving along a bottom passage formed between the support portion and the bottom of the main body is supplied to the inside of the first power conversion portion,
Wherein the first power conversion unit includes a first passage hole formed on a lower surface thereof so as to be connected to the first vent hole. The method according to claim 1,
And a cutoff portion for blocking the movement of the cool air supplied from the adjustment portion toward the auxiliary equipment, wherein the first power conversion portion includes a main body,
The control unit supplies cold air to a floor passage formed between the floor of the main body and the supporting unit,
Wherein the blocking portion is coupled to the body so as to contact the bottom of the body and the support, respectively. The method according to claim 1,
A controller for selectively activating the first supply fan and the second supply fan depending on whether each of the first power conversion unit and the second power conversion unit is in operation, And a first measuring unit,
Wherein the controller adjusts at least one of a rotation speed of the first supply fan and a temperature of a cool air discharged from the controller according to a temperature measured by the first measuring unit when the first power converting unit operates, Management device. The method according to claim 1,
A controller for selectively activating the first supply fan and the second supply fan depending on whether each of the first power conversion unit and the second power conversion unit is in operation, And a first measuring unit,
Wherein the control unit includes a control module for stopping the control unit and operating the first supply fan when the temperature measured by the first measurement unit is lower than the reference temperature when the first power conversion unit is in operation Management device. Selecting a power conversion unit to be operated according to an output command value among the plurality of power conversion units;
Measuring a temperature of the selected power conversion unit;
Determining whether the measured temperature exceeds a predetermined reference temperature;
If the measured temperature is higher than the reference temperature, activating a regulator for generating cold air and a supply fan for moving the generated cold air to forcibly air-cool the selected power converter; And
And stopping the control unit and operating the supply fan to naturally cool the selected power switching unit if the measured temperature is below the reference temperature. 12. The method of claim 11, wherein the step of selecting the power converter to be operated comprises:
Setting a power conversion unit having the shortest operation time among the power conversion units as a first rank;
Comparing the rated output of the power conversion unit set to the first order and the output command value; And
And selecting the power converter as a first power converter to be operated if the rated output of the power converter set to the first order is greater than or equal to the output command value.

Images