KR101654438B1 - Energy Storage System Installed Solar Cell - Google Patents

Abstract

A technology relating to an energy storage device provided with a solar cell is disclosed. The energy storage device provided with a solar cell according to an embodiment of the present invention includes a power conversion unit for managing power of a battery, an air conditioning unit for cooling the power conversion unit, a power conversion unit, And a solar cell installed on an upper surface of the main body to produce electric power for use in an energy storage device, wherein the main body includes a suction passage for passing a gas sucked into the air conditioning portion, And a discharge passage.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an energy storage device,

The present invention relates to an energy storage device using power produced by a solar cell.

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 an energy storage system (ESS) which stores surplus power of a system in a battery or supplies power of a system with insufficient power of the system.

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

Such energy storage devices include a Power Conditioning System (PCS), and a Battery Conditioning System (BCS).

The power regulator has a function of managing power of the battery installed in the battery regulator such as performing power conversion (AC / DC) between the system and the battery regulator.

The battery control unit is responsible for managing the state of the battery. The battery installed in the battery regulating device is discharged (discharged) to supply power to the system. The battery installed in the battery regulating device is charged (charged) using electric power supplied from the system.

An energy storage device including such a power regulator and a battery regulator was operated using electric power provided from the system. Accordingly, there is a problem in that the energy storage system according to the prior art has a limitation in improving the system efficiency as power of the system is consumed in the operation process. In addition, since the energy storage system according to the related art can not be operated when the system is not operated normally, there is a problem that reliability as a power supply source is lowered.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an energy storage device provided with a solar cell capable of reducing an amount of consuming power of a system in a running process.

The present invention provides an energy storage device provided with a solar cell that can be operated even when the system is not operating normally.

In order to solve the above problems, the present invention includes the following configuration.

An energy storage device equipped with a solar cell according to the present invention includes a power conversion unit for managing power of a battery; An air conditioning unit for cooling the power conversion unit; A main body in which the power conversion unit and the air conditioning unit are installed; And a solar cell installed on an upper surface of the main body to produce power for use in an energy storage device. The main body includes a suction passage for passing a gas sucked into the air conditioning portion, and a discharge passage for passing a gas discharged from the air conditioning portion.

An energy storage device equipped with a solar cell according to the present invention includes a battery control unit for storing a battery, and a battery control unit for storing power using the battery. A power regulating device including a power regulating body accommodating a power converting part for converting power, the power regulating device managing power of the battery; A solar battery installed in at least one of an upper surface of the battery adjusting body and an upper surface of the power adjusting body to produce electric power; And a control unit for activating at least one of the battery control unit and the power control unit using the power generated by the solar cell unit.

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

The present invention can reduce the amount of power consumed in the system during the operation, thereby reducing the operating cost and improving the system efficiency.

The present invention can be operated even when the system does not operate normally, thereby improving reliability as a power supply source.

1 is a schematic block diagram of an energy storage device equipped with a solar cell according to the present invention
2 is a schematic perspective view of an energy storage device equipped with a solar cell according to the present invention.
FIG. 3 is a front sectional view of the energy storage device provided with the solar cell according to the present invention,
FIG. 4 is a plan view of the energy storage device equipped with the solar cell according to the present invention, with reference to FIG. 3, line II-
FIG. 5 is a plan view of the energy storage device equipped with the solar cell according to the present invention with reference to the line III-III in FIG. 3
6 is a schematic perspective view of an energy storage device equipped with a solar cell according to the present invention.
FIG. 7 is a front sectional view of the energy storage device provided with the solar cell according to the present invention, with reference to line IV-IV in FIG. 6
8 is a plan view of the energy storage device equipped with the solar cell according to the present invention, which is based on the line V-V in Fig. 7
FIG. 9 is a plan view of the energy storage device equipped with the solar cell according to the present invention, with reference to FIG.
10 to 12 are schematic configuration diagrams of an energy storage device according to the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a power control apparatus equipped with a solar cell according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic block diagram of an energy storage device equipped with a solar cell according to the present invention.

Referring to FIG. 1, an energy storage system (ESS) 1 equipped with a solar cell according to an embodiment of the present invention includes a surplus power generated at night, a surplus power generated from a renewable energy source such as a wind power installed at a remote place, And supplies the power stored in the battery to the system during a peak load or a system accident.

The energy storage device 1 equipped with the solar cell according to the present invention includes a main body in which at least one of the power conversion unit 110 and the battery 20 is installed and a solar battery unit 300 installed in the main body. The solar cell unit 300 produces electric power for use in the energy storage device 1 equipped with the solar cell according to the present invention.

Accordingly, the energy storage device 1 equipped with the solar cell according to the present invention can reduce the amount of power consumed in the system G during the operation, thereby reducing the operating cost. In the energy storage device 1 according to the present invention, even if power can not be supplied from the system G due to the system G not operating normally, And can be operated using electric power. Therefore, the energy storage device 1 according to the present invention can improve reliability as a power supply source.

The energy storage device 1 equipped with the solar cell according to the present invention may include a power conditioning system (PCS) 100 for managing the power of the battery 20. An embodiment in which the energy storage device 1 equipped with the solar cell according to the present invention includes the power control device 100 will be described as follows.

FIG. 2 is a schematic perspective view of an energy storage device equipped with a solar cell according to the present invention, FIG. 3 is a front sectional view of the energy storage device equipped with the solar cell according to the present invention, 3 is a plan sectional view of an energy storage device equipped with a solar cell according to the present invention, and FIG. 5 is a sectional view taken along the line III-III of FIG. 3 for an energy storage device equipped with a solar cell according to the present invention. As shown in FIG.

The energy storage device 1 in which the solar cell according to the present invention is installed includes the power control device 100, An embodiment including the apparatus 100 will be described as a power control apparatus 100 provided with a solar cell according to the present invention.

1 to 5, a power control apparatus 100 equipped with a solar cell according to the present invention includes a power conversion (AC / DC) converter (not shown) between the system G and a battery conditioning system DC) and controls the power of the batteries 20 installed in the battery regulating apparatus 200. [

The power control apparatus 100 provided with the solar cell according to the present invention includes a power conversion unit 110, an air conditioning unit 120, a solar cell 130, and a power control main body 140. Here, the power control body 140 corresponds to the main body described above.

The power conversion unit 110 manages the power of the batteries 20. The power conversion unit 110 mainly performs power conversion. The power converter 110 converts the DC power supplied from the battery controller 200 into AC power. The power conversion unit 110 converts AC power supplied from a renewable energy source into DC power.

The power conversion unit 110 is installed inside the power control body 140. A plurality of the power conversion units 110 may be installed inside the power control body 140. In this case, the power conversion units 110 are disposed adjacent to each other along one row to form a power conversion group. In FIG. 2, three power conversion units 110 belonging to the power conversion group are installed along one row, but the present invention is not limited thereto. The power conversion unit 110 included in the power conversion group includes one column One or more of which may be installed. In the power control body 140, the power conversion groups may be arranged in different rows, and a plurality of power conversion groups may be installed. In FIG. 1, two power conversion groups are shown to be installed in two rows. However, the present invention is not limited thereto, and one or more power conversion groups may be installed in the power regulation body 140.

Referring to FIGS. 1 to 5, the air conditioning unit 120 supplies cooling air for cooling the power conversion unit 110. The air conditioning unit 120 recovers heat generated by the power conversion unit 110. That is, the air conditioning unit 120 generates and supplies cool air to recover the heat. Accordingly, the air conditioning unit 120 may dissipate heat generated during the operation of the power conversion unit 110. [ In addition, the air conditioning unit 120 may adjust the humidity of the space in which the power conversion unit 110 is installed.

The air conditioning unit 120 may include a blower (not shown) for generating a blowing force for supplying cold air. The heat generated by the power conversion unit 110 may be recovered to the air conditioning unit 120 by a negative pressure generated by the blower. The air conditioning unit 120 may include a cooling unit (not shown) that cools the recovered heat to convert it to cool air again.

The air conditioning unit 120 is installed inside the power control body 140. The air conditioning unit 120 sucks gas from the outside of the power regulating body 140 and discharges the gas to the outside of the power regulating main body 140 in the process of cooling the power converting unit 110.

Referring to FIGS. 1 to 5, the solar cell 130 converts solar light into electric energy to produce electric power. For example, the solar cell 130 can generate power using a P-type semiconductor and an N-type semiconductor.

The solar cell 130 is installed in the power control body 140. The solar cell 130 may be installed in the power regulation body 140 in a module or array form in which a plurality of battery cells are connected in series or in parallel. The solar cell 130 produces electric power to be used in the energy storage device 1. For example, the power produced by the solar cell 130 may be used as a control power source in the energy storage device 1.

Accordingly, the power control apparatus 100 equipped with the solar cell according to the present invention is configured to be able to supply power to the energy storage device 1, so that in the process of operating the energy storage device 1, the system G The amount of power consumed by the power source can be reduced. Accordingly, the power control apparatus 100 equipped with the solar cell according to the present invention can reduce the operating cost.

When the energy storage device 1 can not receive power from the system G due to the fact that the system G does not operate normally, the power control apparatus 100 equipped with the solar cell according to the present invention The energy storage device 1 can be operated. Therefore, the power regulating apparatus 100 equipped with the solar cell according to the present invention can improve the reliability of the energy storage device 1 as a power supply source.

Referring to FIGS. 1 to 5, the power control body 140 supports the power conversion unit 110, the air conditioning unit 120, and the solar cell 130. The power conversion unit 110 and the air conditioning unit 120 are installed inside the power control body 140. Inside the power control main body 140, a fire fighting equipment for suppressing a fire, a transformer for boosting and downpressing, and a switchgear for blocking and inputting the system may be further installed. The solar cell 130 is installed outside the power control body 140.

The power control body 140 includes a top surface 141 on which the solar cell 130 is installed. The top surface 141 forms the top of the power conditioning body 140. The top surface 141 corresponds to the outer surface at the top of the power conditioning body 140. Accordingly, the power regulator 100 equipped with the solar cell according to the present invention is installed in the upper surface 141 where the incident amount of sunlight is larger than that of the other portion of the power control main body 140, It is possible to increase the production amount to electric power.

The power control body 140 includes a first side wall 142 (shown in FIG. 4) and a second side wall 143 (shown in FIG. 4) connected to the upper surface 141 on which the solar cell 130 is installed, As shown in FIG.

The first side wall 142 is one of a plurality of side walls of the power regulating body 140. The first side wall 142 is one of two sidewalls forming a long side when the power control body 140 is formed in a rectangular shape. The first side wall 142 may have a rectangular plate shape. The first side wall 142 may be disposed so that the power conversion unit 110 is in contact with the first side wall 142. Although not shown, the power conversion unit 110 may be installed to be spaced apart from the first side wall 142 by a predetermined distance.

The second side wall 143 is one of a plurality of side walls of the power regulating body 140. The second side wall 143 is one of two long side walls when the power control body 140 is formed in a rectangular shape. The second side wall 143 is spaced from the first side wall 142 by a predetermined distance. The second side wall 143 may have a rectangular plate shape. And the power conversion unit 110 may be installed on the second side wall 143 to be in contact with the power conversion unit 110. Although not shown, the power conversion unit 110 may be spaced apart from the second side wall 143 by a predetermined distance.

The power conditioning body 140 includes a bottom 144 (shown in FIG. 3) and a ceiling 145 (shown in FIG. 3) coupled to the first and second sidewalls 142 and 143, respectively can do.

The bottom 144 forms the lower portion of the power conditioning body 140. The bottom 144 is coupled to the first sidewall 142 and the other to the second sidewall 143 to close the bottom of the power regulating body 140. The bottom 144 may be formed in a rectangular plate shape.

The ceiling 145 forms the top of the power conditioning body 140. The ceiling 145 corresponds to the inner surface at the top of the power conditioning body 140. The ceiling 145 is coupled to the first side wall 142 at one side and coupled to the second side wall 143 at the other side to close the upper portion of the power regulating body 140. The ceiling 145 is installed at a predetermined distance from the bottom 144. The ceiling 145 is installed at a height higher than the floor 144. The ceiling 145 and the bottom 144 may be spaced apart from each other by a distance greater than the height of each of the power conversion units 110. The ceiling 145 may be formed in a rectangular plate shape.

The power conditioning body 140 includes a third side wall 146 (shown in FIG. 4) and a fourth side wall 147 (shown in FIG. 4) coupled to the first side wall 142 and the second side wall 143, Lt; / RTI >

The third side wall 146 is one of a plurality of side walls of the power regulating body 140. The third side wall 146 is one of two short side sidewalls when the power control main body 140 is formed in a rectangular shape. The third side wall 146 may have a rectangular plate shape.

The fourth side wall 147 is one of a plurality of side walls of the power regulating body 140. The fourth side wall 147 is one of two short side walls when the power control body 140 is formed in a rectangular shape. The fourth side wall 147 is spaced from the third side wall 146 by a predetermined distance. The fourth side wall 147 may be formed in a rectangular plate shape.

The power conditioning body 140 may include at least one of the first side wall 142, the second side wall 143, the ceiling 145, the bottom 144, the third side wall 146, Are coupled to each other, the inside can be closed. In this case, the power regulating body 140 may be formed in an oblong shape with an empty interior.

The power control body 140 may be implemented as a container for cargo transportation. Accordingly, the power regulating apparatus 100 equipped with the solar cell according to the present invention can be loaded and unloaded to the transportation means by means of the existing transportation facilities for cargo-working the transportation means such as a ship, an airplane, . Therefore, since the power control apparatus 100 equipped with the solar cell according to the present invention does not need to newly provide a separate transportation facility, it is possible to reduce the construction cost for newly providing the transportation facility. Further, the power control apparatus 100 equipped with the solar cell according to the present invention can be installed and used in a state of transportation, thereby improving the ease of transportation and installation. The power conditioning body 140 may be a 20 FT container or a 40 FT container.

1-5, the power conditioning body 140 may include a suction passageway 148 (shown in FIG. 4) and an exhaust passageway 149 (shown in FIG. 4).

The suction passage 148 allows gas to be sucked into the air conditioning unit 120 to pass therethrough. The discharge passage 149 allows gas discharged from the air conditioning unit 120 to pass therethrough. Accordingly, the air conditioning unit 120 installed inside the power control body 140 may be connected to the outside of the power control body 140 through the intake passage 148 in the process of cooling the power conversion unit 110 And discharge the gas to the outside of the power regulating body 140 through the discharge passage 149. [

The suction passage 148 and the discharge passage 149 may be provided on the surface of the power control body 140 other than the top surface 141 on which the solar cell 130 is installed. Accordingly, the power control apparatus 100 equipped with the solar cell according to the present invention can increase the installation area where the solar cell 130 can be installed on the upper surface 141 of the power control main body 140. Accordingly, the power regulator 100 equipped with the solar cell according to the present invention can increase the production amount of electric power by increasing the area of sunlight incident on the solar cell 130.

The suction passage 148 and the discharge passage 149 may be installed on different side walls 142, 143, 146 and 147 of the power control body 140. For example, when the air conditioning unit 120 is installed on the side of the third side wall 146, the suction passage 148 may be installed on the first side wall 142. In this case, the discharge passage 149 may be installed in the third side wall 146. The suction passage 148 may be provided in the third side wall 146 and the discharge passage 149 may be provided in the first side wall 141.

Referring to FIGS. 1 to 5, the power control apparatus 100 equipped with the solar cell according to the present invention may include a separator 150 for separating the moving path of the cold air and the moving path of the hot air.

The separating unit 150 separates the moving path of the cool air supplied from the air conditioning unit 120 and the moving path of the heat recovered to the air conditioning unit 120. The moving path of the cool air is a passage through which cool air discharged from the air conditioning unit 120 moves to cool the power conversion unit 110. The heat transfer passage is a passage through which the heat generated by the power conversion unit 110 is transferred to be recovered to the air conditioning unit 120. The separating unit 150 separates the moving path of the cool air for cooling the power converting unit 110 and the moving path of the heat generated by the power converting unit 110. Accordingly, the separator 150 can prevent the cold air and the hot air from being mixed with each other. Accordingly, the power control apparatus 100 equipped with the solar cell according to the present invention can improve the cooling performance for cooling the power conversion unit 110. [ In addition, the power control apparatus 100 equipped with the solar cell according to the present invention reduces the temperature deviation between the power conversion units 110, thereby reducing the risk of the power conversion unit 110 being damaged or broken due to overheating .

The separating unit 150 may include a first separating member 151.

The first separating member 151 separates a cooling air path (CP) and a first hot air passage (HP1, shown in FIG. 3). The cool air inflow path (CP) is a path through which cool air provided from the air conditioning unit (120) flows. The cool air inflow path CP is located between the power conversion unit 110 and the second side wall 143. When two power conversion groups are formed in the power control body 140 in two rows, the cool air inlet CP is located between the power conversion groups. The first hot air passage HP1 is located between the upper surface of the power conversion unit 110 and the ceiling 145 of the power control body 140. [ The first heat exchanger HP1 is a heat path for heat transfer. The heat generated by the power conversion unit 110 is discharged to the first hot air passage HP1 and then travels along the first hot air passage HP1 and is recovered to the air conditioning unit 120. [ The first hot air passage HP1 is located between the cold air inflow passage CP and the first side wall 142.

The first separating member 151 is installed in the power regulating body 140 to block the upper surface of the power conversion unit 110 and the ceiling 145 of the power regulating body 140. Accordingly, the first separating member 151 can separate the moving path of the heat generated by the power converting unit 110 and the moving path of the cooling air for cooling the power converting unit 110. The first separating member 151 may be installed such that an upper surface of the first separating member 151 contacts the ceiling 145 of the power regulating body 140 and a bottom surface thereof contacts the upper surface of the power converting unit 110. The first separating member 151 may be spaced apart from the first side wall 142 by a predetermined distance. The first separating member 151 may be formed in a rectangular plate as a whole. The first separating member 151 may be formed of a material having excellent heat insulating performance and rigidity. For example, the first separating member 151 may be formed of a fluororesin such as Teflon.

When two power conversion groups are formed in the power control body 140 in two rows, the separating unit 150 may include a second separating member 152.

The second separating member 152 separates the cold air inflow passage CP and the second hot air passage HP2 (shown in FIG. 3). The second hot air passage HP2 is located between the upper surface of the power conversion unit 110 belonging to the power conversion group disposed on the second side wall 143 side and the ceiling 145 of the power regulation body 140. [ In this case, the first hot air passage HP1 is located between the upper surface of the power conversion unit 110 belonging to the power conversion group disposed on the first side wall 142 side and the ceiling 145 of the power control unit 140 Located. The heat generated by the power conversion unit 110 is discharged to the second hot air passage HP2 and then travels along the second hot air passage HP2 and is recovered to the air conditioning unit 120. [ The second hot air passage HP2 is located between the cold air inflow passage CP and the second side wall 143. [

The second separating member 152 is installed in the power regulating body 140 to block the upper surface of the power conversion unit 110 and the ceiling 145 of the power regulating body 140. Accordingly, the second separating member 152 can separate the moving path of the heat generated by the power converting unit 110 and the moving path of the cooling air for cooling the power converting unit 110. The second separating member 152 may be installed such that its upper surface is in contact with the ceiling 145 of the power regulating body 140 and its bottom surface is in contact with the upper surface of the power converting unit 110. The second separating member 152 may be spaced apart from the second side wall 143 by a predetermined distance. The second separating member 152 may be formed in a rectangular plate as a whole. The second separating member 152 may be formed of a material having excellent heat insulating performance and rigidity. For example, the second separating member 152 may be formed of a fluororesin such as Teflon.

4, the separating unit 150 includes the first separating member 151 and the second separating member 152, but the separating unit 150 is not limited thereto, Or may include three or more separating members depending on the form in which they are disposed. In this case, the separating members are installed in the power regulating body 140 so as to block the upper surface of each of the power conversion units 110 and the ceiling 145 of the power regulating body 140. Accordingly, the separation members prevent the cool air and the heat from being mixed with each other, thereby improving the cooling performance for cooling the power conversion unit 110.

1 to 5, a power regulator 100 with a solar cell according to the present invention can include a support 160 (shown in FIG. 3) and a vent 170 (shown in FIG. 3) have.

The support part 160 supports the power conversion part 110. The support 160 is installed in the power conditioning body 140 to be spaced apart from the bottom 144 of the power conditioning body 140 (shown in FIG. 3). Accordingly, the support portion 160 is positioned at a predetermined distance from the bottom 144 of the power control body 140. The power conversion unit 110 is supported by the support unit 160 at a predetermined distance from the bottom 144 of the power control unit 140. The support part 160 may support the air conditioning part 120 such that the air conditioning part 120 is positioned at a predetermined distance from the floor 144. The support portion 160 may have a rectangular plate shape.

The support portion 160 defines the interior of the power control body 140. The support part 160 defines the cool air inflow path CP and the bottom path BP. The bottom passageway (BP) is located between the bottom 144 of the power conditioning body 140 and the support 160. The air conditioning unit 120 supplies cold air for cooling the power conversion unit 110 to the floor passage BP. The cool air moves along the bottom passageway (BP) and then ascends and is supplied to the cool air inflow path (CP) through the vent portion (170).

The ventilation part 170 is coupled to the support part 160 such that chilled air moving along the floor passage BP is supplied to the power conversion part 110. [ The ventilation part 170 may function as a passage through which cool air moving along the floor passage BP is supplied to the cool air inflow path CP. The cool air moving along the bottom passage BP may be supplied to the cool air inflow passage CP through the support portion 160 through the vent portion 170. The ventilation part 170 may include a plurality of ventilation holes (not shown) through which cool air passes.

The vent portion 170 is coupled to the support portion 160 so as to be positioned between the power conversion groups when two power conversion groups are formed in the power control body 140 in two rows. The cool air supplied to the floor passage BP by the air conditioning unit 120 moves along the floor passage BP and then ascends and flows into the cool air inflow passage CP through the air passage unit 170. [ And may be supplied to the power conversion unit 110 by being dispersed toward the power conversion groups. The power control apparatus 100 equipped with the solar cell according to the present invention may include a plurality of the vent portions 170. The vent portions 170 may be coupled to the support portion 160 so as to be spaced apart from each other. Although not shown, the vent portion 170 may be coupled to the support portion 160 to be positioned below the power conversion portion 110.

Referring to FIGS. 1 to 5, a power regulator 100 equipped with a solar cell according to the present invention may include a shutoff unit 180 (shown in FIG. 4).

The blocking unit 180 blocks the upper surface of the air conditioning unit 120 and the ceiling 145 of the power control body 140. Accordingly, the blocking unit 180 can prevent the cool air introduced into the cool air inflow path CP from being immediately recovered to the air conditioning unit 120 without cooling the power conversion unit 110.

Therefore, the shutoff unit 180 can prevent a shortage of cool air for cooling the power conversion unit 110, thereby improving cooling efficiency for cooling the power conversion unit 110. The blocking unit 180 may prevent the suction force generated by the air conditioning unit 120 from being directly transmitted to the cool air inflow path CP, It is possible to prevent an increase in the flow rate of the cool air relative to the portion close to the air outlet. Therefore, the cutoff unit 180 can improve the uniformity of the internal temperature of the power conversion units 110 by reducing a difference in flow rate of cool air partially in the cool air inflow path CP.

The cut-off portion 180 may be installed such that its upper surface is in contact with the ceiling 145 of the power control body 140 and its bottom surface is in contact with the upper surface of the air-conditioning portion 120. The blocking portion 180 may be spaced a predetermined distance from the third side wall 146 (shown in FIG. 4). The blocking portion 180 may be provided to be in contact with the separating members. The blocking portion 180 may be formed in a rectangular plate as a whole. The blocking portion 180 may be formed of a material having excellent heat insulating performance and rigidity. For example, the blocking portion 180 may be formed of a fluororesin such as Teflon.

Hereinafter, embodiments in which the energy storage device 1 equipped with the solar cell according to the present invention includes the battery control device 200 will be described in detail with reference to the accompanying drawings.

FIG. 6 is a schematic perspective view of an energy storage device equipped with a solar cell according to the present invention, FIG. 7 is a front sectional view taken along the line IV-IV of FIG. 6 for an energy storage device equipped with a solar cell according to the present invention, 8 is a plan sectional view based on the V-V line of FIG. 7 for an energy storage device equipped with the solar cell according to the present invention, FIG. 9 is a sectional view of the energy storage device provided with the solar cell according to the VI- VI line.

In the following description of an embodiment in which the energy storage device 1 equipped with the solar cell according to the present invention includes the battery control device 200, an energy storage device 1 equipped with a solar cell according to the present invention will be described. An embodiment including the apparatus 200 will be described as a battery control apparatus 200 provided with a solar cell according to the present invention.

Referring to FIGS. 1, 6 to 9, a battery control apparatus 200 equipped with a solar cell according to the present invention has a function of managing the state of a battery 20 for storing surplus electric power of the system G I am responsible. The battery control apparatus 200 having the solar cell according to the present invention includes a battery rack group 210, an air conditioning unit 220, a solar cell 230, and a battery control unit 240. Here, the battery adjusting body 240 corresponds to the main body described above.

The battery rack group 210 includes at least one battery rack 30 (shown in FIG. 6). The battery racks 30 each receive at least one battery 20. The battery rack group 210 is installed inside the battery adjusting body 240. A plurality of the battery racks 30 may be installed in the battery adjusting body 240. In this case, the battery racks 30 are disposed adjacent to each other along one row to form the battery rack group 210. 5, three battery racks 30 belonging to the battery rack group 210 are installed along one row. However, the present invention is not limited thereto, and the battery racks 30 belonging to the battery rack group 210 may include three battery racks 30, One or more of which may be installed along one row. In the battery adjusting body 240, the battery rack groups 210 may be formed in different rows, and a plurality of battery rack groups 210 may be installed. 1, two battery rack groups 210 are shown to be installed in two rows. However, the present invention is not limited thereto, and one or more battery rack groups 210 may be installed in the battery adjusting body 240 have.

Referring to FIGS. 1 and 6 to 9, the air conditioning unit 220 supplies cool air for cooling the battery 20. The air conditioning unit 220 recovers the heat generated by the battery 20. That is, the air conditioning unit 220 generates and supplies cold air while recovering the heat. Accordingly, the air conditioning unit 220 can dissipate heat generated during the operation of the battery 20. In addition, the air conditioning unit 220 may adjust the humidity of the space where the battery 20 is installed.

The air conditioning unit 220 may include a blower (not shown) for generating blowing power for supplying cold air. The heat generated by the battery 20 can be recovered to the air conditioning unit 220 by a negative pressure generated by the blower. The air conditioning unit 220 may include a cooling unit (not shown) that cools the recovered heat to convert it to cool air.

The air conditioning unit 220 is installed inside the battery control unit 240. The air conditioning unit 220 sucks gas from the outside of the battery adjusting body 240 and discharges the gas to the outside of the battery adjusting body 240 in the process of cooling the battery 20. [

Referring to FIGS. 1 and 6 to 9, the solar cell 230 converts solar light into electric energy to produce electric power. For example, the solar cell 230 can generate power using a P-type semiconductor and an N-type semiconductor.

The solar cell 230 is installed in the battery control unit 240. The solar cell 230 may be installed in the battery control unit 240 in the form of a module or an array in which a plurality of battery cells are connected in series or in parallel. The solar cell 230 produces electric power for use in the energy storage device 1. For example, the power produced by the solar cell 230 may be used as a control power source in the energy storage device 1.

Accordingly, the battery control apparatus 200 equipped with the solar cell according to the present invention is configured to be able to supply power to the energy storage device 1, so that the system G The amount of power consumed by the power source can be reduced. Therefore, the battery control apparatus 200 equipped with the solar cell according to the present invention can reduce the operating cost.

When the energy storage device 1 can not receive power from the system G due to the fact that the system G is not operated normally, the battery control device 200 equipped with the solar cell according to the present invention The energy storage device 1 can be operated. Therefore, the battery control apparatus 200 equipped with the solar cell according to the present invention can improve the reliability of the energy storage device 1 as a power supply source.

Referring to FIGS. 1, 6 to 9, the battery adjusting body 240 supports the battery rack group 210, the air conditioning unit 220, and the solar cell 230. The barrel tile group 210 and the air conditioning unit 220 are installed inside the battery adjusting body 240. The battery adjusting body 240 may further include a fire-fighting device for extinguishing a fire. The solar cell 230 is installed outside the battery control unit 240.

The battery adjusting body 240 includes an upper surface 241 on which the solar cell 230 is installed. The upper surface 241 forms the upper part of the battery adjusting body 240. The upper surface 241 corresponds to the upper surface of the battery adjusting body 240. Accordingly, the battery control device 200 equipped with the solar cell according to the present invention is installed in the upper surface 241 where the incident amount of sunlight is larger than the other parts of the battery control main body 240, It is possible to increase the production amount to electric power.

The battery control unit 240 includes a first side wall 242 (shown in FIG. 8) and a second side wall 243 (see FIG. 8) connected to the upper surface 141 on which the solar cell 130 is installed, As shown in FIG.

The first side wall 242 is one of a plurality of side walls of the battery control body 240. The first side wall 242 is one of two sidewalls forming a long side when the battery adjusting body 240 is formed in a rectangular shape. The first side wall 242 may be formed in a rectangular plate shape. The first sidewall 242 may be formed to contact the battery rack group 210. Although not shown, the battery rack group 210 may be spaced apart from the first side wall 242 by a predetermined distance.

The second side wall 243 is one of a plurality of side walls of the battery control body 240. The second side wall 243 is one of two long side walls when the battery adjusting body 240 is formed in a rectangular shape. The second side wall 243 is spaced a predetermined distance from the first side wall 242. The second side wall 243 may be formed in a rectangular plate shape. The second side wall 243 may be provided to contact the battery rack group 210. Although not shown, the battery rack group 210 may be spaced apart from the second side wall 243 by a predetermined distance.

The battery conditioning body 240 includes a bottom 244 (shown in FIG. 7) and a ceiling 245 (shown in FIG. 7) coupled to the first side wall 242 and the second side wall 243, respectively can do.

The bottom 244 forms the bottom of the battery conditioning body 240. The bottom 244 is coupled to the first side wall 242 at one side and coupled to the second side wall 243 at the other side to close the lower portion of the battery control body 240. The bottom 244 may be formed in a rectangular plate shape.

The ceiling (245) forms the upper part of the battery control body (240). The ceiling 245 corresponds to the inner surface of the upper portion of the battery adjusting body 240. The ceiling 245 is coupled to the first side wall 242 at one side and coupled to the second side wall 243 at the other side to close the upper portion of the battery control body 240. The ceiling 245 is installed at a predetermined distance from the floor 244. [ The ceiling (245) is installed at a height higher than the floor (244). The ceiling 245 and the bottom 244 may be spaced apart from each other by a distance greater than the height of the battery rack group 210. The ceiling 245 may be formed in a rectangular plate shape.

The battery control body 240 includes a third side wall 246 (shown in FIG. 8) and a fourth side wall 247 (shown in FIG. 8) coupled to the first side wall 242 and the second side wall 243, Lt; / RTI >

The third side wall 246 is one of a plurality of side walls of the battery control body 240. The third side wall 246 is one of two short side sidewalls when the battery adjusting body 240 is formed as a rectangular shape. The third side wall 246 may be formed in a rectangular plate shape.

The fourth side wall 247 is one of a plurality of side walls of the battery control body 240. The fourth side wall 247 is one of two short side walls when the battery control body 240 is formed in a rectangular shape. The fourth side wall 247 is spaced from the third side wall 246 by a predetermined distance. The fourth side wall 247 may have a rectangular plate shape.

The battery control body 240 includes a first side wall 242, a second side wall 243, the ceiling 245, the bottom 244, the third side wall 246, and the fourth side wall 247 Are coupled to each other, the inside can be closed. In this case, the battery adjusting body 240 may be formed in a rectangular shape with an empty interior.

The battery control unit 240 may be implemented as a container for cargo transportation. Accordingly, the battery regulating apparatus 200 equipped with the solar cell according to the present invention can be loaded and unloaded to the transportation means by means of a transportation facility established in the past in order to cargo-work the container to a transportation means such as a ship, an airplane, . Accordingly, since the battery control apparatus 200 equipped with the solar cell according to the present invention does not need to newly provide a separate transportation facility, it is possible to reduce the construction cost for newly providing the transportation facility. In addition, the battery control device 200 equipped with the solar cell according to the present invention can be installed and used in a state of transportation, thereby improving the ease of transportation and installation. The battery control body 240 may be a 20 FT container or a 40 FT container.

1, 6 to 9, the battery regulating body 240 may include a suction passage 248 (shown in FIG. 8) and a discharge passage 249 (shown in FIG. 8).

The suction passage 248 allows gas to be sucked into the air conditioning unit 220 to pass therethrough. The discharge passage 249 allows gas discharged from the air conditioning unit 220 to pass therethrough. The air conditioning unit 220 installed in the battery control unit 240 may be installed in the battery control unit 240 through the suction passage 248 in the process of cooling the battery 20. [ And discharges the gas to the outside of the battery adjusting body 240 through the discharge passage 249. [

The suction passage 248 and the discharge passage 249 may be provided on the other side of the battery adjusting body 240 except the upper surface 241 on which the solar cell 230 is installed. Accordingly, the battery control device 200 equipped with the solar cell according to the present invention can increase the installation area where the solar cell 230 can be installed on the upper surface 241 of the battery control main body 240. Accordingly, the battery regulating apparatus 200 equipped with the solar cell according to the present invention can increase the production amount of electric power by increasing the area of sunlight incident on the solar cell 230.

The suction passage 248 and the discharge passage 249 may be provided on different side walls among the side walls 242, 243, 246 and 247 of the battery adjusting body 240. For example, when the air conditioning unit 220 is installed on the side of the third side wall 246, the suction passage 248 may be installed on the first side wall 242. In this case, the discharge passage 249 may be installed in the third side wall 246. The suction passage 248 may be provided in the third side wall 246 and the discharge passage 249 may be provided in the first side wall 141.

Referring to FIGS. 1, 6 to 9, the battery regulating apparatus 200 equipped with the solar cell according to the present invention may include a separating unit 250 for separating the moving path of the cold air and the moving path of the hot air.

The separating unit 250 separates the moving path of the cool air supplied from the air conditioning unit 220 and the moving path of the heat recovered to the air conditioning unit 220. The moving path of the cool air is a path through which cool air discharged from the air conditioning unit 220 moves to cool the battery 20. [ The heat transfer passage is a passage through which heat generated by the battery 20 is transferred to be recovered to the air conditioning unit 220. The separating unit 250 separates the moving path of the cool air for cooling the battery 20 and the moving path of the heat generated by the battery 20. Accordingly, the separator 250 can prevent the cool air and the heat from being mixed with each other. Accordingly, the battery control apparatus 200 equipped with the solar cell according to the present invention can improve the cooling performance for cooling the battery 20. In addition, the battery regulating apparatus 200 equipped with the solar cell according to the present invention can reduce the temperature deviation between the batteries 20, thereby reducing the risk of the battery 20 being damaged or damaged due to overheating.

The separating unit 250 may include a first separating member 251.

The first separating member 251 separates the cold air inflow passage CP and the first hot air passage HP1 (shown in FIG. 7). The cool air inflow path (CP) is a passage through which cool air supplied from the air conditioning unit (220) flows. The cool air inflow path CP is located between the battery rack group 210 and the second side wall 243. When two battery rack groups 210 are formed in the battery adjusting body 240 in two rows, the cool air inlet passages CP are located between the battery rack groups 210. The first hot air passage HP1 is located between the upper surface of the battery rack group 210 and the ceiling 245 of the battery control unit 240. [ The heat generated by the battery 20 is discharged to the first hot air passage HP1 and then travels along the first hot air passage HP1 and is recovered to the air conditioning unit 220. [ The first hot air passage HP1 is located between the cold air inflow passage CP and the first side wall 242.

The first separating member 251 is installed in the battery adjusting body 240 to block the upper surface of the battery rack group 210 and the ceiling 245 of the battery adjusting body 240. Accordingly, the first separating member 251 can separate the moving path of the heat generated by the battery 20 and the moving path of the cool air for cooling the battery 20. The first separating member 251 may be installed such that an upper surface of the first separating member 251 contacts the ceiling 245 of the battery adjusting body 240 and a bottom surface of the battery separating member 251 contacts the upper surface of the battery rack group 210. The first separating member 251 may be spaced apart from the first side wall 242 by a predetermined distance. The first separating member 251 may be formed as a rectangular plate as a whole. The first separating member 251 may be formed of a material having excellent heat insulating performance and rigidity. For example, the first separating member 251 may be formed of a fluororesin such as Teflon.

When the battery adjusting body 240 has two rows and two battery rack groups 210 are installed, the separating unit 250 may include a second separating member 252.

The second separating member 252 separates the cold air inflow passage CP and the second hot air passage HP2 (shown in FIG. 7). The second hot air passage HP2 is located between the upper surface of the battery rack group 210 disposed on the second side wall 243 and the ceiling 245 of the battery adjusting body 240. [ In this case, the first hot air passage HP1 is located between the upper surface of the battery rack group 210 disposed on the first side wall 242 side and the ceiling 245 of the battery adjusting body 240. The heat generated by the battery 20 is discharged to the second hot air passage HP2 and then travels along the second hot air passage HP2 and is recovered to the air conditioning unit 220. [ And the second hot air passage HP2 is located between the cold air inflow passage CP and the second side wall 243. [

The second separating member 252 is installed on the battery adjusting body 240 to block the upper surface of the battery rack group 210 and the ceiling 245 of the battery adjusting body 240. Accordingly, the second separating member 252 can separate the heat transfer path generated by the battery 20 and the cold transfer path for cooling the battery 20. The second separating member 252 may be installed such that the upper surface of the second separating member 252 contacts the ceiling 245 of the battery adjusting body 240 and the lower surface thereof contacts the upper surface of the battery rack group 210. The second separating member 252 may be spaced apart from the second side wall 243 by a predetermined distance. The second separating member 252 may be formed in a rectangular plate as a whole. The second separating member 252 may be formed of a material excellent in heat insulating performance and rigidity. For example, the second separating member 252 may be formed of a fluororesin such as Teflon.

7, the separating unit 250 includes the first separating member 251 and the second separating member 252. However, the separating unit 250 is not limited to the separating unit 250, 30 may be arranged in three or more separate members depending on the type in which they are disposed. In this case, the separating members are installed in the battery adjusting body 240 so as to block the upper surface of each of the battery racks 30 and the ceiling 245 of the battery adjusting body 240. Accordingly, the separating members can prevent the cold air and the hot air from being mixed with each other, thereby improving the cooling performance for cooling the battery 20.

Referring to FIGS. 1 and 6 to 9, a battery regulating apparatus 200 equipped with a solar cell according to the present invention includes a support portion 260 (shown in FIG. 7) and a vent portion 270 (shown in FIG. 7) .

The support portion 260 supports the battery rack group 210. The support portion 260 is installed on the battery control body 240 so as to be spaced apart from the bottom 244 of the battery control body 240 (shown in FIG. 7). Accordingly, the support portion 260 is positioned at a predetermined distance from the bottom 244 of the battery control unit 240. The battery rack group 210 is supported by the support unit 260 at a predetermined distance from the bottom 244 of the battery control unit 240. The support part 260 may support the air conditioning part 220 such that the air conditioning part 220 is positioned at a predetermined distance from the floor 244. The support portion 260 may have a rectangular plate shape.

The support portion 260 defines the inside of the battery adjusting body 240. The support portion 260 defines the cool air inflow path CP and the bottom path BP. The bottom passageway (BP) is located between the bottom 244 of the battery conditioning body 240 and the support 260. The air conditioning unit 220 supplies cool air for cooling the battery 20 to the floor passage BP. The cool air moves along the bottom passageway (BP) and then ascends and is supplied to the cool air inflow path (CP) through the vent portion (270).

The ventilation part 270 is coupled to the support part 260 such that chilled air moving along the bottom passage BP is supplied to the battery 20. The vent portion 270 may function as a passage through which cool air moving along the bottom passage BP is supplied to the cold air inflow passage CP. The cool air moving along the bottom passage BP may be supplied to the cool air inflow passage CP through the support portion 260 through the vent portion 270. The vent portion 270 may include a plurality of vent holes (not shown) through which cool air passes.

The ventilation part 270 may be disposed between the battery rack groups 210 so that the support part 260 is positioned between the battery racks 210 when two battery rack groups 210 are formed in the battery adjusting body 240, Lt; / RTI > The cool air supplied to the floor passage BP by the air conditioning unit 220 moves along the bottom passage BP and then ascends and flows into the cool air inflow passage CP through the air passage 270. [ And then may be supplied to the battery 20 by being dispersed toward the battery rack groups 210. The battery control device 200 equipped with the solar cell according to the present invention may include a plurality of the vent portions 270. The vent portions 270 may be coupled to the support portion 260 so as to be spaced apart from each other. Although not shown, the vent portion 270 may be coupled to the support portion 260 to be positioned below the battery rack group 210.

Referring to FIGS. 1, 6 to 9, a battery control apparatus 200 equipped with a solar cell according to the present invention may include a shutoff unit 280 (shown in FIG. 8).

The blocking part 280 blocks the upper surface of the air conditioning part 220 and the ceiling 245 of the battery adjusting body 240. Accordingly, the blocking unit 280 can prevent the cool air flowing into the cool air inflow path CP from being immediately recovered to the air conditioning unit 220 without cooling the battery 20.

Therefore, the blocking unit 280 prevents the flow rate of cool air for cooling the battery 20 from being shortened, thereby improving the cooling efficiency for cooling the battery 20. [ The blocking unit 280 prevents the suction force generated by the air conditioning unit 220 from being directly transmitted to the cool air inflow path CP so that the air in the air cooler inflow path CP can be blocked by the air conditioning unit 220, It is possible to prevent an increase in the flow rate of the cool air relative to the portion close to the air outlet. Therefore, the blocking unit 280 can improve the uniformity of the internal temperature of the batteries 20 by reducing the occurrence of a difference in flow rate of the cool air partially in the cold air inflow path CP.

The blocking portion 280 may be installed such that an upper surface of the blocking portion 280 contacts the ceiling 245 of the battery control body 240 and a bottom surface of the blocking portion 280 contacts the upper surface of the air conditioning portion 220. The blocking portion 280 may be spaced a predetermined distance from the third side wall 246 (shown in FIG. 8). The blocking portion 280 may be installed in contact with the separating members. The blocking portion 280 may be formed as a rectangular plate as a whole. The blocking portion 280 may be formed of a material having excellent heat insulating performance and rigidity. For example, the blocking portion 280 may be formed of a fluororesin such as Teflon.

Hereinafter, embodiments in which the energy storage device 1 equipped with the solar cell according to the present invention includes the power control device 100 and the battery control device 200 will be described in detail with reference to the accompanying drawings.

10 to 12 are schematic configuration diagrams of an energy storage device according to the present invention.

In the following description of an embodiment in which the energy storage device 1 equipped with the solar cell according to the present invention includes the power control device 100 and the battery control device 200, An embodiment in which the apparatus 1 includes the power regulator 100 and the battery regulator 200 will be described as an energy storage device 1 according to the present invention. FIG. 11 shows the configuration of FIG. 10 from the perspective of the power regulator 100, and FIG. 12 shows the configuration of FIG. 10 from the perspective of the battery regulator 200.

1 to 12, an energy storage device 1 according to the present invention includes the power regulator 100, the battery regulator 200, a solar cell 300 (shown in FIG. 10), and And a control unit 400 (shown in Fig. 10).

The power regulator 100 manages the power of the battery 20. The power regulator 100 is electrically connected to the system G. [ The power regulator 100 is the same as the power regulator 100 provided with the solar cell according to the present invention, and therefore, a detailed description thereof will be omitted.

The battery controller 200 stores power using the battery 20. The battery regulating device 200 is electrically connected to the power regulating device 100. The battery regulating device 200 is electrically connected to the system G. [ The battery regulating device 200 is the same as the battery regulating device 200 in which the solar cell according to the present invention is installed, and a detailed description thereof will be omitted.

The solar cell unit 300 converts solar light into electric energy to produce electric power. The solar cell unit 300 includes a solar cell 130 installed on an upper surface 141 of the power control unit 140 and a solar cell 230 installed on an upper surface 241 of the battery control unit 240. [ As shown in FIG. Since the solar cells 130 and 230 are as described above, a detailed description thereof will be omitted.

The controller 400 controls the power regulator 100 and the battery regulator 200 using the power generated by the solar battery 300 when the solar cell 300 generates electric power. Activate at least one. For example, the controller 400 can operate at least one of the power regulator 100 and the battery regulator 200 by using the power generated by the solar cell unit 300 as a control power source.

Accordingly, the energy storage device 1 according to the present invention can reduce the amount of power consumed in the system G during the operation, thereby reducing the operating cost. In the energy storage device 1 according to the present invention, even if power can not be supplied from the system G due to the system G not operating normally, And can be operated using electric power. Therefore, the energy storage device 1 according to the present invention can improve reliability as a power supply source.

The control unit 400 may electrically connect the system G and the solar battery 300 to the power regulator 100 and the battery regulator 200, respectively. The control unit 400 may be installed outside the power control unit 140 of the power control unit 100 and the battery control unit 240 of the battery control unit 200, respectively. The control unit 400 may be installed in the power control unit 140 of the power control unit 100 and the battery control unit 240 of the battery control unit 200, respectively.

The control unit 400 may supply control power for activating at least one of the power regulator 100 and the battery regulator 200. The control power source includes a power management system (PMS), a controller (PCS controller), a battery management system (BMS), the power control apparatus 100, And may be supplied to a control target such as fire fighting equipment of each of the devices 200. [ In this case, the controller 400 may include a battery conversion module 410, a battery conversion module 420, and a control module 430.

The battery conversion module 410 converts the DC power DC generated by the solar cell unit 300 into AC power. The battery conversion module 410 has one end connected to the solar cell unit 300 and the other end connected to a control target requiring a control power source. The battery conversion module 410 may be connected to the control object via an uninterruptible power supply (UPS) 411. The battery conversion module 410 may include an inverter for performing power conversion. The inverter may be installed in each of the power regulating body 140 of the power regulating device 100 and the battery regulating main body 240 of the battery regulating device 200 in several kW class.

The battery conversion module 420 converts the DC power supplied from the battery 20 accommodated in the battery controller 200 into AC power. The battery conversion module 420 has one end connected to the battery 20 and the other end connected to a control target requiring control power. The battery conversion module 420 and the battery conversion module 410 may be connected to the control object. The battery conversion module 420 may include an inverter for performing power conversion.

The control module 430 supplies control power to any one of the grid-connected operation mode and the independent operation mode depending on whether the system G normally operates. The control module 430 may control the inverter of the battery conversion module 410 and the inverter of the battery conversion module 420 in accordance with the operation mode.

The grid-connected operation mode is an operation mode in which AC power converted by the battery conversion module 410 and AC power provided from the system G are linked and supplied to the control power source.

The independent operation mode is an operation mode in which at least one of the AC power converted by the battery conversion module 410 and the AC power converted by the battery conversion module 420 is supplied to the control power source.

The control module 430 supplies the control power to the grid-connected operation mode when the grid G is normally operated. Accordingly, the control module 430 supplies the power generated by the solar cell unit 130 and the power supplied from the system G to the control power source. In this case, the control module 430 may utilize the power generated by the solar cell unit 130 as basic power, and utilize the power provided from the system G when the power is insufficient. On the other hand, when the solar cell unit 130 can not generate electric power, the control module 430 supplies the electric power provided from the system G to the control power source.

The control module 430 supplies the control power in the independent operation mode when the system G does not operate normally. Accordingly, the control module 430 supplies at least one of the power produced by the solar cell unit 130 and the power stored in the battery 20 to the control power source. When the solar cell unit 130 generates electric power, the control module 430 may utilize the electric power generated by the solar cell unit 130 as basic power, and when the power is insufficient, Can be utilized. If the solar cell unit 130 can not generate electric power, the control module 430 may supply the electric power stored in the battery 20 to the control power source.

Referring to FIGS. 1 to 12, the controller 400 (shown in FIG. 10) can charge the battery 20 using electric power generated by the solar cell unit 300. In this case, the battery conversion module 420 converts the AC power converted by the battery conversion module 410 into DC power. The control module 430 supplies the DC power converted by the battery conversion module 420 to the battery 20. Accordingly, the battery 20 can be charged by the electric power produced by the solar cell unit 300. The control module 430 may charge the battery 20 using both the power supplied from the system G and the power generated by the solar battery unit 300. [

In this case, the control module 430 may use at least one of the power supplied from the system G and the power generated by the solar cell unit 300 to control the battery 20 accommodated in the battery control device 200, Lt; / RTI > may be performed. In this case, the control module 430 may perform voltage balancing in units of the battery rack 30 or the battery rack group 210 with respect to the batteries 20 accommodated in the battery adjusting body 240. The control module 430 uses the power generated by the solar cell unit 300 and the power supplied from the system G in a state where the control module 430 is connected only to the specific battery rack 30 or the battery rack group 210, To charge the battery rack 30 or the battery rack group 210 to another battery rack 30 or the other battery rack group 30 after charging the battery 20 of the battery rack 30 or the battery rack group 210 to an average value. Voltage balancing can be performed by controlling to be connected to the battery rack group 210. [

1 to 12, the controller 400 (shown in FIG. 10) may include a charge / discharge module 440.

The charge / discharge module 440 converts the AC power converted by the battery conversion module 410 into DC power. One end of the charge / discharge module 440 is connected to the battery conversion module 410 and the other end is connected to the battery control device 200. The charge / discharge module 440 may also be connected to the system G. The charge and discharge module 440 may include an inverter for performing power conversion.

The control module 430 regulates the amount of power stored in the battery 20 by the DC power converted by the charge / discharge module 440. In this case, when the battery 20 requiring replacement is generated among the batteries 20 accommodated in the battery regulating apparatus 200, the control module 430 adjusts the amount of power stored in the battery 20 to be replaced, Charge and discharge can be performed so that the voltage becomes equal to that of the battery 20. [ The control module 430 uses at least one of the power produced by the solar cell unit 300, the power supplied from the battery 20, and the power supplied from the system G, It is possible to provide charge / discharge power.

The control unit 400 may supply the air conditioning power for operating the air conditioning units 120 and 220 using the power provided from the system G. [ The control unit 400 may supply the air conditioning power for operating the air conditioning units 120 and 220 using electric power provided from at least one of the solar battery unit 300 and the battery control unit 200.

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.

100: power regulator 110: power converter
120: air conditioning unit 130: solar cell
140: power control unit 200: battery control unit
210: battery rack group 220: air conditioning unit
230: Solar cell 240: Battery regulator
300: solar battery unit 400: control unit

Claims (10)

A power converter for managing power of the battery;
An air conditioning unit for cooling the power conversion unit;
A main body in which the power conversion unit and the air conditioning unit are installed; And
And a solar cell installed on an upper surface of the main body to produce power for use in an energy storage device,
Wherein the main body includes a suction passage through which gas sucked into the air conditioning portion passes, a discharge passage through which the gas discharged from the air conditioning portion passes, and a plurality of side walls connected to an upper surface on which the solar cell is installed,
Wherein the suction passage and the discharge passage are provided on different side walls of the plurality of side walls, respectively. A battery rack group including at least one battery rack for receiving a battery;
An air conditioning unit for cooling the battery;
A body in which the battery rack group and the air conditioning unit are installed; And
And a solar cell installed on an upper surface of the main body to produce power for use in an energy storage device,
Wherein the main body includes a suction passage through which gas sucked into the air conditioning portion passes, a discharge passage through which the gas discharged from the air conditioning portion passes, and a plurality of side walls connected to an upper surface on which the solar cell is installed,
Wherein the suction passage and the discharge passage are provided on different side walls of the plurality of side walls, respectively. 3. The method according to claim 1 or 2,
Further comprising a control unit for supplying control power to any one of the grid-connected operation mode and the independent operation mode depending on whether the system is operating normally,
The control unit supplies the power converted by the battery conversion module for converting the power produced by the solar cell according to the grid-connected operation mode and the power provided from the system to the control power when the system operates normally, When the system is not operating normally, at least one of the power converted by the battery conversion module and the power converted by the battery conversion module for converting the power provided from the battery according to the independent operation mode is supplied to the control power source Wherein the energy storage device is a solar cell. 3. The method according to claim 1 or 2,
A support portion installed to be spaced apart from the bottom of the main body; And
Further comprising a vent portion coupled to the support portion for allowing cool air to pass therethrough along a bottom passageway formed between the support portion and the bottom of the main body,
And the air conditioning unit supplies the cool air to the bottom passage. 3. The method according to claim 1 or 2,
Wherein the plurality of sidewalls includes first and second sidewalls which are connected to an upper surface on which the solar cell is mounted and are disposed to face each other,
A first hot air passage positioned between the cold air inflow passage of the cool air supplied from the air conditioning unit and the first sidewall and the first sidewall to which the heat recovered by the air conditioning unit moves, And a second heat exchanger located between the two side walls and through which the heat recovered by the air conditioning unit moves. A battery regulating device including a battery regulating body for receiving a battery and storing power using the battery;
A power regulating device including a power regulating body accommodating a power converting part for converting power, the power regulating device managing power of the battery;
A solar battery installed in at least one of an upper surface of the battery adjusting body and an upper surface of the power adjusting body to produce electric power;
A control unit for activating at least one of the battery control unit and the power control unit using electric power produced by the solar cell unit; And
And an air conditioning unit for recovering heat generated in at least one of the battery control device and the power control device,
At least one of the battery adjusting body and the power adjusting body includes a suction passage for passing a gas sucked into the air conditioning portion, a discharge passage for passing a gas discharged from the air conditioning portion, and a plurality of side walls / RTI >
Wherein the suction passage and the discharge passage are provided on different side walls of the plurality of side walls, respectively. The method according to claim 6,
The control unit supplies control power to any one of the grid-connected operation mode and the independent operation mode depending on whether the system is normally operated or not, and when the system is normally operated, Wherein the control unit controls the at least one of the power produced by the solar cell unit and the power stored in the battery according to the independent operation mode when the system is not operating normally, Wherein the power supply unit supplies power to the solar cell. 8. The method of claim 7,
The control unit may include: a battery conversion module that converts DC power produced by the solar cell unit into AC power; And
And a battery conversion module for converting DC power supplied from the battery into AC power. The method according to claim 6,
Wherein the plurality of sidewalls includes first and second sidewalls which are connected to an upper surface of the solar cell unit and are disposed opposite to each other,
At least one of the battery adjusting body and the power adjusting body is provided with a cold air inflow passage of cool air supplied from the air conditioning section, a first heat exchanger located between the cold air inflow passage and the first sidewall, And a second hot passage located between the cool air inflow passage and the second sidewall and through which the heat recovered to the air conditioning unit is moved. 7. The apparatus of claim 6, wherein the control unit
A battery conversion module for converting DC power produced by the solar cell unit into AC power,
A battery conversion module for converting the AC power converted by the battery conversion module into DC power, and
And a control module for supplying DC power converted by the battery conversion module to the battery so that the battery is charged with DC power converted by the battery conversion module.

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