JP6983735B2 - Power management system and apartment building - Google Patents

Description

The present disclosure relates to power management systems and apartment buildings.

A configuration is known in which collective power is received in an apartment house (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2017-17779

Even when each house receives power in an apartment house equipped with a distributed power source, it is required that each house can enjoy the merits of the distributed power source.

An object of the present disclosure is to provide an electric power management system and an apartment house in which each house of an apartment house receiving power can enjoy the advantages of a distributed power source.

The power management system according to the embodiment of the present disclosure includes a first dwelling unit meter and a second dwelling unit meter. The first dwelling unit meter measures the electric energy consumption of the first dwelling unit load that receives power from both a distributed power source and a power grid to which power is supplied from a power company. The second dwelling unit meter measures the power consumption of the second dwelling unit load that receives power from the power grid but does not receive power from the distributed power source. The first dwelling unit meter and the second dwelling unit meter are different from the transaction meters managed by the electric power company.

The apartment house according to the embodiment of the present disclosure includes a distributed power source, a plurality of dwelling unit loads, a transaction meter, and a dwelling unit meter. The plurality of dwelling unit loads are received from an electric power grid to which electric power is supplied from an electric power company. The transaction meter is connected between each of the plurality of dwelling unit loads and the electric power grid, and is managed by the electric power company. The dwelling unit meter is connected between each of the plurality of dwelling unit loads and the transaction meter. The distributed power supply supplies power to the partial dwelling unit load by being connected between the trading meter connected to the partial dwelling unit load among the plurality of dwelling unit loads and the dwelling unit meter. However, power is not supplied to the other dwelling unit load among the plurality of dwelling unit loads.

According to the power management system and the apartment house according to the embodiment of the present disclosure, each house of the apartment house that receives power can enjoy the merit of the distributed power source.

It is a block diagram which shows the structural example of the electric power management system which concerns on one Embodiment. It is a block diagram of the system which concerns on a comparative example. It is a perspective view which shows an example of the apartment house which has a distributed power source. It is a flowchart which shows an example of the procedure of the method of determining the number of PCS in a power management system. It is a flowchart which shows an example of the procedure of the method of determining the number of PCS in a power management system.

As shown in FIG. 1, the apartment house 1 according to the embodiment includes a power management system 10, a first dwelling unit load 41a, a second dwelling unit load 41b, and a distributed power source 60. The first dwelling unit load 41a and the second dwelling unit load 41b are collectively referred to as a dwelling unit load 41.

The apartment house 1 may be in various forms such as a condominium, an apartment, or a maisonette. The dwelling unit load 41 is a power load provided in each unit of the housing complex 1, and may be, for example, an electric device such as a lighting fixture, a refrigerator, a television, or an air conditioner used in each unit. The number of each of the first dwelling unit load 41a and the second dwelling unit load 41b is not limited to one, and may be two or more.

The first dwelling unit load 41a is connected to the power grid 80 via the first transaction meter 21a. The second dwelling unit load 41b is connected to the power grid 80 via the second transaction meter 21b. The first transaction meter 21a and the second transaction meter 21b are collectively referred to as a transaction meter 21. The dwelling unit load 41 is connected to the electric power grid 80 via the transaction meter 21, and receives the electric power supplied to the electric power grid 80 from the electric power company. The transaction meter 21 is managed by the electric power company. The transaction meter 21 measures the amount of electric power supplied from the electric power grid 80 to the connected dwelling unit load 41. The transaction meter 21 may be an electric energy meter with a certification. A watt-hour meter with a certification is also called a certification meter. The transaction meter 21 is connected to the electric power company server 82 managed by the electric power company by the communication line represented by the broken line, and outputs the measurement result to the electric power company server 82.

The power management system 10 includes a first dwelling unit meter 22a and a second dwelling unit meter 22b. The first dwelling unit meter 22a measures the power consumption of the first dwelling unit load 41a. The second dwelling unit meter 22b measures the power consumption of the second dwelling unit load 41b. The first dwelling unit meter 22a and the second dwelling unit meter 22b are collectively referred to as a dwelling unit meter 22. The power management system 10 may further include a management device 20. The management device 20 is connected to the dwelling unit meter 22 by a communication line represented by a broken line, and obtains a measurement result from the dwelling unit meter 22. The management device 20 is connected to the apartment house management server 84 managed by the management entity of the apartment house 1 by the communication line represented by the broken line, and outputs the measurement result to the apartment house management server 84. The management entity is the owner of the apartment house 1 or the housing management manufacturer that manages the apartment house 1.

The distributed power source 60 is connected to the first dwelling unit load 41a and supplies electric power to the first dwelling unit load 41a. The distributed power source 60 includes a photovoltaic power generation (hereinafter, also referred to as PV) 61 and a power conditioner (hereinafter, also referred to as PCS) 62. When the power output from the PV 61 and the PCS 62 exceeds the power consumption of the first dwelling unit load 41a, the surplus power is reverse-flowed to the power grid 80. The first transaction meter 21a connected to the distributed power source 60 determines the amount of power supplied from the power grid 80 to the first dwelling unit load 41a and the amount of power flowd back from the distributed power source 60 to the power grid 80. Measure. The second transaction meter 21b, which is not connected to the distributed power source 60, measures the amount of power supplied from the power grid 80 to the second dwelling unit load 41b.

PV61 may be replaced with other renewable energy power generation equipment such as wind power generation equipment. The PCS 62 controls the power output from the PV 61 by converting the DC power output from the PV 61 into AC power or the like. The PCS 62 may include an inverter, a converter, or the like. The distributed power source 60 may include a storage battery and a fuel cell. The number of PV61 and PCS62 is not limited to one, and may be two or more. For example, PV61 may be provided on the roof of the apartment house 1, or may be provided on the roof of the parking lot of the apartment house 1.

The electric power company concludes a power receiving contract with the management entity of the apartment house 1 with respect to the transaction meter 21 connected to each dwelling unit load 41. The electric power company supplies electric power to the dwelling unit load 41 from the electric power network 80 based on the power receiving contract, and measures the amount of electric power supplied to the dwelling unit load 41 by the transaction meter 21. The electric power company server 82 acquires the measurement result of the transaction meter 21, and calculates the electricity charge corresponding to the amount of electric power supplied from the electric power network 80 based on the measurement result. The electric power company charges the management entity of the apartment house 1 for the electricity charge based on the measurement result of the transaction meter 21.

The management device 20 is connected to the housing complex management server 84, acquires the measurement result of the power consumption in the housing unit load 41 from the housing unit meter 22, and outputs the measurement result to the housing complex management server 84. The apartment house management server 84 allocates electricity charges to each dwelling unit load 41 based on the measurement result of the electric energy. The apartment house management server 84 may allocate electricity charges to each dwelling unit load 41 based on a predetermined rule. The predetermined rule may be appropriately set by the management entity of the apartment house 1. The management entity of the apartment house 1 charges the resident of the dwelling unit in which the dwelling unit load 41 is provided with the electricity charge allocated to each dwelling unit load 41.

The amount of power supplied from the power grid 80 to the first dwelling unit load 41a that receives power from both the power grid 80 and the distributed power source 60 is smaller than that in the case where power is not received from the distributed power supply 60. That is, when the power consumption of the first dwelling unit load 41a and the second dwelling unit load 41b is the same, the electricity charge based on the measurement result of the first transaction meter 21a connected to the first dwelling unit load 41a is the second dwelling unit. It is cheaper than the electricity charge based on the measurement result of the second transaction meter 21b connected to the load 41b. When the electric power supplied from the distributed power source 60 flows backward to the electric power grid 80 and is sold, the electricity charge based on the measurement result of the first transaction meter 21a is reduced by the amount of the electric power sold.

In the present embodiment, the electricity charges based on the measurement results of the first transaction meter 21a and the second transaction meter 21b are charged to the management entity of the apartment house 1, respectively. The electricity charge based on the measurement result of the first transaction meter 21a is cheaper depending on the electric power supplied from the distributed power source 60, or becomes lower due to the sale of electric power. Each dwelling unit load is charged to each resident based on the power consumption of each dwelling unit load 41, which is the measurement result of each dwelling unit meter 22, in addition to the electricity charges charged to the management entity of the apartment house 1. The electricity rate of each house is determined regardless of whether the 41 is connected to the distributed power source 60. By doing so, the electricity charge can be fairly charged between the dwelling unit to which the electric power is supplied from the distributed power source 60 and the dwelling unit to which the electric power is not supplied from the distributed power source 60. As a result, the resident of the dwelling unit provided with the second dwelling unit load 41b not connected to the distributed power source 60 can also enjoy the merit that the distributed power source 60 is provided in the apartment house 1.

In the system according to the comparative example shown in FIG. 2, a distributed power source 60 is connected to each transaction meter 21. That is, a distributed power source 60 is connected to each house. In the comparative example, the resident of each house shall conclude a power receiving contract for each house with the electric power company. In this case, the power consumption of the dwelling unit load 41 in each house is covered by the power supplied from the distributed power source 60, so that the power supplied from the power grid 80 to the dwelling unit load 41 of each house is reduced. As a result, the resident of each house can enjoy the merits of the distributed power source 60.

However, when the installation status of the PV61 panel in each house is different, the amount of electric power supplied from the PV61 of each house to the dwelling unit load 41 is different. The amount of electric power supplied from the distributed power source 60 is determined by, for example, the orientation of the panel of the PV61, the sunshine duration of the panel of the PV61, or the like. Power receiving contract for each house The difference in the amount of power supplied from the distributed power source 60 of each house causes unfairness in the merit of reducing the electricity charge by the distributed power source 60 enjoyed by the resident of each house.

In the system according to the comparative example, the number of PCS 62 is increased by connecting the distributed power source 60 to each house. As the number of PCS62s increases, the installation space for PCS62s increases. As a result, the installation cost of the PCS 62 increases, and the appearance image of the apartment house 1 may deteriorate.

When the apartment house 1 is a building having two or more floors and the PCS62 is provided in the space of each house, the PCS62 is provided in the floor dwelling unit on the second floor or more. When the heavy PCS62 is installed on the second floor or higher, the cost of the building designed assuming the installation of the PCS62 may increase, or the cost of the installation work of the PCS62 may increase.

In the apartment house 1 according to the present embodiment, the distributed type enjoyed by the resident of each unit regardless of whether or not the dwelling unit load 41 is connected to the distributed power source 60 or the amount of power output by the distributed power source 60. The merit of reducing the electricity charge by the power source 60 can be set fairly. That is, the distributed power source 60 may not be installed in all the dwelling units, or may be installed in different situations in each unit.

When the distributed power source 60 is installed in a part of the dwelling units of the apartment house 1 having two or more floors, the number of PCS62s is reduced, and the need for the heavy PCS62 to be installed on the second floor or more is reduced. .. For example, as shown in FIG. 3, the PCS 62 may be provided only in the dwelling unit on the first floor. By doing so, the cost of the PCS62, the cost of the building, and the cost of the installation work of the PCS62 can be reduced.

The apartment house 1 according to the present embodiment is provided with a transaction meter 21 in each house. As a result, the resident of each house can conclude a power receiving contract with the electric power company. However, in the present embodiment, the power receiving contract for the transaction meter 21 of each house is concluded between the management entity of the apartment house 1 and the electric power company. In other words, the resident of each house does not conclude a power receiving contract with the electric power company. By doing so, the resident of each house can save the trouble of concluding a power receiving contract with the electric power company at the time of moving in.

The electric power supplied from the distributed power source 60 may be reverse-fed to the power grid 80 when a power receiving contract for the transaction meter 21 to which the distributed power source 60 is connected is concluded. The electric power supplied from the distributed power source 60 is not reversely flowed to the power grid 80 unless a power receiving contract for the transaction meter 21 to which the distributed power source 60 is connected is concluded. By concluding a power receiving contract for each house between the management entity of the apartment house 1 and the electric power company, the electric power supplied from the distributed power source 60 can be reverse-flowed to the electric power network 80 regardless of the presence or absence of residents. As a result, the electric power supplied from the distributed power source 60 can be effectively used.

The apartment house 1 according to the present embodiment further includes a dwelling unit meter 22 in which the management entity of the apartment house 1 can acquire the measurement result. When the management entity of the apartment house 1 charges the resident of each house for electricity, the section for each house is based on the measurement result of the dwelling unit meter 22 of each house, regardless of the measurement result of the transaction meter 21 of each house. You can decide the amount. The management entity of the apartment house 1 can determine the charge amount for each unit by appropriately setting a predetermined rule for allocating the electricity charge to each dwelling unit load 41. That is, the management entity of the apartment house 1 has more freedom in determining the billing amount for each house.

The management entity of the apartment house 1 may determine the charge amount for each house in consideration of the power sale amount of the power reverse power flowed from the distributed power source 60 to the power grid 80. For example, as the amount of power that is reversely flowed from the distributed power source 60 to the power grid 80 for one month increases, the charge amount for each house may be reduced.

The management entity of the apartment house 1 may determine the charge amount for each house in consideration of the daytime power consumption of each house. The smaller the daytime power consumption in the housing complex 1, the more power can be reverse-flowed from the distributed power source 60 to the power grid 80. Based on the amount of electricity sold backwards to the power grid 80, the amount charged to the dwelling unit with low daytime power consumption may be reduced.

When concluding a rental contract with a resident of each house, the management entity of the apartment house 1 may set a rent including an electricity charge for each house. The management entity of the apartment house 1 may set a predetermined rule so as to reduce or make the electricity charge for a predetermined period free in order to promote the move-in to the apartment house 1. The management entity of the apartment house 1 may set a predetermined rule so as to determine the electricity rate of each house based on the occupancy rate of the apartment house 1. The management entity of the apartment house 1 may set a predetermined rule so as to determine the electricity rate of each house based on the period of stay of each house. As a result, the management entity of the apartment house 1 can provide various contract systems to the resident, so that it is possible to improve the customer attraction and the serviceability to the resident.

Net Zero Energy House has been proposed as an energy saving measure for housing. The net zero energy house is also called ZEH (net Zero Energy House). In the apartment house 1, the dwelling unit load 41 self-consumes the electric power supplied from the distributed power source 60, so that the entire apartment house 1 or each house of the apartment house 1 can be recognized as ZEH.

If the amount of electric power supplied from the distributed power source 60 to the entire apartment house 1 or each house satisfies a predetermined condition, the apartment house 1 can be recognized as ZEH. The number of panels of PV61 and the number of PCS62 provided in the apartment house 1 may be determined so that the apartment house 1 is recognized as ZEH. ZEH realized in each residential building of an apartment house 1 is also called ZEH-M. The number of panels of PV61 and the number of PCS62 connected to each house may be determined so that each house is recognized as ZEH-M. The apartment house 1 may include a dwelling unit recognized as ZEH and a dwelling unit not recognized as ZEH-M.

The number of panels of PV61 that can be connected to one PCS62 may be determined based on the capacity of the PCS62. If the number of panels of PV61 exceeds the number of panels that can be connected to one PCS62, an additional PCS62 is required. Even if the number of panels of PV61 is only one, one PCS62 is required. When the panel of PV61 installed in the apartment house 1 is divided into several groups, PCS62 is connected to each group. In other words, the PCS 62 is divided corresponding to a group of panels of PV61 and is connected to each group. When the panel group of PV61 is associated with the first dwelling unit load 41a, the PCS62 is divided into the groups corresponding to the first dwelling unit load 41a. By optimizing the number of panels included in each group in which the panels of PV61 are divided, the number of PCS62s is minimized as a whole.

The number of panels of PV61 and the number of PCS62 shall be determined so that the apartment house 1 is recognized as ZEH-M. The number of PCS 62s can be minimized based on methods that include the steps in the flowcharts illustrated in FIGS. 4 and 5. This method may be performed, for example, by the designer or by the device. In this embodiment, the device shall perform the methods illustrated in FIGS. 4 and 5. The device may be a general-purpose computer or the like.

The apparatus sets parameters necessary for minimizing the number of PCS 62s (step S1). The parameters may be input to the device by the operator of the device. The parameters may be obtained from other devices. The parameter may include the capacity of the electric power equipment of each house of the apartment house 1 or the capacity of the main electric power equipment of the apartment house 1. The capacity of the electric power equipment of each house is also referred to as the equipment capacity of each house. The capacity of the main power equipment is also called the main equipment capacity. The parameter may include the number of dwelling units of the apartment house 1. The parameters may include the capacity of one PCS62. The parameter may include an overinput magnification in the case of overinputting the panel of PV61 for one PCS62. The overinput factor can be expressed as the ratio of the PV capacity that can actually be input to the PCS62 to the nominal capacity of the PCS62. The parameter may include the PV capacity required for the apartment house 1 to be recognized as ZEH-M.

The apparatus calculates the minimum number of PCS 62s based on the parameters (step S2). The minimum number of PCS62s shall be expressed as Mmin. The apparatus calculates the product of the over-input magnification and the capacity of the PCS 62 as the PCS input upper limit. The device divides the number of dwelling units of the apartment house 1 from the PV capacity required for the entire apartment house 1 as the PV capacity required for each unit in order for the apartment house 1 to be recognized as ZEH. The device calculates the value obtained by dividing the PV capacity required for each unit by the upper limit of the PCS input as the number of PCS62s required for each unit and rounding up the result to an integer. The device calculates the product of the number of PCS62s required per unit and the number of dwelling units as the number of PCS62s required for the entire apartment house 1 when the PCS62s are installed in each unit of the apartment house 1. The apparatus considers the number of PCS 62s required for the entire apartment house 1 calculated up to this point to be Mmin.

The apparatus sets the number of divisions of the PV61 panel to 0 (step S3). The number of divisions of the PV61 panel shall be expressed as N1. For example, when N1 is 3, the panel of PV61 is divided into three groups.

The apparatus increases the value of N1 by 1 (step S4).

The device determines whether N1 is equal to or less than the number of dwelling units (step S5).

The apparatus outputs Mmin when N1 is not less than or equal to the number of dwelling units (step S5: NO) (step S6). Mmin can be updated by the procedure of step S16 described later. The apparatus outputs the Mmin calculated in step S2 or the updated Mmin in step S16. The apparatus ends the procedure of the flowchart of FIGS. 4 and 5 after the procedure of step S6.

When N1 is equal to or less than the number of dwelling units (step S5: YES), the apparatus calculates the number of PCS62s per group in which the panels of PV61 are divided (step S11 in FIG. 5). The number of PCS62s per group obtained by dividing the panel of PV61 shall be expressed as MP. The device divides the PV capacity required for the entire apartment house 1 as MP by N1 in order for the apartment house 1 to be recognized as ZEH-M, further divides it by the upper limit of the PCS input, and rounds up the result to an integer. calculate.

The apparatus calculates the number of PCS 62s required when dividing the panel of PV61 into N1 groups (step S12). When the panel of PV61 is divided into groups of N1, the number of PCS62s required for the entire apartment house 1 is expressed as M1. The device calculates the product of MP and N1 as M1.

The apparatus determines whether the installed capacity of each house is equal to or greater than the product of the capacity of the PCS 62 and the MP (step S13). That is, the apparatus determines whether the number of PCS 62s per group is less than or equal to the number that can be connected to the electric power equipment provided in one unit of the apartment house 1.

The apparatus proceeds to the procedure of step S4 of FIG. 4 when the installed capacity of each house is not equal to or more than the product of the capacity of the PCS 62 and the MP (step S13: NO). When the equipment capacity of each house is equal to or greater than the product of the capacity of PCS62 and MP (step S13: YES), the apparatus determines whether the main equipment capacity is equal to or greater than the product of the capacity of PCS62 and M1 (step S14). That is, the apparatus determines whether the number of PCS 62s required for the entire apartment house 1 is less than or equal to the number that can be connected to the main power equipment of the apartment house 1.

The apparatus proceeds to the procedure of step S4 of FIG. 4 when the main equipment capacity is not equal to or more than the product of the capacity of the PCS 62 and M1 (step S14: NO). When the main equipment capacity is equal to or greater than the product of the capacity of the PCS 62 and M1 (step S14: YES), the apparatus determines whether M1 is less than Mmin (step S15).

The apparatus proceeds to the procedure of step S4 of FIG. 4 when M1 is not less than Mmin (step S15: NO). When M1 is less than Mmin (step S15: YES), the apparatus substitutes the value of M1 as the value of Mmin (step S16). That is, the device updates the value of Mmin to a smaller value. The device may store the value of N1 when Mmin is updated. The apparatus proceeds to the procedure of step S4 of FIG. 4 after the procedure of step S16.

As described above, the apparatus can calculate the minimum number of PCS 62s by updating the value of Mmin according to the procedure of the flowcharts of FIGS. 4 and 5.

In the apartment house 1 according to the present embodiment, the number of panels of PV61 and the number of PCS62 may be determined so that at least a part of the dwelling units are recognized as ZEH. In this case, the parameter may include the PV capacity required for at least a part of the dwelling units of the apartment house 1 to be recognized as ZEH. The number of PCS 62s may be determined under predetermined conditions regardless of whether or not the entire apartment house 1 is recognized as ZEH-M, or whether or not each house of the apartment house 1 is recognized as ZEH. Even in these cases, the number of PCS 62s can be minimized based on a method in which the procedure of the flowchart illustrated in FIGS. 4 and 5 is appropriately modified.

The figure illustrating the embodiment according to the present disclosure is schematic. The dimensional ratios on the drawings do not always match the actual ones.

Although the embodiments according to the present disclosure have been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications or modifications based on the present disclosure. It should be noted, therefore, that these modifications or modifications are within the scope of this disclosure. For example, the functions included in each component can be rearranged so as not to be logically inconsistent, and a plurality of components can be combined or divided into one.

In the present disclosure, the description of "first", "second" and the like is an identifier for distinguishing the configuration. The configurations distinguished by the descriptions such as "first" and "second" in the present disclosure can exchange numbers in the configurations. For example, the first terminal can exchange the second terminal with the identifiers "first" and "second". The exchange of identifiers takes place at the same time. Even after exchanging identifiers, the configuration is distinguished. The identifier may be deleted. Configurations with the identifier removed are distinguished by a code. Based solely on the description of identifiers such as "1st" and "2nd" in the present disclosure, it shall not be used as an interpretation of the order of the configurations or as a basis for the existence of identifiers with smaller numbers.

1 Apartment house 10 Power management system 20 Management device 21 (21a, 21b) Transaction meter (1st transaction meter, 2nd transaction meter)
22 (22a, 22b) Dwelling unit meter (1st dwelling unit meter, 2nd dwelling unit meter)
41 (41a, 41b) Dwelling unit load (1st dwelling unit load, 2nd dwelling unit load)
60 Distributed power generation 61 Photovoltaic power generation (PV)
62 Power conditioner (PCS)
80 Electric power grid 82 Electric power company server 84 Apartment management server

Claims (7)

The first dwelling unit meter that measures the power consumption of the first dwelling unit load that receives power from both the distributed power source and the power network supplied by the power company,
It is equipped with a second dwelling unit meter that measures the power consumption of the second dwelling unit load that receives power from the power grid but does not receive power from the distributed power source.
The first dwelling unit meter and the second dwelling unit meter are electric power management systems different from the transaction meters managed by the electric power company. Further equipped with a management device for managing the first dwelling unit meter and the second dwelling unit meter,
The power management system according to claim 1, wherein the charge amount for each of the first dwelling unit load and the second dwelling unit load is calculated based on the measurement results of the first dwelling unit meter and the second dwelling unit meter. The management device acquires an electric charge charged by the electric power company based on the amount of electric power supplied from the electric power network for each of the first dwelling unit load and the second dwelling unit load, and obtains the measurement result and the said. The power management system according to claim 2, wherein the charge amount for each of the first dwelling unit load and the second dwelling unit load is calculated based on the electricity charge. With distributed power sources
Multiple dwelling unit loads that receive power from the power grid to which power is supplied by the power company,
A transaction meter connected between each of the plurality of dwelling unit loads and the electric power grid and managed by the electric power company.
A dwelling unit meter connected between each of the plurality of dwelling unit loads and the transaction meter is provided.
The distributed power supply supplies power to the partial dwelling unit load by being connected between the trading meter connected to the partial dwelling unit load and the dwelling unit meter among the plurality of dwelling unit loads. However, an apartment house that does not supply power to the other dwelling unit loads among the plurality of dwelling unit loads. Further equipped with a management device for managing the dwelling unit meter,
The apartment house according to claim 4, wherein the billing amount for each of the plurality of dwelling unit loads is calculated based on the measurement result of the dwelling unit meter. The management device calculates the charge amount for each of the plurality of dwelling unit loads based on the electricity charge charged by the electric power company based on the measurement result of the transaction meter and the measurement result of the dwelling unit meter. The apartment house according to claim 5. The distributed power source has a plurality of power conditioners and has a plurality of power conditioners.
The apartment house according to any one of claims 4 to 6, wherein the plurality of power conditioners are divided into groups corresponding to a dwelling unit load to which the distributed power source is connected.

Images