JP6147816B2 - Electricity interchange system and residential area equipped with the same - Google Patents

Description

  The present invention relates to an electric power interchange system for accommodating electric power among a plurality of buildings and a technology of a residential area having the electric power interchange system.

  2. Description of the Related Art Conventionally, a technology of an electric power accommodation system that accommodates electric power among a plurality of buildings has been publicly known. For example, as described in Patent Document 1.

  In the technique described in Patent Document 1, each of a plurality of houses is provided with a storage battery, and the power of the storage battery charged from the system power supply can be used in the house at a time zone where electricity charges are low (such as midnight). In addition, power is accommodated from a house with a sufficient amount of storage battery charge to a house where power is insufficient. When accommodating electric power, the daily electric power consumption of each house is predicted, and the electric power interchange is determined based on the electric power usage and the charged amount of the storage battery. The control device accommodates electric power according to the determined accommodation amount.

JP 2010-220428 A

  However, in the technique described in Patent Document 1, no consideration is given to a method for accommodating power when a power failure (stop of power supply from the system power supply) occurs. Therefore, in the event of a power failure, there is a risk that it will be difficult to interchange appropriate power. For example, when a power failure occurs, there is a possibility that the power is insufficient because sufficient power cannot be charged in the storage battery of each house.

  The present invention has been made in view of the situation as described above, and a problem to be solved is a power interchange system capable of appropriately accommodating power even when a power failure occurs and a system including the same. It is to provide a residential block.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

That is, an electric power interchange system for accommodating electric power between a plurality of buildings having a load that consumes electric power, which is provided independently of the plural buildings and capable of charging and discharging electric power from a system power source A device, an individual power storage device provided in each of the plurality of buildings , capable of charging and discharging power from the system power supply and the independent power storage device, and a load of the individual power storage device provided in each of the plurality of buildings When the power conditioner that performs the follow-up operation and a power failure has not occurred , the power from the system power source and the independent power storage device can be supplied to the load and the individual power storage device, and a power failure has occurred. In this case, a first switching unit that enables supply of electric power from the independent power storage device to the load and the individual power storage device is provided.

The power interchange system may further include an individual power generation device provided in each of the plurality of buildings and capable of supplying power to the load and the individual power storage device of each building.
With such a configuration, the electric power generated by the individual power generator can be used in the plurality of buildings.

The power interchange system further includes an independent power generation device provided independently of the plurality of buildings, and the first switching unit, when no power failure occurs, the system power supply, the independent power storage device And the power from the independent power generation device can be supplied to the load and the individual power storage device, and when a power failure occurs, the power from the independent power storage device and the independent power generation device is supplied to the load and the individual power generation device. Supply to the power storage device may be possible.
With such a configuration, the electric power generated by the independent power generator can be used in the plurality of buildings.

The load includes a limited load, and is provided in each of the plurality of buildings, and may further include a second switching unit that cannot supply power to the limited load when a power failure occurs.
With such a configuration, it is possible to suppress wasteful power consumption during a power failure.

The load includes an important load, and is provided in each of the plurality of buildings. When a power failure occurs and the amount of power stored in the independent power storage device is equal to or lower than a predetermined value, the individual power storage device A third switching unit that can supply the power to the important load only may be further included.
With such a configuration, when a power failure occurs and the power stored in the independent power storage device decreases, the power of the individual power storage device can be used.

The residential block includes the power accommodation system and a plurality of accommodation houses configured to allow power to be interchanged by the power accommodation system.
With such a configuration, even when a power failure occurs, power can be appropriately accommodated among a plurality of houses.

  Even if a power failure occurs, power can be appropriately accommodated.

Schematic which showed the smart city which comprises the power interchange system which concerns on 1st embodiment. The single line connection figure which showed the electric power interchange system which concerns on 1st embodiment. The figure which showed the outline | summary of the electric power sales contract seen from the electric power retailer. The single wire connection diagram which showed the detailed structure of the switch board. The single line connection figure which showed the mode of the switching board in normal time. The single line connection figure which showed the mode of the electric power interchange system in the normal time. A single-line diagram showing the state of the switchboard in an emergency. The single wire connection diagram which showed the mode of the electric power interchange system in emergency. The single line connection figure which showed the mode of the power interchange system when the electric power of an independent electrical storage apparatus was lose | eliminated in an emergency. The single line connection figure which showed the electric power interchange system which concerns on 2nd embodiment. The single line connection figure which showed the electric power interchange system which concerns on 3rd embodiment.

  Below, the outline | summary of the smart city 1 which comprises the power interchange system 100 which concerns on 1st embodiment is demonstrated using FIG.

  The smart city 1 is a city built mainly for the purpose of effectively using energy. The smart city 1 according to the present embodiment assumes a residential block mainly composed of a plurality of detached houses. The smart city 1 is provided with an energy accommodation area 10 in which energy (mainly electric power) is exchanged between installed buildings and devices. In the energy accommodation area 10 according to the present embodiment, three houses (a first house 11, a second house 12, and a third house 13), a security light 14, a quick charger 15, and a common station 21 are provided.

  Three houses (the 1st house 11, the 2nd house 12, and the 3rd house 13) are buildings where people live. The house is provided with appropriate electrical products and consumes electric power. The house is provided with a solar power generation unit 117, a power storage device 118, and the like, which will be described later.

  The security light 14 is a street light installed for the purpose of crime prevention. The security light 14 is installed at an appropriate location in the energy interchange area 10.

  The quick charger 15 is a device for charging an electric vehicle. The quick charger 15 is installed at an appropriate location in the energy accommodation area 10.

  The common station 21 is a facility for generating power and storing electricity. The common station 21 is provided independently of the three houses. The common station 21 includes a regulation pond, a disaster prevention warehouse, and the like. The joint station 21 is provided with an independent solar power generation unit 201, an independent power storage device 202, and the like (see FIG. 2), which will be described later.

  The three houses, the security light 14, the quick charger 15 and the common station 21 are respectively connected to a power distribution board 101 that draws in power from the system power supply S of the power company. The electric power from the system power source S is supplied to the three houses, the security light 14, the quick charger 15 and the common station 21 through the incoming distribution board 101. The electric power and the electric power generated by the solar power generation unit 117 or the independent solar power generation unit 201 are stored in the power storage device 118 or the independent power storage device 202 as appropriate. In addition, surplus power (power that cannot be stored in the power storage device 118 or the independent power storage device 202) in any one of the homes or the common station 21 is appropriately supplied to other homes that lack power through the service distribution board 101. Be flexible.

  In the present embodiment, in consideration of future liberalization of power retailing, it is assumed that a power retailer purchases power from a power company in a lump and supplies the power to the three houses. Yes. Specifically, the power retailer has jurisdiction over the service distribution board 101 and the common station 21. The electric power retailer sells the electric power purchased from the grid power source S of the electric power company as appropriate to the three houses via the incoming distribution board 101 and stores the electric power in the common station 21 as appropriate. In addition, when there is surplus power in any of the three houses, the power retailer purchases the power (surplus power) and sells it to another house that lacks power. . The electric power retailer also sells surplus power from the common station 21 to a deficient house. In this way, power is exchanged between the three houses in the energy accommodation area 10 and the common station 21.

  Below, the detailed structure of the power interchange system 100 is demonstrated using FIG. The power interchange system 100 supplies power as appropriate, and allows power to be interchanged between the three houses (the first house 11, the second house 12, and the third house 13) and the common station 21. The power interchange system 100 mainly includes an incoming distribution board 101, a sub-power meter 111, a leakage breaker 112, a switching board 113, a general circuit 114, a first specific circuit 115, a second specific circuit 116, a solar power generation unit 117, a power storage A device 118, a power conditioner 119, an independent solar power generation unit 201, an independent power storage device 202, an independent power conditioner 203, a power transformer 204, and the like are provided.

  The service distribution board 101 distributes the power supplied to the smart city 1 as appropriate. The lead-in distribution board 101 is mainly composed of a parent power meter 102, a parent power meter 103, a first power extraction unit 104, a second power extraction unit 105, a first current sensor 106, a second current sensor 107, and a third current sensor. 108, a fourth current sensor 109 and a switching board 110.

  In addition, in the following description, the positional relationship of each part is demonstrated on the basis of the distribution line L in the service distribution board 101. FIG. One end of the distribution line L is connected to the system power source S. In FIG. 2, the distribution line L is indicated by a line extending linearly from the system power supply S side to the right side of the drawing. In the following description, for the sake of convenience, in the direction in which the distribution line L extends (left and right direction in the drawing), the left side (side closer to the system power supply S) is referred to as the upstream side, and the right side is referred to as the downstream side.

  The parent power meter 102 detects the amount of power purchased by the service distribution board 101 from the system power source S (electric power company). The power purchase meter 102 is provided in the middle of the distribution line L (near the upstream end).

  The parent power meter 103 detects the amount of power sold by the incoming distribution board 101 to the system power source S (electric power company). The parent electricity meter 103 is provided in the middle of the distribution line L (on the downstream side of the parent electricity meter 102).

  The first power extraction unit 104 is a part that extracts electric power flowing through the distribution line L. The 1st electric power extraction part 104 is connected to the connection point P1 arrange | positioned in the middle part of the distribution line L (downstream side of the parent power meter 103). A security light 14 is connected to the first power extraction unit 104. The security light 14 can use electric power supplied from the system power source S via the incoming distribution board 101.

  The second power extraction unit 105 is a part that extracts electric power flowing through the distribution line L. The 2nd electric power extraction part 105 is connected to the connection point P2 arrange | positioned in the middle part (downstream side of the connection point P1) of the distribution line L. As shown in FIG. The quick charger 15 is connected to the second power extraction unit 105. The quick charger 15 can use electric power supplied from the system power supply S via the incoming distribution board 101.

  The first current sensor 106 detects the amount of power flowing through the distribution line L. The first current sensor 106 is provided in the middle of the distribution line L (on the downstream side of the connection point P2). The value detected by the first current sensor 106 is used for load following operation of the power storage device 118 provided in the first house 11 described later.

  The second current sensor 107 detects the amount of power flowing through the distribution line L. The second current sensor 107 is provided in the middle of the distribution line L (on the downstream side of the first current sensor 106). The value detected by the second current sensor 107 is used for load following operation of the power storage device 118 provided in the second house 12 described later.

  The third current sensor 108 detects the amount of power flowing through the distribution line L. The third current sensor 108 is provided in the middle of the distribution line L (on the downstream side of the second current sensor 107). The value detected by the third current sensor 108 is used for load following operation of the power storage device 118 provided in the third house 13 described later.

  The fourth current sensor 109 detects the amount of power flowing through the distribution line L. The fourth current sensor 109 is provided in the middle of the distribution line L (on the downstream side of the parent power meter 103 and on the upstream side of the connection point P1). The detection value by the fourth current sensor 109 is used for load follow-up operation or the like of the independent power storage device 202 provided in the joint station 21 described later.

The switching board 110 switches the power distribution route. The switching board 110 is provided in the middle of the distribution line L (on the downstream side of the fourth current sensor 109 and on the upstream side of the connection point P1).
The detailed configuration of the switching board 110 will be described later.

  The sub-electricity meter 111, the earth leakage breaker 112, the switching board 113, the general circuit 114, the first specific circuit 115, the second specific circuit 116, the photovoltaic power generation unit 117, the power storage device 118, and the power conditioner 119 One house 11, a second house 12 and a third house 13) are provided. Therefore, in the following, only the sub-electricity meter 111 etc. provided in the first house 11 will be described in detail, and the sub-electricity meter 111 etc. provided in other homes are different from those provided in the first house 11. Only the point will be briefly described.

  The sub-electricity purchase meter 111 detects the amount of power purchased (purchased) by the first house 11 via the service distribution board 101. The sub-electricity purchase meter 111 is provided in the first house 11. The sub power purchase meter 111 is connected to a connection point P3 arranged at the downstream end of the distribution line L.

  The earth leakage breaker 112 interrupts the distribution of electric power when an overcurrent or an earth leakage occurs. The earth leakage breaker 112 is connected to the sub power purchase meter 111.

The switch board 113 appropriately distributes the power supplied to the first house 11 and switches the power distribution route. The switch board 113 is connected to the earth leakage breaker 112.
The detailed configuration of the switching board 113 will be described later.

  The general circuit 114 is provided in the first house 11 and supplies power to an appropriate electrical product or the like (power load). The general circuit 114 is connected to the switching board 113 and receives the power distributed by the switching board 113. The general circuit 114 is connected to a power load provided in the first house 11 that is relatively unhindered even if power is not supplied when a power failure occurs (for example, an acoustic device).

  The first specific circuit 115 is provided in the first house 11 and supplies power to an appropriate electrical product or the like (power load). The first specifying circuit 115 is connected to a power conditioner 119 described later, and receives power supplied via the power conditioner 119. The first specific circuit 115 is connected to a power load provided in the first house 11 that is preferably supplied with power even when a power failure occurs (for example, a refrigerator, an outlet in a living room, etc.).

  The second specific circuit 116 is provided in the first house 11 and supplies power to an appropriate electrical product or the like (power load). The second specifying circuit 116 is connected to the switching board 113 and receives the power distributed by the switching board 113. Of the power loads provided in the first house 11, one that is preferably supplied with power even when a power failure occurs (for example, a living room lighting) is connected to the second identification circuit 116.

  As the power load connected to the first specific circuit 115, one that is more important than the power load connected to the second specific circuit 116 (preferably supplied with power when a power failure occurs) is selected. Is done.

  The solar power generation unit 117 is a device that generates power using sunlight. The solar power generation unit 117 is installed in a sunny place such as on the roof of the first house 11.

  The power storage device 118 is a device that can charge and discharge electric power. The power storage device 118 includes a storage battery such as a lithium ion battery or a nickel metal hydride battery that can charge and discharge electric power, a charger that rectifies supplied AC power and charges the storage battery.

  The power conditioner 119 is a hybrid power conditioner connected to the photovoltaic power generation unit 117 and the power storage device 118. The power conditioner 119 includes a conversion device that converts DC power and AC power as appropriate, a control unit that controls the conversion device, and the like. The power conditioner 119 is connected to the switching board 113 of the first house 11. In FIG. 2, a part of the distribution line that connects the power conditioner 119 and the switching board 113 is omitted. Further, the power conditioner 119 is connected to a connection point P <b> 6 arranged in the middle part of the distribution line L (on the downstream side of the first current sensor 106 and on the upstream side of the second current sensor 107). In addition, the power conditioner 119 is connected to the first specific circuit 115 of the first house 11 via a terminal for independent operation. In addition, the power conditioner 119 can receive the detection value (the amount of power flowing through the distribution line L) by the first current sensor 106.

  The power conditioner 119 appropriately converts the power generated by the solar power generation unit 117 and the power discharged from the power storage device 118 and supplies the converted power to the switching panel 113 and the first specific circuit 115 of the first house 11. it can. Further, the power conditioner 119 supplies the power supplied from the switching panel 113 (power from the system power source S) and the power generated by the solar power generation unit 117 to the first specific circuit 115 and to the power storage device 118 ( Power storage). Further, the power conditioner 119 can sell (power sale) the electric power generated by the solar power generation unit 117 via the incoming distribution board 101.

  Further, the power conditioner 119 can perform grid connection and independent operation. In the grid interconnection, the photovoltaic power generation unit 117 and the power storage device 118 are operated in conjunction with the grid power source S. When performing grid connection, the power conditioner 119 can perform load following operation (control based on electric power used via the general circuit 114) based on the detection value of the first current sensor 106. In the self-sustained operation, the photovoltaic power generation unit 117 and the power storage device 118 are operated independently from the system power source S. When a power failure occurs, the power conditioner 119 performs a self-sustained operation (output of electric power from the terminal for self-sustained operation).

  Similarly to the first house 11, the second house 12 and the third house 13 also have a sub-electricity meter 111, a leakage breaker 112, a switch board 113, a general circuit 114, a first specific circuit 115, a second specific circuit 116, a sun A photovoltaic unit 117, a power storage device 118, and a power conditioner 119 are provided.

  The sub-electricity meter 111 of the second house 12 is connected to an interconnection point P4 arranged in the middle of the distribution line L (downstream side of the third current sensor 108 and upstream side of the interconnection point P3). The The sub-electricity purchase meter 111 of the third house 13 is connected to a connection point P5 disposed in the middle of the distribution line L (downstream side of the third current sensor 108 and upstream side of the connection point P4). The

  The power conditioner 119 of the second house 12 is connected to an interconnection point P7 disposed in the middle of the distribution line L (on the downstream side of the second current sensor 107 and on the upstream side of the third current sensor 108). The The power conditioner 119 of the third house 13 is connected to a connection point P8 that is disposed in the middle of the distribution line L (on the downstream side of the third current sensor 108 and on the upstream side of the connection point P5). .

  The independent solar power generation unit 201 is a device that generates power using sunlight. The independent solar power generation unit 201 is provided in the common station 21. The independent solar power generation unit 201 is installed in a sunny place such as the upper part of the adjustment pond.

  The independent power storage device 202 is a device that can charge and discharge electric power. The independent power storage device 202 is provided in the common station 21. The independent power storage device 202 includes a storage battery such as a lithium ion battery or a nickel metal hydride battery that can charge and discharge power, a charger that rectifies supplied AC power and charges the storage battery. The independent power storage device 202 is installed in the disaster prevention warehouse or the like.

  The independent power conditioner 203 is a hybrid power conditioner connected to the independent photovoltaic power generation unit 201 and the independent power storage device 202. The independent power conditioner 203 is provided in the common station 21. The independent power conditioner 203 is connected to a connection point P9 disposed in the middle of the distribution line L (on the downstream side of the fourth current sensor 109 and on the upstream side of the switching panel 110). The independent power conditioner 203 is connected to the switching panel 110 via a terminal for independent operation. The independent power conditioner 203 can receive the detection value (the amount of power flowing through the distribution line L) from the fourth current sensor 109.

  The independent power conditioner 203 can appropriately convert the power generated by the independent solar power generation unit 201 and the power discharged from the independent power storage device 202 and supply the converted power to the incoming distribution board 101. At this time, the independent power conditioner 203 supplies power to the incoming distribution board 101 via either the interconnection point P9 or the switching board 110. The independent power conditioner 203 supplies the power (power from the system power source S) supplied from the power distribution board 101 (interconnection point P9) and the power generated by the independent solar power generation unit 201 to the independent power storage device 202. Supply (electric storage) can be performed.

  The independent power conditioner 203 can perform grid connection and independent operation. In the grid interconnection, the independent photovoltaic power generation unit 201 and the independent power storage device 202 are operated in linkage with the grid power source S. The independent power conditioner 203 can perform a load following operation based on the detection value of the fourth current sensor 109 when performing grid connection. In the independent operation, the independent photovoltaic power generation unit 201 and the independent power storage device 202 are operated independently from the system power source S. The independent power conditioner 203 can detect whether or not a power failure has occurred (whether or not power is supplied from the system power supply S) based on the detection value of the fourth current sensor 109. The independent power conditioner 203 performs a self-sustaining operation (output of electric power from the terminal for the self-sustaining operation) when a power failure occurs.

  The power transformer 204 converts the voltage of power from the independent power conditioner 203. The power transformer 204 is disposed between the independent power conditioner 203 and the switching board 110.

  Hereinafter, a state in which power is interchanged between the three houses by the power interchange system 100 configured as described above will be described.

  The electric power retailer purchases electric power from the grid power source S of the electric power company and supplies the electric power to the three houses and the communal station 21 as appropriate through the service distribution board 101.

  In each house, the load follower operation of the power storage device 118 is performed by the power conditioner 119. Specifically, charging / discharging of the power storage device 118 is performed according to the amount of power (power load) required from the general circuit 114, the first specifying circuit 115, and the second specifying circuit 116. At this time, the power generated in the solar power generation unit 117 is used as much as possible (supplied to the general circuit 114, the first specific circuit 115, and the second specific circuit 116, or the surplus is stored in the power storage device 118). Therefore, it is possible to reduce the electric power to be purchased and the economic burden.

  In each house, the power purchased from the service distribution board 101 (power retailer) is used as necessary. The electric power is detected by the sub power purchase meter 111. The power retailer can grasp the amount of power purchased by each house from the power retailer from the detection value of the sub-electricity meter 111.

  In addition, although the electric power generated by the solar power generation unit 117 of each house is used, the surplus power (surplus power) that is not used in the house is appropriately sold to the distribution board 101 (power retailer). The

  The electric power sold by each house to a power retailer is supplied to the distribution line L via the connection point P6, the connection point P7, or the connection point P8. The electric power can be further supplied from the downstream connection point P3, the connection point P4, or the connection point P5 to each house. That is, the electric power sold from each house to the electric power retailer can be supplied (accommodated) to another house where power is insufficient via the service distribution board 101.

  In this way, each house can exchange power with each other simply by using power (buying or selling power) as usual without requiring special equipment or control.

  Furthermore, power generation and power storage can be performed at the common station 21 under the jurisdiction of the power retailer. Specifically, power can be generated by the independent solar power generation unit 201, and the electric power from the independent solar power generation unit 201 can be stored in the independent power storage device 202. In addition, power purchased from the system power source S (for example, inexpensive nighttime power) can be stored in the independent power storage device 202. The electric power stored in the independent power storage device 202 is supplied to the incoming distribution board 101 as appropriate. The electric power can be accommodated to the three houses connected to the downstream side of the distribution line L.

  Since power is interchanged between the three houses and the common station 21 in this way, it is possible to improve the self-sufficiency rate of the electric power in the three houses and the common station 21 (smart city 1). That is, the power purchased from the grid power source S of the power company can be reduced by accommodating the power shortage in a certain house from other houses. Further, in order to allow power to be exchanged between a plurality of houses and the like in this way, the power generation capacity (power generation amount, power generation efficiency, etc.) of the solar power generation unit 117 and the independent solar power generation unit 201 and the power storage device 118 and the independent power storage device 202 The storage capacity can be reduced. Thereby, the capital investment of each house and the common station 21 can be suppressed.

  The power generation capacity of the solar power generation unit 117 and the independent solar power generation unit 201 and the power storage capacity of the power storage device 118 and the independent power storage device 202 can be fully self-supplied in the smart city 1 on a sunny day. It is desirable to be designed.

  Below, the advantage of an electric power retailer and each house (resident) by using the above-mentioned electric power interchange system 100 is demonstrated using FIG. For the explanation, FIG. 3 shows an outline (specific example) of an electric power sales contract between an electric power company, an electric power retailer, and each house.

  A power retailer signs a contract with a power company according to time (specifically, a plan with a low nighttime electricity charge and a high daytime electricity charge) and purchases (receives) power in a lump ((Fig. 3 ( A)). In addition, a power retailer supplies (sells) electric power to each house at a fixed price throughout the day (however, it is more expensive than the nighttime electricity rate in a contract by time zone) (see FIG. 3B). . At this time, the power storage device 118 of each house stores low-priced power purchased by the power retailer from the power company at night.

  A power retailer purchases surplus power from each house at a price lower than a fixed purchase price (the price of power when selling power to a power company) (see FIG. 3C). The power retailer sells surplus power to a power company at a fixed purchase price (see FIG. 3D).

  In such an example, the electric power retailer makes the difference between the fixed purchase price (see (D) of FIG. 3) and the purchase price from each house (see (C) of FIG. 3), and the nighttime power charge. A profit can be obtained from the difference between the power charge (see FIG. 3B) when selling to each house (see FIG. 3A).

  Each house (resident) can purchase electric power from a power retailer with a plan that is cheaper than a normal pay-per-use light contract. In addition, although the unit price is lower than the fixed purchase price, a profit can be obtained by selling the power to a power retailer. Further, with the installation of the power storage device 118 at home (house), the power stored in the power storage device 118 can be used during a power failure.

  Below, the detailed structure of the switching board 110 and the switching board 113, and the mode of switching of the distribution route of the electric power by the switching board 110 and the switching board 113 are demonstrated.

  First, detailed configurations of the switching board 110 and the switching board 113 will be described with reference to FIGS. 2 and 4. In FIG. 4, for convenience of explanation, detailed configurations of the switching board 110 and the switching board 113 are illustrated, and other members are appropriately omitted.

  The switching board 110 mainly includes a first relay 110a and a second relay 110b.

  The first relay 110a switches whether power can be distributed. The first relay 110 a is provided in the middle of the distribution line L in the switching panel 110. When the first relay 110a is in the closed state, the contacts of the first relay 110a are connected to each other so that power can flow through the distribution line L. On the other hand, if the 1st relay 110a will be in an open state, the connection of the contacts of the said 1st relay 110a will be cancelled | released, and electric power will be unable to distribute | circulate the distribution line L. FIG.

  The second relay 110b switches whether power can be distributed. The second relay 110b is provided in the switching panel 110 in the middle of a distribution line (hereinafter referred to as a distribution line L1) that connects the power transformer 204 and the distribution line L. Here, one end of the distribution line L1 is connected to a midway portion of the distribution line L (downstream of the first relay 110a) in the switching panel 110. When the second relay 110b is in the closed state, the contacts of the second relay 110b are connected to each other, and power can flow through the distribution line L1. On the other hand, if the 2nd relay 110b will be in an open state, the connection of the contact of the said 2nd relay 110b will be cancelled | released, and electric power will be unable to distribute | circulate the distribution line L1.

  The switching board 110 can control the operations of the first relay 110a and the second relay 110b. Specifically, when one of the first relay 110a and the second relay 110b is in an open state, the switching panel 110 performs control (so-called exclusive control) in which the other is closed. The switching board 110 is connected to the fourth current sensor 109, and can detect the occurrence of a power failure based on the detection value of the fourth current sensor 109.

  The switching board 113 mainly includes a relay 113a and a branch breaker 113b.

  The relay 113a switches whether power can be distributed. The relay 113a is provided in the middle of the distribution line (hereinafter referred to as the distribution line L2) connecting the earth leakage breaker 112 and the general circuit 114 in the switching panel 113. When the relay 113a is in the closed state, the contacts of the relay 113a are connected to each other, and power can flow through the distribution line L2. On the other hand, when the relay 113a is in the open state, the connection between the contacts of the relay 113a is released, and power cannot flow through the distribution line L2.

  The branch breaker 113b cuts off the power distribution when an overcurrent or a leakage occurs. The branch breaker 113b is provided in the middle of the distribution line (hereinafter referred to as distribution line L3) connecting the switching panel 113 and the second specific circuit 116 in the switching panel 113. Here, one end of the distribution line L3 is connected to the middle part of the distribution line L2 (upstream side of the relay 113a (leakage breaker 112 side)) in the switching panel 113.

  The switch board 113 can control the operation of the relay 113a. The switching board 113 is connected to the fourth current sensor 109, and can detect the occurrence of a power failure based on the detection value of the fourth current sensor 109.

  Next, the manner in which the power distribution path is switched by the switching panel 110 and the switching panel 113 will be described with reference to FIGS.

  First, the case where a power failure has not occurred (hereinafter referred to as normal time) will be described with reference to FIGS. 5 and 6.

  At the normal time, the switching board 110 switches the first relay 110a to the closed state and switches the second relay 110b to the open state. The switch board 113 switches the relay 113a to the closed state. The independent power conditioner 203 performs grid connection (load following operation).

  In this state, the power from the system power source S, the independent photovoltaic power generation unit 201, and the independent power storage device 202 is supplied to the incoming distribution board 101 via the connection point P9. The electric power is appropriately supplied to the security light 14 and the quick charger 15 via the connection point P1 and the connection point P2 arranged on the downstream side. Moreover, the electric power is supplied to each house via the connection point P3, the connection point P4, and the connection point P5.

  Focusing on the first house 11, the power from the distribution board 101 (power purchased) is supplied to the general circuit 114 and the second specific circuit 116 via the switching board 113. In addition, the electric power from the incoming distribution board 101 is supplied to the first specific circuit 115 via the switching board 113 and the power conditioner 119. At this time, the power conditioner 119 can supply the power from the switching panel 113 to the first specific circuit 115 from the terminal for independent operation through a bypass circuit provided in the power conditioner 119. it can.

  Further, as described above, the power conditioner 119 performs grid connection (load following operation), and surplus power is appropriately sold (sold) to the incoming distribution board 101 (power retailer). Accordingly, power interchange with other houses is appropriately performed.

  Next, a case where a power failure occurs (hereinafter referred to as an emergency) will be described with reference to FIGS. 7 and 8.

  In an emergency, the switching board 110 switches the first relay 110a to the open state and switches the second relay 110b to the closed state. The switch board 113 switches the relay 113a to the open state. The independent power conditioner 203 performs an independent operation.

  In this state, power from the independent photovoltaic power generation unit 201 and the independent power storage device 202 is supplied to the power distribution board 101 via the power transformer 204. The electric power is appropriately supplied to the security light 14 and the quick charger 15 via the connection point P1 and the connection point P2 arranged on the downstream side. Moreover, the electric power is supplied to each house via the connection point P3, the connection point P4, and the connection point P5.

  Focusing on the first house 11, the power from the distribution board 101 (power purchased) is supplied to the second specific circuit 116 via the switching board 113. At this time, the supply of power to the general circuit 114 is interrupted. In this way, the power consumption can be suppressed by shutting off the supply of power to the general circuit 114 that has a relatively low power requirement at the time of a power failure. Thus, wasteful consumption of power stored in the power storage device (the independent power storage device 202 or the power storage device 118) can be suppressed. In addition, the electric power from the incoming distribution board 101 is supplied to the first specific circuit 115 via the switching board 113 and the power conditioner 119.

  In this state, since the current is detected by the first current sensor 106, the power conditioner 119 determines that a power failure has not occurred, and performs grid connection (load following operation) in the same manner as normal. . Accordingly, power interchange with other houses is appropriately performed.

  Strictly speaking, immediately after a power failure occurs (before the second relay 110b of the switching panel 110 is switched to the closed state), no current is detected by the first current sensor 106. For this reason, the power conditioner 119 determines that a power failure has occurred, and stops the grid connection. However, immediately after that, the second relay 110b is switched to the closed state, and the first current sensor 106 detects the current. For this reason, the power conditioner 119 starts grid connection again.

  As shown in FIG. 9, when there is no power stored in the independent power storage device 202 in the state where a power failure has occurred (strictly speaking, output from the terminal for independent operation of the independent power conditioner 203) In the case where the amount of power storage is reduced to an extent that is impossible), it becomes impossible to supply power from the independent power conditioner 203 to the incoming distribution board 101. In this case, the power conditioner 119 of each house determines that a power failure has occurred because the current is not detected by the first current sensor 106 or the like, and performs independent operation.

  That is, in this case, in each house, the electric power from the solar power generation unit 117 and the power storage device 118 is supplied to the first specific circuit 115 via the terminal for independent operation of the power conditioner 119. As described above, when the amount of power stored in the independent power storage device 202 becomes equal to or less than a predetermined value during a power failure, power is supplied only to the first specific circuit 115 in each house. Thereby, wasteful consumption of power can be more effectively suppressed.

As described above, the power interchange system 100 according to the present embodiment is
A power accommodation system 100 for accommodating power between three houses (buildings) having loads (general circuit 114, first specific circuit 115, and second specific circuit 116) that consume power,
An independent power storage device 202 provided independently of the three houses and capable of charging and discharging power from the system power source S;
A power storage device 118 (individual power storage device) provided in each of the three houses, capable of charging and discharging power from the system power source S and the independent power storage device 202;
When a power failure has not occurred, power from the system power source S and the independent power storage device 202 can be supplied to the load and the power storage device 118, and when a power failure has occurred, the power from the independent power storage device 202 can be supplied. An independent power conditioner 203 (first switching unit) that can supply power to the load and the power storage device 118;
It comprises.
By comprising in this way, electric power can be appropriately accommodated even if a power failure occurs. That is, even during a power failure, the power stored in the independent power storage device 202 can be supplied to the three houses, and the occurrence of power shortage can be suppressed. In particular, in the present embodiment, the power storage device 118 of each house performs grid interconnection (load following operation) in the same way as normal based on the power from the independent power storage device 202. Electric power interchange can be performed smoothly.

In addition, the power interchange system 100
A solar power generation unit 117 (individual power generation device) that is provided in each of the three homes and can supply power to the load and the power storage device 118 of each home is further provided.
By comprising in this way, the electric power generated in the solar power generation part 117 can be utilized in the three houses. In particular, the occurrence of power shortage can be suppressed by using the power from the solar power generation unit 117 during a power failure.

In addition, the power interchange system 100
Further comprising an independent photovoltaic power generation unit 201 (independent power generation device) provided independently of the three houses,
The independent power conditioner 203 is
When a power failure has not occurred, the power from the system power source S, the independent power storage device 202, and the independent solar power generation unit 201 can be supplied to the load and the power storage device 118. The electric power from the independent power storage device 202 and the independent solar power generation unit 201 can be supplied to the load and the power storage device 118.
By comprising in this way, the electric power generated in the independent solar power generation unit 201 can be used in the three houses. In particular, the occurrence of power shortage can be suppressed by using the power from the independent solar power generation unit 201 during a power failure.

The load is
Including general circuit 114 (limit load),
Each of the three houses is further provided with a switching panel 113 (second switching unit) that cannot supply power to the general circuit 114 when a power failure occurs.
By comprising in this way, the useless consumption of the electric power at the time of a power failure can be suppressed. As a result, it is possible to ensure a period during which power can be used during a power failure over a long period of time.

The load is
Including a first specific circuit 115 (important load),
Provided in each of the three houses, when a power failure occurs and the amount of power stored in the independent power storage device 202 falls below a predetermined value, the power from the power storage device 118 is supplied only to the first specific circuit 115. And a power conditioner 119 (third switching unit) that can be supplied.
With such a configuration, when a power failure occurs and the power stored in the independent power storage device decreases, the power of the power storage device 118 can be used. At the same time, wasteful consumption of power can be further suppressed. Accordingly, even if the power of the independent power storage device 202 is reduced, the power can be used in each house.

In addition, the smart city 1 (residential block) according to this embodiment is
A power interchange system 100;
A plurality of houses (accommodating houses) configured to allow power to be interchanged by the power accommodation system 100;
It comprises.
By comprising in this way, even if it is a case where a power failure generate | occur | produces, electric power can be interchanged appropriately between several houses.

The general circuit 114, the first specifying circuit 115, and the second specifying circuit 116 are an embodiment of a load.
The general circuit 114 is an embodiment of a limit load.
The first specifying circuit 115 is an embodiment of an important load.
The three houses (the first house 11, the second house 12, and the third house 13) are an embodiment of a building and a flexible house.
Power storage device 118 is an embodiment of an individual power storage device.
The independent power conditioner 203 is an embodiment of the first switching unit.
Moreover, the solar power generation unit 117 is an embodiment of the individual power generation device.
The independent solar power generation unit 201 is an embodiment of an independent power generation apparatus.
The switching board 113 is an embodiment of the second switching unit.
The power conditioner 119 is an embodiment of the third switching unit.
Smart city 1 is an embodiment of a residential block.

  Although the first embodiment has been described above, the present invention is not limited to the above-described configuration, and various modifications can be made within the scope of the invention described in the claims.

  For example, the building is not limited to a house (for the purpose of living), but may be various other buildings.

  Moreover, the electrical products etc. connected to the general circuit 114, the 1st specific circuit 115, and the 2nd specific circuit 116 can be selected arbitrarily.

  In addition, the individual power generation device and the independent power generation device are not limited to the solar power generation unit 117 and the independent solar power generation unit 201, and other devices capable of generating power (for example, power generation devices using natural energy (wind power generation devices, etc.), A fuel cell).

  Further, in the present embodiment, when the amount of electric power (electric storage amount) stored in the independent power storage device 202 is lost (below a predetermined value), electric power is supplied only to the first specific circuit 115. However, the value (predetermined value) of the power storage amount can be set arbitrarily.

  Moreover, the number of houses in the residential block is not limited to three, and any number of houses can be provided.

  Moreover, although the security light 14 and the quick charger 15 are connected to the first power extraction unit 104 and the second power extraction unit 105, respectively, other arbitrary electrical products can be connected. is there.

  The operation of each member of the power interchange system 100 can be controlled by a control unit provided in each member, or a controller that manages the operation of the entire power interchange system 100 can be performed collectively. is there.

  Below, the electric power interchange system 200 which concerns on 2nd embodiment is demonstrated using FIG. The power interchange system 200 according to the second embodiment is mainly different from the power interchange system 100 according to the first embodiment in that a sub power meter 120 is provided. Therefore, below, the said difference is demonstrated and the same code | symbol is attached | subjected about the structure similar to 1st embodiment other than that, and description is abbreviate | omitted.

  The sub-electricity sales meter 120 detects the amount of power that each house sells (sells power) via the incoming distribution board 101. The sub power meter 120 is provided in each house (the first house 11, the second house 12, and the third house 13). Specifically, the sub power meter 120 of the first house 11 is disposed between the power conditioner 119 of the first house 11 and the interconnection point P6. Further, the sub-electricity sales meter 120 of the second house 12 is disposed between the power conditioner 119 of the second house 12 and the connection point P7. Further, the sub-electricity sales meter 120 of the third house 13 is disposed between the power conditioner 119 of the third house 13 and the connection point P8.

  By configuring in this way, the amount of power that each house buys and sells is detected by the sub power purchase meter 111 and the sub power sale meter 120 provided in each house, and can be grasped by the power retailer. For this reason, the power generated by the solar power generation unit 117 of a certain house is prevented from being used in other houses without knowing it, thereby reducing unfairness when accommodating the power. can do.

  Below, the electric power interchange system 300 which concerns on 3rd embodiment is demonstrated using FIG. The power interchange system 300 according to the third embodiment is mainly different from the power interchange system 200 according to the second embodiment in that the V2H system 30 is provided. Therefore, below, the said difference is demonstrated and the code | symbol same about the structure similar to 2nd embodiment is attached | subjected, and description is abbreviate | omitted. Moreover, in FIG. 11, the 2nd house 12 and the 3rd house 13 are simplified and shown suitably.

  The V2H (Vehicle to Home) system 30 is an electric vehicle (EV), a plug-in hybrid vehicle (PHV), a fuel cell vehicle (FCV), and the like. It is for use in one house 11 or the like. The V2H system 30 mainly includes a solar power generation unit 301, an EV 302, a power conditioner 303, and the like.

  The power conditioner 303 is connected to a connection point P9 arranged in the middle of the distribution line L. Further, the power conditioner 303 is connected to the switching panel 110 via a terminal for independent operation. Further, the power conditioner 303 is a value detected by the fifth current sensor 304 (distributed through the distribution line L) provided in the middle of the distribution line L (on the downstream side of the parent power meter 103 and on the upstream side of the connection point P9). Power amount) to be received.

  In addition, since the structure of the solar power generation part 301 and the power conditioner 303 is substantially the same as the structure of the independent solar power generation part 201 and the independent power conditioner 203, description is abbreviate | omitted.

  The EV 302 includes a power storage device that can charge and discharge electric power. The EV 302 can be connected to the power conditioner 303. When the EV 302 is connected, the power conditioner 303 can accommodate the electric power stored in the power storage device of the EV 302 to the first house 11 or the like. Moreover, the electric power from the system | strain power supply S can be suitably stored in the electrical storage apparatus of EV302.

  When such a V2H system 30 is provided, the independent power conditioner 203 and the like of the common station 21 are connected to the downstream side of the distribution line L from the V2H system 30. Specifically, the independent power conditioner 203 of the common station 21 is connected to the interconnection point P10 arranged on the distribution line L on the downstream side of the switching board 110 and on the upstream side of the interconnection point P1.

  In the power interchange system 300 configured as described above, the power distribution path is switched by the switching panel 110 in the event of a power failure, and the power from the photovoltaic power generation unit 301 and the EV 302 can be supplied to each house via the switching panel 110. It is said.

  When the V2H system 30 is provided in the power interchange system 400, the quick charger 15 as shown in the second embodiment or the like is not necessary.

  Further, in the example of FIG. 11, the example in which the EV 302 is connected to the power conditioner 303 is shown, but it is also possible to connect PHV, FCV, or the like instead of the EV 302.

DESCRIPTION OF SYMBOLS 1 Smart city 100 Power interchange system 110 Switching board 114 General circuit 115 1st specific circuit 116 2nd specific circuit 117 Solar power generation part 118 Power storage device 201 Independent solar power generation part

Claims (6)

An electric power interchange system for accommodating electric power between a plurality of buildings having loads that consume electric power,
An independent power storage device provided independently of the plurality of buildings and capable of charging and discharging power from a system power supply;
An individual power storage device provided in each of the plurality of buildings, capable of charging and discharging power from the system power supply and the independent power storage device;
A power conditioner that is provided in each of the plurality of buildings and performs load following operation of the individual power storage device;
When a power failure has not occurred, power from the grid power source and the independent power storage device can be supplied to the load and the individual power storage device, and when a power failure occurs, from the independent power storage device A first switching unit that can supply the power to the load and the individual power storage device,
A power interchange system comprising: An individual power generation device provided in each of the plurality of buildings, and further capable of supplying power to the load and the individual power storage device of each building;
The power interchange system according to claim 1. Further comprising an independent power generation device provided independently of the plurality of buildings,
The first switching unit is
When a power failure has not occurred, power from the grid power source, the independent power storage device and the independent power generation device can be supplied to the load and the individual power storage device, and when a power failure has occurred, The power from the independent power storage device and the independent power generation device can be supplied to the load and the individual power storage device.
The power interchange system according to claim 1 or 2. The load is
Including limit load,
Provided in each of the plurality of buildings, and when a power failure occurs, further comprising a second switching unit that makes it impossible to supply power to the limited load,
The electric power interchange system as described in any one of Claim 1- Claim 3. The load is
Including critical loads,
Provided in each of the plurality of buildings, when a power failure occurs and the amount of power stored in the independent power storage device becomes a predetermined value or less, the power from the individual power storage device is transferred only to the important load. A third switching unit that enables supply;
The electric power interchange system as described in any one of Claim 1- Claim 4. The power interchange system according to any one of claims 1 to 5,
A plurality of flexible housings configured such that power can be interchanged with each other by the power interchange system;
A residential area with

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