JP2017038490A - Disaster prevention warehouse - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a disaster prevention warehouse which can supply electric power to a load for a long time at a power failure.SOLUTION: The disaster prevention warehouse includes: a building body having a specific load 22; a first power generation unit 40 having power storage capability and capable of supplying power to the specific load 22; a second power generation unit 50 having electric generation capability and capable of supplying power to the specific load 22; and a first automatic switch board 60 inserted in distribution lines L5, L7-L10, to select, as a power source for supplying power to the specific load 22, the first power generation unit 40 or the second power generation unit 50. When the second power generation unit 50 generates electricity at a power failure, the first automatic switch board 60 selects the second power generation unit 50 to supply power to the specific load 22, whereas when the second power generation unit 50 does not generate electricity at the power failure, the first power generation unit 40 is selected to supply power to the specific load 22.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a technology for a disaster prevention warehouse including a power storage unit having a power storage capability and a power generation unit having a power generation capability.

  2. Description of the Related Art Conventionally, a technology for a disaster prevention warehouse including a power storage unit having a power storage capability and a power generation unit having a power generation capability has been publicly known. For example, as described in Patent Document 1.

  The disaster prevention warehouse described in Patent Document 1 supplies electric power from a commercial power source to a load (such as an electric lamp or a ventilation fan provided inside) during a non-power failure. Moreover, the said disaster prevention warehouse supplies the electric power from a power generation unit (solar cell or wind power generator) and an electrical storage unit (storage battery) to a load at the time of a power failure.

JP 2004-352477 A

  However, the disaster prevention warehouse described in Patent Document 1 discharges the power storage unit without considering the power generation state of the power generation unit during a power failure. For this reason, the said disaster prevention warehouse may discharge an electrical storage unit, even when it can cover the power consumption of load with the electric power from a power generation unit. In this case, there is a possibility that the remaining amount of the power storage unit that can stably supply electric power is not short. Therefore, the disaster prevention warehouse may not be able to supply power to the load for a long time during a power failure.

  This invention is made | formed in view of the above situations, The subject which it is going to solve is providing the disaster prevention warehouse which can supply electric power to a load for a long time at the time of a power failure.

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

  That is, the building body 10 having a load, a power storage unit having a power storage capability and capable of supplying power to the load, a power generation unit having a power generation capability and capable of supplying power to the load, and the power storage A first switching panel that is inserted into a unit and an electrical path connecting the power generation unit and the load, and switches a power supply source to the load to the power storage unit or the power generation unit, and the first switching panel Switches the power supply source to the load to the power generation unit if the power generation unit is generating power during a power failure, and switches the power supply source to the power storage unit if the power generation unit is not generating power during a power failure Is.

A second switching board that is inserted in an electric path connecting the power storage unit and the first switching board, and that switches power supply permission / rejection from the power storage unit to the load; Power supply from the power storage unit to the load may be prohibited during a power failure, and power supply from the power storage unit to the load may be permitted during a power failure.
With such a configuration, the power supply source to the load can be quickly switched between the power storage unit and the power generation unit.

The contact relay is inserted in an electric circuit connecting the first switching panel and the second switching panel, and further includes a contact relay for connecting and disconnecting the electric circuit. The connection of the electric circuit connecting the switching panel and the second switching panel may be connected, and the connection of the electric circuit connecting the first switching panel and the second switching panel may be canceled when there is no power failure.
With such a configuration, the power supply source to the load can be quickly switched between the power storage unit and the power generation unit.

The building main body has a load different from the load, and the power storage unit and the power generation unit are used as a power supply source to the load and the different load without going through the first switching panel when there is no power failure. It is good.
With such a configuration, it is possible to reduce the amount of power supplied during a power failure.

A power storage device that is inserted in an electrical path connecting the first switching panel and the load, and that can charge and discharge power from at least one of the power storage unit, the power generation unit, or a commercial power source and is portable. It may be further provided.
With such a configuration, electric power can be used at a predetermined place during a power failure.

The power storage unit includes a power generation device having a power generation capability, a power storage device capable of charging / discharging the power of the power generation device, and capable of supplying the power generated by the power generation device to the power storage device and the load and the power storage And a power conditioner capable of supplying power discharged from the apparatus to the load.
With such a configuration, it is possible to supply power to the load for a long time at the time of a power failure.

  Long-term power can be supplied to the load during a power outage.

The perspective view which showed the inside of a disaster prevention warehouse. The block diagram which showed the structure of the disaster prevention warehouse. The figure which showed a mode that electric power was supplied to load at the time of a non-power failure. The figure which showed a mode that the electric power of a 2nd electric power generation unit was supplied to load at the time of a power failure. The figure which showed a mode that the electric power of a 1st electric power generation unit was supplied to a load at the time of a power failure.

  In the following description, the up-down direction, the left-right direction, and the front-rear direction are defined according to the arrows shown in the figure.

  Below, the disaster prevention warehouse 1 which concerns on one Embodiment of this invention is demonstrated.

  The disaster prevention warehouse 1 shown in FIGS. 1 and 2 serves as a disaster prevention base when a disaster or a large-scale power outage occurs. The disaster prevention warehouse 1 includes a building body 10, a power storage device 30, a first power generation unit 40, a second power generation unit 50, a first automatic switching panel 60, a second automatic switching panel 70, and a contact relay 80.

  The building body 10 includes a floor 11 and a roof (not shown). The building body 10 is surrounded by a plurality of walls on four sides. More specifically, the building body 10 is disposed at the front wall portion 12 disposed at the front portion, the rear wall portion 13 disposed at the rear portion, the left wall portion 14 disposed at the left portion, and the right portion. The right wall portion 15 is formed so as to surround the front-rear direction and the left-right direction. The building body 10 is formed in a substantially rectangular shape in plan view with its longitudinal direction directed in the left-right direction. The building body 10 according to the present embodiment has a large internal shape that can be used as a garage for an electric vehicle.

  A shelf 16 is provided at the left end of the front wall 12 of the building body 10. On the shelf 16, emergency supplies 30 a (for example, blankets, helmets, etc.) are arranged. The front wall portion 12 and the left wall portion 14 are provided with an outlet 22a for a specific load 22 to be described later. The rear wall portion 13 is opened at the left portion, and a door 17 through which a person can enter and exit is provided at the opened portion. Further, the rear wall portion 13 is opened from the right and left halfway portion to the right end portion, and a shutter 18 through which the electric vehicle can enter and exit is provided at the opened portion.

  The building body 10 configured as described above includes a general load 21, a specific load 22, and a charging outlet 23.

  The general load 21 is a device that does not have a big trouble even if power is not supplied during a power failure. Examples of the general load 21 include a security camera and a security light. The general load 21 is supplied with electric power from the commercial power supply 100 via the distribution lines L1 to L3.

  The distribution line L1 has one end connected to the commercial power supply 100 and the other end connected to the power conditioner 52 of the second power generation unit 50 described later. The distribution line L2 has one end connected to the middle part of the distribution line L1 and the other end connected to the distribution board B21. Leakage breakers B11 and B12 are provided in the middle of the distribution lines L1 and L2. The distribution line L3 has one end connected to the distribution board B21 and the other end connected to the general load 21.

  The specific load 22 is a device that is preferably supplied with power during a power failure. Examples of the specific load 22 include indoor lighting, an outlet 22a, a ventilation fan, and a transducer that converts signals from a pyranometer and a thermometer. The specific load 22 is supplied with power from the commercial power supply 100 via the distribution lines L1, L2, L4, and L5 when no power failure occurs.

  Distribution line L4 has one end connected to distribution board B21 and the other end connected to power storage device 30 described later. Distribution line L5 has one end connected to power storage device 30 and the other end connected to specific load 22. Terminal blocks T1 and T2 are provided in the middle of the distribution lines L4 and L5.

  The charging outlet 23 is for charging a power storage device of an electric vehicle. The power outlet 23 is supplied with power from the commercial power source 100 via the distribution lines L1, L2, L6, and L7 when no power failure occurs.

  One end of the distribution line L6 is connected to the middle part of the distribution line L2 (commercial power supply 100 side with respect to the leakage breaker B12), and the other end is connected to the power conditioner 43 of the first power generation unit 40 described later. An earth leakage breaker B13 is provided in the middle of the distribution line L6. The distribution line L7 has one end connected to the power conditioner 43 and the other end connected to the charging outlet 23. A terminal block T3 is provided in the middle of the distribution line L7.

  The power storage device 30 is a device configured to be able to charge / discharge electric power from the commercial power source 100 or the like. The power storage device 30 includes a storage battery composed of a lithium ion battery, a nickel metal hydride battery, or the like that can charge and discharge power, a charger that rectifies supplied AC power and charges the storage battery, and direct current power from the storage battery. The inverter which converts into alternating current power and outputs it, the control part which controls charging / discharging of the said storage battery, etc. are comprised. The power storage device 30 is configured to be portable with a handle or the like, for example. The power storage device 30 is disposed inside the building body 10. The power storage device 30 includes an independent operation outlet 31.

  The independent operation outlet 31 is for supplying electric power to the storage battery at the time of a power failure. Self-supporting outlet 31 is provided on the side surface of power storage device 30.

  Distribution lines L4 and L5 are connected to power storage device 30 configured as described above. In addition, a distribution line L9, which will be described later, is connected to the independent operation outlet 31. The power storage device 30 is configured to be able to discharge power to the distribution line L5 while charging power supplied from the distribution lines L4 and L9. In addition, the power storage device 30 is configured to be able to distribute the power supplied from the distribution lines L4 and L9 to the distribution line L5 as it is (without being charged) when the battery is fully charged. Thereby, the power storage device 30 can supply power from the commercial power supply 100 or the like to the specific load 22.

  The first power generation unit 40 is a facility capable of generating and storing electricity. The first power generation unit 40 includes a solar cell panel 41, a power storage device 42, and a power conditioner 43.

  The solar cell panel 41 generates power using sunlight. The solar cell panel 41 is configured by attaching a plurality of solar cells to a frame. The solar cell panel 41 generates power when sunlight hits the solar cell. The solar cell panel 41 is laid on a sunny place, in the present embodiment, on the roof of the building body 10.

  The power storage device 42 is a device configured to be able to charge and discharge the power generated by the solar cell panel 41 and the power from the commercial power source 100. The power storage device 42 includes a storage battery, a charger that rectifies supplied AC power and charges the storage battery, an inverter that converts DC power from the storage battery into AC power, and the like. The power storage device 42 is installed, for example, on the left side of the building body 10.

  The power conditioner 43 is a hybrid power conditioner that appropriately converts power from the solar cell panel 41, the power storage device 42, and the commercial power supply 100. The power conditioner 43 is disposed closer to the commercial power supply 100 than the solar cell panel 41 and the power storage device 42, and is connected to the solar cell panel 41 and the power storage device 42 via two different distribution lines. The power conditioner 43 includes a converter that appropriately converts DC power generated by the solar battery panel 41 into a predetermined voltage, an inverter that converts DC power to AC power, a control unit that controls operations, and the like. The power conditioner 43 is configured to be able to supply the power generated by the solar battery panel 41 to the power storage device 42. The power conditioner 43 is connected to a voltage sensor provided in the distribution line L1. A signal related to the supply voltage from the commercial power supply 100 is input to the power conditioner 43 from the voltage sensor. The power conditioner 43 is configured to detect a power failure based on the signal.

  The power conditioner 43 is connected to the charging outlet 23 via the distribution line L7. The power conditioner 43 is connected to the commercial power supply 100 via the distribution lines L6, L2, and L1. The power conditioner 43 is connected to the general load 21 via the distribution lines L6, L2, and L3. The power conditioner 43 is connected to the specific load 22 via the distribution lines L6, L2, L4, and L5. The power conditioner 43 is also connected to the specific load 22 via the distribution lines L7 to L9 and L5.

  The distribution line L8 has one end connected to the terminal block T3 (middle part of the distribution line L7) and the other end connected to the middle part of the distribution line L9. Distribution line L9 has one end connected to terminal block T1 (the middle part of distribution line L4) and the other end connected to self-sustained operation outlet 31 of power storage device 30.

  The power conditioner 43 configured as described above can perform the interconnection operation and the independent operation. In the interconnected operation, the solar cell panel 41 and the power storage device 42 are operated in conjunction with the commercial power source 100 to supply power to the general load 21 and the like. In the self-sustained operation, the solar battery panel 41 and the power storage device 42 are operated independently from the commercial power supply 100 to supply power to the specific load 22 and the like. The power supply mode in the case of performing the interconnection operation and the independent operation will be described in detail later.

  The second power generation unit 50 is a facility capable of generating power. The second power generation unit 50 includes a solar cell panel 51 and a power conditioner 52.

  The solar cell panel 51 is configured in the same manner as the solar cell panel 41 of the first power generation unit 40.

  The power conditioner 52 converts the DC power generated by the solar cell panel 51 into AC power. The power conditioner 52 is connected to the solar cell panel 51 via a predetermined distribution line. The power conditioner 52 is connected to a voltage sensor provided in the distribution line L1. A signal related to the supply voltage from the commercial power supply 100 is input to the power conditioner 52 from the voltage sensor. The power conditioner 52 is configured to be able to detect a power failure based on the signal. The power conditioner 52 includes an autonomous operation outlet 52a.

  The independent operation outlet 52a is supplied with electric power from the solar cell panel 51 at the time of a power failure.

  The power conditioner 52 is connected to the commercial power supply 100 via the distribution line L1. The power conditioner 52 is connected to the general load 21 via the distribution lines L1 to L3. The power conditioner 52 is connected to the charging outlet 23 via the distribution lines L1, L2, L6, and L7. The power conditioner 52 is connected to the specific load 22 via the distribution lines L1, L2, L4, and L5. The power conditioner 52 is also connected to the specific load 22 via the distribution lines L10, L9, and L5.

  The distribution line L10 has one end connected to the self-sustained operation outlet 52a and the other end connected to a midway part of the distribution line L9.

  The power conditioner 52 configured as described above can perform the interconnection operation and the independent operation. The power supply mode in the case of performing the interconnection operation and the independent operation will be described in detail later.

  The first automatic switching board 60 switches the power supply source to the specific load 22 to the first power generation unit 40 or the second power generation unit 50. The first automatic switching panel 60 is provided at the connection portion of the distribution lines L9 and L10. The first automatic switching board 60 is connected to the power conditioner 52 of the second power generation unit 50. The first automatic switching panel 60 receives signals relating to the operating state and the power generation amount of the solar battery panel 51 from the power conditioner 52. The first automatic switching panel 60 is configured to be able to detect whether the solar cell panel 51 is generating power during the self-sustaining operation based on the signal. The first automatic switching board 60 includes a first relay 61 and a second relay 62.

  The first relay 61 performs connection of the distribution line L10 and release of the connection (switching of the open / closed state). The first relay 61 is provided at the other end of the distribution line L10 (in the first automatic switching panel 60). When the first relay 61 is in a closed state, the distribution line L10 (the contacts of the first relay 61) are connected. On the other hand, when the first relay 61 is in the open state, the connection of the distribution line L10 is released.

  The second relay 62 performs connection of the distribution line L9 and release of the connection (switching of the open / closed state). The second relay 62 is provided in the middle part of the distribution line L9 (in the first automatic switching panel 60). When the second relay 62 is closed, the distribution line L9 (the contacts of the second relay 62) are connected. On the other hand, when the second relay 62 is opened, the connection of the distribution line L9 is released.

  The first automatic switching board 60 configured in this way performs exclusive control to make one of the first relay 61 and the second relay 62 open and the other closed.

  The second automatic switching panel 70 switches permission / inhibition of power supply from the first power generation unit 40 to the specific load 22. The second automatic switching panel 70 is provided at the connection portion of the distribution lines L8 and L9. The second automatic switching panel 70 is arranged closer to the first power generation unit 40 than the first automatic switching panel 60. The second automatic switching board 70 is connected to a voltage sensor provided on the distribution line L1. A signal relating to the supply voltage from the commercial power supply 100 is input to the second automatic switching board 70 from the voltage sensor. The second automatic switching board 70 is configured to detect a power failure based on the signal. The second automatic switching board 70 includes a first relay 71 and a second relay 72.

  The first relay 71 performs connection of the distribution line L8 and release of the connection (switching of the open / closed state). The first relay 71 is provided at the other end of the distribution line L8 (in the second automatic switching panel 70). When the first relay 71 is in a closed state, the distribution line L8 (contacts of the first relay 71) is connected. On the other hand, when the first relay 71 is in the open state, the connection of the distribution line L8 is released.

  The second relay 72 is for connecting the distribution line L9 and releasing the connection (switching the open / close state). The second relay 72 is provided in the middle part of the distribution line L9 (in the second automatic switching panel 70). When the second relay 72 is in a closed state, the distribution line L9 (the contacts of the second relay 72) are connected. On the other hand, when the second relay 72 is opened, the connection of the distribution line L9 is released.

  The second automatic switching board 70 configured in this way performs exclusive control to make one of the first relay 71 and the second relay 72 open and the other closed.

  The contact relay 80 performs connection of the distribution line L9 and release of the connection (switching of the open / closed state). The contact relay 80 is provided between the first automatic switching board 60 and the second automatic switching board 70. The contact relay 80 is connected to the voltage sensor provided on the distribution line L1. A signal related to the supply voltage from the commercial power source 100 is input to the contact relay 80 from the voltage sensor. The contact relay 80 is configured to detect a power failure based on the signal. When the contact relay 80 is closed, the distribution line L9 (contacts of the contact relay 80) is connected. On the other hand, when the contact relay 80 is opened, the connection of the distribution line L9 is released.

  Next, the power supply mode at the time of non-power failure in the disaster prevention warehouse 1 will be described with reference to FIG.

  The power conditioners 43 and 52 determine that a power failure has not occurred based on a signal from a voltage sensor provided in the distribution line L1, and perform an interconnection operation. At this time, the power conditioner 52 supplies the power generated by the solar cell panel 51 to the general load 21, the specific load 22, and the charging outlet 23 together with the power from the commercial power supply 100 via the distribution lines L1 to L7. The power conditioner 43 supplies the power from the second power generation unit 50 and the commercial power source 100 to the charging outlet 23 as it is via the distribution line L7, and charges the power storage device 42 with the power generated by the solar cell panel 41. To do. In addition, the power conditioner 43 generates power generated by the solar panel 41 via the distribution lines L2 to L7 together with the power from the commercial power supply 100 and the specific load when the power storage device 42 is fully charged. 22 and charging outlet 23.

  The first automatic switching panel 60 confirms that the power conditioner 52 is operating in an interconnected manner based on a signal from the power conditioner 52 of the second power generation unit 50. Then, the first automatic switching board 60 brings the first relay 61 into an open state and the second relay 62 into a closed state.

  The second automatic switching board 70 determines that no power failure has occurred based on the signal from the voltage sensor provided in the distribution line L1, and opens the first relay 71 and the second relay 72. Is closed.

  The contact relay 80 determines that no power failure has occurred based on a signal from a voltage sensor provided in the distribution line L1, and opens the contact relay 80.

  Here, the power flowing through the distribution line L4 also flows to the distribution line L9 via the terminal block T1. Since the second relay 72 of the second automatic switching panel 70 is in the closed state, the electric power flows from the second automatic switching panel 70 to the contact relay 80. However, since the contact relay 80 is in the open state, the electric power does not flow downstream from the contact relay 80 (on the power storage device 30 side).

  Moreover, the electric power which distribute | circulates the distribution line L7 distribute | circulates also to the distribution line L8 via the terminal block T3. However, since the first relay 71 of the second automatic switching panel 70 is in the open state (power supply from the first power generation unit 40 to the specific load 22 is prohibited), the electric power is The automatic switching panel 70 is not distributed downstream (the power storage device 30 side).

  The power conditioners 43 and 52 reversely flow (sell power) the surplus power to the commercial power supply 100 via the distribution line L1 and the like when there is surplus power from the solar battery panels 41 and 51 at the time of the power failure. In addition, the power conditioner 43 is connected to the second power generation unit 50 and the commercial power source 100 as needed during a non-power failure (when the solar cell panel 41 is not generating power or when the remaining amount of the power storage device 42 is low). Is charged in the power storage device 42.

  Next, the power supply mode at the time of a power failure in the disaster prevention warehouse 1 will be described with reference to FIGS. 4 and 5.

  In the disaster prevention warehouse 1 according to the present embodiment, the power supply mode changes according to the power generation state (power generation presence / absence) of the second power generation unit 50 during a power failure. For this reason, first, the supply mode of electric power when the second power generation unit 50 is generating power during a power failure will be described with reference to FIG. In the following, it is assumed that a power failure has occurred during power generation by the second power generation unit 50.

  The power conditioners 43 and 52 detect a power failure based on a signal from a voltage sensor provided in the distribution line L1, and switch from the grid operation to the independent operation. At this time, the power conditioner 43 distributes the electric power generated by the solar cell panel 41 to the distribution line L7 and supplies it to the charging outlet 23. Moreover, the power conditioner 52 supplies the electric power generated by the solar cell panel 51 to the independent operation outlet 52a.

  The first automatic switching panel 60 confirms that the power conditioner 52 is operating independently based on the signal from the power conditioner 52 of the second power generation unit 50 and confirms that the solar panel 51 is generating power. Check. Then, the first automatic switching panel 60 closes the first relay 61 and opens the second relay 62.

  Thereby, the electric power from the second power generation unit 50 (the electric power supplied to the self-sustained operation outlet 52a) flows from the distribution line L10 through the first automatic switching panel 60 and is supplied to the self-sustained operation outlet 31 of the power storage device 30. Is done. The electric power is distributed from the power storage device 30 to the distribution line L5 and supplied to the specific load 22.

  The second automatic switching panel 70 detects a power failure based on a signal from a voltage sensor provided in the distribution line L1, and closes the first relay 71 and opens the second relay 72. .

  The contact relay 80 detects a power failure based on a signal from a voltage sensor provided in the distribution line L1, and switches from an open state to a closed state.

  Thereby, the electric power from the first power generation unit 40 flowing from the distribution line L7 to the distribution line L8 flows from the second automatic switching panel 70 and the contact relay 80 to the first automatic switching panel 60. However, since the second relay 62 of the first automatic switching panel 60 is in the open state (the power supply source to the specific load 22 is the second power generation unit 50), the power is the first The automatic switching panel 60 is not distributed downstream (the power storage device 30 side).

  As described above, the disaster prevention warehouse 1 supplies the power from the second power generation unit 50 to the specific load 22 when the second power generation unit 50 is generating power during a power failure. In addition, the disaster prevention warehouse 1 supplies power from the first power generation unit 40 to the charging outlet 23. That is, the disaster prevention warehouse 1 does not supply the power from the first power generation unit 40 to the general load 21 and the specific load 22. According to this, since the first power generation unit 40 only needs to supply power to the charging outlet 23 as long as the second power generation unit 50 is generating power even during a power failure, The amount can be reduced.

  The power conditioner 43 discharges the power storage device 42 only when the power generated by the solar cell panel 41 cannot cover the power of the charging outlet 23. Thereby, the power conditioner 43 can make it difficult to reduce the remaining amount of the power storage device 42.

  The first power generation unit 40 charges the power storage device 42 with the power generated by the solar battery panel 41 when there is a surplus. Thereby, the power conditioner 43 can increase the remaining amount of the power storage device 42 even during a power failure.

  Next, the supply mode of electric power when the second power generation unit 50 (solar cell panel 51) is not generating power during a power failure will be described with reference to FIG. In the following, it is assumed that the power generation of the second power generation unit 50 is stopped from the state shown in FIG. 4 (the state where the second power generation unit 50 generates power during a power failure). In the following, it is assumed that the power generation of the first power generation unit 40 is also stopped.

  The power conditioners 43 and 52 determine that a power outage has continued to occur based on a signal from a voltage sensor provided in the distribution line L1. For this reason, the power conditioners 43 and 52 continue to operate independently. At this time, since the power generation of the solar cell panel 41 is stopped, the power conditioner 43 discharges the power storage device 42 and supplies the discharged power to the charging outlet 23 via the distribution line L7. Moreover, since the power generation of the solar panel 51 is stopped, no power is supplied to the self-sustained operation outlet 52a.

  The second automatic switching panel 70 and the contact relay 80 determine that a power failure has continued to occur based on a signal from a voltage sensor provided on the distribution line L1. For this reason, the second automatic switching panel 70 and the contact relay 80 do not operate even when the power generation of the second power generation unit 50 is stopped (the state shown in FIG. 4 is maintained).

  The first automatic switching board 60 confirms that the power conditioner 52 is operating independently based on the signal from the power conditioner 52 of the second power generation unit 50 and confirms that the solar cell panel 51 is not generating power. Check. Then, the first automatic switching board 60 brings the first relay 61 into an open state and the second relay 62 into a closed state. Accordingly, the first automatic switching board 60 switches the power supply source to the specific load 22 from the second power generation unit 50 to the first power generation unit 40.

  As a result, the electric power from the first power generation unit 40 is supplied from the second automatic switching panel 70, the contact relay 80, and the first automatic switching panel 60 to the autonomous operation outlet 31 of the power storage device 30. The electric power is distributed from the power storage device 30 to the distribution line L5 and supplied to the specific load 22. Moreover, the electric power from the 1st electric power generation unit 40 is supplied to the charging outlet 23 via the distribution line L7. On the other hand, the power from the first power generation unit 40 is not supplied to the general load 21.

  According to this, the first power generation unit 40 supplies power from the power storage device 42 to the specific load 22 only when it is necessary at the time of a power failure (when the solar cell panels 41 and 51 are in a time zone where power generation is not possible or when bad weather occurs). Can be supplied. For this reason, the 1st electric power generation unit 40 can reduce the electric energy discharged from the electrical storage apparatus 42 at the time of a power failure. As a result, the disaster prevention warehouse 1 can maintain the remaining amount of the power storage device 42 that can stably supply power regardless of the weather or the like for a long period of time, and thus can supply power for a long time during a power failure.

  Further, the second automatic switching panel 70 according to the present embodiment permits power supply from the first power generation unit 40 in advance when a power failure occurs. Thereby, the disaster prevention warehouse 1 can supply electric power to the specific load 22 from the 1st power generation unit 40 or the 2nd power generation unit 50 at the time of a power failure by operating only the 1st automatic switching panel 60. FIG. According to this, the disaster prevention warehouse 1 can switch the electric power supply source quickly (without a big time lag) at the time of a power failure.

  In addition, the disaster prevention warehouse 1 operates the contact relay 80 in advance when a power failure occurs and connects the distribution line L9 so that the power supply source can be quickly detected in the event of a power failure as in the case of the second automatic switching panel 70. Can be switched.

  Further, the first power generation unit 40 and the second power generation unit 50 do not supply power to the general load 21 at the time of a power failure (supply power to the general load 21 only at normal time). According to this, the 1st electric power generation unit 40 and the 2nd electric power generation unit 50 can reduce the electric energy supplied at the time of a power failure.

  Further, in the present embodiment, the disaster prevention warehouse 1 includes a portable power storage device 30. For this reason, the user of the disaster prevention warehouse 1 can use the electric power by carrying the power storage device 30 to a desired place (for example, a shelter) when a disaster or a large-scale power outage occurs. When the power storage device 30 is taken out, the distribution lines L4 and L5 can be connected using a predetermined cable.

  As described above, the disaster prevention warehouse 1 according to the present embodiment includes the building body 10 having the specific load 22 (load), the first power generation unit 40 having the power storage capacity and capable of supplying power to the specific load 22. (Power storage unit), a second power generation unit 50 (power generation unit) having power generation capability and capable of supplying power to the specific load 22, and distribution lines L5, L7 to L10 (first power generation unit 40) And an electric path connecting the second power generation unit 50 and the specific load 22), and the power supply source to the specific load 22 is switched to the first power generation unit 40 or the second power generation unit 50. One automatic switching panel 60 (first switching panel), and the first automatic switching panel 60 is connected to the specific load 22 when the second power generation unit 50 generates power during a power failure. The power source is the second power generation With switching to knit 50 is intended to switch the power supply source of the the second power generation unit 50 is the specific load and not generating power 22 to the first power generation unit 40 in the event of a power failure.

  By comprising in this way, electric power can be supplied to the specific load 22 for a long time at the time of a power failure.

  In addition, power distribution permission from the first power generation unit 40 to the specific load 22 is inserted in the distribution lines L7 to L9 (electric path connecting the first power generation unit 40 and the first automatic switching panel 60). The second automatic switching panel 70 (second switching panel) is further provided, and the second automatic switching panel 70 supplies power from the first power generation unit 40 to the specific load 22 when there is no power failure. While prohibiting, the electric power feeding from said 1st electric power generation unit 40 to the said specific load 22 is permitted at the time of a power failure.

  With this configuration, the power supply source to the specific load 22 can be quickly switched between the first power generation unit 40 and the second power generation unit 50.

  Further, a contact relay 80 that is inserted into the distribution line L9 (the electric path connecting the first automatic switching panel 60 and the second automatic switching panel 70) and that connects and disconnects the distribution line L9 is further provided. The contact relay 80 connects the distribution line L9 during a power failure and releases the connection of the distribution line L9 during a non-power failure.

  With this configuration, the power supply source for the specific load 22 can be quickly switched between the first power generation unit 40 and the second power generation unit 50.

  Moreover, the building body 10 has a general load 21 (a load different from the specific load 22), and the first power generation unit 40 and the second power generation unit 50 are connected to the first automatic power source during a non-power failure. The power supply source to the specific load 22 and the general load 21 is not provided through the switching panel 60.

  By comprising in this way, the electric energy supplied at the time of a power failure can be reduced.

  Further, the first power generation unit 40, the second power generation unit 50, or the commercial power source 100 is inserted into the distribution lines L5 and L9 (electric path connecting the first automatic switching panel 60 and the specific load 22). It further includes a power storage device 30 that can charge and discharge power from at least one of the above and can be carried.

  By comprising in this way, electric power can be used in a desired place at the time of a power failure.

  The first power generation unit 40 is generated by the solar cell panel 41 (power generation device) having power generation capacity, the power storage device 42 capable of charging / discharging the power of the solar cell panel 41, and the solar cell panel 41. And a power conditioner 43 (power conditioner) capable of supplying the electric power discharged from the power storage device 42 to the specific load 22. .

  By comprising in this way, electric power can be supplied to the specific load 22 for a long time at the time of a power failure.

The specific load 22 according to this embodiment is an embodiment of the load.
The power storage unit according to this embodiment is an embodiment of the first power generation unit 40.
The power generation unit according to this embodiment is an embodiment of the second power generation unit 50.
Moreover, the distribution lines L5 and L7 to L10 according to the present embodiment are an embodiment of an electric circuit that connects the power storage unit and the power generation unit to the load.
Moreover, the 1st automatic switch board 60 which concerns on this embodiment is one Embodiment of the 1st switch board which concerns on this invention.
Moreover, the distribution lines L7 to L9 according to the present embodiment are an embodiment of an electric circuit that connects the power storage unit and the first switching board.
Further, the second automatic switching board 70 according to the present embodiment is an embodiment of the second switching board.
The distribution line L9 according to the present embodiment is an embodiment of an electric circuit that connects the first switching board and the second switching board.
Moreover, the distribution lines L5 and L9 according to the present embodiment are an embodiment of an electric circuit that connects the first switching panel and the load.
Moreover, the solar cell panel 41 according to the present embodiment is an embodiment of the power generation device.

  The embodiment of the present invention has been described above, but 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 first power generation unit 40 does not need to include the solar cell panel 41 (having power generation capability).

  The second power generation unit 50 does not need to include the solar cell panel 51 as long as it can generate power. For example, the second power generation unit 50 may include a fuel cell or a wind power generator instead of the solar cell panel 51. The first power generation unit 40 may include a fuel cell or a wind power generator instead of the solar cell panel 41.

  In the present embodiment, the first power generation unit 40 and the second power generation unit 50 supply power to the specific load 22 and the charging outlet 23 at the time of a power failure, but the general load 21 and the specific load 22 at the time of a power failure. Alternatively, power may be supplied to at least one of the charging outlets 23.

  Moreover, in this embodiment, although the electrical storage apparatus 30 shall charge / discharge the electric power from the 1st electric power generation unit 40, the 2nd electric power generation unit 50, and the commercial power source 100, the 1st electric power generation unit 40, the 2nd What is necessary is that the power from at least one of the power generation unit 50 or the commercial power source 100 can be charged and discharged.

  Further, the disaster prevention warehouse 1 does not necessarily need to include the power storage device 30.

  The first power generation unit 40 can also be configured to be able to supply power to an external outlet provided separately in addition to the charging outlet 23 in the event of a power failure. In this case, the first power generation unit 40 may supply power to the external outlet when the charging outlet 23 is not connected to the electric vehicle. Moreover, the 1st electric power generation unit 40 may be equipped with the manual switch which can switch an electric power feeding destination to the charging outlet 23 and an external outlet.

  Moreover, in this embodiment, the power conditioners 43 and 52, the 1st automatic switching board 60, and the 2nd automatic switching board 70 detect a power failure based on the signal input from the voltage sensor provided in the distribution line L1. However, the means for detecting a power failure is not limited to this. For example, the power conditioners 43 and 52, the first automatic switching board 60, and the second automatic switching board 70 may detect a power failure based on a signal input from a predetermined control device capable of detecting the power failure.

1 Disaster prevention warehouse 10 Building body 22 Specific load 40 First power generation unit (storage unit)
50 Second power generation unit (power generation unit)
60 First automatic switchboard (first switchboard)

Claims (6)

A building body having a load;
A power storage unit having power storage capability and capable of supplying power to the load;
A power generation unit having power generation capability and capable of supplying power to the load;
A first switching panel that is inserted in an electrical path connecting the power storage unit and the power generation unit and the load, and switches a power supply source to the load to the power storage unit or the power generation unit;
Comprising
The first switching board is:
When the power generation unit is generating power during a power failure, the power supply source to the load is switched to the power generation unit, and when the power generation unit is not generating power during a power failure, the power supply source to the load is switched to the power storage unit,
Disaster prevention warehouse. A second switching board that is inserted into an electrical path connecting the power storage unit and the first switching board, and that switches power supply permission from the power storage unit to the load;
The second switching board is
Prohibiting power supply from the power storage unit to the load during a non-power failure, and permitting power supply from the power storage unit to the load during a power failure,
The disaster prevention warehouse according to claim 1. Further comprising a contact relay that is inserted in an electric circuit connecting the first switching panel and the second switching panel, and performs connection and release of the electric circuit;
The contact relay is
Connecting the electric circuit connecting the first switching board and the second switching board at the time of a power failure, and releasing the connection of the electric circuit connecting the first switching board and the second switching board at the time of a power failure,
The disaster prevention warehouse according to claim 2. The building body has a load different from the load,
The power storage unit and the power generation unit at the time of a non-power failure, the power supply source to the load and the different load without going through the first switching panel,
The disaster prevention warehouse according to any one of claims 1 to 3. A power storage device that is inserted in an electrical path connecting the first switching panel and the load, and that can charge and discharge power from at least one of the power storage unit, the power generation unit, or a commercial power source and is portable. In addition,
The disaster prevention warehouse according to any one of claims 1 to 4. The power storage unit is
A power generation device having power generation capacity;
A power storage device capable of charging and discharging the power of the power generation device; and
A power conditioner capable of supplying the power generated by the power generation device to the power storage device and the load and capable of supplying the power discharged from the power storage device to the load;
Comprising
The disaster prevention warehouse according to any one of claims 1 to 5.

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