JP6769887B2 - Power supply system - Google Patents

Description

The present disclosure relates to a power supply system.

Conventionally, a power supply system for charging or discharging a fixed storage battery installed in a house and a mobile storage battery mounted on an electric vehicle or the like has been known (see Patent Document 1).

The conventional power supply system charges a fixed storage battery or a mobile storage battery with power from a power system or a power generation device that uses natural energy, and charges the charged power to each electric load or power system in the house. It discharges. As a result, the power supply system can effectively use various electric powers.

Japanese Patent No. 5327248

However, the power supply system described above is only capable of operating even during a power outage. Here, in the event of a power failure, it is necessary to efficiently use the electric power from the power generation device, but the mode of using the electric power varies from person to person. Therefore, in the power supply system, it is desirable that the power can be efficiently used while dealing with various modes even in the event of a power failure.

The present disclosure has been made in view of the above circumstances, and an object of the present disclosure is to provide a power supply system capable of efficiently using electric power while coping with various modes even in the event of a power failure.

In order to achieve the above object, the power supply system of the present disclosure includes a fixed storage battery installed at a predetermined position, a fixed side power generation device provided corresponding to the fixed storage battery and generating power by using natural energy. A mobile storage battery mounted on a moving body, a mobile power generation device provided corresponding to the mobile storage battery to generate power using natural energy, a selected load selected as the minimum required in the event of a power failure, and other than the selected load. In the event of a power failure, the fixed storage battery is charged with the power from the fixed-side power generation device, and the power from the mobile-side power generation device is used to charge the mobile storage battery and the general load and the selection. The first mode used for supplying the load and the power from the fixed-side power generation device are used for charging the fixed storage battery and supplying to the selected load, and the power from the mobile-side power generation device is used for charging the mobile storage battery and charging the mobile storage battery. It is characterized in that it is possible to switch between the second mode used for supplying to the general load.

Here, in the first mode and the second mode, when the electric power from the mobile power generation device and the mobile storage battery is insufficient, the supply of electric power from the mobile power generation device to the general load is stopped and fixed. The electric power from the side power generation device can be switched to the third mode used for charging the fixed storage battery and supplying the selected load. Further, the electric power from the mobile power generation device and the mobile storage battery is determined to be insufficient when the mobile storage battery is not connected, and in the third mode, when the mobile storage battery is not connected, the mobile power generation device The power generated by the battery can be supplied to the emergency outlet.

Further, the electric power from the mobile power generation device and the mobile storage battery is insufficient when the electric power used by the general load and the selected load exceeds the power supply amount from the mobile power generation device and the mobile storage battery. It may be a structure to be judged. In addition, a general distribution board to which the general load is connected and an independent distribution board to which the selected load is connected are provided, and are provided between the general distribution board and the independent distribution board. The intermittent switch can be configured to enable switching between the first mode and the second mode. Further, the intermittent switch may be configured so that the first mode and the second mode can be manually switched. In addition, the intermittent switch automatically switches to the second mode when there is surplus power from the fixed-side power generation device in the first mode and the fixed storage battery is sufficiently charged, and in the second mode. When the surplus power from the fixed-side power generation device is exhausted or the remaining amount of the fixed storage battery is low, the mode can be automatically switched to the first mode.

The power supply system of the present disclosure configured in this way can efficiently use power while responding to various modes even during a power failure.

Here, in the first mode and the second mode, when the power from the mobile power generation device and the mobile storage battery is insufficient, the supply of power from the mobile power generation device to the general load is stopped and fixed. If the configuration is such that the power from the side power generation device is switched to the third mode used for charging the fixed storage battery and supplying the selected load, the power from the fixed side power generation device should be used while protecting the mobile side power generation device. Can be done. Further, the electric power from the mobile power generation device and the mobile storage battery is determined to be insufficient when the mobile storage battery is no longer connected, and in the third mode, the mobile power generation device is used when the mobile storage battery is not connected. If the power generated by the mobile power generator is supplied to the emergency outlet, the electric power generated by the mobile power generator can be used in the emergency outlet while protecting the mobile power generator.

Further, the electric power from the mobile power generation device and the mobile storage battery is insufficient when the electric power used by the general load and the selected load exceeds the power supply amount from the mobile power generation device and the mobile storage battery. The mobile storage battery and the mobile power generation device can be protected if the configuration is determined. In addition, a general distribution board to which the general load is connected and an independent distribution board to which the selected load is connected are provided, and are provided between the general distribution board and the independent distribution board. If the configuration is such that the first mode and the second mode can be switched by the intermittent switch, the first mode and the second mode can be reliably switched with a simple configuration. Moreover, if the intermittent switch has a configuration in which the first mode and the second mode can be manually switched, it is possible to prevent the mode from being switched at a timing not intended by the user, and the user can be more. It is possible to select a mode that matches the mode of use of. In addition, the intermittent switch automatically switches to the second mode when there is surplus power from the fixed-side power generation device in the first mode and the fixed storage battery is sufficiently charged, and in the second mode. If the configuration is such that when the surplus power from the fixed-side power generation device is exhausted or the remaining amount of the fixed storage battery is low, the mode can be automatically switched to the first mode, the power generated by the fixed-side power generation device or the mobile-side power generation device can be used. It can be used efficiently and the remaining amount of fixed storage batteries and mobile storage batteries can be kept more balanced.

It is explanatory drawing which shows typically the structure of the electric power supply system as an example which concerns on one Embodiment of the electric power supply system which concerns on this disclosure. It is explanatory drawing for demonstrating operation in the 1st mode at the time of power failure in a power supply system. It is explanatory drawing for demonstrating operation in a 2nd mode at the time of a power failure in a power supply system. It is explanatory drawing for demonstrating operation in a 3rd mode at the time of a power failure in a power supply system.

The power supply system 10 of the first embodiment as an example of the power supply system according to the present disclosure will be described below with reference to the drawings.

The power supply system 10 of the first embodiment according to the embodiment of the power supply system according to the present disclosure will be described with reference to FIGS. 1 to 4. As shown in FIG. 1, the power supply system 10 includes a fixed-side charge / discharge unit 11, a fixed-side power generation system 12, a mobile-side charge / discharge unit 13, and a mobile-side power generation system 14 installed outside the building H. The fixed-side power generation system 12 and the mobile-side power generation system 14 are power generation systems that generate power using natural energy. The fixed-side power generation system 12 is provided corresponding to the fixed-side charge / discharge unit 11, and the mobile-side power generation system 14 is provided corresponding to the mobile-side charge / discharge unit 13.

The fixed-side charge / discharge unit 11 is connected to the system power supply line (power supply line) 2 of the system power supply E by the power supply connection line 1. The mobile side charge / discharge unit 13 is connected to the system power supply line 2 by the power supply connection line 3. AC power is supplied from the system power source E to the connection point (branch point) 4 between the power supply connection line 1 and the power supply connection line 3.

The power supply connection line 3 is provided with a relay circuit 6 between the connection point (branch point) 5 and the connection point 4 with the power supply connection line 41 described later. The relay circuit 6 disconnects the mobile side charge / discharge unit 13 and the mobile power generation system 14 from the system power supply E in the event of a power failure (the supply from the system power supply E is cut off), and is between the connection point 5 and the connection point 4. The power supply connection line 3 is cut off. The system power supply line 2 is provided with power detectors 7 and 8 for detecting the power supplied from the system power source E to the connection point 4. The power supply connection line 1 includes a power detector 9 that detects power supplied from the system power supply E to the fixed-side charge / discharge unit 11 and power discharged (supplied) from the fixed-side charge / discharge unit 11 to the connection point 4. It is provided.

The fixed side charge / discharge unit 11 is provided for charging or discharging the fixed storage battery 21, and has a fixed side charge / discharge converter (fixed battery charge / discharge converter) 22 and a fixed side control device 23. The fixed storage battery 21 is provided in the building H to store electric power, and has a capacity of 3 kWh in the first embodiment.

The fixed-side charge / discharge converter 22 converts the AC power supplied from the system power supply E and the AC power output from the fixed-side power conditioner 25 and the mobile-side power conditioner 35, which will be described later, into DC power to charge the fixed storage battery 21. The DC power charged in the fixed storage battery 21 is converted into AC power and discharged to the power supply connection line 1 and the power supply connection line 45 described later. The fixed-side control device 23 switches the operation of the fixed-side charge / discharge converter 22 to charge control or discharge control based on the detected power detected by the power detector 8, and also controls the fixed-side charge / discharge converter 22 to control the fixed storage battery. 21 is charged and discharged. The fixed-side control device 23 is capable of acquiring the voltage of the fixed storage battery 21, the amount of power generated by the fixed-side power generation device 24 described later, and the load amount by the general distribution board 51 and the independent distribution board 52 described later. Based on the above, it is determined that the fixed storage battery 21 is at the lower limit of full charge or discharge, and the presence or absence of surplus power, which will be described later, is determined.

The fixed-side power generation system 12 is provided corresponding to the fixed storage battery 21, and has a fixed-side power generation device 24 and a fixed-side power conditioner (fixed-side power conditioner) 25. The fixed-side power generation device 24 is an example of a power generation device that uses natural energy to generate power, and in the first embodiment, it is a photovoltaic power generation panel that generates power from sunlight. The fixed-side power generation device 24 may be, for example, a wind power generation device or another device as long as it uses natural energy to generate power, and is not limited to the example of the first embodiment.

The fixed-side power conditioner 25 converts the DC power generated by the fixed-side power generation device 24 into AC power and outputs it to the power supply connection line 1 and the power supply connection line 45 described later. The fixed-side power controller 25 cooperates with the fixed-side power generation device 24 to form a photovoltaic power generation system (renewable energy system) as an example of the fixed-side power generation system 12. In the first embodiment, the fixed-side power conditioner 25 is a power conditioner integrated with the fixed-side charge / discharge converter 22, and they are connected to the power supply connection line 1 and the power supply connection line 45. The fixed-side power conditioner 25 is capable of detecting the power (voltage) from the system power supply E, and determines whether or not there is a power failure depending on the presence or absence of the detection. In the event of a power failure, the fixed-side power conditioner 25 internally cuts off the connection with the power supply connection line 1.

The moving side charge / discharge unit 13 is provided to charge or discharge the mobile storage battery 31 mounted on the electric vehicle EV as an example of the moving body, and moves with the mobile side charge / discharge converter (charge / discharge converter for mobile storage battery) 32. It has a side control device 33. The mobile storage battery 31 is used as a drive source for an electric vehicle EV, and has a capacity of 6 kWh in the first embodiment.

The mobile side charge / discharge converter 32 is connected to the power supply connection line 3. The mobile charge / discharge converter 32 converts the AC power output from the mobile power controller 35 and the fixed power controller 25, which will be described later, or the AC power supplied from the grid power source E into DC power, and charges the mobile storage battery 31. The DC power charged in the mobile storage battery 31 is converted into AC power and supplied (discharged) to the power supply connection line 3. The mobile side control device 33 switches the operation of the mobile side charge / discharge converter 32 to charge control or discharge control based on the detected power detected by the power detector 7, and also controls the mobile side charge / discharge converter 32 to control the mobile storage battery 31. Charge and discharge. The mobile side control device 33 is capable of acquiring the voltage of the mobile storage battery 31, the amount of power generated by the mobile side power generation device 34 described later, and the load amount by the general distribution board 51 and the self-sustaining distribution board 52 described later. Based on the above, it is determined that the mobile storage battery 31 is at the lower limit of full charge or discharge, and the presence or absence of surplus power, which will be described later, is determined. Further, the mobile side control device 33 can determine whether or not the mobile storage battery 31 (electric vehicle EV) is connected.

The mobile power generation system 14 is provided corresponding to the mobile storage battery 31, and has a mobile power generation device 34 and a mobile power conditioner (mobile power conditioner) 35. The mobile power generation device 34 is an example of a power generation device that uses natural energy to generate power, and in the first embodiment, it is a photovoltaic power generation panel that generates power from sunlight. The mobile power generation device 34 may be, for example, a wind power generation device or another device as long as it uses natural energy to generate power, and is not limited to the example of the first embodiment.

The mobile power conditioner 35 is connected to the power supply connection line 3 via the power supply connection line 41. The power supply connection line 41 is provided with a power detector 42 that detects AC power output from the mobile power conditioner 35. The power supply connection line 3 is connected to the mobile side charge / discharge converter 32, and is also connected to the general distribution board 51 described later via the power supply connection line 43. The mobile power conditioner 35 converts the DC power generated by the mobile power generator 34 into AC power and outputs it to the power supply connection line 41. The mobile power controller 35 cooperates with the mobile power generation device 34 to form a photovoltaic power generation system (renewable energy system) as an example of the mobile power generation system 14.

An emergency outlet 36 is connected to the moving side power conditioner 35. The emergency outlet 36 is provided to use the electric power generated by the mobile power generation device 34 in a state where the mobile storage battery 31 (electric vehicle EV) is not connected. The mobile power conditioner 35 can supply the electric power generated by the mobile power generator 34 to the emergency outlet 36.

In the power supply system 10, a general distribution board 51 and an independent distribution board 52 are provided in the building H. A plurality of general loads Q1 to Qn provided in the building H are connected to the general distribution board 51. A plurality of selected loads R1 to R3 provided in the building H are connected to the self-supporting distribution board 52. The selected loads R1 to R3 are a part of the minimum load required at the time of a power failure in the building H, and are set to three in the first embodiment. In this explanation, outlets and the like are omitted, and it is assumed that a general load and a selected load are connected to each outlet and the like.

A power supply connection line 43 is connected to the general distribution board 51. Therefore, in addition to the power supply connection line 43, the general distribution board 51 connects the power supply connection line 3 and the power supply connection line 1 to the system power supply E via the power supply connection line 3 and the system power supply line 2. To the fixed side charge / discharge converter 22 and the fixed side power conditioner 25 via the power supply connection line 3, to the mobile side charge / discharge converter 32 via the power supply connection line 3, and to the mobile side power conditioner 35 via the power supply connection line 3 and the power supply connection line 41. , Each is connected. An independent distribution board 52 is connected to the general distribution board 51 via a power supply connection line 44. The power supply connection line 44 is provided with an intermittent switch S1 and a changeover switch S2 in order from the general distribution board 51 side.

The intermittent switch S1 interrupts the connection between the general distribution board 51 and the self-supporting distribution board 52 via the power supply connection line 44 (including the changeover switch S2), and the connection can be manually switched. ing. The intermittent switch S1 is basically in a connected state, and connects the general distribution board 51 and the self-sustaining distribution board 52 via the power supply connection line 44.

The changeover switch S2 has a terminal S2a connected to the general distribution board 51 via the power supply connection line 44, and a terminal S2b connected to the fixed side charge / discharge converter 22 via the power supply connection line 45. .. The changeover switch S2 can be switched so that the connector extending from the terminal S2c connected to the self-supporting distribution board 52 is connected to either the terminal S2a or the terminal S2b. The changeover switch S2 is in a state of connecting the terminal S2a and the terminal S2c when a voltage is applied to the terminal S2a (hereinafter also referred to as S2a-S2c connection), and when a voltage is applied only to the terminal S2b. It is configured to be in a state of connecting the terminal S2b and the terminal S2c (hereinafter, also referred to as S2b-S2c connection).

When the intermittent switch S1 is connected and a voltage is applied to the terminal S2a, the changeover switch S2 is connected to S2a-S2c, and a part of the electric power supplied to the general distribution board 51 is transferred to the self-sustaining distribution board 52. It is ready to be supplied. Further, the changeover switch S2 is connected to S2b-S2c because the voltage is not applied to the terminal S2a and the voltage is applied only to the terminal S2b connected to the fixed side charge / discharge converter 22 when the intermittent switch S1 is cut off. Then, power can be supplied from the fixed-side charge / discharge converter 22 to the self-supporting distribution board 52. When the changeover switch S2 is connected to S2b-S2c, it is possible to return to the S2a-S2c connection by operating the operation unit such as a remote control device (hereinafter, also referred to as a remote controller) in the moving side charging / discharging unit 13. There is. In other words, the changeover switch S2 does not automatically change to the S2a-S2c connection even if a voltage is applied to the terminal S2a when the S2b-S2c connection is made.

The power supply system 10 having the above configuration can supply power from the system power source E to the general distribution board 51 and the independent distribution board 52, and can charge (store) the fixed storage battery 21 and the mobile storage battery 31 with the power. Further, the power supply system 10 can supply the electric power generated by the fixed-side power generation device 24 and the mobile-side power generation device 34 to the general distribution board 51 and the self-sustaining distribution board 52, and the fixed storage battery 21 and the mobile storage battery 31 can be supplied with the electric power. Can be charged. Further, the power supply system 10 can supply the electric power stored in the fixed storage battery 21 to the general distribution board 51 and the self-sustaining distribution board 52, and can charge the mobile storage battery 31 with the electric power. Then, the electric power supply system 10 can supply the electric power stored in the mobile storage battery 31 to the general distribution board 51 and the independent distribution board 52.

In the power supply system 10, it is possible to set an economic mode and a green mode as a normal operation mode by operating an operation unit such as a remote controller. When the mobile storage battery 31 is not connected due to the electric vehicle EV going out, the power supply system 10 cancels the green mode or the economic mode, and as a normal operation, the solar power generation system (fixed side power generation). The fixed storage battery 21 is charged with the surplus power described later by using the power generated by the system 12 and the mobile power generation system 14), and if there is surplus power, the power is sold. Further, in that case, if the generated power of the photovoltaic power generation system is insufficient (including the case where the power is not generated), the fixed storage battery 21 is used, and if it is still insufficient, the system power source E is used. Further, the power supply system 10 of the first embodiment preferentially charges the mobile storage battery 31 when charging the mobile storage battery 31 and the fixed storage battery 21, and charges the fixed storage battery 21 when the charging is completed or there is spare capacity. It is supposed to be.

The economic mode is economic by selling the surplus (hereinafter also referred to as surplus power) for the power used by the general loads Q1 to Qn and the selected loads R1 to R3 among the power generated by the photovoltaic power generation system during the daytime. Get sex. In the economic mode, cheap electricity at night from the electric power company (system power supply E) is stored, and the electricity from the solar power generation system during the day is supplemented with the stored electricity. In the economic mode of the first embodiment, the fixed-side power generation device 24 and the mobile-side power generation device 34 are preferentially used during the daytime, the fixed storage battery 21 charged at night is used when the amount is insufficient, and the fixed storage battery 21 is charged at night when the amount is insufficient. The mobile storage battery 31 charged in the daytime is used.

In the green mode, surplus electricity out of the electricity generated by the daytime solar power generation system is stored, and the stored electricity is used in the morning and evening to reduce the purchase of electricity from the electric power company and to be self-sufficient in electricity. Is aimed at. In the green mode of the first embodiment, the fixed-side power generation device 24 and the mobile-side power generation device 34 are preferentially used during the daytime, and the mobile storage battery 31 and the fixed storage battery 21 are charged with the surplus power. 21 is used, and if the number is insufficient, the mobile storage battery 31 is used.

Next, the operation of the power supply system 10 at the time of a power failure will be described. In this description, it is assumed that the mobile storage battery 31 (electric vehicle EV) is connected in the power supply system 10. In the power supply system 10, when a power failure occurs and the supply from the system power supply E is cut off, as shown in FIG. 2, the relay circuit 6 provided in the power supply connection line 3 is cut off and the connection point 4 and the connection point 5 are connected. The fixed side power conditioner 25 internally cuts off the connection with the power supply connection line 1 while cutting off the space. Then, in the fixed-side charging / discharging unit 11 and the fixed-side power generation system 12, the power supply path to the general distribution board 51 is cut off, and only the power supply path to the independent distribution board 52 via the power supply connection line 45 is cut off. It will be ready to connect to. Further, the mobile side charge / discharge unit 13 and the mobile side power generation system 14 are connected with a power supply path to the general distribution board 51 via the power supply connection line 3, the power supply connection line 41, and the power supply connection line 43. The state is set, and the power supply path to the self-supporting distribution board 52 can be connected from there via the power supply connection line 44. This is because the moving side control device 33 detects the electric power from the mobile storage battery 31 and can be regarded as the system power source E being active even if there is no supply from the system power source E. At this time, since the intermittent switch S1 has not been shut off, it is in a state of being connected.

Therefore, the general distribution board 51 is supplied with power from the mobile side charge / discharge unit 13 and the mobile side power generation system 14, and the power supply connection line 45 is supplied with the fixed side charge / discharge unit 11 and the fixed side power generation system. The power from 12 can be supplied. Then, the changeover switch S2 is connected to S2a-S2c because a voltage is applied to both the terminal S2a and the terminal S2b. This is the first mode at the time of a power failure in the power supply system 10.

In this first mode, since the terminal S2b is not connected to the changeover switch S2, the power supply path from the fixed side charge / discharge unit 11 and the fixed side power generation system 12 to the self-sustaining distribution board 52 is cut off. Therefore, in the first mode, when the fixed-side power generation device 24 generates electric power, the fixed-side power controller 25 and the fixed-side charge / discharge converter 22 only charge the fixed storage battery 21 with the electric power (see arrow A1), and the fixed side The electric power of the power generation device 24 and the fixed storage battery 21 is not used elsewhere. As a result, in the first mode, the charge amount of the fixed storage battery 21 can be reliably secured.

Further, in the first mode, when the mobile power generation device 34 generates power, the power is supplied to the general loads Q1 to Qn via the mobile power conditioner 35 and the general distribution board 51 (see arrows A2 and A3), and is self-supporting. It is supplied to the selected loads R1 to R3 via the distribution board 52 (see arrow A4). Then, in the first mode, when there is surplus power of the mobile power generation device 34 with respect to the used power, the mobile storage battery 31 is charged via the mobile side charge / discharge converter 32 (see arrows A2 and A5). .. In the first mode, when the amount of power generated by the mobile power generation device 34 is insufficient for the power used by the general loads Q1 to Qn and the selected loads R1 to R3, the power of the mobile storage battery 31 is used as the power of the mobile storage battery 31. It is supplied to the general loads Q1 to Qn via the 32 and the general distribution board 51 (see arrows A6 and A3), and is also supplied to the selected loads R1 to R3 via the self-supporting distribution board 52 (see arrows A4). As a result, in the first mode, the electric power from the mobile power generation device 34 can be effectively used in cooperation with the mobile storage battery 31.

Further, in the power supply system 10, as shown in FIG. 3, by manually shutting off the intermittent switch S1 at the time of a power failure, the second mode can be set at the time of a power failure. In this second mode, the intermittent switch S1 is cut off, so that even if a voltage is supplied to the general distribution board 51, no voltage is applied to the terminal S2a of the changeover switch S2. Then, since the voltage is applied only to the terminal S2b, the changeover switch S2 is connected to S2b-S2c.

In this second mode, the changeover switch S2 is connected to S2b-S2c, so that the power supply path from the fixed side charge / discharge unit 11 and the fixed side power generation system 12 to the self-sustaining distribution board 52 is connected. Therefore, in the second mode, when the fixed-side power generation device 24 generates power, the power is supplied from the fixed-side power conditioner 25 and the fixed-side charge / discharge converter 22 to the selected loads R1 to R3 via the self-supporting distribution board 52 (arrows). See A7 and A8). Further, in the second mode, the fixed storage battery 21 is charged via the fixed side charge / discharge converter 22 with the surplus power from the fixed side power generation device 24 with respect to the used power (see arrows A7 and A9). Then, in the second mode, when the amount of power generated by the fixed-side power generation device 24 is insufficient for the power used by the selected loads R1 to R3, the power of the fixed storage battery 21 is used for the fixed-side charge / discharge converter 22 and the self-supporting component. It is supplied to the selected loads R1 to R3 via the electric board 52 (see arrows A10 and A8). As a result, in the second mode, the electric power from the fixed-side power generation device 24 can be effectively used in cooperation with the fixed storage battery 21.

Further, in the second mode, when the mobile power generation device 34 generates electric power, the electric power is supplied to the general loads Q1 to Qn via the mobile power conditioner 35 and the general distribution board 51 (see arrows A2 and A3). Then, in the second mode, the mobile storage battery 31 is charged via the mobile side charge / discharge converter 32 with the surplus power from the mobile side power generation device 34 with respect to the used power (see arrows A2 and A5). In addition, in the second mode, when the amount of power generated by the mobile power generation device 34 is insufficient for the power used by the general loads Q1 to Qn, the power of the mobile storage battery 31 is transferred to the mobile side charge / discharge converter 32 and the general. It is supplied to the general loads Q1 to Qn via the distribution board 51 (see arrows A6 and A3). As a result, in the second mode, the electric power from the mobile power generation device 34 can be effectively used in cooperation with the mobile storage battery 31.

Here, in the power supply system 10, as shown in FIG. 4, it is assumed that the power from the mobile power generation device 34 and the mobile storage battery 31 is insufficient in the first mode. Such a shortage of electric power causes the mobile storage battery 31 (electric vehicle EV) to be disconnected, and the general load Q1 to Qn and the selected load R1 with respect to the amount of electric power supplied from the mobile power generation device 34 and the mobile storage battery 31. It can be mentioned that the power consumption in ~ R3 exceeds (overload). Note that FIG. 4 shows an example of the former.

In the former case, the moving side control device 33 cannot detect the power from the mobile storage battery 31, so that it cannot be regarded that the system power supply E is active due to the power failure, and the power supply connection is established. Power cannot be supplied via the wire 41. As a result, even if the intermittent switch S1 is connected, power is not supplied to the general distribution board 51, so that no voltage is applied to the terminal S2a of the changeover switch S2. Further, in the latter case, the system for supplying electric power from the mobile side charge / discharge unit 13 and the mobile power generation system 14 to the self-sustaining distribution board 52 is stopped due to the power shortage. As a result, even if the intermittent switch S1 is connected, power is not supplied to the general distribution board 51, so that no voltage is applied to the terminal S2a of the changeover switch S2. Therefore, the changeover switch S2 is connected to S2b-S2c because the voltage is applied only to the terminal S2b. This is set as the third mode at the time of power failure in the power supply system 10. Here, in the power supply system 10, the changeover switch S2 is configured to return from the S2b-S2c connection to the S2a-S2c connection by operating an operation unit such as a remote controller. Therefore, the mobile power generation device 34 and the mobile storage battery When the shortage of power from 31 is resolved, the operation unit can be operated to return from the third mode to the first mode.

In this third mode, the changeover switch S2 is connected to S2b-S2c, so that the power supply path from the fixed-side charge / discharge unit 11 and the fixed-side power generation system 12 to the self-sustaining distribution board 52 is connected. Therefore, in the third mode, when the fixed-side power generation device 24 generates power, the power is supplied from the fixed-side power conditioner 25 and the fixed-side charge / discharge converter 22 to the selected loads R1 to R3 via the self-sustaining distribution board 52 (arrows). See A7 and A8). Further, in the third mode, the fixed storage battery 21 is charged via the fixed side charge / discharge converter 22 with the surplus power from the fixed side power generation device 24 with respect to the used power (see arrows A7 and A9). Then, in the third mode, when the amount of power generated by the fixed-side power generation device 24 is insufficient for the power used by the selected loads R1 to R3, the power of the fixed storage battery 21 is used for the fixed-side charge / discharge converter 22 and the self-supporting component. It is supplied to the selected loads R1 to R3 via the electric board 52 (see arrows A10 and A8). As a result, in the third mode, the electric power from the fixed-side power generation device 24 can be effectively used in cooperation with the fixed storage battery 21.

Further, in the third mode, the supply of electric power from the mobile storage battery 31 (corresponding only to the latter case described above) and the mobile power generation device 34 to the general loads Q1 to Qn via the general distribution board 51 is stopped. Then, in the third mode, when the mobile storage battery 31 is not connected (corresponding to the former described above), when the mobile power generation device 34 generates power, the emergency outlet 36 can be used (see arrow A11). As a result, in the third mode, the mobile side charge / discharge unit 13 and the mobile side power generation system 14 can be protected, and when the mobile storage battery 31 is not connected, the electric power from the mobile side power generation device 34 can be used.

Here, in the power supply system 10, it is assumed that the power from the mobile power generation device 34 and the mobile storage battery 31 is insufficient in the second mode. Such a shortage of electric power means that the mobile storage battery 31 (electric vehicle EV) is not connected, and the electric power used in the general loads Q1 to Qn with respect to the amount of electric power supplied from the mobile power generation device 34 and the mobile storage battery 31. Can be said to exceed. At this time, no voltage is applied to the terminal S2a of the changeover switch S2 as in the first mode, but since the intermittent switch S1 is already in the cutoff state in the second mode, the changeover switch S2 is S2b-S2c. Stay connected. In this case as well, the third mode at the time of a power failure in the power supply system 10 similar to the above is set, and the operation is the same as the above. That is, in the third mode, the intermittent switch S1 is in the connected state (state in FIG. 4) when shifting from the first mode, and the intermittent switch S1 is in the cutoff state when shifting from the second mode (FIG. 3). However, in both cases, the power supply relationship is the same (operation in FIG. 4). Even when the mode is changed from the second mode to the third mode, the operation unit is operated when the shortage of electric power from the mobile power generation device 34 and the mobile storage battery 31 is resolved, so that the third mode is changed to the second mode. Can return to.

In this power supply system 10, by setting the first mode in the event of a power failure, the power from the mobile power generation device 34 can be effectively used in cooperation with the mobile storage battery 31 while ensuring the charge amount of the fixed storage battery 21. The fixed storage battery 21 can be charged while using the general loads Q1 to Qn and the selected loads R1 to R3. Therefore, for example, even when the electric vehicle EV goes out later and the mobile storage battery 31 is not connected (corresponding to the third mode), the selected loads R1 to R3 are used by charging the fixed storage battery 21. can do. Further, in the power supply system 10, by setting the second mode in the event of a power failure, the electric power from the fixed side power generation device 24 is effectively used in cooperation with the fixed storage battery 21, and the mobile side is cooperated with the mobile storage battery 31. The electric power from the power generation device 34 can be effectively used. Therefore, the electric power generated by the fixed-side power generation device 24 and the mobile-side power generation device 34 and the electric power charged in the fixed storage battery 21 and the mobile storage battery 31 can be used as the general load Q1 to Qn and the selected loads R1 to R3. More electricity can be used and the energy self-sufficiency rate can be improved. Further, even if the general loads Q1 to Qn and the selected loads R1 to R3 are used in the same manner as in the first mode, the power consumption of the mobile storage battery 31 can be suppressed, so that the electric vehicle EV is used (running) when necessary. It is possible to suppress the occurrence of a situation in which it cannot be done. Then, in the power supply system 10, by operating the intermittent switch S1, it is possible to switch between the first mode and the second mode at the time of a power failure. Therefore, in the power supply system 10, even in the event of a power failure, for example, the first mode or the second mode can be selected according to whether or not the electric vehicle EV is scheduled to be used and the amount of power used in the building H. Electric power can be efficiently used while appropriately corresponding to the mode in which electric power is used.

The power supply system 10 of one embodiment can obtain the following effects.

Since the power supply system 10 can switch between the first mode and the second mode in the event of a power failure, the user selects a mode that matches his / her own power usage mode, for example, the user's lifestyle and weather. It is possible to improve usability. That is, when the fixed storage battery 21 is fully charged in the first mode or there is surplus power from the fixed side power generation device 24 for charging the fixed storage battery 21, it is switched to the second mode, or in the second mode. If there is a plan to use the electric vehicle EV, it is possible to switch to the first mode.

Further, since the power supply system 10 switches to the third mode when the power from the mobile power generation device 34 and the mobile storage battery 31 is insufficient in the first mode and the second mode, the power supply system 10 and the mobile side charge / discharge unit 13 having the mobile storage battery 31 The electric power from the fixed side power generation device 24 can be used while protecting the mobile side power generation system 14 having the mobile side power generation device 34. Here, in the power supply system 10, when the mobile storage battery 31 is connected in the third mode, the power generated by the mobile power generation device 34 can be used to supply the emergency outlet 36, so that the mobile power generation can be generated. It is possible to prevent the power from the device 34 from being wasted.

Further, the power supply system 10 enables switching between the first mode and the second mode by interrupting the intermittent switch S1 provided between the general distribution board 51 and the self-supporting distribution board 52. Therefore, the power supply system 10 can reliably switch between the first mode and the second mode with a simple configuration. Further, since the power supply system 10 has a configuration in which the intermittent switch S1 is manually switched between intermittent switching, it is possible to prevent the mode from being switched at a timing not intended by the user, and a mode that more closely matches the usage mode of the user is selected. can do.

In the power supply system 10, the changeover switch S2 provided on the self-sustaining distribution board 52 side of the intermittent switch S1 between the general distribution board 51 and the self-sustaining distribution board 52 is the general distribution board 51 and the self-supporting distribution board. When the electric power from the mobile power generation device 34 and the mobile storage battery 31 is insufficient while the 52 is connected, the state is switched to the state in which the fixed side power generation device 24 and the fixed storage battery 21 are connected to the self-supporting distribution board 52. Therefore, the power supply system 10 protects the mobile side charging / discharging unit 13 having the mobile storage battery 31 and the mobile side power generation system 14 having the mobile power generation device 34, and the electric power of the fixed side power generation device 24 and the fixed storage battery 21. The self-supporting distribution board 52 (selected loads R1 to R3 connected to the independent distribution board 52) can be used.

Therefore, in the power supply system 10 of the first embodiment as the power supply system according to the present disclosure, the power can be efficiently used while corresponding to various modes even at the time of a power failure.

Although the power supply system of the present disclosure has been described based on the first embodiment, the specific configuration is not limited to the first embodiment and deviates from the gist of the invention according to each claim of the claims. Unless otherwise, design changes and additions are allowed.

For example, in the first embodiment, the intermittent switch S1 is manually switched between intermittent and intermittent, but it may be configured to automatically switch between intermittent and discontinuous. In this case, in the first mode, when the surplus power from the fixed side power generation device 24 is detected and the fixed storage battery 21 is sufficiently charged, the intermittent switch S1 is changed to the cutoff state to switch to the second mode. Can be considered. In this way, the surplus power from the fixed-side power generation device 24 can be effectively used. Further, in the second mode, when the surplus power from the fixed side power generation device 24 is exhausted or the remaining amount of the fixed storage battery 21 is low, it is conceivable to shift the intermittent switch S1 to the connected state and switch to the first mode. Be done. By doing so, it is possible to secure the charge of the fixed storage battery 21, and it is possible to use the selected loads R1 to R3 even when the electric vehicle EV goes out and the mobile storage battery 31 is not connected. By automatically switching the intermittent switch S1, the electric power generated by the fixed-side power generation device 24 and the mobile-side power generation device 34 can be used more efficiently, and the remaining amount of the fixed storage battery 21 and the mobile storage battery 31 can be further reduced. You can keep a good balance.

Further, in the first embodiment, when the power from the mobile power generation device 34 and the mobile storage battery 31 is insufficient in the first mode and the second mode, the mode is switched to the third mode. However, the mode is switched between the first mode and the second mode. The present invention is not limited to the configuration of the first embodiment described above.

Further, in the first embodiment, the first mode and the second mode can be switched by the intermittent operation of the intermittent switch S1, but it is sufficient if the first mode and the second mode can be switched, and the above-described embodiment is sufficient. It is not limited to the configuration of 1.

In the first embodiment, the mode is switched from the first mode to the third mode by switching the changeover switch S2, but when the power from the mobile power generation device 34 and the mobile storage battery 31 is insufficient, the mode is switched from the first mode to the third mode. However, the configuration is not limited to the configuration of the first embodiment described above.

In the first embodiment, the electric vehicle EV is shown as an example of the moving body, but for example, a plug-in hybrid car, an electric bicycle, an electric bicycle including an electric assist type bicycle, an electric wheelchair, and an agricultural machine. Alternatively, it may be an industrial device or the like, and is not limited to the configuration of the first embodiment described above.

10 Power supply system 21 Fixed storage battery 24 Fixed side power generation device 31 Mobile storage battery 34 Mobile side power generation device 36 Emergency outlet 51 General distribution board 52 Independent distribution board EV (as an example of mobile body) Electric vehicle Q1 to Qn General load R1 to R3 Selected load S1 Intermittent switch S2 Changeover switch

Claims (7)

Fixed storage batteries installed in place and
A fixed-side power generation device that is provided in response to the fixed storage battery and uses natural energy to generate power.
The mobile storage battery mounted on the mobile body and
A mobile power generator that is provided in response to the mobile storage battery and uses natural energy to generate electricity.
The selected load selected as the minimum required during a power outage,
With a general load other than the selected load,
In the event of a power outage
A first mode in which the fixed storage battery is charged with the electric power from the fixed side power generation device, and the electric power from the mobile power generation device is used for charging the mobile storage battery and supplying the general load and the selected load.
A second mode in which the electric power from the fixed-side power generation device is used for charging the fixed storage battery and supplying the selected load, and the electric power from the mobile power generation device is used for charging the mobile storage battery and supplying the general load. A power supply system characterized by being able to switch between. When the power from the mobile power generation device and the mobile storage battery is insufficient in the first mode and the second mode, the supply of power from the mobile power generation device to the general load is stopped and the fixed side power generation device is stopped. The power supply system according to claim 1, wherein the power from the power generation is switched to a third mode used for charging the fixed storage battery and supplying the selected load. The electric power from the mobile power generation device and the mobile storage battery is determined to be insufficient when the mobile storage battery is no longer connected.
The power supply system according to claim 2, wherein in the third mode, the power generated by the mobile power generation device is supplied to the emergency outlet when the mobile storage battery is not connected. It is determined that the electric power from the mobile power generation device and the mobile storage battery is insufficient when the electric power used by the general load and the selected load exceeds the power supply amount from the mobile power generation device and the mobile storage battery. The power supply system according to claim 2, wherein the power supply system is characterized by the above. The power supply system according to any one of claims 1 to 4.
Further, with the general distribution board to which the general load is connected,
It is equipped with an independent distribution board to which the selected load is connected.
A power supply system characterized in that an intermittent switch provided between the general distribution board and the self-supporting distribution board enables switching between the first mode and the second mode. The power supply system according to claim 5, wherein the intermittent switch can be manually switched between the first mode and the second mode. The intermittent switch automatically switches to the second mode when there is surplus power from the fixed side power generation device in the first mode and the fixed storage battery is sufficiently charged, and the fixed side in the second mode. The power supply system according to claim 5, wherein when the surplus power from the power generation device is exhausted or the remaining amount of the fixed storage battery is low, the mode is automatically switched to the first mode.