JP6248396B2 - Power supply system and power supply control device - Google Patents

Description

  The present invention relates to a power supply system and a power supply control device, and more particularly to a power supply system and a power supply control device that control a first power supply means and a second power supply means for supplying power to a house.

  In recent years, in addition to a commercial power source as a main power source, an increasing number of houses have an auxiliary power source that is urgently used during natural disasters or power outages. For example, in Patent Document 1, a power supply that includes a main power supply unit connected to a commercial power supply and an auxiliary power supply unit for emergency use, and the auxiliary power supply unit supplies power on behalf of the main power supply unit when disaster information is received. A system is disclosed.

JP 2011-223841 A

  However, in the power supply system of Patent Document 1, when disaster information is received, the auxiliary power supply unit automatically supplies power instead of the main power supply unit. That is, when the information on the natural disaster is received, the switching to the auxiliary power supply unit is performed uniformly, and thus the user's intention cannot be reflected at the time of switching.

  In particular, when the battery of an electric vehicle or a hybrid vehicle is used as the auxiliary power source, there is a problem that the remaining charge of the battery is insufficient and the vehicle cannot be used when the influence of the disaster is mitigated. That is, conventionally, since the main power supply is automatically switched to the auxiliary power supply without confirming the user's intention, there is a disadvantage that the auxiliary power supply cannot be used when the main power supply is restored.

  Accordingly, the present invention has been made to solve the above-described problem, and an object of the present invention is to provide power supply for confirming whether or not switching is possible when switching from the first power supply means to the second power supply means. A system and a power supply control device are provided.

In the first invention,
First power supply means for supplying power to the house;
A second power supply means for auxiliary power supply to the house in place of the first power supply means;
Confirmation means for performing a switching confirmation asking whether or not to switch the power supply to the house from one of the first power supply means and the second power supply means to the other;
Control means for controlling the confirmation means, and a control means for switching power supply to the house from one of the first power supply means and the second power supply means to the other,
In the case where power is supplied to the house by the first power supply means, when the first condition is satisfied, the control means causes the confirmation means to execute the switching confirmation, and for the switching confirmation. When permission is received from the user, the power supply to the house is switched to the second power supply means.

According to the first invention, when the first power supply means is switched to the second power supply means, the confirmation means is made to execute the switching confirmation. When the user confirms the switching confirmation, the first power supply unit is switched to the second power supply unit. Therefore, for example, the user's intention can be accurately reflected when the user wants to continue the power supply by the first power supply means or when there is a situation where the user does not want to use the second power supply means.

In a second invention, the second power supply means is a storage battery.

According to the second aspect of the invention, the user can determine whether to switch from the first power supply means to the second power supply means according to the state of the storage battery as the second power supply means. Therefore, for example, in a state where the remaining amount of the storage battery is low, the use of the storage battery can be refused.

In a fourth invention, the control means causes the confirmation means to execute the switching confirmation when the second condition is satisfied when power is supplied to the house by the second power supply means. In addition, the power supply to the house is switched to the first power supply means when the user confirms the switching confirmation.

According to the fourth aspect of the invention, when the second power supply means is switched to the first power supply means, the confirmation means is made to execute the switching confirmation. Then, when permission from the user is met for this switching confirmation, the second power supply means is switched to the first power supply means. That is, the user's intention can be reflected by confirming with the user whether or not the second power supply means can be continuously used. Thereby, the user can determine whether or not to continue depending on the status of the first power supply means and the second power supply means. As a result, for example, when returning to the first power supply means, a situation in which the second power supply means becomes unusable can be avoided at the user's judgment.

In an eighth aspect of the invention, the first condition is that disaster forecast information relating to a natural disaster is input to the control means or a power failure occurs.

According to the eighth aspect, when the disaster forecast information is input to the control means or when a power failure occurs, the switching confirmation by the confirmation means is executed. Therefore, for example, when the influence of a natural disaster is expected to be small, it is possible to continue using the first power supply means without switching to the second power supply means. Further, when the switching to the second power supply means is impossible or difficult, the use of the first power supply means can be continued.

In a ninth aspect, the second condition is that the parameter relating to the remaining capacity of the storage battery is smaller than a preset threshold value.

According to the ninth aspect, when the parameter relating to the remaining amount of the storage battery becomes smaller than a preset threshold value, the switching confirmation by the confirmation unit is executed. Therefore, the user can recognize that the remaining amount of the storage battery is low. That is, it is possible to determine whether or not the storage battery can be used continuously after grasping the remaining capacity of the storage battery. Therefore, when switching to the first power supply means, it is possible to avoid a situation where the remaining capacity of the storage battery runs out and the storage battery becomes unusable.

In the fifteenth invention,
First power supply means for supplying power to the house, second power supply means for assisting power supply to the house in place of the first power supply means, and power supply to the house for the first power supply. A power supply control device for controlling a confirmation means for confirming switching to a user as to whether or not to switch from one of the first power supply means and the second power supply means to the other,
In the case where power is supplied to the house by the first power supply means, when the first condition is satisfied, the confirmation means is caused to execute the switching confirmation, and permission from the user for the switching confirmation is given. If there is, the power supply to the house is switched to the second power supply means.

According to the fifteenth aspect, when the first power supply means is switched to the second power supply means, the confirmation means is made to execute the switching confirmation. When the user confirms the switching confirmation, the first power supply unit is switched to the second power supply unit. Therefore, for example, the user's intention can be accurately reflected when the user wants to continue the power supply by the first power supply means or when there is a situation where the user does not want to use the second power supply means.

The conceptual diagram which shows the whole structure of the electric power supply system which concerns on 1st Embodiment. The block diagram which shows the system configuration | structure of the electric power supply system which concerns on 1st Embodiment. The flowchart which shows the control flow of the electric power supply system which concerns on 1st Embodiment. The power supply system which concerns on 2nd Embodiment WHEREIN: The flowchart which shows the control flow of normal mode. 9 is a flowchart showing a control flow in a forced switching mode in the power supply system according to the second embodiment. The block diagram which shows the system configuration | structure of the electric power supply system which concerns on 3rd Embodiment. The flowchart which shows the control flow of the electric power supply system which concerns on 3rd Embodiment.

  Next, the power supply system according to the embodiment will be described. In the following embodiment, the case where the commercial power supply 16 is adopted as the first power supply means and the battery 20 of the plug-in hybrid vehicle 18 (PHV) is adopted as the second power supply means will be described.

[First Embodiment]
FIG. 1 is a conceptual diagram showing an overall configuration of a power supply system 10 according to the first embodiment. The power supply system 10 controls power supply to the house 12 by a control device 14 installed in the house 12. That is, in the present embodiment, the power supply to the house 12 is comprehensively controlled by one control device 14 as a power supply control device. For power supply to the house 12, a commercial power source 16 is normally used. When a natural disaster forecast is issued or when a power failure occurs, a battery 20 (storage battery) of a hybrid vehicle (hereinafter referred to as an automobile 18) is used as an auxiliary. In addition, in this embodiment, the case where a detached house is employ | adopted as the house 12 is illustrated. This house 12 is a so-called smart house in which electrical appliances, equipment and the like are connected to a network.

  The control device 14 includes an electronic control unit (power control ECU) that includes a CPU, ROM, RAM, and the like (not shown). As shown in FIG. 2, the control device 14 is electrically connected to the commercial power supply 16 and the battery 20, and switches the power supply to the house 12 from one of the commercial power supply 16 and the battery 20 to the other.

  The control device 14 receives information on natural disasters transmitted from a public institution such as the Japan Meteorological Agency or municipalities, or from a transmitting station 22 of a private company that provides disaster information. Moreover, the control apparatus 14 transmits / receives with respect to the smart phone 24 (confirmation means) which a user possesses.

  The control device 14 receives information related to a natural disaster forecast transmitted from the transmitting station 22 via an Internet line, a television, a radio wave communication line, or the like. Information relating to natural disaster prediction includes disaster prediction information relating to weather such as lightning, typhoons, and tornadoes. Further, the information related to the natural disaster prediction includes prediction information such as earthquake occurrence prediction information, arrival time of an earthquake that has occurred, and the like. Furthermore, forecast information of the arrival time of the tsunami due to the earthquake is included. That is, the information transmitted from the transmitting station 22 is based on the possibility and timing of a natural disaster occurring in an area where the house 12 is located, or the possibility and timing when the influence of the natural disaster that has already occurred extends to the area where the house 12 is located. It is information about. In the following description, the information related to the natural disaster forecast is referred to as disaster forecast information.

  When the first condition is satisfied when the commercial power source 16 is used, the control device 14 causes the smartphone 24 to perform a switching confirmation asking whether or not switching to the battery 20 is possible. In the present embodiment, the first condition is to receive disaster forecast information from the transmission station 22.

  For example, the control device 14 causes the smartphone 24 to perform switching confirmation via a telephone line or an Internet line. Specifically, the control device 14 sends a message asking whether the switching from the commercial power supply 16 to the battery 20 is possible to the smartphone 24. Upon receiving the message, the smartphone 24 displays a message asking whether or not switching from the commercial power supply 16 to the battery 20 is possible (executes switching confirmation), as shown in FIG. In response to this switching confirmation, the user returns whether switching is possible from the smartphone 24. In the following description, the switching confirmation asking whether or not switching from the commercial power source 16 to the battery 20 may be referred to as a first switching confirmation.

  When the battery 20 is being used and the second condition is satisfied, the control device 14 causes the smartphone 24 to execute a switching confirmation asking whether or not switching to the commercial power supply 16 is possible. In the present embodiment, the second condition is satisfied each time a predetermined time elapses after switching from the commercial power supply 16 to the battery 20. The predetermined time can be changed by the user, and is set to 1 hour, for example.

  Specifically, the control device 14 transmits a message asking whether or not switching from the battery 20 to the commercial power supply 16 is possible to the smartphone 24. When the smartphone 24 receives the message, the smartphone 24 displays a message asking whether switching from the battery 20 to the commercial power supply 16 is possible. In response to this switching confirmation, the user returns whether switching is possible from the smartphone 24. That is, it can be said that the switching confirmation executed when the battery 20 is used asks the user whether or not the battery 20 can be continuously used. In the following description, switching confirmation that asks whether switching from the battery 20 to the commercial power supply 16 is possible may be referred to as second switching confirmation.

  In response to the first switching confirmation, the control device 14 switches the power supply to the house 12 from the commercial power supply 16 to the battery 20 when the user sends a reply permitting switching (switching permission). On the other hand, when the user makes a reply that does not permit switching (switching rejection) in response to the first switching confirmation, the control device 14 causes the commercial power supply 16 to continuously supply power to the house 12.

  Further, when the user replies switching permission with respect to the second switching confirmation, the control device 14 switches the power supply to the house 12 from the battery 20 to the commercial power supply 16. On the other hand, when the user responds to the second switching confirmation, the control device 14 causes the battery 20 to continuously supply power to the house 12.

  Next, the operation and effect of the power supply system 10 according to the present embodiment will be described with reference to the flowchart of FIG. In the following description, it is assumed that disaster forecast information is transmitted from the transmission station 22 when the commercial power supply 16 is used. In addition, it is assumed that the user has gone out with the smartphone 24 in hand.

  When the control device 14 receives the disaster forecast information (step S10), the control device 14 transmits a first switching confirmation message to the smartphone 24 (step S12). When the smartphone 24 receives the first switching confirmation message, the smartphone 24 displays a first switching confirmation message (step S14). Thereby, the user can recognize that the judgment of switching from the commercial power supply 16 to the battery 20 is required. Then, the user determines whether or not to switch to the battery 20 in consideration of the situation of natural disasters, the remaining amount of the battery 20, and the like.

  When the user permits switching to the battery 20 (Yes in step S16), the smartphone 24 is operated to transmit a switching permission instruction (step S18). When receiving the switching permission instruction, the control device 14 switches the power supply to the house 12 from the commercial power supply 16 to the battery 20 (step S20). As a result, power supply from the battery 20 to the house 12 is started (step S22).

  As described above, according to the power supply system 10 of the present embodiment, when the disaster forecast information is received, the user is confirmed to switch to the battery 20. Therefore, the user can switch to the battery 20 before the area of the house 12 is affected by a natural disaster. As a result, the commercial power supply 16 can be safely switched to the battery 20 before being damaged by a natural disaster.

  Here, in step S <b> 16, for example, when the scale of a natural disaster is small and the impact on an area where the house 12 is located is expected to be small, the user may desire to continue using the commercial power supply 16. In addition, when the remaining amount of the battery 20 is low or when it is desired to ensure a sufficient remaining amount in the battery 20, the user may not want to switch to the battery 20. In such a case (No in step S16), the user operates the smartphone 24 to return a switching rejection instruction to the control device 14 (step S24).

  When receiving the switching rejection instruction from the smartphone 24, the control device 14 continues to use the commercial power supply 16 without switching to the battery 20 (step S26). Thus, according to the power supply system 10 of the present embodiment, it is possible to reflect the intention of the user who does not want to switch to the battery 20. Therefore, for example, a situation where the battery 20 is switched to can be determined by the user's judgment until there is almost no influence of a natural disaster.

  Here, if the battery 20 is forcibly switched to a state where the remaining amount is low, the remaining amount of the battery 20 may be insufficient when the influence of the natural disaster is eliminated, and the automobile 18 may not be used. On the other hand, in this embodiment, the user can determine whether or not to switch to the battery 20 in consideration of the remaining amount of the battery 20. Accordingly, when the remaining amount is low, switching of the battery 20 is rejected, so that a situation where the remaining amount of the battery 20 is insufficient when the influence of the natural disaster is resolved can be avoided.

  In step S22, when the use of the battery 20 is started, the control device 14 determines whether or not a predetermined time (for example, 1 hour) has elapsed (step S28). When a predetermined time elapses after switching to the battery 20 (Yes in step S28), the control device 14 transmits a second switching confirmation message (step S30). When the smartphone 24 receives the second switching confirmation message, it displays a message for confirming whether or not switching from the battery 20 to the commercial power supply 16 is possible (step S32). Thereby, the user can recognize that the judgment of whether or not to continue using the battery 20 is required.

  Here, when the smartphone 24 performs the second switching confirmation, if the influence of the natural disaster has already been eliminated or the influence of the natural disaster is slight, it is not necessary to continue to use the battery 20. In such a case (Yes in step S34), the user operates the smartphone 24 to transmit a switching permission instruction to the control device 14 (step S36).

  Receiving the switching permission instruction, the control device 14 switches the power supply to the house 12 from the battery 20 to the commercial power supply 16 (step S38). As a result, the use of the battery 20 is stopped and the use of the commercial power supply 16 is resumed (step S40). As described above, in the power supply system 10, when a predetermined time elapses after the battery 20 is used, the user is confirmed to continue using the battery 20 (second switching confirmation). Therefore, when the influence of the natural disaster is eliminated, the use of the battery 20 can be stopped. That is, the user can appropriately determine whether or not the battery 20 can be used continuously according to the situation of a natural disaster.

  On the other hand, when the user desires to continue using the battery 20 in Step S34 (No in Step S34), the user transmits the content of the switch rejection from the smartphone 24 (Step S42). When receiving the switch rejection instruction, the control device 14 continues to use the battery 20 (step S44). And it transfers to step S28 and the control apparatus 14 determines whether predetermined time passed.

  That is, even after the use of the battery 20 is continued, the control device 14 causes the smartphone 24 to execute the second switching confirmation every time a predetermined time elapses. That is, while the battery 20 is being used, the control device 14 periodically confirms whether or not continuous use is possible with the user. Therefore, it is possible to avoid unnecessary use of the battery 20 by switching to the commercial power supply 16 at the timing when the influence of the natural disaster is eliminated.

  As described above, according to the power supply system 10 according to the present embodiment, when switching from the commercial power supply 16 to the battery 20, the first switching confirmation is executed for the user. Therefore, the user's intention can be reflected when switching to the battery 20. As a result, for example, when the remaining amount is low, switching to the battery 20 is rejected, so that a situation in which the automobile 18 cannot be used when the influence of a natural disaster is eliminated can be avoided.

  In addition, when the battery 20 is used, the control device 14 confirms whether or not the battery 20 can be used continuously every predetermined time. As a result, it is possible to avoid a situation in which the battery 20 is continuously used even though the influence of the natural disaster has been eliminated.

  Since the control device 14 causes the smartphone 24 to perform switching confirmation, it is possible to instruct whether switching is possible even when the user is out.

[Second Embodiment]
Next, a power supply system according to the second embodiment will be described. In the second embodiment, only parts different from the first embodiment will be described, and the same parts as those in the first embodiment will be denoted by the same reference numerals and description thereof will be omitted.

  In the first embodiment, when the commercial power supply 16 is used, the first switching confirmation is executed when the control device 14 receives the disaster forecast information (first condition). In the second embodiment, in addition to when the control device 14 receives disaster forecast information, the first switching confirmation is also performed when a power failure occurs (first condition).

  The control device 14 incorporates an auxiliary battery (not shown), and is operated by the power of the auxiliary battery when a power failure occurs. That is, while a power failure occurs, transmission of a switching confirmation message and switching to the battery 20 are executed by the power of the auxiliary battery.

  In the first embodiment, when the battery 20 is used, the second switching confirmation is executed every time a predetermined time elapses (second condition). On the other hand, in the second embodiment, the second switching confirmation is executed when the control device 14 receives the forecast cancellation information for canceling the disaster forecast information or when the power failure is resolved (second condition). ing.

  Here, the control apparatus 14 of 2nd Embodiment is provided with two control modes, normal mode and forced switching mode. The user can freely set the normal mode and the forced switching mode in the control device 14.

  When the control device 14 is set to the normal mode, if a power failure occurs while the commercial power supply 16 is used, the control device 14 causes the smartphone 24 to execute the first switching confirmation. In other words, even if a power failure occurs, the switch to the battery 20 is not immediately performed, and the user is asked whether the switch is possible.

  On the other hand, when the control device 14 is set to the forced switching mode, if a power failure occurs while the commercial power supply 16 is used, the control device 14 is forcibly switched from the commercial power supply 16 to the battery 20. ing. When a predetermined time (for example, 30 minutes) elapses after switching to the battery 20, the control device 14 causes the smartphone 24 to execute whether or not the battery 20 can be used continuously (that is, second switching confirmation). That is, in the forced switching mode, when a power failure occurs, the battery 20 is used urgently without executing the first switching confirmation.

  In both the normal mode and the forced switching mode, when the control device 14 receives the disaster forecast information, the smartphone 24 is caused to execute the first switching confirmation. This is because when the disaster forecast information is received, the influence of the natural disaster does not reach the house 12, and there is time to ask the user whether or not switching to the battery 20 is possible.

  Next, the operation and effect of the power supply system of the second embodiment will be described. First, the case where a power failure occurs while the control device 14 is set to the normal mode will be described with reference to FIG.

  When a power failure occurs, the commercial power supply 16 becomes unusable and the control device 14 detects the occurrence of the power failure (step S50). When the power failure is detected, the control device 14 transmits a first switching confirmation message with the power of the auxiliary battery (step S52). When the smartphone 24 receives the first switching confirmation message, the smartphone 24 displays the message and executes the first switching confirmation (step S54). The user can recognize that a power failure has occurred in the house 12 by displaying a message on the smartphone 24.

  When the user desires to switch the battery 20 (Yes in step S56), a switching permission instruction is transmitted from the smartphone 24 (step S58). Receiving the switching permission instruction, the control device 14 switches from the commercial power supply 16 to the battery 20 and starts using the battery 20 (steps S60 and 62).

  On the other hand, in step S56, for example, when a power failure is expected to be short-term, or when the user does not want to use the battery 20 (No in step S56), the user switches to the battery 20 via the smartphone 24. Can be refused. When the switching rejection instruction is transmitted from the smartphone 24 (step S64), the control device 14 maintains the state in which the commercial power supply 16 cannot be used (power failure state) without switching to the battery 20 (step S66).

  Thus, in the normal mode, the first switching confirmation is executed even when a power failure occurs, so that the user's intention can be reflected when switching to the battery 20.

  In step S62, if the power failure is resolved after the use of the battery 20 is started (Yes in step S68), the control device 14 transmits a second switching confirmation message (step S70). The smartphone 24 that has received the second switching confirmation message executes the second switching confirmation (step S72). Thereby, the user can recognize that the power failure has been eliminated.

  When the user desires to switch to the commercial power supply 16 (Yes in Step S74), a switching permission instruction is transmitted from the smartphone 24 (Step S76). When receiving the switching permission instruction, the control device 14 switches from the battery 20 to the commercial power source 16 (step S78), and resumes the use of the commercial power source 16 (step S80).

  On the other hand, in step S74, for example, when it is predicted that a power outage is likely to occur again, the user may desire to continue using the battery 20. In this case (No in step S74), a switching rejection instruction is transmitted from the smartphone 24 (step S82). Receiving the switch rejection instruction, the control device 14 continues to use the battery 20 without switching to the commercial power supply 16 (step S84).

  In this way, in the normal mode, when the power failure is resolved, the user is confirmed to switch to the commercial power supply 16, and thus the user can determine whether or not the battery 20 can be used continuously. Accordingly, it is possible to avoid a situation in which the battery 20 continues to be used even though the power failure has been eliminated, and the remaining amount of the battery 20 runs out.

  In the normal mode, the same control as described above is executed even when the disaster prediction information is received by the control device 14. That is, the control device 14 executes the first switching confirmation when the disaster forecast information is received, and executes the second switching confirmation when the forecast release information is received.

  Next, a case where a power failure occurs while the control device 14 is set to the forced switching mode will be described with reference to FIG.

  When a power failure occurs, the control device 14 detects the occurrence of the power failure (step S90), and switches the power supply to the house 12 from the commercial power source 16 to the battery 20 (step S92). That is, in the forced switching mode, the battery 20 is forcibly switched without executing the first switching confirmation. When the use of the battery 20 is started (step S94), the control device 14 determines whether or not a predetermined time (for example, 30 minutes) has elapsed (step S96). When a predetermined time has elapsed since the use of the battery 20 was started (Yes in step S96), the control device 14 transmits a second switching confirmation message (step S98).

  When receiving the second switching confirmation message, the smartphone 24 displays the message and executes the second switching confirmation (step S100). Thus, the user can recognize that the battery 20 has been forcibly switched due to the occurrence of a power failure.

  When the user desires to continue using the battery 20 (No in step S102), a switching rejection instruction is transmitted from the smartphone 24 (step S104). When receiving the switch rejection instruction, the control device 14 continues to use the battery 20 without switching to the commercial power supply 16 (step S106).

  On the other hand, if the user does not want to continue using the battery 20 in step S102 (Yes in step S102), a switching permission instruction is transmitted from the smartphone 24 (step S110). When receiving the switching permission instruction, the control device 14 switches from the battery 20 to the commercial power supply 16 (step S112). In this case, until the power failure is eliminated, the commercial power supply 16 cannot be used (power failure state) (step S114).

  If the power failure is eliminated after the use of the battery 20 is continued in step S106 (Yes in step S108), the process proceeds to step S98. That is, the control device 14 causes the smartphone 24 to execute the second switching confirmation and confirms with the user whether or not switching from the battery 20 to the commercial power supply 16 is possible (steps S98 and S100).

  When the user desires to switch to the commercial power supply 16 (Yes in step S102), a switching permission instruction is transmitted from the smartphone 24 (step S110). When receiving the switching permission instruction, the control device 14 switches from the battery 20 to the commercial power source 16 (step S112), and the use of the commercial power source 16 is resumed (step S114).

  Thus, in the forced switching mode, when a power failure occurs, the battery 20 is used for emergency evacuation. Therefore, it is possible to prevent a power outage from suddenly occurring in the house 12. Further, when a predetermined time elapses after the battery 20 is forcibly used, whether or not the battery 20 can be continuously used is determined for the user. Therefore, since the user can determine whether or not the battery 20 can be used continuously, the intention of the user can be reflected.

  Moreover, even in the forced switching mode, the second switching confirmation is executed when the power failure is resolved. Therefore, it is possible to avoid a situation in which the battery 20 is continuously used even if the power failure is eliminated, based on the judgment of the user.

  In the forced switching mode, when the disaster forecast information is received by the control device 14, the same control as in the normal mode is executed. That is, the control device 14 executes the first switching confirmation when the disaster forecast information is received, and executes the second switching confirmation when the forecast release information is received.

[Third Embodiment]
Next, the power supply system 26 according to the third embodiment will be described below. Also in the third embodiment, only parts different from the first embodiment will be described, and the same parts as those in the first embodiment will be denoted by the same reference numerals and description thereof will be omitted.

  FIG. 6 is a block diagram showing a control configuration of the power supply system 26 according to the present embodiment. In the power supply system 26 of the present embodiment, a control device 28 (first control unit, power supply control device) installed in the house 12 and an in-vehicle ECU 30 (second control unit, power supply) mounted on the automobile 18. The power supply to the house 12 is controlled by two control units with the control device. That is, in this embodiment, the power supply control device is configured by the control device 28 and the in-vehicle ECU 30. The control device 28 is electrically connected to the commercial power supply 16. When the user desires to use the commercial power supply 16, the control device 28 continues using the commercial power supply 16 or switches to the commercial power supply 16. The control device 28 is adapted to receive disaster forecast information transmitted from the transmission station 22.

  The in-vehicle ECU 30 includes an electronic control unit including a CPU, ROM, RAM, and the like (not shown), and is electrically connected to the battery 20. When the user desires to use the battery 20, the user switches to the battery 20 or continues using the battery 20.

  The control device 28 is configured to transmit a first command signal to the in-vehicle ECU 30 when receiving the disaster forecast information (first condition) while the commercial power supply 16 is being used. When the in-vehicle ECU 30 receives the first command signal from the control device 28, the in-vehicle ECU 30 causes the smartphone 24 to execute the first switching confirmation.

  The vehicle-mounted ECU 30 is configured to transmit a second command signal to the control device 28 when receiving an instruction from the smartphone 24 for switching rejection for the first switching confirmation or switching permission for the second switching confirmation. When the control device 28 receives the second command signal from the in-vehicle ECU 30, the control device 28 continues to use the commercial power source 16 or switches from the battery 20 to the commercial power source 16.

  The in-vehicle ECU 30 is set to monitor the remaining amount of the battery 20 when the use of the battery 20 is started. Specifically, when a parameter relating to the remaining amount of the battery 20 (hereinafter referred to as a remaining amount parameter) becomes smaller than a preset threshold (second condition), the smartphone 24 is caused to execute the second switching confirmation. That is, when the remaining amount of the battery 20 decreases, the in-vehicle ECU 30 confirms with the user whether the battery 20 can be used continuously.

  Here, as the remaining amount parameter, for example, the ratio (%) of the remaining amount in the total capacity of the battery 20 and the travel distance (km) of the automobile 18 are cited. When the ratio of the remaining amount of the battery 20 is adopted as the remaining amount parameter, when the ratio becomes smaller than a threshold value (for example, 30%), the in-vehicle ECU 30 executes the second switching confirmation.

  When the travel distance of the automobile 18 is adopted as the remaining amount parameter, the in-vehicle ECU 30 executes the second switching confirmation when the travel distance of the automobile 18 estimated from the remaining amount of the battery 20 becomes smaller than a threshold (for example, 50 km). Let

  The threshold value of the remaining amount parameter can be changed by the user. For example, when the ratio of the remaining amount is adopted as the remaining amount parameter, the user can freely set the ratio as the threshold, such as 10% or 20%. When the travel distance is adopted as the remaining amount parameter, the user can freely set the travel distance as the threshold value. For example, the user can set the distance required for commuting as a threshold, or can set the distance from the house 12 to an emergency evacuation area at the time of a disaster as a threshold.

  Next, the operation and effect of the power supply system 26 according to the present embodiment will be described with reference to the flowchart of FIG. In the following description, a case where disaster forecast information is transmitted from the transmission station 22 in a state where the commercial power source 16 is used is shown.

  When the control device 28 receives the disaster forecast information transmitted from the transmission station 22 (step S120), the control device 28 transmits a first command signal to the in-vehicle ECU 30 (step S122). When the in-vehicle ECU 30 receives the command signal (step S124), the in-vehicle ECU 30 transmits a first switching confirmation message to the smartphone 24 (step S126). When receiving the first switching confirmation message, the smartphone 24 displays the message (step S128). Thereby, the user recognizes that the determination of switching to the battery 20 is required.

  When the user desires to switch to the battery 20 (Yes in step S130), a switching permission instruction is transmitted from the smartphone 24 to the in-vehicle ECU 30 (step S132). When the in-vehicle ECU 30 receives the switching permission instruction, the in-vehicle ECU 30 switches the power supply to the house 12 from the commercial power supply 16 to the battery 20 (step S134).

  On the other hand, if the user does not want to switch to the battery 20 in step S130 (No in step S130), a switching rejection instruction is transmitted from the smartphone 24 to the in-vehicle ECU 30 (step S136). When the in-vehicle ECU 30 receives the switching rejection instruction, the in-vehicle ECU 30 transmits a second command signal to the control device 28 (step S138). And control device 28 will continue use of commercial power supply 16, without switching to battery 20, if the 2nd command signal is received from in-vehicle ECU30 (Step S140) (Step S142).

  As described above, in the power supply system 26 according to the present embodiment, when switching from the commercial power supply 16 to the battery 20, the in-vehicle ECU 30 causes the smartphone 24 to execute the first switching confirmation. Therefore, as in the first embodiment, the user's intention can be reflected when the battery 20 is switched.

  When the use of the battery 20 is started in step S144, the in-vehicle ECU 30 monitors the remaining amount parameter of the battery 20 (step S146). The remaining amount of the battery 20 decreases as the battery 20 is used. When the remaining amount parameter becomes smaller than the threshold value (Yes in step S146), the in-vehicle ECU 30 transmits a second switching confirmation message to the smartphone 24 (step S148).

  When receiving the second switching confirmation message, the smartphone 24 displays the message and executes the second switching confirmation (step S150). Thereby, the user can recognize that the remaining amount of the battery 20 is low.

  If the user does not want to continue using the battery 20 (Yes in step S152), a switching permission instruction is transmitted from the smartphone 24 (step S154). When receiving the switch permission instruction from the smartphone 24, the in-vehicle ECU 30 transmits a second command signal to the control device 28 (step S138). And the control apparatus 28 will switch from the battery 20 to the commercial power source 16, if the 2nd command signal is received from vehicle-mounted ECU30 (step S140) (step S142).

  On the other hand, in step S152, for example, when the user desires to continue using the battery 20 because there is no plan to use the car 18 (No in step S152), an instruction to switch is transmitted from the smartphone 24 (step S152). S156). When receiving the switch rejection instruction from the smartphone 24, the in-vehicle ECU 30 continues to use the battery 20 without transmitting the second command signal to the control device 28 (step S158).

  As described above, according to the power supply system 26 of the present embodiment, when the use of the battery 20 is started, the in-vehicle ECU 30 monitors the remaining amount parameter of the battery 20. When the remaining amount parameter becomes smaller than the threshold value (that is, when the remaining amount of the battery 20 decreases), the second switching confirmation is executed for the user. Therefore, the user can determine whether or not the battery 20 can be used continuously after recognizing that the remaining amount of the battery 20 is low.

  Moreover, if disaster forecast information is received, the control apparatus 28 will transmit a 1st command signal, and vehicle-mounted ECU30 will perform 1st switching confirmation in response to this. Accordingly, the user's intention can be reflected when switching from the commercial power supply 16 to the battery 20. In addition, the occurrence of disaster forecast information can be transmitted from the control device 28 to the in-vehicle ECU 30 via the first command signal.

  The vehicle-mounted ECU 30 transmits a second command signal to the control device 28 when receiving an instruction for switching rejection for the first switching confirmation or switching permission for the second switching confirmation. When the control device 28 receives the second command signal, the control device 28 switches to the commercial power source 16 or continuously uses the commercial power source 16. Therefore, the user's intention with respect to the switching confirmation can be transmitted from the in-vehicle ECU 30 to the control device 28 via the second command signal.

  In addition, the electric power supply system which concerns on this invention is not limited to the content of 1st-3rd embodiment mentioned above, The following changes are possible.

  1. In the first to third embodiments, the first power supply means is the commercial power supply 16, and the second power supply means is the battery 20 of the automobile 18. However, a storage battery may be employed as the first power supply means, or a solar power generation device or a wind power generation device may be employed as the first power supply means. Further, as the second power supply means, an uninterruptible power supply installed in the house 12 can be adopted, or a rechargeable portable power supply can be adopted.

  Furthermore, the battery is not limited to the battery 20 mounted on the plug-in hybrid vehicle 18 as in the embodiment, and a battery mounted on a hybrid vehicle or an electric vehicle (EV) can also be employed.

  2. In 1st-3rd embodiment, the case where disaster forecast information was received or the case where a power failure occurred was illustrated as 1st conditions which perform 1st switching confirmation. Further, as a second condition for executing the second switching confirmation, every time a predetermined time elapses after the use of the battery 20 is started (first embodiment), when the power failure is resolved, or the forecast release information is received. In this case (second embodiment), the case where the remaining amount parameter of the battery 20 becomes smaller than the threshold value (third embodiment) is illustrated. However, the first condition and the second condition are not limited to these embodiments.

  For example, a state in which power supply from the commercial power supply 16 to the house 12 becomes impossible due to an abnormality in a device or a circuit that supplies the power of the commercial power supply 16 (first power supply means) to the house 12 in the first state. It is good also as conditions. In this case, it is good also considering the time when the supply abnormality of the electric power from the commercial power source 16 to the house 12 is solved as the second condition.

  Further, when the first power supply means is the commercial power supply 16 and the second power supply means is the storage battery (the battery 20 of the automobile 18), the timing when the daytime in which the electricity rate is high arrives is the first condition, The timing when the night time when the charge is low can be set as the second condition. This makes it possible for the user to judge that the storage battery is used during the daytime when the electricity rate is high, and the commercial power supply 16 is used during the nighttime when the electricity rate is low.

  Furthermore, when a solar power generation device or a wind power generation device is adopted as the first power supply means, when the amount of power generation by sunlight decreases due to continued rain or cloudy weather, or the amount of power generation by wind power decreases due to weak wind. The case where it falls can be made into the 1st condition. And the case where the electric power generation amount by sunlight and the electric power generation amount by wind power are recovered can be set as the second condition.

  3. In the first to third embodiments, the smartphone 24 is used as the confirmation unit, but a portable terminal such as a mobile phone or a notebook computer can be used as the confirmation unit. Furthermore, a household electronic bulletin board, a personal computer, a touch panel, etc. installed in the house 12 can be used as the confirmation means. Further, not only one smartphone 24 but also a plurality of smartphones 24, personal computers, and the like may be caused to execute switching confirmation all at once.

  4). In the first to third embodiments, when switching is confirmed, a message is sent by e-mail to the smartphone 24 so that the smartphone 24 displays the message. However, for example, the smartphone 24, the mobile phone, or the like may perform voice switching confirmation, or may perform switching confirmation via a dedicated application or software. Furthermore, vibrations and notification sounds may be combined.

  5. In the first to third embodiments, the switching confirmation is executed for the user who is out, but the user may be present in the house 12 or the automobile 18. When targeting a user in the house 12, control means (control devices 14, 28, on-vehicle ECU 30) and confirmation via communication means such as wireless LAN, Bluetooth (registered trademark), WiFi (registered trademark), proximity wireless, etc. Communication between means may be performed. By using these communication means, it is possible to communicate even in a house (user) in a place where radio waves from the smartphone 24 and the mobile phone do not reach.

  6). In the first to third embodiments, a detached house is adopted as the house 12, but the house 12 may be an apartment house such as an apartment or an apartment.

  DESCRIPTION OF SYMBOLS 10 ... Power supply system, 12 ... House, 14 ... Control apparatus (control means, power supply control apparatus), 16 ... Commercial power supply (first power supply means), 18 ... Automobile, 20 ... Battery (second power supply means, Storage battery), 24 ... smart phone (confirming means), 28 ... control device (control means, first control unit, power supply control device), 30 ... vehicle-mounted ECU (control means, second control unit, power supply control device) .

Claims (17)

A first power supply means (16) for supplying power to the house (12);
A second power supply means (20) for assisting power supply to the house in place of the first power supply means;
Confirmation means (24) for confirming to the user whether or not to switch the power supply to the house from one of the first power supply means and the second power supply means to the other;
Control means (14, 28, 30) for controlling the confirmation means, and switching power supply to the house from one of the first power supply means and the second power supply means to the other,
In the case where power is supplied to the house by the first power supply means, disaster forecast information is received, or the power supply from the first power supply means to the house is disabled Thus, when the first condition is satisfied, the control unit causes the confirmation unit to execute the switching confirmation, and when there is permission from the user for the switching confirmation, the control unit supplies power to the house. The power supply system is characterized in that the power supply system is switched to the second power supply means. A first power supply means (16) for supplying power to the house (12);
A second power supply means (20) for assisting power supply to the house in place of the first power supply means;
Confirmation means (24) for confirming to the user whether or not to switch the power supply to the house from one of the first power supply means and the second power supply means to the other;
Control means (14, 28, 30) for controlling the confirmation means, and switching power supply to the house from one of the first power supply means and the second power supply means to the other,
When the first condition is satisfied by receiving disaster forecast information when power is supplied to the house by the first power supply means, the control means confirms the switching confirmation with the confirmation means. And switching the power supply to the house to the second power supply means when there is permission from the user for the switching confirmation.
A power supply system characterized by that. The power supply system according to claim 1 or 2 , wherein the second power supply means is a storage battery (20). The power supply system according to claim 3 , wherein the storage battery is a battery (20) mounted on an automobile (18). In the case where power is supplied to the house by the second power supply means, the control means causes the confirmation means to execute the switching confirmation and satisfy the switching confirmation when the second condition is satisfied. The power supply system according to claim 3 or 4 , wherein when there is permission from a user, the power supply to the house is switched to the first power supply means. A first power supply means (16) for supplying power to the house (12);
A second power supply means (20) for assisting power supply to the house in place of the first power supply means;
Confirmation means (24) for confirming to the user whether or not to switch the power supply to the house from one of the first power supply means and the second power supply means to the other;
Control means (14, 28, 30) for controlling the confirmation means, and switching power supply to the house from one of the first power supply means and the second power supply means to the other,
The second power supply means is a storage battery (20),
In the case where power is supplied to the house by the first power supply means, disaster forecast information is received, or the power supply from the first power supply means to the house is disabled Thus, when the first condition is satisfied, the control unit causes the confirmation unit to execute the switching confirmation, and when there is permission from the user for the switching confirmation, the control unit supplies power to the house. When the second condition is satisfied in the case where power is supplied to the house by the second power supply means and the second power supply means is switched to the second power supply means, the confirmation means executes the switching confirmation, A power supply system that switches power supply to the house to the first power supply means when there is permission from the user for the switching confirmation. The control means includes
In the case where power is supplied to the house by the first power supply means, when the first condition is satisfied, a first control unit (28) that transmits a first command signal;
When the first command signal is transmitted from the first control unit, the confirmation unit is caused to execute the switching confirmation, and when there is permission from the user for the switching confirmation, the power to the house The power supply system according to claim 5 or 6 , further comprising a second control unit (30) for switching supply to the second power supply means. The second control unit causes the confirmation unit to execute the switching confirmation when the second condition is satisfied when power is supplied to the house by the second power source unit. If there is permission from the user to confirm the switch, send a second command signal,
The power supply system according to claim 7 , wherein the first control unit switches the power supply to the house to the first power supply unit when the second command signal is transmitted from the second control unit. . The power supply system according to any one of claims 5 to 8 , wherein the first power supply means is a commercial power supply (16). The power supply system according to any one of claims 5 to 9 , wherein the first condition is a case where disaster forecast information related to a natural disaster is input to the control unit or a power failure occurs. The power supply system according to any one of claims 5 to 10 , wherein the second condition is a case where a parameter relating to the remaining amount of the storage battery is smaller than a preset threshold value. The power supply system according to claim 11 , wherein the threshold is set to be changeable. The power supply system according to claim 10, wherein the second condition is a case where forecast cancellation information for canceling the disaster forecast information is input to the control means or a power failure is eliminated. When the power supply to the house is performed by the first power supply means, the control means does not cause the confirmation means to execute the switching confirmation when a power failure occurs. The power supply system according to claim 10 , further comprising a forced switching mode for switching supply to the second power supply means. In the forced switching mode, the control means causes the confirmation means to execute the switching confirmation after a predetermined time has elapsed since the power supply to the house is switched to the second power supply means, and for the switching confirmation. The power supply system according to claim 14 , wherein when there is a permission from a user, the power supply to the house is switched to the first power supply means. The power supply system according to any one of claims 1 to 15 , wherein the confirmation unit is a mobile terminal. First power supply means for supplying power to the house, second power supply means for assisting power supply to the house in place of the first power supply means, and power supply to the house for the first power supply. A power supply control device (14, 28, 30) for controlling a confirmation means for confirming switching to a user as to whether or not to switch from one of the first power supply means and the second power supply means to the other,
In the case where power is supplied to the house by the first power supply means, disaster forecast information is received, or the power supply from the first power supply means to the house is disabled Thus, when the first condition is established, the confirmation unit is caused to execute the switching confirmation, and when there is permission from the user for the switching confirmation, the second power supply is used to supply power to the house. A power supply control device characterized by switching to means.

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