JP6536002B2 - Ampere breaker and power management system - Google Patents

Description

  The present invention relates to an ampere breaker and a power management system.

  Conventionally, there is a system described in Patent Document 1 as a power management system of a consumer. The power management system described in Patent Document 1 monitors the power consumption of the electric devices in the consumer, and when the sum of the power consumption approaches the contract power, new according to the priority order and the power consumption of each electric device. It is determined whether power can be supplied to the appropriate electrical device. When it is determined that the power supply to the new electric device is difficult, the power management system cuts off the power supply to the lower priority electric device and then supplies the power to the new electric device. According to such a configuration, since the power consumption of the customer is unlikely to exceed the contract power, it is possible to avoid the interrupting operation of the wiring breaker.

JP, 2001-69668, A

  By the way, if the power consumption of each customer increases in summer etc., the supply and demand of power may be tight. Under such circumstances, if a situation occurs in which the power supply of the power system can not catch up with the demand power of the customer, there is a risk that a so-called large-scale power outage may occur, which causes a power outage over a wide area. In this respect, in the power management system described in Patent Document 1, although the interrupting operation of the wiring breaker at each customer can be avoided, the demand power itself of each customer can not be suppressed. Therefore, the power supply and demand condition can not be stabilized, and as a result, a large-scale blackout and the like may occur when the power supply and demand condition is tight.

  The present invention has been made in view of these circumstances, and it is an object of the present invention to provide an ampere breaker and a power management system capable of more accurately stabilizing the supply and demand of power.

In order to solve the above problems, a power management system for managing power supplied to a plurality of customers (3) is provided to the customers, and power based on the usage current value of the customers exceeding the current limit value with interrupts power supply from the system (2) to the customer, monitoring and possible ampere breaker to variably set the current limit value (32), the supply state of the power between the consumer and power system integration And a central monitoring server (40) . Chuo monitoring server, when the power supply reserve rate of determining whether a predetermined proper determination value or more, the power supply reserve rate is determined to be smaller than the proper determination value, the power of While setting the current limit indication value based on the supply reserve rate, transmitting the current limit indication value to the ampere breaker, and temporarily determining that the supply reserve rate is less than the predetermined appropriate judgment value, the supply reserve rate is determined. If it is determined that the value exceeds the appropriate determination value, it is determined whether an event related to a power failure has occurred, and if an event related to a power failure has occurred, the current limit indication value is reset. Also , send the current limit indication value to the ampere breaker. The ampere breaker sets the current limit value based on the current limit indication value.

  According to the present invention, by setting the current limit value according to the supply and demand condition of the power, the external device such as the central monitoring server can limit the demand power of the customer or cancel the limit. Therefore, since it becomes easy to balance supply power and demand power, the demand-and-supply state of electric power can be stabilized more appropriately.

  According to the present invention, it is possible to more accurately stabilize the supply and demand of power.

FIG. 1 is a block diagram showing a schematic configuration of an embodiment of a power management system. The block diagram which shows schematic structure of the electric power system of a consumer. The flowchart which shows the operation example about one embodiment of an ampere breaker. The sequence chart which shows a part of operation example of the power system server, the central monitoring server, and the relay server about the power management system of an embodiment. The sequence chart which shows a part of operation example of the power system server, the central monitoring server, and the relay server about the power management system of an embodiment. The sequence chart which shows a part of operation example of the power system server, the central monitoring server, and the relay server about the power management system of an embodiment. The sequence chart which shows a part of operation example of the power system server, the central monitoring server, and the relay server about the power management system of an embodiment.

  Hereinafter, an embodiment of the power system using the ampere breaker and the power management system will be described.

  As shown in FIG. 1, the power system 1 of the present embodiment includes a power system 2 and a customer 3.

  The power system 2 includes a power plant 20, a power transmission system 21, a power transformation system 22, and a power distribution system 23. The power transmission system 21 transmits high-voltage power generated by the power plant 20 to the power transformation system 22 via the power transmission system 21. The transformation system 22 steps down high-voltage power transmitted from the transmission system 21 and transmits the power to each of the distribution systems 23. Each power distribution system 23 further steps down the power transmitted from the power transformation system 22 and distributes the power to each customer 3 through the power line 24.

  As shown in FIG. 2, the customer 3 has a smart meter 30 and a distribution board 31.

  The smart meter 30 is provided in the middle of the power line 24 drawn from the distribution system 23 to the distribution board 31. The smart meter 30 measures the amount of power supplied to the distribution board 31 via the power line 24, that is, the amount of power supplied to the customer 3. The smart meter 30 can bi-directionally communicate with an external device via the communication line 46. Note that bidirectional communication with the smart meter 30 may use PLC (power line carrier communication) superimposed on the power line 24 instead of the communication line 46 or may use various wireless communication (not shown).

  The distribution board 31 includes an ampere breaker 32, an earth leakage breaker 33, and a plurality of branch breakers 34. The ampere breaker 32, the earth leakage breaker 33, and the branch breaker 34 are provided in the middle of the power line 24 in this order from the side closer to the smart meter 30.

  The ampere breaker 32 monitors the energized state of the power line 24. The amp breaker 32 shuts off the power line 24 when the current value flowing through the power line 24, ie, the working current value of the customer 3 exceeds the current limit value Im, to supply power from the power system 2 to the customer 3 Cut off. The current limit value Im can be arbitrarily set in the range from the lower limit value to the upper limit value. The upper limit value of the power limit value is set to a current value corresponding to the power value contracted between the power company and the customer 3, that is, a contract current value (for example, 30 [A]). The lower limit value of the current limit value Im is set to a value larger than zero and smaller than the contracted current value. As the lower limit value of the current limit value Im, for example, a value (for example, 15 [A]) that can supply power to the minimum home appliance of the customer 3 is used. In addition, as the current limit value Im, a value obtained through an experiment, simulation, or the like may be used so that electric power can be supplied to the minimum home electric appliances of each customer 3, or a value predetermined by a standard. May be used. Further, the set value of the current limit value Im may be a continuous value or may be two or more discrete values. The amp breaker 32 is connected to the smart meter 30 via the communication line 35. The ampere breaker 32 sets the current limit value Im based on the current limit indication value Id transmitted from the smart meter 30 via the communication line 35. The transmission of the current limit indication value Id may be performed by wireless communication or the like as in the communication between the smart meter 30 and the external device.

  In the ampere breaker 32, the current limit value Im can be arbitrarily changed while power is supplied via the power line 24, but when the power supply is stopped due to a power failure or the like, the current limit value Im is It will be reset to the initial value. The initial value is set to the lower limit value of the current limit value Im. The configuration for setting the current limit value Im to a plurality of values in the ampere breaker 32 may be an electrical configuration or a mechanical configuration.

  The earth leakage breaker 33 has a function of interrupting the earth leakage by detecting the leakage current when the earth leakage occurs and interrupting the power line 24.

  The branch breakers 34 are respectively provided in the middle of the plurality of wires 24 a branched from the power line 24. The plurality of wires 24 a are electrically connected to the lighting, the outlet, and the like in the customer 3. The branch breaker 34 protects, for example, a load or wiring connected to the outlet from damage by interrupting the wiring 24 a when an abnormal overcurrent flows in the wiring 24 a due to a cause such as an overload or short circuit.

  Next, the power management system 4 will be described.

  As shown in FIG. 1, the power management system 4 includes a central monitoring server 40, a power system server 41, and a relay server 42.

  The power system server 41 is provided in a facility that comprehensively manages the power plant 20, the power transmission system 21, the transformation system 22, and the like. The power system server 41 can communicate bi-directionally with the central monitoring server 40 via the communication line 43. The power system server 41 constantly monitors the status of the power plant 20, the transmission system 21, the transformation system 22, and the like. The power system server 41 transmits the status and information of the power plant 20, the transmission system 21, and the transformation system 22 to the central monitoring server 40 in response to a request from the central monitoring server 40.

  The relay server 42 is provided in a substation or the like. The relay server 42 can bidirectionally communicate with the central monitoring server 40 via the communication line 44. Further, the relay server 42 can perform two-way communication with the smart meter 30 of each customer 3 via the communication line 45 connected to the power distribution system 23 and the communication line 46 connected to each customer 3 from the power distribution system 23 It has become. The relay server 42 constantly monitors the state of the distribution system 23. The relay server 42 constantly monitors the power consumption and the like of each customer 3 based on the communication with the smart meter 30 of each customer 3. The relay server 42 transmits, to the central monitoring server 40, the status and information of the distribution system 23, information on the power consumption of each customer 3, etc. in response to a request from the central monitoring server 40.

  The central monitoring server 40 constantly monitors the state of the power system 2 based on various information transmitted from the power system server 41 and the relay server 42. The central monitoring server 40 monitors, for example, whether disconnection of the power plant 20, blocking of the transmission system 21, a local power failure, or the like has occurred. Local power outages mean that power outages occur in only some areas. Further, the central monitoring server 40 also grasps information as to whether or not planned power restriction is performed on the customer 3 in order to avoid a large-scale power failure.

  The central monitoring server 40 sets an indication value Id of the current limit value Im based on various information transmitted from the power system server 41 and the relay server 42. The central monitoring server 40 transmits the set current limit indication value Id to the relay server 42 via the communication line 44. When receiving the current limit indication value Id transmitted from the central monitoring server 40, the relay server 42 transmits the current limit indication value Id to the smart meter of the customer 3 via the communication line 45, the distribution system 23, and the communication line 46. Send to 30 When the smart meter 30 receives the current limit indication value Id transmitted from the relay server 42, the smart meter 30 transmits the current limit indication value Id to the ampere breaker 32. The ampere breaker 32 sets the current limit value Im based on the current limit indication value Id transmitted from the smart meter 30. Thus, the central monitoring server 40 has a function of setting the current limit value Im of the ampere breaker 32 of the customer 3 based on the state of the power plant 20, the transmission system 21 and the like.

  Next, the operation of the ampere breaker 32 will be described in detail.

  As shown in FIG. 3, when power feeding from power system 2 via power line 24 is started, ampere breaker 32 sets current limit value Im to the lower limit value (step S1). That is, the ampere breaker 32 monitors the energized state based on the lower limit value of the current limit value Im. Thereafter, the ampere breaker 32 monitors whether or not the relay server 42 has sent the current limit indication value Id (step S2). When the ampere breaker 32 transmits the current limit indication value Id from the relay server 42 (step S2: YES), the ampere breaker 32 changes the current limit value Im based on the value (step S3). In this case, the ampere breaker 32 monitors the energized state based on the current limit value Im after the change.

  Next, the ampere breaker 32 determines whether or not a power failure has occurred by judging whether or not the power supply via the power line 24 is stopped (step S4). Also, even when the relay server 42 does not transmit the current limit indication value Id (step S2: NO), the ampere breaker 32 determines whether a power failure has occurred (step S4). If a power failure has not occurred (step S4: NO), the ampere breaker 32 returns to the state of monitoring whether or not the relay server 42 has sent the current limit indication value Id (step S2). On the other hand, if a power failure has occurred (step S4: YES), the ampere breaker 32 returns the current limit value Im to the lower limit value (step S1).

  The change of the current limit value Im in the ampere breaker 32 may be performed by all the customers 3 or may be performed only by the customer 3 who has accepted the change. At this time, the power company prepares a contract with a high charge setting instead of fixing the current limit value Im, and a contract with a low charge setting instead of being able to raise or lower the current limit value Im according to the circumstances of the power system 2 It is conceivable to take a method of making the user select.

  Next, operations of the central monitoring server 40, the power system server 41, and the relay server 42 will be described. The current limit value Im of the ampere breaker 32 of each customer 3 is set to the contract current value in the initial state.

  As shown in FIG. 4, the central monitoring server 40 periodically transmits a power status notification command to the power system server 41 and the relay server 42 (step S <b> 200).

  When the power system server 41 receives the notification command of the power condition, it collects the status of the power plant 20 and the power transmission system 21 and information etc. (step S100), and transmits the collected information to the central monitoring server 40 (step S101) .

  When the relay server 42 receives the notification command of the power status, it collects the status and information of the distribution system 23 and the information of the power consumption of each customer 3 (step S300), and sends the collected information to the central monitoring server 40. It transmits (step S301).

  The central monitoring server 40 analyzes the supply and demand of power based on various information transmitted from the power system server 41 and the relay server 42 (step S201). For example, the central monitoring server 40 acquires information on the power supply side based on the state and information of the power plant 20 and the power transmission system 21. The information on the power supply side includes peak power supply and the like. Further, the central monitoring server 40 acquires the information on the power demand side based on the state and information of the distribution system 23 and the information on the power consumption of each customer 3. Information on the power demand side includes estimated maximum power and the like.

  The central monitoring server 40 determines whether the supply and demand state of power is appropriate based on the acquired state of power supply and the state of demand power (step S202). For example, the central monitoring server 40 obtains the backup power by calculating the difference between the peak power supply and the estimated maximum power. Further, the central monitoring server 40 calculates the power supply reserve ratio by calculating the ratio of the reserve power to the estimated maximum power. When the supply reserve ratio is equal to or more than the predetermined appropriate determination value, the central monitoring server 40 determines that the supply and demand of power is appropriate (step S202: YES). In this case, the central monitoring server 40 returns to the process of step S200. Therefore, when the power supply and demand condition is appropriate, the central monitoring server 40 periodically monitors the power supply and demand condition. Thus, the process shown in FIG. 4 corresponds to the normal time monitoring process performed by the central monitoring server 40 in a situation where a power failure or the like does not occur.

  On the other hand, when the power supply becomes unstable due to, for example, a large amount of power supply system 2 disconnection or a large-scale loss of the power generation source, the supply reserve ratio becomes less than the appropriate determination value. In this case, the central monitoring server 40 determines that the power supply and demand condition is not appropriate (step S202: NO). In this situation, since the power supply and demand condition is tight, the central monitoring server 40 executes the process shown in FIG. 5 in order to adjust the power supply and demand condition. That is, the central monitoring server 40 sets the power reduction value, the power limit area, the current limit value, and the like in order to make the supply reserve rate equal to or more than the appropriate determination value (step S203). The power reduction value indicates the amount of demand power that needs to be reduced to make the supply reserve rate equal to or higher than the appropriate determination value. The power-restricted area indicates the area where power demand is restricted. Note that one or more areas are selected as the power limit area based on a preset priority or the like. The central monitoring server 40 sets the current limit indication value Id based on the power reduction value and the limited area. The current limit indication value Id is set to a value smaller than the contracted current value. The central monitoring server 40 transmits, to the relay server 42, information and the like of the set limited area and the current limit indication value Id (step S204). Also, the central monitoring server 40 transmits a notification command of the power status to the power system server 41 (step S205).

  When the relay server 42 receives the information on the restricted area and the current limit instruction value Id, the relay server 42 transmits the current limit instruction value Id to each customer 3 corresponding to the restricted area (step S302). Further, the relay server 42 collects the state and information of the distribution system 23, information of the power consumption of each customer 3 and the like (step S303), and transmits the collected information to the central monitoring server 40 (step S304).

  When the power system server 41 receives the notification command of the power status, it collects the status of the power plant 20 and the power transmission system 21 and information etc. (step S102), and transmits the collected information to the central monitoring server 40 (step S103) .

  The central monitoring server 40 analyzes the supply and demand of power based on the information transmitted from the power system server 41 and the relay server 42 (step S206). Specifically, the central monitoring server 40 performs the same processing as step S201 described above, to thereby provide information on the power supply side including peak supply power and the like, and information on the power demand side including estimated maximum power and the like. To get Next, the central monitoring server 40 determines whether the supply and demand condition of the power is appropriate based on the acquired condition of the supplied power and the condition of the required power (step S207). For example, the central monitoring server 40 calculates the power supply reserve ratio by performing the same process as step S202 described above, and if the supply reserve ratio is less than the appropriate determination value, the power supply and demand condition is not appropriate. It judges (Step S207: NO). In this case, the central monitoring server 40 returns to the process of step S203 and sets the current limit indication value Id to a smaller value. As a result, since the current limit value Im of the ampere breaker 32 of each customer 3 is set to a smaller value, the power consumption of each customer 3 is further suppressed, and the demand power is reduced.

  When the supply reserve ratio becomes equal to or more than the appropriate determination value due to the decrease in demand power, the central monitoring server 40 determines that the supply and demand condition of the power is appropriate (step S207: YES). In this case, the central monitoring server 40 executes the process shown in FIG. 6 to monitor whether or not an event related to a power failure has occurred. In the present embodiment, as an event related to a power failure, an abnormality in the power system 2, a regional power failure, and planned power restriction are adopted.

  As shown in FIG. 6, the central monitoring server 40 first determines whether or not an abnormality has occurred in the power system 2 (step S208). The central monitoring server 40 determines whether, for example, disconnection of the power plant 20 or interruption of the transmission system 21 occurs as an abnormality of the power system 2. When an abnormality occurs in the power system 2 (step S208: YES), the central monitoring server 40 transmits a notification command of the recovery status to the power system server 41 (step S209).

  When receiving the notification command of the recovery status, the power system server 41 collects the recovery status and recovery information of the power plant 20 and the transmission system 21 (step S104), and transmits the collected information to the central monitoring server 40 (step S104) S105).

  The central monitoring server 40 determines whether the abnormality of the power system 2 has been eliminated based on the information transmitted from the power system server 41 (step S210). Here, when the abnormality of the electric power system 2 is not eliminated (step S210: NO), there is a possibility that the supply and demand state of electric power may be tight in the future. In order to cope with this, the central monitoring server 40 returns to the process of step S203 shown in FIG. 5 when the abnormality of the power system 2 is not eliminated (step S210: NO). As a result, since the current limit value Im of each customer 3 is reset during a period in which an abnormality occurs in the power system 2, it is possible to stabilize the supply and demand of power.

  When the abnormality of the power system 2 is eliminated (step S210: YES), the central monitoring server 40 sets the recovery flag F to the on state (step S211). The recovery flag F is initially set to the off state. Next, the central monitoring server 40 determines whether a local power failure has occurred (step S212). The central monitoring server 40 also determines whether or not a regional power failure has occurred (step S212), even when no abnormality has occurred in the power system 2 in the first place (step S208: NO). If a local power failure has occurred (step S212: YES), the central monitoring server 40 transmits a notification command of recovery status to the relay server 42 (step S213).

  When receiving the notification command of the recovery status, the relay server 42 collects the recovery status of the power distribution system 23, recovery information and the like (step S305), and transmits the collected information to the central monitoring server 40 (step S306).

  When the central monitoring server 40 receives the information on the recovery status transmitted from the relay server 42, the central monitoring server 40 determines, based on the information, whether or not the regional power failure has been eliminated (step S214). Here, if the local power failure has not been eliminated (step S214: NO), there is a possibility that the power supply and demand condition will be tight in the future. In order to cope with this, the central monitoring server 40 returns to the process of step S203 shown in FIG. 5 when the local power failure is not eliminated (step S214: NO). As a result, since the current limit value Im of each customer 3 is reset during a period in which a local power failure occurs, the power supply and demand can be stabilized.

  When the regional power failure is eliminated (step S214: YES), the central monitoring server 40 sets the recovery flag F to the on state (step S215), and then determines whether planned power restriction is performed (step S215). Step S216). The central monitoring server 40 also determines whether or not planned power restriction has been performed (step S216), even when a local power failure does not occur originally (step S212: NO). If the planned power restriction has been performed (step S216: YES), the central monitoring server 40 determines whether the planned power restriction has been canceled (step S217). Here, if the planned power restriction has not been canceled (step S217: NO), there is a possibility that the supply and demand of power will be tight in the future. In order to cope with this, the central monitoring server 40 returns to the process of step S203 shown in FIG. 5 when the planned power restriction has not been released (step S217: NO). As a result, since the current limit value Im of each customer 3 is reset during a period when planned power limitation is performed, it is possible to stabilize the supply and demand of power.

  The central monitoring server 40 executes the recovery process shown in FIG. 7 after setting the recovery flag F to the on state (step S218) when the planned power limitation is released (step S217: YES). . The central monitoring server 40 also executes the recovery process shown in FIG. 7 even when planned power limitation is not performed originally (step S216: NO).

  As shown in FIG. 7, the central monitoring server 40 first determines whether the recovery flag F is in the on state (step S219). When the recovery flag F is in the on state (step S219: YES), the central monitoring server 40 either recovers from an abnormality in the power system 2, recovers from a regional power failure, or cancels a planned power limit. If it is determined, it is determined that recovery processing needs to be performed. In this case, the central monitoring server 40 determines the power supply and demand power after restoration and the restoration area (step S220). Further, the central monitoring server 40 sets the current limit indication value Id based on the power supply and demand power after restoration and the restoration area (step S220). For example, the central monitoring server 40 determines how much it is possible to increase the current limit value Im of each customer 3 in the recovery area within a range in which the power supply and demand can be stabilized, and the determination result The current limit indication value Id is set based on The central monitoring server 40 transmits, to the relay server 42, information such as the set recovery area and the current limit indication value Id (step S221).

  When the relay server 42 receives the information on the restoration area and the current limit indication value Id, the relay server 42 transmits the current restriction indication value Id to each customer 3 corresponding to the restoration area (step S307). Further, the relay server 42 collects the state and information of the distribution system 23, the information of the power consumption of each customer 3, etc. (step S308), and transmits the collected information to the central monitoring server 40 (step S309).

  The central monitoring server 40 analyzes the supply and demand of power based on the information transmitted from the relay server 42 (step S222). Specifically, the central monitoring server 40 performs the same processing as step S201 described above, to thereby provide information on the power supply side including peak supply power and the like, and information on the power demand side including estimated maximum power and the like. To get Next, the central monitoring server 40 determines whether the supply and demand condition after restoration has stabilized based on the analyzed supply and demand condition of power (step S223). For example, the central monitoring server 40 calculates the power supply reserve ratio by performing the same process as step S202 described above. Then, the central monitoring server 40 increases the power consumption of each customer 3 when there is a customer 3 whose current limit value Im has not reached the contract current value and there is an allowance in the power supply reserve ratio. It is determined that there is room to do it. In this case, the central monitoring server 40 determines that the supply / demand state after recovery is not stable (step S207: NO), and returns to the process of step S220 to further increase the current limit value Im of the customer 3.

  If the current limit value Im of all the customers 3 has reached the contract current value, the central monitoring server 40 determines that the supply and demand state after restoration is stable (step S223: YES). In this case, the central monitoring server 40 returns to the process of step S200 in FIG. That is, the central monitoring server 40 returns to the normal monitoring process.

  According to the ampere breaker 32 and the power management system 4 of the present embodiment described above, the actions and effects shown in the following (1) to (6) can be obtained.

  (1) In a situation where the power supply and demand condition is tight, the central monitoring server 40 changes the current limit value Im of the ampere breaker 32 of each customer 3 according to the power supply and demand condition. Thereby, the power consumption of each customer 3 can be restricted or the restriction can be canceled according to the demand condition of the power. Therefore, since it becomes easy to balance supply power and demand power, the demand-and-supply state of electric power can be stabilized more appropriately. As a result, a wide area blackout can be suppressed. Moreover, since each consumer 3 can use electric power freely if it is a range which does not exceed current limit value Im, the fall of the convenience of consumer 3 can be minimized. Furthermore, infrastructure costs can be reduced because it is not necessary to set advanced power management devices for each customer 3.

  (2) The current limit value Im is set to the lower limit value at the start of power supply from the power system 2 to the ampere breaker 32. Thereby, for example, since it can avoid that power consumption will increase suddenly at the time of first use of the ampere breaker 32, the demand-and-supply state of electric power can be stabilized more.

  (3) The current limit value Im is set to the lower limit value at the time of a power failure. Thereby, for example, it is possible to reduce the demand power when the power system 2 is restored after the power failure and the power supply from the power system 2 to each customer 3 is started. Therefore, it is possible to further stabilize the supply and demand of power at the time of power recovery.

  (4) The central monitoring server 40 sets the current limit indication value Id based on the power supply reserve ratio and determines the current limit indication value Id of the customer 3 when it determines that the power supply and demand condition is not appropriate. Send to the ampere breaker 32. As a result, the current limit value Im of each customer 3 can be easily set to a value suitable for stabilizing the supply and demand condition of the power, so that the supply and demand condition of the power can be further stabilized.

  (5) After the central monitoring server 40 once determines that the power supply and demand condition is not appropriate, if the power supply and demand condition becomes appropriate, the central monitoring server 40 relates to a power failure, such as disconnection of the power plant 20 or a regional power failure, for example. To determine if an event has occurred. The central monitoring server 40 resets the current limit indication value Id and sends the current limit indication value Id to the ampere breaker 32 of the customer 3 when an event related to a power failure occurs. As a result, since the power consumption of each customer 3 can be more accurately limited until the event related to the power failure is resolved, it becomes easy to stabilize the power supply and demand. Therefore, early recovery from an event related to a power failure can be promoted.

  (6) The central monitoring server 40 repeats the process of steps S220 to 223 in FIG. 7 until the power supply and demand condition after recovery is stabilized, when the event related to the power failure is resolved and the power condition is recovered. Run. As a result, the current limit value Im of each customer 3 in the recovery area gradually increases to the contract current value, so after comparing the case where the current limit value Im of each customer 3 is restored immediately to the contract current value after restoration, It is possible to suppress a sharp rise in demand power. Therefore, it is possible to further stabilize the supply and demand of power after restoration.

  In addition, the said embodiment can also be implemented with the following forms.

  -The central monitoring server 40 of the above embodiment sets the current limit indication value Id to the contract current value of each customer 3 when the event related to the power failure is eliminated, thereby enabling each customer 3 in the recovery area. The current limit value Im of V may be immediately raised to the contract current value. According to this configuration, it is possible for each customer 3 to use all the home appliances immediately after restoration, and thus the convenience can be improved.

  -In the above-mentioned embodiment, although the abnormalities of power system 2, the regional blackout, and the plan power restriction were adopted as an event relevant to blackout, other than these may be adopted.

  -In the said embodiment, although the restoration condition of the event was confirmed by each of the abnormality of the electric power grid | system 2, the regional power failure, and the planned power limitation, when these overlap, it can confirm similarly. . In this case, it is also possible to set and identify the recovery flag F as a separate flag for each individual event, and perform processing such as recovery for each individual event in the power recovery process (S219) in the central monitoring server 40. It is.

  The central monitoring server 40 of the above embodiment sets the current limit indication value Id based on the power supply reserve rate, but the method of setting the current limit indication value Id can be changed as appropriate. For example, the central monitoring server 40 may gradually decrease the current limit indication value Id until the supply and demand condition of the power is stabilized, when it is determined that the supply and demand condition of the power is not appropriate.

  In the above embodiment, the central monitoring server 40 transmits the current limit indication value Id to the ampere breaker 32. However, the transmission subject of the current limit indication value Id may be other than the central monitoring server 40. For example, the central monitoring server 40 determines only the limited area and the limited amount of power (it may be a reduction value) and transmits it to the relay server 42. The relay server 42 determines the current limit indication value Id of the customer 3 in the target area based on the limited area and the limited power amount notified from the central monitoring server 40, and sets the determined current limit indication value Id to the ampere breaker 32. It may be sent. The point is that the ampere breaker 32 may be one that variably sets the current limit value Im based on communication with an external device.

  In the above embodiment, the current limit value Im of the ampere breaker 32 is set to the lower limit value at the time of a power failure, but the setting value of the current limit value Im at the power failure is equal to or higher than the lower limit value and less than the contracted current value. If it is, it can be set to any value. Similarly, the setting value of the current limit value Im at the start of feeding can be set to any value as long as it is a value equal to or greater than the lower limit value and less than the contracted current value. As in the above embodiment, when the current limit value Im of the ampere breaker 32 is set to the lower limit value at the time of power failure and at the start of power feeding, the effects of the above (2) and (3) are most enhanced. It is

  The present invention is not limited to the above specific example. That is, to the above specific examples, those skilled in the art may appropriately modify the design as long as the features of the present invention are included in the scope of the present invention. For example, each element included in each specific example described above and its arrangement, material, conditions, shape, size, and the like are not limited to those illustrated, and can be appropriately changed. Moreover, each element with which the above-mentioned embodiment is equipped can be combined as much as technically possible, and what combined these is also included in the scope of the present invention as long as the feature of the present invention is included.

2: Power system 3: customer 32: Amp breaker 40: Central monitoring server (external equipment)

Claims (5)

A power management system for managing power supplied to a plurality of customers (3), comprising:
The power supply (2) is provided to the customer, and the power supply from the power system (2) to the customer is cut off and the current limit is variably set based on the fact that the working current value of the customer exceeds the current limit value. Possible ampere breakers (32),
A central monitoring server (40) that monitors the supply and demand of power between the customer and the power system;
The central monitoring server is
It is determined whether or not the power supply reserve rate is equal to or greater than a predetermined appropriate determination value, and the power supply reserve rate is determined when it is determined that the power supply reserve rate is less than the appropriate determination value. Setting a current limit indication value based on the current limit indication value and transmitting the current limit indication value to the
After judging once that the supply reserve rate is less than a predetermined appropriate determination value, if it is determined that the supply reserve rate has become equal to or greater than the appropriate determination value, does an event related to a power failure occur? If the event related to the power failure occurs, the current limit indication value is reset and the current limit indication value is transmitted to the ampere breaker.
The ampere breaker is
A power management system, wherein the current limit value is set based on the current limit indication value. The power management system according to claim 1 , wherein the central monitoring server determines whether an abnormality occurs in the power system as an event related to the power failure. The power management system according to claim 1 , wherein the central monitoring server determines whether a regional power failure has occurred as an event related to the power failure. The power management system according to claim 1 , wherein the central monitoring server determines whether planned power restriction is performed as an event related to the power failure. The central monitoring server determines whether or not the power supply and demand condition after recovery has stabilized if the event related to the blackout has been resolved, and the power supply and demand condition after recovery is not stable. The power management system according to any one of claims 1 to 4 , wherein the current limit indication value is reset and the current limit indication value is transmitted to the ampere breaker.