JP2013017365A - Electrification management system, electrification management device, wide area management system and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electrification management system for improving convenience of a user while safety after a disaster is secured.SOLUTION: The electrification management system for managing electrification of a house includes: an electrification management device 107; and a generation transmission device. A state reception section 136 receives state information generated and transmitted by the generation transmission device. A normal state acquiring section 137 acquires normal state information showing a normal state of the house. A state determining section 139 determines whether the house is in the normal state or not on the basis of the received state information and the acquired normal state information. When the house is determined to be in the abnormal state, an electrification control section 140 sets a breaker section 112 in an interruption state. When the house is determined to be in the normal state, the electrification control section 140 sets the breaker section 112 in an electrification state.

Description

  The present invention relates to an energization management system, an energization management apparatus, a wide area management system, and a program.

  When a disaster such as an earthquake occurs, not only direct damage due to the disaster but also a fire may occur as a secondary disaster. One such fire is called an energizing fire. For example, if a household appliance that has fallen due to an earthquake shake receives the heat of an electric stove, the indoor wiring underneath the household appliance will be damaged by the shaking of the household appliance due to the earthquake, and the internal conductive material will be exposed. In some cases, a fire may occur.

  In order to prevent an energized fire, for example, Patent Document 1 discloses a breaker control system. This breaker control system includes a breaker and breaker control means. The breaker controls the supply state of power to at least one electric device used in a predetermined area indoors. The breaker control means sets the breaker to the shut-off state after the occurrence of the earthquake based on at least one of the information about the occurrence of the earthquake and the information about the occurrence of the power outage, or restores the power outage after the occurrence of the earthquake After restarting, set the breaker to the shut-off state.

JP 2006-313728 A

  In the technique described in Patent Document 1, the breaker is set to a cut-off state immediately after the occurrence of an earthquake or after a power failure that has occurred after the occurrence of an earthquake is restored and energization is resumed. When the breaker is shut off, it is necessary for the user to return the breaker to the energized state after confirming whether it is safe to supply power to the electrical equipment. Such a breaker operation is troublesome for the user.

  In addition, there is a possibility that the user may overlook a dangerous state in which an electric fire may occur, such as an electric stove beside a fallen household goods tool or a conductive material of the wiring being exposed.

  This invention is made | formed in view of such a situation, and it aims at providing the electricity supply management system etc. which can improve a user's convenience, ensuring safety | security.

An energization control system according to the present invention is an energization management system including one or more generation transmission devices and an energization management device,
The generation transmission device generates one or a plurality of state information indicating a state of a management range by the energization management device and transmits the generated state information to the energization management device,
The energization management device is
Status receiving means for receiving the status information from the generating and transmitting device;
Normal state acquisition means for acquiring normal state information indicating a normal state of the management range;
When the status indicated by the status information received by the status receiving means is not the status indicated by the normal status information, the management range is determined to be an abnormal status and is indicated by the received status information. State determination means for determining that the management range is a normal state when the state to be displayed is a state indicated by the normal state information;
Energization switching means for switching between an energized state in which the supplied power is energized within the management range and an interrupted state in which the power is not energized within the management range;
The energization control for setting the energization switching means to the cut-off state when it is determined that the management range is in an abnormal state and for setting the energization switching means to the energization state when it is determined that the management range is in a normal state Means.

  According to the present invention, the state of the management range is determined based on the state information. Then, when it is determined that the state is abnormal, the energization control unit sets the energization switching unit to the cutoff state. Thereby, safety can be ensured. Further, when it is determined that the current state is normal, the energization control unit sets the energization switching unit to the energized state. As a result, convenience for the user can be improved. Therefore, it is possible to improve user convenience while ensuring safety.

It is a figure which shows the structure of the electricity supply management system which concerns on Embodiment 1. FIG. It is a figure which shows the structure of the electricity supply management apparatus which concerns on Embodiment 1. FIG. It is a figure which shows the normal state information which concerns on Embodiment 1. FIG. It is a figure which shows the status information which concerns on Embodiment 1. FIG. It is a figure which shows the structure of the 1st production | generation transmission apparatus A which concerns on Embodiment 1. FIG. It is a figure which shows the structure of the 2nd production | generation transmission apparatus which concerns on Embodiment 1. FIG. It is a figure which shows the structure of the 3rd production | generation transmission apparatus which concerns on Embodiment 1. FIG. It is a figure which shows the structure of the 4th production | generation transmission apparatus which concerns on Embodiment 1. FIG. It is a figure which shows the structure of the 1st position production | generation part which concerns on Embodiment 1. FIG. It is a figure which shows the structure of the reference position apparatus A which concerns on Embodiment 1. FIG. It is a flowchart of the process which the electricity supply management apparatus which concerns on Embodiment 1 performs. 6 is a flowchart of processing executed by the first generation transmission device according to the first embodiment. It is a figure which shows the detailed flow of the normal state information generation process regarding the position shown in FIG. It is a flowchart of the process which the 2nd production | generation transmission apparatus which concerns on Embodiment 1 performs. 6 is a flowchart of processing executed by a third generation transmission device according to the first embodiment. It is a flowchart of the process which the 4th production | generation transmission apparatus which concerns on Embodiment 1 performs. It is a figure which shows the outline | summary of a structure of the wide area management system which concerns on Embodiment 2. FIG. It is a figure which shows the structure of the electricity supply management apparatus which concerns on Embodiment 2. FIG. It is a figure which shows the structure of the wide area management apparatus which concerns on Embodiment 2. FIG. It is a figure which shows the status information according to house which concerns on Embodiment 2. FIG. It is a figure which shows the normal state information which concerns on Embodiment 2. FIG. It is a figure which shows the correspondence information which concerns on Embodiment 2. FIG. It is a figure which shows the map information which concerns on Embodiment 2. FIG. It is a figure which shows the detailed structure of the corresponding | compatible part which concerns on Embodiment 2. FIG. 10 is a flowchart of processing executed by a wide area management apparatus according to the second embodiment. It is a flowchart which shows the detail of the corresponding | compatible process shown in FIG. It is a flowchart which shows the detail of the evacuation route notification process shown in FIG. It is a figure which shows the evacuation route information which concerns on Embodiment 2. FIG.

  Embodiments of the present invention will be described with reference to the drawings. Throughout the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.

Embodiment 1. FIG.
As shown in FIG. 1, the energization management system 101 according to the first embodiment of the present invention manages the energization of the power supplied from the commercial power supply 102 via the power transmission line 103 to the house 104 based on the state information. System.

  The state information is information indicating the state of the house 104 and indicates a state related to the energized fire. The state of the house 104 includes the state of the house 104 itself, the state of the objects 110a-b and 111 provided in association with the house 104, the state of the resident 105 as a user, and the like.

  As a specific example of the type of state indicated by the state information, the objects 110a to b and 111 in the house are inclined due to the position of the resident 105, the seismic intensity at the house 104 at the time of the earthquake, the earthquake, etc. The degree of inclination, the occurrence of fire (smoke concentration), etc. can be mentioned. The type of state may further include disconnection and ground fault in the wirings 106a and 106b in the house, water leakage, gas leakage, and the like.

  The commercial power source 102 is an example of a power source (external power source) outside the energization management system, and the external power source may be a solar panel or a storage battery provided in the house 104. The house 104 is an example of a certain range (management range) managed by the energization management system 101, and may be an office, a building, or the like, and may be a certain range of land, a park, a certain range of roads, or the like. May be.

  The energization management system 101 includes an energization management device 107, a generation transmission device 108, and reference position devices A 109a and B 109b. The generation transmission device 108 of the present embodiment includes first generation transmission devices A 108a and B 108b, a second generation transmission device 108c, a third generation transmission device 108d, and a fourth generation transmission device 108e.

  A power transmission line 103 that sends power supplied from the commercial power supply 102 is connected to the power management device 107. In addition, electrical devices A110a and B110b are connected to the energization management device 107 via wirings 106a and 106b in the house.

  The first generation transmission devices A 108a and B 108b are respectively built in or attached to the outside of the electric devices A 110a and B 110b. The electric devices A110a and B110b are, for example, an electric lamp, a refrigerator, a washing machine, an air conditioner, a television, and the like.

  The second generation transmission device 108 c is provided in the fixture 111. The fixture 111 is, for example, a desk, a dresser, a shelf, or the like. The third generation transmission device 108 d is carried by the resident 105 of the house 104. The fourth generation transmitting device 108e and the reference position devices A 109a and B 109b are fixed to the house 104. “Fixed” refers to being attached to the house 104 in a manner that does not cause displacement. For example, it includes being screwed to the floor or wall using metal fittings, or being adhered or adhered to the floor via an adhesive sheet or the like.

  The energization management device 107 is a device that manages energization of the power supplied from the commercial power supply 102 to the house 104 based on the state information. As shown in FIG. 2, the energization management device 107 includes a breaker unit (energization switching unit) 112 disposed between the power transmission line 103 and the wirings 106 a and 106 b.

  The breaker unit 112 is in an energized state in which the power supplied from the commercial power supply 102 via the power transmission line 103 is energized in any of the wirings 106a and 106b, and in an interrupted state in which the power is not energized in any of the wirings 106a and 106b. Can be switched. The electric devices A110a and B110b are connected to the wirings 106a and 106b through an outlet (not shown) as appropriate. In the present embodiment, the wirings 106a and 106b connected to the breaker unit 112 may be an arbitrary number.

  The energization management device 107 further includes a normal state storage unit 113 and a state storage unit 114. The storage units 113 and 114 are, for example, a flash memory, an HDD (Hard Disc Drive), or the like that is built in the energization management device 107 or attached to the outside of the energization management device 107.

  The normal state storage unit 113 stores information (normal state information) 113a indicating the normal state of the house 104. The normal normal state information 113a may be set periodically (for example, 10 minutes, 30 minutes, etc.) when the resident 105 intends, for example, when the energization management device 107 is started for the first time. That is, the normal state is, for example, a state when the energization management device 107 is activated for the first time, a state intended by the resident 105, or a state before a disaster occurs.

  FIG. 3A shows normal state information 113a according to the present embodiment. The normal state information 113a shown in the figure includes the normal state information 115a related to the position, the normal state information 116a related to the inclination, and the normal state information 117a related to the ground fault / disconnection, for the first generation transmission device A 108a provided in the electric device A 110a. 118a.

  The normal state information 115 a regarding the position of the first generation transmission device A 108 a is information indicating the normal position of the first generation transmission device A 108 a in the house 104. RA1 illustrated in FIG. 3A represents a normal distance from the reference position device A 109a to the first generation transmission device A 108a. RA2 represents a normal distance from the reference position device B 109b to the first generation transmission device A 108a. ± 10 cm is an allowable change amount related to the position of the first generation transmitter A108a, and may be determined in consideration of a measurement error, an amount of movement of the electric device A110a due to a relatively slight fluctuation, and the like.

  The normal state information 116a regarding the inclination of the first generation transmission device A 108a is information indicating the normal inclination of the first generation transmission device A 108a, for example, as an angle with respect to the horizontal plane. As shown in FIG. 3A, the normal state information 116a regarding the inclination indicates ± 5 degrees centering on 0 degrees. ± 5 degrees is an allowable change amount related to the inclination of the first generation transmitter A108a, and may be determined in the same manner as the allowable change amount related to the position. The normal state information 117a and 118a regarding the ground fault / disconnection is information indicating the presence / absence of a ground fault or disconnection in the wiring 106a to which the electric device A 110a is connected.

  The normal state information 113a includes the normal state information 115b related to the position, the normal state information 116b related to the inclination, and the normal state information 117b and 118b related to the ground fault / disconnection for the first generation transmission device B 108b provided in the electric device B 110b. . Each of the normal state information 115b related to the position, the normal state information 116b related to the inclination, and the normal state information 117b and 118b related to the ground fault / disconnection is the same as each of the normal state information 115a to 118a related to the first generation transmitter A108a. Shows the state.

  The normal state information 113a includes the normal state information 115c regarding the position and the normal state information 116c regarding the inclination with respect to the second generation transmission device 108c provided in the fixture 111. The normal state information 115c related to the position and the normal state information 116c related to the inclination are the same as the normal state information 115a and 116a for the first generation transmission device A 108a described above.

  The normal state information 113a includes the normal state information 115d regarding the position of the third generation transmission device 108d carried by the resident 105. The normal state information 115d regarding the position is information indicating a range in which the resident 105 at home is normally located. Each of 0-RD1 and 0-RD2 shown in FIG. 3A represents a distance from the reference position devices A 109a and B 109b. Each of RD1 and RD2 is, for example, a distance from the reference position devices A 109a and B 109b measured when the resident 105 moves to every corner of the house 104, and +5 cm is an allowable change amount considering a measurement error or the like.

  The normal state information 113a includes the normal state information 119 regarding the earthquake, the normal state information 120 regarding the fire, the normal state information 121 regarding the water leak, and the normal state regarding the gas leak, with respect to the fourth generation transmission device 108e installed in the house 104. Information 122. The normal state information 119 relating to an earthquake is information indicating a criterion for determining whether or not the shaking at the time of an earthquake is large enough to cut off the energization. The normal state information 120 regarding the fire is information indicating the smoke density that serves as a reference for determining whether or not a fire has occurred. Each of the normal state information 121 and 122 regarding water leakage and gas leakage is information indicating that there is no water leakage and gas leakage at the normal time in the house 104.

  Returning to FIG. 2, the state storage unit 114 is a storage unit that stores state information 114a. The state information 114a is the latest state information received by the energization management device 107 from the generation transmission device 108, and indicates the state of the house 104 when the generation transmission device 108 generates the state information.

  In the present embodiment, the state information 114a according to the present embodiment is state information generated by each of the generating and transmitting apparatuses 108 at the time of power recovery, in order to describe an example of generating state information at the time of power recovery. The power recovery means that the power supply from the commercial power source 102 is restored after a power failure occurs due to a disaster or the like.

  As shown in FIG. 3B, the state information 114a includes state information indicating the same type of state as the normal state information 113a. That is, the status information 114a includes the status information 123a (123b) related to the position, the status information 124a (124b) related to the inclination, and the status information related to the ground fault / disconnection for the first generation transmission device A 108a (first generation transmission device B 108b). 125a, 126a (125b, 126b). The status information 114a includes status information 123c related to the position and status information 124d related to the tilt for the second generation transmission device 108c. Furthermore, the status information 114a includes status information 123d regarding the position of the third generation transmission device 108d. Furthermore, the status information 114a includes status information 127 to 130 regarding each of the earthquake, fire, water leak, and gas leak for the third generation transmission device 108e.

  Returning to FIG. 2, the energization management device 107 further includes a power switch 132 that switches whether or not to operate the control unit 131, a control unit 131 that controls switching between the energized state and the cut-off state of the breaker unit 112, and a control A power switching unit 133 that switches a power source for operating the unit 131.

  The power switch 132 is a switch that switches between operation (ON) and stop (OFF) of the control unit 131. The power switch 132 includes a button operated by the resident 105, a switching lever, and the like.

  The control unit 131 receives the state information from the generation transmission device 108 at the time of power recovery, and controls the breaker unit 112 based on the received state information.

  The control unit 131 includes a power monitoring unit 134, a request transmission unit 135, a state reception unit 136, a normal state acquisition unit 137, a state acquisition unit 138, a state determination unit 139, an energization control unit 140, and a notification unit. 141.

  The power monitoring unit 134 monitors whether power is supplied from the commercial power source 102. As shown in FIG. 2, the power monitoring unit 134 includes a power supply sensor 142, a power failure determination unit 143, and a power recovery determination unit 144.

  The power supply sensor 142 is a sensor that detects the supply state of power from the commercial power supply 102.

  The power failure determination unit 143 determines that a power failure has occurred when a power supply stop (power failure) is detected by the power supply sensor 142. The power failure determination unit 143 that has determined that a power failure has occurred generates and holds information (power failure information) indicating the occurrence of the power failure.

  When it is determined that a power failure has occurred by the power failure determination unit 143 (for example, when power failure information is retained), the power recovery determination unit 144 detects when the power supply sensor 142 resumes power supply. Judge that power has been restored. The power recovery determination unit 144 that has determined that power has been recovered causes the power failure information of the power failure determination unit 143 to be deleted.

  The request transmission unit 135 transmits the request information to each generation transmission device 108. The request information is information including a request for generating and transmitting state information to be generated. The request transmission unit 135 transmits request information for updating the state information 114a when the power recovery determination unit 144 determines that power has been recovered. The request transmission unit 135 transmits request information for updating the normal state information 113a at a predetermined time.

  In the energization management device 107, the generation transmission device 108 may detect a change in the state of the house 104 and accept a notification indicating the change. Then, the request transmission unit 135 may transmit the request information to each of the generation transmission devices 108 when receiving this notification.

  The state reception unit 136 receives state information from the generation transmission device 108 for a certain period of time. The state receiving unit 136 that has received the state information updates the state information in the state storage unit 114 or the normal state information 113a in the normal state storage unit 113 with the received state information. As shown in FIG. 2, the state receiving unit 136 includes a reception timing unit 145, a state information receiving unit 146, and a state information updating unit 147.

  The reception timing unit 145 measures an elapsed time after the request transmission unit 135 transmits the request information. The state information receiving unit 146 receives the state information from each of the generating and transmitting devices 108 until the elapsed time measured by the reception timing unit 145 reaches a predetermined time.

  When the state information according to the request information for updating the state information 114a is received, the state information update unit 147 updates the state information 114a stored in the state storage unit 114 with the received state information. To do. In addition, when the state information according to the request information for updating the normal state information 113a is received, the state information update unit 147 stores the normal state stored in the normal state storage unit 113 according to the received state information. Information 113a is updated.

  The normal state acquisition unit 137 acquires the normal state information 113a from the normal state storage unit 113. The state acquisition unit 138 acquires the state information 114a from the state storage unit 114.

  The state determination unit 139 determines whether the house 104 is in a normal state based on the normal state information 113a acquired by the normal state acquisition unit 137 and the state information 114a received by the state acquisition unit 138. To do. For example, when even one state indicated by the state information 114a is not the state indicated by the normal state information 113a, the state determination unit 139 determines that the house 104 is not in a normal state, that is, an abnormal state. To do. In addition, when all of the states indicated by the state information 114a are the states indicated by the normal state information 113a, the state determination unit 139 determines that the house 104 is in a normal state.

  The state determination unit 139 is based on part of the state information 114a received by the state information reception unit 146, for example, state information transmitted by the first, second, and fourth generation transmission devices 108a to 108c, e. The state of the house 104 may be determined.

  Note that the normal state information 113a may indicate a normal state with respect to the state indicated by the state information 114a related to a predetermined plurality of combinations. For example, a combination of the state information 114a indicating the state relating to the position of the first generation transmitting apparatus A 108a and the state information 114a indicating the state relating to the earthquake can be cited as an example. In this case, the normal state information 113a indicates, for example, that the seismic intensity is less than 5 and the position of the first generation transmission device A 108a is (RA1 ± 10 cm, RA2 ± 10 cm). The state determination unit 139 indicates that the state information 114a received by the state information reception unit 146 does not indicate a seismic intensity of less than 5 or is within the range of (RA1 ± 10 cm, RA2 ± 10 cm) for the position of the first generation transmitter A108a. If not, it may be determined that the house 104 is in an abnormal state. In addition, the state determination unit 139 indicates that the state information 114a received by the state information reception unit 146 indicates a seismic intensity of less than 5, and indicates the position of the first generation transmission device A 108a (RA1 ± 10 cm, RA2 ± 10 cm), In addition, when the normal state information 113a indicates the other state, it may be determined that the house 104 is in a normal state. In addition, the state information 114a related to a plurality of predetermined combinations may be, for example, a combination of state information 114a indicating a state related to the position and inclination of the first generation transmission device A 108a.

  The energization control unit 140 controls the breaker unit 112 based on the determination result by the state determination unit 139. When the state determination unit 139 determines that the house 104 is in an abnormal state, the energization control unit 140 puts the breaker unit 112 in a disconnected state. When the state determination unit 139 determines that the house 104 is in a normal state, the energization control unit 140 places the breaker unit 112 in an energized state. In addition, the energization control unit 140 may temporarily turn off the breaker unit 112 immediately when a disaster such as an earthquake is detected.

  When the state determination unit 139 determines that the house 104 is in an abnormal state, the notification unit 141 notifies the inhabitant 105 of the abnormal state or the contents thereof using characters, images, light, sound, or the like. The notification unit 141 is, for example, a liquid crystal monitor, a lamp, a speaker, or the like. Thereby, when the house 104 is in an abnormal state, it becomes possible to quickly notify the resident 105 of the abnormality of the house 104.

  When the power switch 132 is “ON”, the power supply switching unit 133 switches the power supply for operating the control unit 131 between the commercial power supply 102 and the standby power supply 148. The standby power source 148 is a power source for operating the control unit 131 when the commercial power source 102 cannot be used as a power source, and is a battery or the like.

  For example, the power supply switching unit 133 detects whether or not a power failure has occurred. The power source switching unit 133 switches to use the commercial power source 102 when power is supplied from the commercial power source 102 and to use the standby power source 148 when a power failure occurs. It should be noted that when the energization management device 107 obtains power from the subsequent stage (for example, the wiring 106a) from the breaker unit 112, it is included when the commercial power source 102 cannot be used as a power source even when the breaker unit 112 is in a cut-off state. It is. By providing the standby power supply 148, the control unit 131, that is, the energization management device 107 can be operated regardless of whether the commercial power supply 102 can be used as a power supply.

  When the power switch 132 is “OFF”, the power supply switching unit 133 cuts off the power supply from the commercial power supply 102 and the standby power supply 148 to the control unit 131, thereby stopping the control unit 131. When the control part 131 stops, the resident 105 etc. can operate the breaker part 112 manually. As a result, when power supply is unnecessary due to a long absence or the like, the breaker unit 112 can be kept in a cut-off state, and safety can be improved.

  Note that the specific mode in which the power switch 132 included in the energization management device 107 switches between operation and stop of the control unit 131 is not limited to that of the present embodiment. For example, the power switch 132 may be a switch that executes a software program executed by the control unit 131 to stop the control unit 131. Further, the energization management device 107 may be provided so as not to completely stop the control unit 131 even when the power switch 132 is OFF. For example, for example, the power monitoring unit 134 may be always operated regardless of whether the power switch 132 is ON or OFF, and the control unit 131 may be always operated when power is restored.

  The control unit 131 and the power supply switching unit 133 described so far are configured by one or a plurality of processors. Further, the functions provided in the control unit 131 and the power supply switching unit 133 may be realized as functions provided in a processor or the like constituting the control unit 131 and the power supply switching unit 133. These functions may be realized as functions provided by a processor or the like executing a software program (hereinafter referred to as a program) stored in a storage unit (not shown). Further, these functions may be realized by a combination of a function such as a processor and a function included in a processor that executes a program.

  The generation transmission device 108 is a device that generates and transmits status information when request information is received from the power management device 107 by wireless communication. The generation / transmission device 108 uses, for example, a battery as a power source, and thus the generation / transmission device 108 can be provided without being restricted by the power supply line.

  Note that the generation / transmission apparatus 108 may switch to using the commercial power source 102 when the commercial power source 102 cannot be used as a power source, and using the battery as a standby power source when the commercial power source 102 can be used as a power source. . In this case, battery consumption can be suppressed, and the frequency of communication with the energization management device 107 and the reference position devices A 109a and B 109b can be increased.

  As illustrated in FIG. 4, the first generation transmission device A 108a includes a request reception unit 149, a first state generation unit A150, and a first state transmission unit A151. The request reception unit 149 receives the request information transmitted by the request transmission unit 135. The request information may be received via the wiring 106a.

  1st state production | generation part A150 produces | generates the status information regarding the position of the electric equipment A110a, a disconnection, a ground fault, and an inclination. As illustrated in FIG. 4, the first state generation unit A150 includes a first position generation unit 152, a disconnection generation unit 153, a ground fault generation unit 154, and a first inclination generation unit 155.

  The first position generation unit 152 generates state information regarding the position of the first generation transmission device A 108a. The first position generation unit 152 measures the distance between each of the reference position devices A 109a and B 109b and the first generation transmission device A 108a by exchanging signals with each of the reference position devices A 109a and B 109b. And the 1st position production | generation part 152 produces | generates the status information which shows the position of 1st production | generation transmission apparatus A108a based on the measured distance. A detailed configuration of the first position generation unit 152 will be described later.

  The disconnection generation unit 153 generates state information regarding the disconnection of the wiring 106a. The disconnection generation unit 153 includes a transistor provided so that a current flows when the disconnection occurs in the wiring 106a, for example, and detects the disconnection by monitoring the current flowing through the transistor. The disconnection generation unit 153 generates state information indicating the presence or absence of disconnection in the wiring 106a based on whether or not the disconnection of the wiring 106a is detected.

  The ground fault generation unit 154 generates state information related to the ground fault of the wiring 106a. The ground fault generation unit 154 detects the ground fault of the wiring 106a based on the resistance value of the wiring 106a, for example. The ground fault generation unit 154 generates state information indicating the presence or absence of a ground fault in the wiring 106a based on whether or not a ground fault has been detected in the wiring 106a.

  The 1st inclination production | generation part 155 produces | generates the status information regarding the inclination of 1st production | generation transmission apparatus A108a. The first inclination generation unit 155 includes, for example, an acceleration sensor. The first inclination generation unit 155 measures in advance the direction and magnitude of gravitational acceleration at the position where the first generation transmission device A 108a is installed using an acceleration sensor, and stores information indicating each. The first inclination generation unit 155 compares the direction and magnitude of the gravitational acceleration obtained from the acceleration sensor as needed with the direction and magnitude of the gravitational acceleration indicated by the stored information, thereby generating the first generation transmitting device A 108a. The state information indicating the tilt angle with respect to the horizontal direction is generated.

  The first state transmitting unit A151 associates the position information generated by the first state generating unit A150 with the state information related to the position, disconnection, ground fault, and inclination and the information that can identify the first generation transmitting device A 108a, and manages the energization. Transmit to device 107.

  Since the first generation transmission device B 108b has the same configuration as the first generation transmission device A described above, a detailed description thereof will be omitted.

  As illustrated in FIG. 5, the second generation transmission device 108 c includes a request reception unit 149, a second state generation unit 156, and a second state transmission unit 157. The description of the request receiving unit 149 is omitted here because it has been described above.

  The second state generation unit 156 generates state information regarding the position and inclination of the second generation transmission device 108c. The second state generation unit 156 includes a second position generation unit 158 and a second inclination generation unit 159. The second position generation unit 158 has a configuration similar to that of the first position generation unit 152, and measures the distance between each of the reference position devices A 109a and B 109b and the second generation transmission device 108c. Status information indicating the position of the generation transmitting device 108c is generated. The second inclination generation unit 159 has the same configuration as the first inclination generation unit 155, and generates state information indicating the inclination angle of the second generation transmission device 108c with respect to the horizontal direction.

  The second state transmission unit 157 transmits the state information relating to the position and inclination generated by the second state generation unit 156 to the energization management device 107 in association with the information that can specify the second generation transmission device 108c.

  As illustrated in FIG. 6, the third generation transmission device 108d includes a request reception unit 149, a third state generation unit 160, and a third state transmission unit 161. The description of the request receiving unit 149 is omitted here because it has been described above.

  The third state generation unit 160 generates state information regarding the position of the resident 105. The third state generation unit 160 includes a third position generation unit 162. The third position generation unit 162 has the same configuration as the first position generation unit 152, measures the distance between each of the reference position devices A 109a and B 109b and the resident 105, thereby indicating the position of the resident 105. Generate state information.

  The third state transmission unit 161 transmits the state information related to the position generated by the third state generation unit 160 to the energization management device 107 in association with the information that can specify the third generation transmission device 108d.

  As illustrated in FIG. 7, the fourth generation transmission device 108 e includes a request reception unit 149, a fourth state generation unit 163, and a fourth state transmission unit 164. The description of the request receiving unit 149 is omitted here because it has been described above.

  The fourth state generation unit 163 generates state information regarding earthquakes, fires, water leaks, and gas leaks. The fourth state generation unit 163 includes a seismic intensity generation unit 165, a fire detection unit 166, a water leak detection unit 167, and a gas leak detection unit 168.

  The seismic intensity generation unit 165 generates state information related to the earthquake. The seismic intensity generation unit 165 includes an acceleration sensor, for example, and measures the seismic intensity by estimating the seismic intensity from the acceleration of the earthquake shake measured by the acceleration sensor. Then, the seismic intensity generation unit 165 generates state information indicating the measured seismic intensity.

  The fire detection unit 166 generates state information related to a fire in the house 104. The fire detection unit 166 includes, for example, a light emitting element and a light receiving element that receives light emitted from the light emitting element, and measures the smoke density based on the amount of light received by the light receiving element. And the fire detection part 166 produces | generates the status information which shows the measured smoke density | concentration.

  The water leak detection unit 167 generates state information regarding water leaks in the house 104. The water leak detection unit 167 includes, for example, a pair of electrodes, and detects water leaks depending on whether or not the electrodes are short-circuited. The water leak detection unit 167 generates state information indicating the presence or absence of water leak based on whether or not water leak is detected.

  The gas leak detection unit 168 generates state information regarding the gas leak in the house 104. The gas leak detection unit 168 includes, for example, a gas sensor whose resistance value changes when gas is adsorbed on the surface. The gas leak detection unit 168 generates state information indicating the presence or absence of gas leak based on whether or not the gas concentration estimated based on the resistance value of the gas sensor is equal to or higher than a certain level.

  The fourth state transmission unit 164 is energized in association with the state information generated by the fourth state generation unit 163 relating to the earthquake, fire, water leakage, and gas leakage and information that can identify the fourth generation transmission device 108e. Transmit to the management device 107.

  Here, with reference to FIG. 8, the detailed structure of the 1st position production | generation part 152 with which 1st production | generation transmission apparatus A108a is provided is demonstrated.

  As shown in FIG. 8, the first position generation unit 152 includes a distance measurement signal transmission unit 169, a distance measurement response reception unit 170, a response time measurement unit 171, a response time storage unit 172, and a specific availability determination unit 173. And a position specifying unit 174 and a position information generating unit 175.

  The ranging signal transmission unit 169 transmits a signal (ranging signal) for measuring the distance between each of the reference position devices A 109a and B 109b to each of the reference position devices A 109a and B 109b.

  The ranging response receiving unit 170 receives a ranging response signal that is a response to the ranging signal from each of the reference position devices A 109a and B 109b.

  The response time measuring unit 171 measures the response times TA and TB from when the ranging signal is transmitted to when the ranging response signals of the reference position devices A 109a and B 109b are received, and the response times TA and TB are measured. The response time information shown is generated. In the response time storage unit 172, response time information indicating the response times TA and TB measured by the response time measurement unit 171 is stored by the response time measurement unit 171. The response times TA and TB may be times obtained by subtracting the processing time in the reference position devices A 109 a and B 109 b from the time measured by the response time measuring unit 171.

  Based on whether or not the ranging response receiving unit 170 has received the ranging response signal from the reference position devices A 109a and B 109b, the identification availability determining unit 173 determines whether or not the position of the electrical device A 110a can be identified. to decide. Specifically, for example, when the distance measurement response reception unit 170 receives distance measurement response signals from all of the reference position devices A 109a and B 109b within a predetermined time, the identification availability determination unit 173 identifies the position of the electric device A 110a. Judge that you can. Further, when the ranging response receiving unit 170 has not received the ranging response signal from any of the reference position devices A 109a and B 109b within a predetermined time, the identification determination unit 173 determines whether the first generation transmitting device A 108a It is determined that the position cannot be specified.

  When the position determination unit 174 determines that the position of the first generation transmission device A 108a can be specified by the determination unit 173, the distance (RAx) from each of the reference position devices A 109a and B 109b to the electrical device A 110a. , RAy). And the position specific | specification part 174 specifies the position of 1st production | generation transmission apparatus A108a in the house 104 based on the calculation result. In the present embodiment, the position of the first generation transmission device A 108a is specified by (RAx, RAy).

  Here, RAx represents the distance from the reference position device A 109a to the first generation transmission device A 108a. RAx is calculated by (response time T) × (speed of light) / 2. The distance RAy from the reference position device B to the first generation transmission device A 108a is calculated in the same manner.

  The position information generation unit 175 generates state information indicating the position specified by the position specifying unit 174.

  The first position generation unit 152 may specify the position of the first generation transmission device A 108a based on the image data. For example, the first position generation unit 152 acquires image data obtained by photographing the electric device A 110a provided with the first generation transmission device A 108a with a camera installed at a fixed position. The position of the first generation transmission device A 108a can be specified by pattern matching the image data. This makes it possible to specify the position of the first generation transmission device A 108a with a small number of reference position devices with high accuracy.

  The first generation transmission device B 108b also includes the same first position generation unit 152. The second and third position generation units 158 and 162 included in the second and third generation transmission devices 108c and d are both the same as the first position generation unit 152 included in the first generation transmission device A 108a described so far. Therefore, the detailed description of the configuration is omitted.

  The reference position devices A109a and B109b are devices that serve as a reference for the position indicated by the state information regarding the position. The reference position device A 109a includes a ranging signal receiving unit 176 and a ranging response transmitting unit 177. The ranging signal receiving unit 176 receives the ranging signal transmitted by the ranging signal transmitting unit 169. The ranging response transmission unit 177 transmits the ranging response signal to the generation transmission device 108 that has transmitted the ranging signal.

  Since the reference position device B 109b has the same configuration as the reference position device A 109a, detailed description thereof is omitted here.

  Three or more reference position devices A 109a and B 109b may be provided. Accordingly, the first position generation unit 152 can specify the position with high accuracy or a high-dimensional position. Further, the first position generation unit 152 may adopt an evaluation function such as the following expression and specify the position by calculating Pt by the least square method or the like.

ここで、基準位置装置は、ｋ個とする。Ｐｔは、ｋ個の成分を含むベクトルであり、第１生成送信装置Ａ１０８ａの位置を表す。Ｐｉ（ｉ＝１・・・ｋ）は、ｋ個の成分を含むベクトルであり、第ｉ基準位置装置の位置を表す。ｄｉ（ｉ＝１・・・ｋ）は、第１生成送信装置Ａ１０８ａと第ｉ基準位置装置との間の距離を表す。

Here, there are k reference position devices. Pt is a vector including k components and represents the position of the first generation transmitter A108a. Pi (i = 1... K) is a vector including k components and represents the position of the i-th reference position device. di (i = 1... k) represents a distance between the first generation transmission device A 108a and the i-th reference position device.

  In addition, each of the method of producing | generating the status information regarding the position, disconnection, ground fault, inclination, earthquake, fire (smoke), water leak, and gas leak described in the present embodiment is merely an example, and other methods are appropriately used. It may be adopted.

  From here, the process which the electricity supply management system 101 which concerns on Embodiment 1 of this invention performs is demonstrated.

  FIG. 10 is a flowchart of processing executed by the energization management device 107 according to the first embodiment of the present invention.

  When a power failure is not detected by the power supply sensor 142, the power failure determination unit 143 determines that a power failure has not occurred (step S101: No), and continues the power failure determination process (step S101).

  When a power failure is detected by the power supply sensor 142, the power failure determination unit 143 determines that a power failure has occurred (step S101: Yes), and generates and holds the power failure information. When a power failure occurs, the power source switching unit 133 switches the power source for operating the control unit 131 from the commercial power source 102 to the standby power source 148.

  When power supply is not detected by the power supply sensor 142, the power recovery determination unit 144 determines that power has not been recovered (step S102; No), and continues the power recovery determination process (step S102).

  When the power failure determination unit 143 holds the power failure information and the power supply sensor 142 detects power supply, the power recovery determination unit 144 determines that the power has been restored (step S102; Yes).

  If it is determined that power has been restored (step S102; Yes), the request transmission unit 135 transmits request information for updating the state information 114a to the generation transmission device 108 (step S103).

  When the request information is transmitted by the request transmission unit 135 (step S103), the reception timing unit 145 starts measuring the elapsed time. When the elapsed time measured by the reception timing unit 145 does not reach a predetermined time (for example, 10 seconds) (step S104; No), the state information reception unit 146 transmits the state information transmitted from the generation transmission device 108. Continue receiving.

  During this time, each of the generation / transmission apparatuses 108 receives the request information, and generates and transmits status information. The processing executed by each of the generation / transmission apparatuses 108 will be described later.

  When the elapsed time measured by the reception timing unit 145 reaches a predetermined time (step S104; Yes), the state information receiving unit 146 determines whether the state information has been received (step S105).

  When it is determined that the state information has been received (step S105; Yes), the state information update unit 147 updates the state information 114a stored in the state storage unit 114 with the received state information (step S106). .

  The normal state acquisition unit 137 acquires the normal state information 113a from the normal state storage unit 113 (step S107). The state acquisition unit 138 acquires the state information 114a from the state storage unit 114, that is, the state information received by the state information reception unit 146 (step S108).

  The state determination unit 139 determines that the house 104 is in an abnormal state when at least one of the states indicated by the state information 114a is not the state indicated by the corresponding normal state information 113a (step S109; abnormal). State).

  A case where the state determination process (step S109) determines “abnormal state” will be described based on the specific example of the normal state information 113a illustrated in FIG.

  For example, when (RAx, RAy) indicated by the status information 114a related to the position transmitted from the first generation transmission device A 108a is RAx <RA1-10 cm, RAx> RA1 + 10 cm, RAy <RA2-10 cm, or RAy> RA2 + 10 cm. The state determination unit 139 determines that the house 104 is in an abnormal state. Similarly, when the state information 114a related to the tilt transmitted from the first generation transmission device A 108a indicates outside the range indicated by the corresponding normal state information 113a, the state determination unit 139 determines that the house 104 is in an abnormal state. to decide.

  In addition, for example, when the state information 114a related to the ground fault or disconnection transmitted from the first generation transmission device A 108a is not the state indicated by the corresponding normal state information 113a (“none”), the state determination unit 139 indicates that the house 104 is Judged to be in an abnormal state.

  Further, for example, when the seismic intensity indicated by the state information 114a related to the earthquake transmitted from the fourth generation transmission device 108e is 5 or more, the state determination unit 139 determines that the house 104 is in an abnormal state. When the smoke density indicated by the state information 114a related to the fire transmitted from the fourth generation transmission device 108e is 10% / m or more, the state determination unit 139 determines that the house 104 is in an abnormal state.

  Further, for example, when the state information 114a related to water leakage or gas leakage transmitted from the fourth generation transmission device 108e is not the state (“None”) indicated by the corresponding normal state information 113a, the state determination unit 139 sets the house 104 Is in an abnormal state.

  On the other hand, the state determination unit 139 determines that the house 104 is in a normal state when all of the states indicated by the state information 114a are the states indicated by the corresponding normal state information 113a. (Step S109: normal state).

  When the state determination unit 139 determines that the house 104 is in a normal state (step S109; normal state), the energization control unit 140 places the breaker unit 112 in an energized state (step S110). When the state determination unit 139 determines that the house 104 is in an abnormal state (step S109; abnormal state), the energization control unit 140 places the breaker unit 112 in a shut-off state (step S111).

  When it is determined that the state information is not received (step S105; No), or after the breaker control process (step S110 or S111), the power switch 132 is “ON” (step S112; “ON”). The control unit 131 returns to the power failure determination process (step S101). When the power switch 132 is “OFF” (step S112; “OFF”), the control unit 131 ends the process.

  From here, the process which each of the production | generation transmission apparatuses 108 performs is demonstrated.

  FIG. 11 is a flowchart illustrating processing executed by the first generation transmission device A 108a according to the first embodiment to generate and transmit state information.

  The request reception unit 149 of the first generation transmission device A 108a receives the request information transmitted by the energization management device 107 (step S201). When the request information is received, the first position generation unit 152 generates state information 123a related to the position by communicating with the reference position devices A 109a and B 109b (step S202).

  Here, FIG. 12 shows details of processing executed in the normal state information generation processing (step S202) regarding the position.

  The ranging signal transmission unit 169 of the first generation transmission device A 108a transmits a ranging signal to each of the reference position devices A 109a and B 109b (step S301). At this time, the response time measuring unit 171 starts measuring time.

  The ranging signal receivers 176 of the reference position devices A 109a and B 109b each receive the ranging signal transmitted by the ranging signal transmitter 169 (step S302). The distance measurement response transmitters 177 of the reference position devices A 109a and B 109b transmit distance measurement response signals (step S303).

  The ranging response receiving unit 170 receives the ranging response signals transmitted from the ranging response transmitting units 177 of the reference position devices A 109a and B 109b until a predetermined time elapses. Then, the ranging response receiving unit 170 notifies the response time measuring unit 171 of which of the reference position devices A 109a and B 109b has received the ranging response signal (step S304).

  The response time measurement unit 171 that has received the notification from the distance measurement response reception unit 170 stores response time information indicating the response time from the start of measurement until reception of the distance measurement response signal in the response time storage unit 172 ( Step S305). The response time information stored at this time is associated with information that can specify which of the reference position devices A 109a and B 109b the response time relates to.

  The identification determination unit 173 determines that the position cannot be specified when the ranging response receiving unit 170 has not received the ranging response signal within a predetermined time from either or one of the reference position devices A 109a and B 109b. (Step S306; No). When it is determined that the position cannot be specified (step S306; No), the distance measurement signal transmission unit 169 executes the distance measurement signal transmission process (step S301) again. When the determination that the position cannot be specified is repeated a predetermined number of times, the specification availability determination unit 173 may end the normal state information generation process (step S202) regarding the position.

  The specifiability determining unit 173 determines that the position can be specified when the ranging response receiving unit 170 receives the ranging response signal from both the reference position devices A 109a and B 109b within a predetermined time (step S306). ; Yes).

  When it is determined that the position can be specified (step S306; Yes), the position specifying unit 174 acquires the response time information from the response time storage unit 172, and calculates the distances RAx and RAy from each of the reference position devices A 109a and B 109b. calculate. Thereby, the position specifying unit 174 specifies the position (RAx, RAy) of the first generation transmission device A 108a (step S307).

  Each of the distances RAx and RAy may be calculated based on the average of response times TA and TB measured a predetermined number of times. Thereby, the error can be reduced and the distances RAx and RAy can be measured more accurately. In this case, if the ranging response receiving unit 170 has not received the predetermined number of ranging response signals, the identification determination unit 173 may determine that the position cannot be identified (step S306; No). ).

  In the present embodiment, the position of the first generation transmission device A 108a is represented by the distance from each of the reference position devices A 109a and B 109b (RAx, RAy), but is not limited thereto. The position of the first generation transmission device A 108a may be converted into a position or a range that can be identified from the distances RAx and RAy from each of the reference position devices A 109a and B 109b. The position or range here may be represented by a coordinate system on a plane when the house 104 is viewed from above, with a certain position in the house (for example, the position of the reference position device A 109a) as the origin.

  In addition, since the response time TA and TB can be accurately measured by using, for example, an ultra-wideband impulse radio signal that transmits an impulse signal as a distance measurement signal and a distance measurement response signal, a more accurate distance can be measured. can do.

  The position information generation unit 175 generates state information indicating the position (RAx, RAy) specified by the position specifying unit 174 (step S308). Thereby, the first position generation unit 152 ends the process.

From here, it returns to FIG.
When the disconnection generation unit 153 detects disconnection of the wiring 106a, the disconnection generation unit 153 generates state information indicating that the wiring 106a is disconnected (step S203). Further, the disconnection generation unit 153 generates state information indicating that there is no disconnection in the wiring 106a when the disconnection of the wiring 106a is not detected (step S203).

  When detecting a ground fault of the wiring 106a, the ground fault generation unit 154 generates state information indicating that there is a ground fault (step S204). The ground fault generation unit 154 generates state information indicating that there is no ground fault when the ground fault of the wiring 106a is not detected (step S204).

  The first inclination generation unit 155 generates state information indicating the inclination angle of the first generation transmission apparatus A 108a with respect to the horizontal direction (step S205).

  The first state transmission unit A151 associates the state information generated by the first state generation unit A150 in the above-described processing (steps S202 to S205) with the information that can identify the first state generation unit A150, and the energization management device 107. (Step S208). Thereby, the first generation transmission apparatus A 108a ends the generation / transmission process of the state information.

  Since the process executed by the first generation transmission apparatus B 108b is the same as the process executed by the first generation transmission apparatus A 108a, the description thereof is omitted.

  FIG. 13 is a flowchart illustrating processing executed by the second generation transmission device 108c according to the first embodiment to generate and transmit state information.

  The request reception unit 149 of the second generation transmission device 108c receives the request information transmitted by the energization management device 107 (step S401).

  When the request information is received, the second position generation unit 158 executes a process similar to the normal state information generation process (step S202) regarding the position (see FIG. 12), and thereby the second generation transmission apparatus 108c. Status information indicating the position is generated (step S402). The second inclination generation unit 159 generates state information indicating the inclination angle of the second generation transmission device 108c with respect to the horizontal direction (step S403).

  The second state transmission unit 157 associates the state information generated by the second state generation unit 156 in the above-described processing (steps S402 to S403) with the information that can specify the second generation transmission device 108c, and sends the information to the energization management device 107. Transmit (step S404). Thereby, the second generation transmission apparatus 108c ends the generation / transmission process of the state information.

  FIG. 14 is a flowchart illustrating processing executed by the third generation transmission device 108d according to the first embodiment to generate and transmit state information.

  The request reception unit 149 of the third generation transmission device 108d receives the request information transmitted by the energization management device 107 (step S501).

  When the request information is received, the third position generation unit 162 executes the same process as the normal state information generation process (step S202) related to the position (see FIG. 12), thereby the third generation transmission device 108d. Status information indicating the position is generated (step S502).

  The third state transmission unit 161 associates the state information related to the position generated by the third state generation unit 160 with the information that can identify the third generation transmission device 108d and transmits the information to the energization management device 107 (step S503). Thereby, the third generation transmission apparatus 108d ends the generation / transmission process of the state information.

  FIG. 15 is a flowchart illustrating processing executed by the fourth generation transmission device 108e according to the first embodiment to generate and transmit state information.

  The request reception unit 149 of the fourth generation transmission device 108e receives the request information transmitted by the energization management device 107 (step S601). When the request information is received, the seismic intensity generation unit 165 measures the seismic intensity and generates information indicating the measured seismic intensity (step S602). The fire detection unit 166 measures the smoke density and generates state information indicating the measured smoke density (step S603).

  The water leak detection part 167 produces | generates the status information which shows that there exists a water leak, when a water leak is detected (step S604). The water leak detection part 167 produces | generates the status information which shows that there is no water leak, when not detecting a water leak (step S604).

  The gas leak detection unit 168 generates state information indicating that there is a gas leak when it is estimated that the gas concentration is equal to or higher than a certain level (step S605). When it is estimated that the gas concentration is less than a certain level, the gas leak detection unit 168 generates state information indicating that there is no gas leak (step S605).

  The fourth state transmission unit 164 associates the state information generated in the above-described processing (steps S602 to S605) with the information that can identify the fourth generation transmission device 108e and transmits the information to the energization management device 107 ( Step S609). Thereby, the fourth generation transmission device 108e ends the generation / transmission processing of the state information.

  So far, Embodiment 1 of the present invention has been described.

  According to the present embodiment, the energization control unit 140 causes the breaker unit 112 to be in a cut-off state when it is determined that any one of the state information 114a received by the state information receiving unit 146 is not in a normal state. As a result, it is possible to prevent energized fire and to ensure safety.

  Further, whether or not the state of the house 104 is a normal state, that is, whether it is a safe state even when energized is determined based on the state information 114a generated by the plurality of generation transmission devices 108. The status information 114a employs information indicating a plurality of types of status. Therefore, it becomes possible to improve safety.

  For example, the 1st production | generation transmission apparatus 108a, b and the 2nd production | generation transmission apparatus 108c produce | generate the status information 123a-c and 124a-c regarding the position and inclination of electric equipment A110a, B110b and the fixture 111. When the state information 123a to c and 124a to c is not in the state indicated by the normal state information 115a to c and 116a to c, the energization control unit 140 puts the breaker unit 112 into a cut-off state. When the positions of the electric devices A110a, B110b and the fixture 111 are greatly shifted or tilted, there is a possibility that they may fall down, and there is a risk that an energizing fire will occur when energized. According to the present embodiment, it is possible to suppress the danger of such energized fire.

  Further, for example, the first position generation units 108a and 108b and the second generation transmission device 108c generate state information 125a to 125b and 126a to 126b related to the ground faults and disconnections of the wirings 106a and 106b. When it is determined that there is a ground fault or disconnection based on the state information 125a-b, 126a-b and the normal state information 117a-b, 118a-b, the energization control unit 140 causes the breaker unit 112 to Turn off. If there is a ground fault or disconnection in the wirings 106a and 106b, energizing the wirings 106a and 106b may cause an energizing fire. According to the present embodiment, it is possible to suppress the danger of such energized fire and improve safety.

  Further, for example, the third position generation unit 108d generates state information 123d regarding the position of the resident 105. Based on the state information 123 d and the normal state information 115 d, the energization control unit 140 sets the breaker unit 112 to an energized state when the resident 105 is in the house 104, and breaker unit 112 when the resident 105 is not in the house 104. Is turned off. If an energizing fire occurs, if there is a resident 105, it can be dealt with appropriately at an early stage, so that a large fire caused by energization can be prevented. Therefore, this makes it possible to increase safety. Moreover, since it is possible to determine whether or not the resident 105 is in the house 104 based on the status information relating to the position of the resident 105, it is possible to quickly confirm the safety of the resident 105 and take measures such as rescue if necessary. become.

  Further, for example, the fourth generation transmission device 108e generates state information 127 to 130 regarding an earthquake, a fire, a water leak, and a gas leak. On the basis of the state information 127 to 130 and the normal state information 119 to 122, the energization control unit 140 sets the breaker unit 112 in a shut-off state when any of an earthquake, a fire, a water leak, and a gas leak occurs. To do. After an earthquake, there is a risk that an energized fire may occur due to things scattered in the house 104, for example. There is a danger of enlarging the fire quickly, for example, if energized when a fire occurs. If power is supplied when there is a water leak, there is a risk of a fire due to a short circuit, for example. If power is supplied when there is a gas leak, for example, there is a risk that the leaked gas will explode, and further there is a risk of fire. According to the present embodiment, it is possible to suppress these dangers and improve safety.

  In addition, when it is determined that all of the state information 114a received by the state information receiving unit 146 is in the normal state, the energization control unit 140 places the breaker unit 112 in the energized state. As described above, the breaker unit 112 is not necessarily in the cut-off state. If the breaker unit 112 is in the energized state, the state is maintained. If the breaker unit 112 is in the cut-off state, the state is switched to the energized state. Therefore, it is possible to at least reduce the trouble of the user confirming safety and returning the breaker unit 112 from the shut-off state to the energized state, and the convenience for the user can be improved.

  Thus, according to the present embodiment, it is possible to improve convenience for the user while ensuring safety.

  In addition, since the energization management device 107 includes the standby power source 148 and the generation transmission device 108 includes the standby power source as appropriate, it can be operated regardless of whether the commercial power source 102 can be used as a power source. Therefore, the breaker unit 112 can be controlled based on the state information 114a immediately before controlling the breaker unit 112, such as when power is restored. Whether or not to energize can be determined based on the state immediately before energization, so that it is possible to improve safety during energization.

  In the present embodiment, the breaker unit 112 switches between energizing all the wirings 106a and 106b or not energizing, but the configuration of the breaker unit 112 is not limited to this. For example, the breaker unit 112 may include a first breaker unit and a second breaker unit that can be controlled by the energization control unit 140. The first breaker unit switches whether to energize the first part (range) that is a part of the house 104, for example, whether to energize the wiring 106a. The second breaker unit switches whether to energize the second part (range), which is another part of the house 104, for example, whether to energize the wiring 106b.

  When such first and second breaker parts are provided, the energization of the house 104 can be controlled for each part (range). For example, when the state information 114a indicates that the wiring 106a is disconnected and the others are normal states, the state determination unit 139 indicates that the first portion is in an abnormal state and the second portion is in a normal state. If it is, it judges for every part (range). As a result, the energization control unit 140 can place the first breaker unit in the cut-off state and put the second breaker unit in the energized state. That is, when energized, it is possible to energize a safe part (range) without energizing a dangerous part (range). Therefore, the breaker unit 112 includes a breaker unit that can switch energization for each of a plurality of parts (ranges) such as the first and second breaker units, thereby ensuring the safety and the convenience for the user. It becomes possible to improve.

  In particular, if the light goes off after a disaster, it may not be possible to evacuate safely. However, if the second breaker unit is connected to the electric light in the above example, the resident 105 can evacuate safely. become.

Embodiment 2. FIG.
The second embodiment of the present invention is a system for managing the safety of a house 104 and its inhabitants 105 within a certain wide management area. FIG. 16 shows a wide area management system 301 according to the second embodiment of the present invention.

  The wide area management system 301 manages the safety of the house 104 and its inhabitants 105 based on the energization management system 201 provided in each of the houses 104 in a certain management area and the status information acquired from the plurality of energization management systems 201. And a wide area management apparatus 302.

  The energization management system 201 according to the present embodiment includes an energization management device 207, and a generation transmission device 108 and reference position devices 109a and 109b similar to those in the first embodiment. As illustrated in FIG. 17, the control unit 231 of the energization management device 207 includes a wide area communication unit 278 in addition to the configuration included in the control unit 131 according to the first embodiment. The control unit 231 includes a notification unit 241 instead of the notification unit 141 of the control unit 131 according to the first embodiment.

  The wide area communication unit 278 is an interface that transmits and receives information to and from the wide area management apparatus 302. The wide area communication unit 278 includes a wide area transmission unit 279 and a wide area reception unit 280.

  The wide area transmission unit 279 transmits state information to the wide area management apparatus 302 at a preset time. For example, when the energization management device 207 receives the state information, the state determination unit 139 is in an abnormal state when the energization management device 207 receives the state information, and when the breaker unit 112 is switched between the energized state and the interrupted state. Or when the normal state is restored.

  When the normal state is restored, the state determination unit 139 determines that the state determination unit 139 determines that the state information is not the normal state, and then determines that the new state information is the normal state. is there. Whether or not the normal state has been restored is determined by, for example, storing state determination information indicating the determination result of the state determination unit 139 in the state determination storage unit, and using the state determination information and a new determination result by the state determination unit 139. The determination may be made by comparing the state determination information shown.

  The state information according to the present embodiment includes information indicating the state of the breaker unit 112 (state information regarding the breaker unit) in addition to the state information generated by the generation and transmission device 108 similar to that of the first embodiment. The state information regarding the breaker unit is acquired from the energization control unit 140, for example.

  The wide area receiving unit 280 receives information generated and transmitted by the wide area management apparatus 302.

  The notification unit 241 notifies the resident about the abnormality based on the determination of the state determination unit 139 as in the first embodiment. In addition to this, the notification unit 241 includes a presentation unit 281. The presentation unit 281 presents the contents of information (for example, evacuation route information described later) received by the wide area reception unit 280 from the wide area management device 302 to the resident 105.

  FIG. 18 shows a configuration of the wide area management apparatus 302 according to the second embodiment of the present invention. As shown in the figure, the wide area management apparatus 302 includes a residential state storage unit (area state storage unit) 303, a correspondence storage unit 304, and a map storage unit 305. Each of the storage units 303 to 305 is, for example, a flash memory, an HDD (Hard Disc Drive), or the like that is built in the wide area management apparatus 302 or attached to the outside of the wide area management apparatus 302.

  The house-specific state storage unit 303 stores house-specific state information (zone state information) 303a. The house state information 303a is information indicating a normal state for each house in the area managed by the wide area management device 302.

  As shown in FIG. 19, the house-specific state information 303a includes house ID information (Identification Data) 306, address information 307, contact information 308, and normal state information 213a. Each information 306-308,213a is linked | related for every house.

  The house ID information 306 is information for identifying each house 104. The house ID information 306 is information indicating a different number assigned to each house, for example, as shown in FIG.

  The address information 307 is information indicating the address of each house 104. The contact information 308 is information indicating the contact address of each house 104, for example, the mail address of the resident 105 of each house 104.

  The normal state information 213a is state information indicating a normal state in each house 104. As shown in FIG. 20, the normal state information 213a of each house includes the state information 309 related to the breaker unit as described above in addition to the normal state information 113a (see FIG. 3A) similar to that of the first embodiment. The state information 309 related to the breaker shown in FIG. 20 indicates that the state of the breaker unit 112 at the normal time is “energized state”. The specific contents set in the normal state information 213a of the wide area management device 302 may not be the same as the normal state information 113a of the energization management device 207. For example, an allowable change amount different from the normal state information 113a is set. May be included.

  The correspondence storage unit 304 stores correspondence information 304a indicating a correspondence method according to the type of the state that has been determined to be in an abnormal state when the house 104 is determined to be in an abnormal state. Yes. FIG. 21 shows correspondence information according to the present embodiment. As shown in the figure, the correspondence information 304a includes type information 310 indicating a group of state types, and correspondence method information 311 indicating a specific correspondence method. The type information 310 and the handling method information 311 are associated with each other.

  In the correspondence information 304a illustrated in FIG. 21, for example, the type information 310 includes “type 1” that is a group related to types of states of disconnection, ground fault, water leak, and gas leak. Corresponding method information 311 indicating “corresponding method 1 (notification to related parties)” is associated with the type information 310 indicating “type 1”.

  The map storage unit 305 includes information (map information) 305a indicating a map in the management area. As shown in FIG. 22, the map information includes houses, roads, evacuation places at the time of disasters, etc. in the management area.

  As shown in FIG. 18, the wide area management apparatus 302 further includes a state reception unit 310, a power demand prediction unit 311, a residential state acquisition unit (area state acquisition unit) 312, an abnormality determination unit 313, and a response unit 314. With.

  The state receiving unit 310 of the wide area management apparatus 302 receives the latest state information (state information) of each house 104.

  When the state reception unit 310 receives the state information, the power demand prediction unit 311 predicts the power demand based on the state information regarding the breaker unit 112 included in the state information. The power demand prediction unit 311 determines whether or not there is a resident 105 in the house 104 based on the state information regarding the position of the resident 105, and predicts the power demand based on the determination result and the state information regarding the breaker unit. Also good. By providing such a power demand prediction unit 311, it is possible to predict power demand based on state information, and it is possible to accurately predict power demand that is difficult to predict at the time of a disaster such as an earthquake.

  The house-specific state acquisition unit 312 acquires the house-specific state information 303 a of the house 104 whose state is indicated by the state information received by the state reception unit 310 from the house-specific state storage unit 303.

  The abnormality determination unit 313 compares the state information received by the state reception unit 310 with the house-specific state information 303a acquired by the house-specific state acquisition unit 312, and the house 104 whose state is indicated by the state information is abnormal. It is determined whether or not the current state is correct. The determination by the abnormality determination unit 313 may be performed in the same manner as the state determination unit 139.

  The abnormality determination unit 313 may communicate with the energization management device 207 to confirm the safety of the resident 105 based on whether or not the operation of the resident 105 can be confirmed. Then, the abnormality determination unit 313 may determine whether the dwelling 104 is in an abnormal state using the result of the safety confirmation as the state information.

  When the abnormality determination unit 313 determines that the house 104 is in an abnormal state, the response unit 314 executes a response corresponding to the state. As shown in FIG. 23, the response unit 314 includes a response method acquisition unit 315, a related party notification unit 316, a contact address acquisition unit 317, a neighborhood notification unit 318, and an evacuation route notification unit 319.

  When the abnormality determination unit 313 determines that the house 104 is in an abnormal state, the response method acquisition unit 315 acquires response method information 311 corresponding to the abnormal state from the correspondence storage unit 304. The response method information 311 acquired here is associated with the type information 310 including the type of the state that caused the determination that the house 104 is in an abnormal state.

  When the handling method information 311 indicating the handling method 1 is acquired, the related party notifying unit 316 notifies a preset related party. The related parties are, for example, an electric power company, a fire department, a gas company, and the like. For example, the contact information is stored in advance in the related person notification unit 316.

  When the response method information 311 indicating the response method 2 is acquired, the contact address acquisition unit 317 identifies the home 104 included in a certain range from the home 104 where the fire has occurred, based on the address information 307, for example. Then, the contact acquisition unit 317 acquires contact information 308 associated with the identified house 104.

  The proximity notification unit 318 notifies the contact indicated by the contact information 308 acquired by the contact acquisition unit 317 that a fire has occurred in the vicinity. Note that the notification destination here may be the energization management device 207 provided in the neighboring house 104.

  When the response method information 311 indicating the response method 3 is acquired, the evacuation route notification unit 319 notifies the energization management device 207 of the evacuation route information indicating the evacuation route from each house 104. As shown in FIG. 23, the evacuation route notification unit 319 includes a map acquisition unit 320, an evacuation route generation unit 321 and an evacuation route transmission unit 322.

  The map acquisition unit 320 acquires map information 305a. The evacuation route generation unit 321 generates evacuation route information indicating an evacuation route from each house 104 to the evacuation site. The evacuation route transmission unit 322 transmits evacuation route information to the energization management device 207 provided in each house 104. The notification destination here may be a contact address indicated by contact information 308 associated with each house 104.

  From here, the process which the wide area management apparatus 302 which concerns on Embodiment 2 of this invention performs is demonstrated.

  As shown in FIG. 24, when the state information is not received (step S701; No), the state receiving unit 310 waits until the state information is received. When the state receiving unit 310 receives the state information (step S701; Yes), the house state acquisition unit 312 acquires the house state information 303a of the house 104 whose state is indicated by the received state information (step S701). S702).

  The abnormality determination unit 313 determines whether the house 104 whose state is indicated by the received state information is in an abnormal state based on the received state information and the acquired house state information 303a ( Step S703). When the state indicated by the state information is the state indicated by the house-specific state information 303a, the abnormality determination unit 313 determines that the house 104 is not in an abnormal state, that is, a normal state (step S703). No), the process is terminated.

  When the state indicated by the state information is not the state indicated by the house-specific state information 303a, the abnormality determination unit 313 determines that the house 104 is in an abnormal state (step S703; Yes). When it is determined that the house 104 is in an abnormal state (step S703; Yes), the response unit 314 performs a response according to the type of the abnormal state of the house 104 (step S704).

  The abnormality determination unit 313 may compare the status information received this time with the status information received last time, and specify the type of status indicated by the status information different from the previous time. Then, the abnormality determination unit 313 determines that the house 104 whose state is indicated by the received state information is abnormal based on the state information received this time and the acquired state information 303a for each house for the specified type. It may be determined whether or not there is. In this case, the wide area management apparatus 302 may further include state information storage means for storing state information received last time.

  FIG. 25 is a flowchart showing details of the handling process (step S704).

  When the abnormality determination unit 313 determines that the house 104 is in an abnormal state, the response method acquisition unit 315 acquires response method information 311 corresponding to the abnormal state from the correspondence storage unit 304 (step S801). .

  When the response method information 311 indicating the response method 1 is acquired (step S802; Yes), the related party notification unit 316 notifies a predetermined related party (step S803) and ends the process.

  When the response method information 311 indicating the response method 2 is acquired (step S802; No, and step S804; Yes), the contact acquisition unit 317 refers to the address information 307, and starts from the house 104 where the fire has occurred. The house 104 included in a certain range is specified. Then, the contact acquisition unit 317 acquires contact information 308 associated with the identified house 104 (step S805).

  The proximity notification unit 318 notifies the contact indicated by the contact information 308 acquired by the contact acquisition unit 317 that a fire has occurred in the vicinity (step S806). Thereby, even if there is no fire in the house 104 provided with the energization management device 207 that has received the notification, the resident 105 can know the fire in the vicinity. As a result, the residents 105 in the management area can take appropriate measures such as evacuating for safety.

  When the response method information 311 indicating the response method 3 is acquired (step S804; No, and step S807; Yes), the evacuation route notification unit 319 displays the evacuation route information indicating the evacuation route from each house 104. It transmits to the energization management device 207 (step S808).

  FIG. 26 is a flowchart showing details of the evacuation route notification process (step S808). As shown in the figure, the map acquisition unit 320 acquires map information 305a (step S901). The evacuation route generation unit 321 generates evacuation route information 323 indicating the evacuation route from each house 104 to the evacuation site (step S902).

  FIG. 27 shows an example of the evacuation route indicated by the evacuation route information 323 generated by the evacuation route generation unit 321. The figure shows a route from the house 104a to the evacuation site 324. As shown in FIG. 27, the evacuation route is a route that avoids the house 104b where the fire is occurring as much as possible. The house 104b where the fire has occurred can be identified based on the state information received by the state receiving unit 310. By evacuating through such an evacuation route, the resident 105 can evacuate safely.

  The evacuation route transmission unit 322 transmits each of the evacuation route information generated by the evacuation route generation unit 321 to the energization management device 207 provided in the corresponding house 104 (step S903). Thereby, the evacuation route notification unit 319 ends the evacuation route notification processing (step S807), and the wide area management apparatus 302 ends the processing.

  So far, the second embodiment of the present invention has been described.

  According to the present embodiment, the wide area management device 302 determines whether each house 104 is in an abnormal state based on the state information of the house 104 in the wide management area. If it is determined that the state is abnormal, the handling unit 314 executes the handling method indicated by the handling method information 311 included in the handling information 304a. As a result, appropriate measures such as rescue of the resident 105 of each house 104 can be taken at an early stage to improve the safety of the resident 105 of the house 104 in the management area.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to these embodiment. The present invention includes combinations of the embodiments and equivalents thereof.

101, 201 Energization management system 102 Commercial power supply 104 Residential 106a, b Wiring 107, 207 Energization management device 108a-e First to fourth generation transmission devices 109a, b Reference position device 112 Breaker unit 113 Normal status storage unit 114 Status storage unit 131, 231 Control unit 134 Power monitoring unit 135 Request transmission unit 136 Status reception unit 137 Normal status acquisition unit 138 Status acquisition unit 139 Status determination unit 140 Energization control unit 143 Power failure determination unit 144 Power recovery determination unit 146 Status information reception unit 147 Status Information update unit 148 Standby power supply 149 Request reception unit 150, 156, 160, 163 First to fourth state generation units 151, 157, 161, 164 First to fourth state transmission units 152, 158, 162 First to third Position generation unit 153 Disconnection generation unit 154 Ground fault generation unit 155, 1 59 1st-2nd inclination production | generation part 165 Seismic intensity production | generation part 166 Fire detection part 167 Water leak detection part 168 Gas leak detection part 278 Wide area communication part 279 Wide area transmission part 280 Wide area reception part 301 Wide area management system 302 Wide area management apparatus 303 By house State storage unit 304 Corresponding storage unit 305 Map storage unit 310 State reception unit 311 Electricity demand prediction unit 312 Housing-specific state acquisition unit 313 Abnormality determination unit 314 Response unit 315 Response method acquisition unit 316 Person notification unit 317 Contact acquisition unit 318 Neighborhood Notification unit 319 Evacuation route notification unit 320 Map acquisition unit 321 Evacuation route generation unit 322 Evacuation route transmission unit

Claims (12)

An energization management system comprising one or more generation and transmission devices and an energization management device,
The generation transmission device generates one or a plurality of state information indicating a state of a management range by the energization management device and transmits the generated state information to the energization management device,
The energization management device is
Status receiving means for receiving the status information from the generating and transmitting device;
Normal state acquisition means for acquiring normal state information indicating a normal state of the management range;
When the status indicated by the status information received by the status receiving means is not the status indicated by the normal status information, the management range is determined to be an abnormal status and is indicated by the received status information. State determination means for determining that the management range is a normal state when the state to be displayed is a state indicated by the normal state information;
Energization switching means for switching between an energized state in which the supplied power is energized within the management range and an interrupted state in which the power is not energized within the management range;
The energization control for setting the energization switching means to the cut-off state when it is determined that the management range is in an abnormal state and for setting the energization switching means to the energization state when it is determined that the management range is in a normal state An energization management system comprising: means. The energization management device further includes:
Power recovery detection means for detecting power recovery;
When power recovery is detected by the power recovery detection means, comprising request transmission means for transmitting request information for requesting transmission of the status information to the generation transmission device,
The energization management system according to claim 1, wherein the generation and transmission device generates and transmits the state information when the request information is received. The generation and transmission device includes:
State generating means for generating the state information;
State transmission means for transmitting the state information generated by the state generation means to the energization management device,
The state generation means includes
The energization management system according to claim 1, further comprising position generation means for generating status information relating to the position of the generation transmission device itself. The state generation means further generates a disconnection generation means for generating state information relating to a disconnection of the wiring associated with the generation transmission device itself, and generates state information relating to a ground fault of the wiring associated with the generation transmission device itself. The energization management system according to claim 3, further comprising at least one of ground fault generating means. The energization management system according to claim 3, wherein the state generation unit further includes an inclination generation unit that generates state information about the inclination of the generation transmission device itself. The state generation means further includes at least one of a fire generation means for generating state information about fire, a water leak generation means for generating state information about water leak, and a gas leak generation means for generating state information about gas leak. The energization management system according to claim 3, comprising: The energization management system according to any one of claims 1 to 6, wherein the energization management device and the generation and transmission device further include a standby power source for operating without depending on an external power source. A wide area management system comprising the energization management system according to any one of claims 1 to 7 and a wide area management device,
The energization management device provided in the energization management system further includes:
Wide area transmission means for transmitting the state information received from the generation transmission apparatus to the wide area management apparatus,
The wide area management device includes:
Correspondence storage means for storing correspondence method information indicating a handling method when the management range is in an abnormal state;
Status receiving means for receiving status information transmitted by the wide area transmitting means from the energization management device;
Area state acquisition means for acquiring area state information indicating a normal state of the management range;
When the state indicated by the state information received by the state receiving unit of the wide area management device is the state indicated by the acquired area state information, the management range is determined to be a normal state, and the reception An abnormality determining means for determining that the management range is in an abnormal state when the state indicated by the acquired state information is not the state indicated by the acquired area state information;
A wide area management system comprising: a response unit that executes a response method indicated by the response method information when the abnormality determination unit determines that the state is abnormal. The handling method information is notified to the parties concerned, notified to the vicinity of the management range determined to be in an abnormal state, and the evacuation route to the energization management device in the management range determined to be in an abnormal state The wide area management system according to claim 8, further comprising information indicating at least one of notifying evacuation route information indicating. The wide area management device further includes map storage means for storing map information including the management range and an evacuation place from the management range,
The handling method information includes information indicating that evacuation route information including an evacuation route from a management range to an evacuation site is generated and transmitted,
The handling means is
When it is determined that the abnormality determination unit is in an abnormal state, a response method acquisition unit that acquires the response method information;
Evacuation route notification means for acquiring the map information, generating evacuation route information including an evacuation route from the management range to the evacuation site, and transmitting the evacuation route information to the energization management device,
The energization management device further includes:
Wide area receiving means for receiving the evacuation route information transmitted from the wide area management device;
The wide area management system according to claim 9, further comprising: presentation means for presenting the content of the evacuation route information received by the wide area receiving means to a user. Status receiving means for receiving status information from the generating and transmitting device;
Normal state acquisition means for acquiring normal state information indicating the normal state of the management range;
When the status indicated by the status information received by the status receiving means is not the status indicated by the normal status information, the management range is determined to be an abnormal status and is indicated by the received status information. State determination means for determining that the management range is a normal state when the state to be displayed is a state indicated by the normal state information;
Energization switching means for switching between an energized state in which the supplied power is energized within the management range and an interrupted state in which the power is not energized within the management range;
The energization control for setting the energization switching means to the cut-off state when it is determined that the management range is in an abnormal state and for setting the energization switching means to the energization state when it is determined that the management range is in a normal state An energization management device comprising: means. Receiving status information from the generating and sending device,
Obtain normal status information indicating the normal status of the management range,
When the state indicated by the state information received by the state receiving means is not the state indicated by the normal state information, the management range is determined to be an abnormal state;
When the state indicated by the received state information is the state indicated by the normal state information, the management range is determined to be a normal state;
When it is determined that the management range is in an abnormal state, the supplied power is turned off so as not to energize the management range.
A program for causing a computer to execute an energization state in which supplied power is energized into the management range when it is determined that the management range is in a normal state.

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