JP6220422B2 - Plug type power supply control device and power supply node - Google Patents

Description

  The present invention relates to a plug-type power supply control device and a power supply node. For example, the power supply control device is installed in a general home or building, and monitors power consumption consumed in a tenant of a company in the home or building. The present invention relates to a plug-type power supply control device that controls power and a power supply node.

  Electricity consumption increases during periods of high demand, such as in summer. How to control power consumption during periods of high consumption is an important social issue. As power control, there are a case where the supply amount is controlled on the power supply side and a case where the consumption amount is controlled on the power (energy) use side.

  Of these, it has not been conventionally performed to control power consumption on the side of using energy in ordinary households and companies in buildings. Control at the side that uses energy in the home (Demand Side Management), or control the energy in response to information from the side where the center uses energy in the tenant in the building (Demand Response) Has been proposed in the field of the smart grid, but the implemented system is hardly realized.

  Patent Document 1 discloses an automatic operation control system that monitors the operation status of each home appliance that is simultaneously operated in a home and controls the power consumption of a plurality of home appliances to be controlled so as not to exceed a set value. ing.

  Further, in Patent Document 2, a power supply plug for a household appliance can be inserted, and a device for monitoring a household appliance that can also be plugged into a power outlet, and each of the monitoring devices are home appliances. A connected home electrical user system is shown. The measuring device MP of this system measures the total power in the system.

  Further, in Patent Document 3, a tag is attached to a plug of a device, a tag reader is installed near the plug insertion port of the power strip, and when the device plug is inserted, the tag information is transferred to an external monitoring computer. A system for monitoring the power usage status of the entire device by transmitting from the power tap is shown.

  However, in order to manually turn on / off the device and immediately reflect the result in the system, device authentication based on the device ID described in the tag is not sufficient, and consumption considering user convenience The power control system is not shown in any of Patent Documents 1, 2, and 3.

JP 2002-369383 A Special table 2003-508002 gazette JP 2011-010436 A Japanese Patent No. 4446854

  The present invention has been made to solve the above problems, and is installed in a general home or building, and the power consumption in the tenant of a company in the home or building is considered in consideration of user convenience. It is an object of the present invention to provide a plug type power supply control device and a power supply node that can accurately manage power consumption in a power consumption control system that can be controlled.

In order to achieve the above object, the present invention is a plug-type power supply control apparatus that is interposed between a node consisting of an outlet or a power strip having a communication function for power management and a device connected to the node. A plug housing, a plug portion protruding from the plug housing and connected to the node, an insertion port provided in the plug housing and into which a general-purpose plug of the device is inserted, and the plug A relay that opens and closes a power supply path between the communication unit and the insertion port, a communication unit that performs information communication with the communication function of the node, and the information between the communication function and the communication unit of the node Based on communication, control means for controlling the opening / closing operation of the relay, a power supply section for supplying operating power from the plug section to the control section, and security by disassembling the plug casing Seen including a security means for exerting a lifting function, wherein the communication function of the node is an IC card reader / writer, the communication means of the plug-type power supply control device includes an IC chip and an antenna, the IC A contactless IC card that can operate without a power source by using radio waves received from a card reader / writer as operating power, and the security means is an adhesive that adheres at least a part of the antenna to the plug housing And the antenna is destroyed by disassembling the plug casing, thereby functioning to disable the information communication .

  The present invention also relates to a power supply node comprising an outlet or a power strip having a communication function for power management, the node casing and a plug protruding from the node casing and connected to a general-purpose power outlet , An IC tag installed so as to be sandwiched between the node housing and the general-purpose power outlet in a state where the plug portion is inserted into the general-purpose power outlet, and the node housing includes the general-purpose power And security means for destroying the IC tag when leaving the outlet.

  According to the present invention, power consumption can be accurately managed in a power consumption control system.

1 is an overall view of a power consumption control system according to an embodiment of the present invention. It is a figure which shows the data structure of the status information transmitted to a server from a node. It is a figure which shows the system configuration information table which a server manages. It is a figure which shows the example of arrangement | positioning of the outlet socket and power strip of a power consumption control system corresponding to FIG. It is detail drawing of a power strip. It is a figure which shows the hardware constitutions of a server. FIG. 7 is a diagram illustrating a program and a table stored in the external storage device of FIG. 6. It is a whole flowchart of a power consumption control process. It is a flowchart of the process performed by the power tap or the outlet side when a new device flag is inserted. It is a flowchart of the process performed by a power strip or an outlet side when a card is brought close to a plug insertion slot into which a power plug is inserted. It is a figure which shows the data structure of the instruction information transmitted to each node from a server. It is a detailed flowchart of step S4 of FIG. It is a flowchart of the process performed by the power strip or outlet side which received instruction information. It is the example of a screen display which showed the power consumption condition in the system at the server side. It is a conceptual diagram which shows the structural example of the plug type power supply control apparatus of this modification. It is the external appearance perspective view. It is a conceptual diagram explaining the effect | action with FIG. It is the conceptual diagram explaining the effect | action with FIG. It is a conceptual diagram which shows the structural example of the power supply node of the further another modification which is one embodiment of this invention. It is a conceptual diagram which shows the structure and effect | action. It is a conceptual diagram which shows the structure and effect | action. It is a perspective view which shows the structural example of the outlet socket of the further another modified example of this invention. It is a perspective view which shows the structural example of the outlet socket of the further another modified example of this invention. It is an external view of the card reader and tag reader provided in the outlet of still another modified example of the present invention. It is an external view of the card reader and tag reader provided in the outlet of still another modified example of the present invention. It is an external view of the outlet socket in which the card reader / tag reader according to still another modification of the present invention is mounted. It is an external view of the outlet socket in which the card reader / tag reader according to still another modification of the present invention is mounted. It is a side view which shows the structural example of the plug inserted / extracted in the outlet socket of the further another modified example of this invention. It is explanatory drawing which shows the effect | action of the mechanical insertion / extraction recognition of the plug in the outlet socket of the further another modified example of this invention. It is explanatory drawing which shows the effect | action of the insertion / extraction recognition by the non-contact IC tag of the plug in the outlet socket of the further another modified example of this invention. It is a conceptual diagram explaining the electricity supply control with respect to the plug in the outlet socket of the further another modification of this invention. It is a wiring diagram which shows an example of the wiring in the outlet socket of the further another modified example of this invention.

  Hereinafter, embodiments according to the present invention will be described in detail with reference to the drawings. The present application uses Patent Document 4. “Felica”, “FeliCa”, “Mifare”, and “ZigBee” are trademarks.

  FIG. 1 is an overall view of a power consumption control system according to an embodiment of the present invention. As shown in FIG. 1, the power consumption control system includes any one of a home server 1, a router 2, a server 3, and a database 4, and an outlet parent device 6, an outlet child device 8, 10, 12, Power supply taps 17 and 18 are provided.

  When installing this system in a home, the system includes a home server 1, and when installing this system in a company that rents a tenant in a building, a router 2 is provided on the floor where the tenant is located, A center in which the server 3 and the database 4 are installed is provided in another place outside the building.

  Using a wireless communication network, each node (outlet, power strip) in the system communicates. In the present embodiment, ZigBee, which is one of short-range wireless communication standards, is assumed as an example of a wireless communication network, but other networks may be used.

  The server 3 (or the home server 1) activates the system, collects status information from each node through an outlet (master unit), and stores it in a system configuration information table as described later.

  In this embodiment, the power strip does not have a data transfer function (router function), functions as a ZigBee End Device (ZED), and the outlet (master unit) functions as a ZigBee Coordinator (ZC) with a network startup function. The (child device) functions as a ZigBee Router (ZR) having a data transfer function (router function).

  The outlet (master unit, slave unit) and power strip are provided with an IC card reader such as FeliCa Reader (F / R) and a UPS (uninterruptible circuit, battery). In the present embodiment, F / R is used as an example of an IC card reader or IC tag reader, but any standard may be used as long as it has functions of both a card reader and a tag reader, such as Mifare.

  In the present embodiment, each home appliance has a tag including ID information of its own device attached to a power plug. When the power plug is inserted into the outlet of the power outlet or the flag socket of the power strip, the F / R that serves as both the card reader and the tag reader reads the tag attached to the power plug and performs device authentication.

  Also, if you want to change the connection status of an IC card such as a Felica card owned by an individual (in the case of a tenant in a building, for example, an IC card that also serves as an employee card) By performing personal authentication close to the slot, the connection state of the home appliance of the power plug can be changed.

  In FIG. 1, for example, it is assumed that this system is installed in a home. Here, no home appliances are connected to the outlet master unit 6. In addition, a power plug of the microwave oven 13 is inserted into the plug socket of the outlet slave unit 8 (not shown in FIG. 1, the same applies hereinafter), and the power source of the dryer 14 is plugged into the plug socket of the outlet slave unit 12. The plug is inserted.

  Further, the power plug of the power tap 18 is inserted into the plug insertion port of the outlet slave unit 10, and the power plug of the power tap 17 is inserted into the plug insertion port of the power tap 18. Further, the power plug of the electric vacuum cleaner 16 is inserted into the plug insertion port of the power tap 17.

  The outlet master unit 6 and the outlet slave units 8, 10 and 12 are ZRs having a data transfer function (router function), and information necessary for ZC according to a procedure defined in the ZigBee communication protocol (status information described later in FIG. 2) ) To form a parent-child relationship with nearby nodes.

  In FIG. 1, for example, the outlet parent device 6 manages the outlet child devices 8, 10, and 12 as child devices. On the other hand, the outlet child device 8 is a child device for the outlet parent device 6, but acts as a parent device for the power strip 17 as a ZED having no router function. That is, the outlet slave unit 8 manages the power tap 17 as a slave unit.

  Similarly, for example, the outlet slave unit 10 manages the power tap 18 as a slave unit. As shown in FIG. 2, the status information 19 notified from each node to the server directly or via the ZR is, after the node ID (outlet ID, power strip ID), card ID, device ID or power strip ID, F / The number of plug outlets in which connection state information 20 of a device having RID (IC card reader ID), measurement value D1, measurement value D2, measurement value D3, and status items is provided in a node (outlet or power strip) It has a data structure that only lasts.

  On the server side that collects the status information from each node, a system configuration information table is created from the information. Since the status information is collected from each node at a considerable frequency, the system configuration information table is updated frequently.

  In order to detect the connection of a new home appliance (device) or to detect that the inserted power plug has been removed, it is necessary to compare at least the state immediately before the system configuration information table. . Therefore, it is necessary to keep a history for the system configuration information table. Actually, in addition to this, a history of the system configuration information table for a predetermined period in the past is required for the purpose of collecting statistics on the usage state of power.

  FIG. 3 shows a system configuration information table managed by the server. As shown in FIG. 3, the system configuration information table 21 includes a node ID, a card ID, a device ID or a power strip ID, F / RID, a measured value D1 (power consumption value obtained from a current measured by a current sensor), The measured value D2 (the temperature of the outlet and the power strip is obtained from the measured value of the temperature sensor), the measured value D3 (power), and the status (state) are included. “Node ID” can be referred to as a connection destination, and “device ID or power strip ID” can be referred to as a connection source. In addition, the modification which adds the item of the electric power value calculated | required from the measured value D1 as the measured value D3 by making the measured value D1 into the electric current value which the current sensor measured separately is also considered. In addition, a configuration in which the status of the plug insertion port of the node is set as a value such as a value of measurement value abnormality (temperature abnormality, power value abnormality, etc.) by various sensors during energization, tag recognition, or the like is also conceivable. For this reason, two items of measurement value D3 and status are added to FIG. 2 and FIG. 3, but the following description is made assuming that there is no measurement value D3 and status of FIG. 2 and FIG. Yes. As described above, a system configuration having the measured value D3 and status is also conceivable.

  FIG. 4 shows an arrangement example of outlets and power strips of the power consumption control system corresponding to FIG. In FIG. 4, the power tap 30 has a plug insertion port 36-1, a plug insertion port 36-2, and a plug insertion port 36-3, and these plug insertion ports 36-1, 36-2, 36. -3 has a card reader / tag reader 37-1, a card reader / tag reader 37-2, and a card reader / tag reader 37-3 on one side, and is inserted into the plug insertion port on the other side. LED35-1, LED35-2, and LED35-3 which display the influence which household appliances have on the power consumption of the whole system by changing a lighting color are provided.

  In FIG. 4, the power plug of the personal computer 27 is inserted into the plug insertion port 36-1 of the power tap 30, and the power plug 39 of the power tap 30 is inserted into the plug insertion port of the power tap 32. Yes.

Further, the power plug of the power tap 32 is inserted into the plug insertion port of the outlet 33. The refrigerator 28 is inserted into the outlet of the outlet 29.
In FIG. 4, the outlets 29, 31, and 33 function as ZR, and the power strips 30 and 32 function as ZED.

  In FIG. 4, the outlet 31 manages the outlets 29 and 33 as slave units, the outlet 29 manages the power strip 30 as a slave unit, and the outlet 33 manages the power strip 32 as a slave unit. Therefore, for example, the status information from the power tap 30 is transferred in the order of the outlet 29 and the outlet 31, and finally received by the server. The state information from the power tap 32 is transferred in the order of the outlet 33 and the outlet 31, and finally received by the server. Also, the status information of the outlet 29 is transferred through the outlet 31 and finally received by the server. Further, the status information of the outlet 33 is transferred through the outlet 31, and finally received by the server.

  In correspondence with the table of FIG. 3, it is assumed here that the power strip 30 has the node ID “ZE100003”, the power strip 32 has the node ID “ZE100004”, and the outlet 29 has the node ID “ZR100007”.

  In FIG. 4, the fact that the power plug of the personal computer 27 is connected to the plug socket 36-1 of the power strip 30 means that “device ID or power strip ID” is displayed on the first line of the system configuration information table 21 in FIG. "DEV_PC_001" is set in "." Note that “FR100021” is set in the F / RID in the same first line because the ID of the card reader / tag reader 37-1 provided near the plug insertion port 36-1 in FIG. FR100021 ".

  Further, in FIG. 4, the fact that the power plug 39 of the power strip 30 is inserted into the plug insertion port of the power strip 32 means that “device ID or power strip” is displayed on the fourth line of the system configuration information table 21 of FIG. This corresponds to the setting of “ZE100003” in “ID”. In FIG. 4, the fact that the power plug of the refrigerator 28 is inserted into the plug socket of the outlet 29 indicates that “DEV_REFRI — 001” is added to “DEVICE ID or POWER TAP ID” on the seventh line of the system configuration information table 21 in FIG. Corresponds to the setting.

  FIG. 5 is a detailed view of the power strip. The power plug 39 is connected to the plug insertion port 36-1, the plug insertion port 36-2, and the plug insertion port 36-3 via switches (relays) 51-1, 51-2, and 51-3. Yes. Between the relay 51-1, the relay 51-2, the relay 51-3, and the power plug 39, there are a current sensor 53-1, a current sensor 53-2, a current sensor 53-3, and a temperature sensor for temperature measurement. 55-1, a temperature sensor 55-2, and a temperature sensor 55-3 are provided. The temperature of the power tap can be known from the measured value of each temperature sensor.

  The card reader / tag reader 37-1 is provided near the plug insertion port 36-1, and when the power plug of the home appliance is inserted into the plug insertion port 36-1, the card reader / tag reader 37-1 is attached to the power plug of the home appliance. The tag information (the ID of the device and the expected wattage of the device) is read by the card reader / tag reader 37-1 and output to the relay control circuit 41 and the transmission data generation unit 48. Status information in which a valid value is set in the card ID item is transmitted to the server. The same applies to the card reader / tag readers 37-2 and 37-3.

  The control unit 40 includes a relay control circuit 41, a power supply switching circuit 43, an LED lighting control circuit 45, a communication circuit 46, and a transmission data generation unit 48. The relay control circuit 41 controls conduction (ON) / non-conduction (OFF) of the relays 51-1, 51-2, and 51-3.

  The power supply switching circuit 43 generates a signal for turning on (ON) one of the switches 62 and 64 and the switch 65, so that the power supply system side (the outlet or the power supply circuit 56 (the connection destination of the power supply plug 39)). To supply power to each device connected to the control unit 40 and plug insertion ports 36-1, 36-2, 36-3, or from the UPS (uninterruptible circuit, battery) 58 to the control unit 40 and plug It is determined whether to supply power to each device connected to the insertion ports 36-1, 36-2, 36-3. The inverter 61 generates an inverted signal.

  The transmission data generation unit 48 includes card reader / tag readers 37-1, 37-2, 37-3, current sensors 53-1, 53-2, 53-3, temperature sensors 55-1, 55-2, 55-3. Based on the information (measured value) from, state information about the own device is generated and transmitted to the node (parent device) that manages the own device through the communication circuit 46 and the network connection unit 38.

The LED lighting control circuit 45 performs control to turn on the corresponding LED among the LEDs 35-1, 35-2, and 35-3 with the color of the LED color information included in the instruction information received from the server.
The relay control circuit 41 stores a correspondence relationship between the card reader / tag readers 37-1, 37-2, and 37-3 and the relays 51-1, 51-2, and 51-3. When the ID of the card reader / tag reader 37-1 is received, it is recognized that the relay to be controlled is the relay 51-1.

  Similarly, the LED lighting control circuit 45 stores the correspondence relationship between the card reader / tag readers 37-1, 37-2, and 37-3 and the LEDs 35-1, 35-2, and 35-3. For example, when the ID of the card reader / tag reader 37-1 is received from the relationship, it is recognized that the LED to be controlled is the LED 35-1.

  FIG. 6 is a diagram illustrating a hardware configuration of the server. As shown in FIG. 6, the server 80 includes a CPU (Central Processing Unit) 81, a memory 82, an input device 83 such as a mouse and a keyboard, an external storage device 84, and a portable recording medium driving device capable of driving a portable recording medium 86. 85, a network connection device 87 and a display device 88 that communicate with a node to be managed are connected through a bus 89.

  FIG. 7 is a diagram showing programs and tables stored in the external storage device 84 of FIG. As shown in FIG. 7, the external storage device 84 has a power consumption control program 91 for executing processing of flowcharts of FIGS. 8 and 12 described later, and system configuration information generated when the power consumption control program 91 is executed. The table 21 and system configuration history information 92 that is a history of the system configuration information table 21 are stored.

  FIG. 8 is an overall flowchart of the power consumption control process. The processing of this flowchart is executed by the CPU 81 executing the power consumption control program 91 on the server side.

  A series of processes starts when the server is turned on. First, in step S1, it is determined whether or not a predetermined number has been received from a node that manages state information (see FIG. 2). Note that whether or not a predetermined time has elapsed can also be determined in step S1.

  Unless the predetermined number of state information is received in step S1, the determination in step S1 is repeated. If it is determined in step S1 that a predetermined number of state information has been received (if the determination result in step S1 is Yes), the system configuration information table 21 is updated using the predetermined number of state information received in step S2. Processing is performed.

  When the system configuration information table 21 is updated in step S <b> 2, the contents of the system configuration information table immediately before the update are stored in the system configuration history information 92. In step S3, whether the system configuration information table 21 has been changed by comparing the system configuration information table immediately before in the system configuration history information 92 with the system configuration information table 21 updated in step S2. Is determined.

  If it is determined in step S3 that the system configuration information table 21 has not changed, the process returns to step S1. When it is determined in step S3 that the system configuration information table 21 has changed, in step S4, processing corresponding to the detected change is executed, the instruction information is notified to the related nodes, and the process returns to step S1. “Detected changes” includes “a new device was plugged in”, “there was a device whose power consumption changed”, “a device was requested to turn on manually”, “manually There was a request to turn off the device ".

  When the power plug of a new device is inserted, in step S5 in the flowchart of FIG. 9, the user brings the power plug with the device tag affixed close to the plug insertion port of the node (power tap or outlet). The card reader / tag reader (F / R in this embodiment) reads the tag, and in step S6, status information is transmitted from the node to the server. As a result, the newly connected device can be recognized on the system side.

  Note that the status information transmitted to the server at this time is the device ID corresponding to the corresponding F / RID in FIG. 2 and the ID of the newly connected device is the corresponding measured value D1. The expected consumption wattage of each is set.

  Regarding the manual device ON / OFF request, in step S7 in the flowchart of FIG. 10, the power supply of the device whose user wants to change the connection state of the node (power strip or outlet) with an IC card such as a FeliCa card. By approaching the plug insertion port to which the plug is connected and causing the card reader / tag reader (F / R in the present embodiment) to read it, in step S8, from the node, the item of the card ID in FIG. Status information in which a valid value (information of the IC card that has been brought close to) is set is transmitted to the server. Thereby, for example, a device supplied with power from a power supply system (power supply line) is changed to a power supply from UPS (battery), and a device supplied with power from a battery is supplied from the power supply system (power supply line). The power supply is changed.

  3 and FIG. 4, the power plug 39 of the power strip 30 (node ID: ZE100003) is inserted into the plug insertion port of the power strip 32 (node ID: ZE100004). Yes. The power plug of the power tap 32 is inserted into the outlet 33.

  Therefore, when no battery is used on the upstream side of the power strip 30 (the side close to the server) and only the power plug of the power strip 30 is connected to the power strip 32, all plug insertion ports (this) Is the device connected to the IC reader ID), in FIG. 3, the F / RID value is FR100021, FR100022, FR100023 three rows of measured values D1 values (this item contains device consumption) If the sum of the power value is set and the value of the measured value D1 of the corresponding FRID of the power tap 32 (the row of F / RID is “FR100031” in FIG. 3) match, The power tap 30 is supplied with power from a power system. On the other hand, if the measured value D1 of the corresponding row (fourth row in FIG. 3) of the power tap 32 is smaller than the sum of the measured values D1 of the power tap 30, the difference is supplied from the UPS at the power tap 30 ( However, in the detailed configuration example of the power strip shown in FIG. 5, the power supply from the UPS is only controlled by a single switch 64, so this must be configured to provide three switches corresponding to each relay. Such a case is unlikely). Further, if the total sum of the measured values D1 of the power strip 30 has a constant value and the measured value D1 of the corresponding row (fourth row in FIG. 3) of the power strip 32 is “0 (zero)”, the power source The tap 30 supplies power from the UPS for all the devices inserted into the plug insertion port.

  As described above, by analyzing the system configuration information table, it can be determined whether the power is supplied from the UPS or the power supply system. When the server side receiving the state information including the power supply from the UPS (battery) at that time, if the device inserted in the plug insertion port is supplied with power, If the device inserted into the plug insertion port is supplied with power from the power system, the status information is determined as “manual device OFF request”. . Although only the device has been described here, in addition to this, the user can also manually turn on / off a power strip inserted into an outlet or a plug socket of another power strip.

  In addition, as shown in FIG. 11, the instruction information 96 notified from the server 80 to each node includes LED color information, card ID, personal authentication result, device ID, node ID (outlet ID, power tap ID), Number of items of information 98 to be instructed that include items such as device authentication result, F / RID, energization availability, and battery availability that require an indication among plug outlets provided in nodes (outlets and power strips) Only has a data structure (which may simply be “lasts as many as the number of plug-in ports”).

  FIG. 12 is a detailed flowchart of step S4 in FIG. In FIG. 12, in step S10 which is a transition destination when a change from the previous history of the system configuration information table 21 is detected in step S3 of FIG. 8, the detected change is “there is a device whose power consumption has changed. If it is "", the process immediately proceeds to step S13. The case where “the power plug of the device that has been plugged in is removed” is also included here.

  If the detected change content is “new power plug inserted” in step S10, the connection source (device or power strip) set in the item “device ID or power strip ID” in step S11. ) Device authentication by ID (which is referred to as “device authentication”, but strictly speaking, “device” includes a power strip) is executed. The device authentication is not required to be so strict. For example, if the device ID is registered in a device list table (not shown) managed by the server, the authentication is OK. Then, the process proceeds to step S13. Note that a tag may not be attached to the power plug of the device or the like, and step S11 may not be executed.

  If the detected change content is “manual device ON” or “manual device OFF” in step S10, personal authentication based on the card ID is executed in step S12. Personal authentication is more strict than device authentication. For example, if the combination of the user's card ID and password registered in the user list table (not shown) managed by the server matches, the authentication is OK. Then, the process proceeds to step S13.

  In step S13, the current power consumption (total) in the system is obtained from the contents of the system configuration information table 21. At this time, the power consumption (expected amount of consumption) of the power plug of the newly inserted device and the power consumption (measured value) of the device that has been authenticated in step S12 and turned on manually are consumed. Include in the sum as a thing. The power supply from the battery that is not turned ON manually is excluded from the total.

  The addition of a new device or power strip can be determined by detecting the newly added device ID in comparison with the history immediately before the system configuration information table 21 in step S3 in FIG. Manual ON / OFF is determined by setting a value other than “NULL” indicating invalidity in the card ID item in the status information of FIG.

  As for the amount of power supplied from the battery, “device ID or power strip ID” in the system configuration information table 21 of FIG. 3 is a power strip (in this case, the ID starts with “ZE”) or an outlet (here, The row (the first row in FIG. 3) whose ID begins with “ZR” is specified, and the measured value D1 (power consumption) in that row is zero, and each row of the node ID (1 to 3 in FIG. 3). When the sum of the measured values D1 (power consumption) of the (line) is not zero, it is determined that the node ID of the node ID is supplying power from the battery.

  In step S14 subsequent to step S13, it is determined whether or not the current total power consumption in the system calculated in step S13 is smaller than the planned power consumption (power consumption upper limit value, hereinafter simply referred to as “threshold”). .

  If it is determined in step S14 that the sum is smaller than the threshold (if the determination result in step S14 is Yes), all requests from the corresponding node are permitted in step S15. In other words, this time, among the nodes that have newly received status information, do nothing for the node that has a device whose power consumption has changed, and conduct the corresponding relay for the node where the power plug of the new device is inserted (ON) to control the device to take power from the power supply system (power line). For nodes that have been requested to turn on the device manually, the power supply destination is changed from the battery to the power system (power line). For nodes that have been switched or manually requested to turn off the device, the power supply destination is switched from the power supply system (power supply line) to the battery. Then, the process proceeds to step S17.

  If it is determined in step S14 that the sum is equal to or greater than the threshold (if the determination result in step S14 is No), a node that falls within the threshold (a value set as the power consumption upper limit value in the system) in step S16 Find combinations for all requests from. Specifically, this time, each node that newly received the status information is disallowed one by one, and when it falls within the threshold, a combination of permission and disapproval is determined. Then, the process proceeds to step S17.

  For nodes that are not permitted, nothing is done if there is a device whose power consumption has changed, and if it is a node into which a power plug of a new device has been inserted, the corresponding relay is turned off. Turn on (OFF) and control the device to take power from the battery or not from anywhere (the system construction method in this case is optional), and turn on the device manually If the requested node, the request is invalidated and nothing is done. However, if the node has been requested to turn off the device manually, the power consumption can be reduced. Therefore, the power supply destination is switched from the power supply system (power supply line) to the battery as it is.

  In steps S15 and S16, for a node whose personal authentication by the card is authentication NG in step S12, a manual device ON / OFF request from the node is not permitted (invalid).

In step S17 to which control is passed from step S15 or step S16, the lighting color of the LED is obtained for all nodes.
There are three LED lighting colors: blue, yellow, and red. The ratio of the difference obtained by subtracting the current power consumption (total) from the threshold (power consumption upper limit value) and the current power consumption of each device of each node is 60% or less as an example, and the power supply system (power supply Blue if power is taken from the line), greater than 60%, yellow if the power is taken from the power system (power line), regardless of the ratio value, if added (if newly added to the power system) the upper limit ( If the power supply switching from the battery to the power supply system (power supply line) is necessary, the LED color is controlled to turn red. Thereby, the influence which it has with respect to the total power consumption of the system of supplying with electricity through a power supply system (power supply line) from the power plug of the plug insertion port can be visualized by color. Information for this visualization (LED color information) is set for all nodes. You may make it determine blue, yellow, and red in the range of another ratio.

  In step S18 following step S17, instruction information in which each value is set is created and transmitted to all nodes. The data structure of the instruction information is as shown in FIG. And it returns to step S1 of FIG.

  In step S18, except for the node that has newly received the status information this time, only the value is set in the LED color information in the instruction information (in this case as well, the card is inserted in order to specify the position of the plug insertion port. F / RID for specifying a reader / tag reader (in this embodiment, an IC card reader) is designated).

  If there is a surplus power that can be consumed, the power supply from the battery can be switched to the power supply from the power supply system (power supply line) as long as it falls within the threshold (power consumption upper limit value).

  In that case, between step S15 or step S16 in FIG. 12 and step S17, a step of determining whether or not the difference between the threshold value and the current power consumption (total) in the system is greater than or equal to a predetermined value. When the difference is determined to be greater than or equal to the predetermined value in the determination step, the supply from the battery is less than the above difference for the node supplying power from the battery, excluding the portion that is manually turned on by the authentication OK. In the instruction information for the node, a step for determining whether or not the node is small, and an instruction for switching to the power supply from the power supply system (power line) for the node supplying power from the battery when it is determined to be small And recalculating the power consumption (total) in the system at the current time by adding the supply from the battery, Inserted, it executes the processing of step S17 by the sum of the recalculated.

  FIG. 13 is a flowchart of processing performed on the power strip or outlet side that has received the instruction information. In step S31 of FIG. 13, it is determined whether instruction information has been received.

  While the instruction information is not received in step S31, step S31 is repeated. If it is determined in step S31 that the instruction information has been received, step S32, a combination of one or more F / RIDs included in the instruction information and energization availability is acquired. Then, in subsequent step S33, it is determined whether or not the value of the energization enable / disable item corresponding to each F / RID is energizable.

  When the energization possible value is energizable in step S33 (when the determination result in step S33 is Yes), in step S34, the relay (switch) corresponding to each F / RID is turned on. Then, the process proceeds to step S37.

  If it is determined in step S33 that the energization is not possible (when the determination result in step S33 is No), in step S35, the relay (switch) corresponding to each F / RID is turned off (OFF). . In step S36, a control signal is output from the power supply switching circuit 43 to switch the power supply (power supply destination) from the power supply system (power supply line) to the UPS (uninterruptible circuit, battery). Then, the process proceeds to step S37.

  In step S37, a combination of one or more F / RIDs and LED color information included in the received instruction information is acquired, and the LED lighting control circuit 45 recognizes that each is associated with each F / RID. Control is performed so that the LED designated by the LED color information is lit. Then, the process returns to step S31.

  When the personal authentication result or the device authentication result is authentication NG, it is naturally considered that the item of the personal authentication result or the device authentication result is not included in the instruction information in FIG.

  FIG. 14 is a screen display example showing a power consumption state in the system on the server side. As shown in FIG. 14, on the screen, the current power consumption for each home appliance (device), the threshold value (displayed in the upper center as “power upper limit” in the figure), and each home appliance (each device) at the current time The power consumption (total) (displayed as “total” in the figure on the right side of the upper center) is displayed.

  As described above, in the power consumption control system of the present embodiment, the power supply from the power supply system (power supply line) is switched to the power supply from the battery, and the power supply from the battery is supplied from the power supply system (power supply line). While switching to power supply can be performed manually, the total power consumption value of each device in the system can be kept below the power upper limit value, and control can be realized in consideration of user convenience.

  Also, out of the power consumption value collected from each node on the server side, the power supplied by the battery is excluded, the power supplied from the power system is summed, and the power consumption (total value) in the system is calculated. And compare it to the power cap in the system. For this reason, for example, for devices that can be switched at the time of the year when the power consumption is statistically peaked, at the time of the day, etc., switch to the power supply from the battery. The power consumption in the system can be controlled flexibly.

  In the above description, a tag is attached to the power plug of each device. However, it is also possible not to attach a tag. In this case, the device authentication is not performed, and the connection of the device is recognized on the system side through the measured values of the current sensor and the temperature sensor. Even in this case, by supplying power from the battery to the unauthenticated device, the power consumption of the device can be grasped on the system side, so power consumption control is included in the system component of the device. be able to. In addition, in the configuration where power is supplied from a battery to a device that could not be authenticated, even if the total power consumption in the system exceeds the power upper limit when power is supplied to the device from the power supply system, the battery It is possible to avoid that the total power consumption exceeds the power upper limit by supplying power from.

  In the above description, the current sensor and the temperature sensor are only included. However, another sensor may be added to collect other information. In the above description, a communication standard called ZigBee is used. However, communication may be performed using a standard such as Z-web, eco-net, and HEMS. Also, depending on whether the medium that provides the IC card (card reader / tag reader) function is a mobile phone or a personal digital assistant (PAD, etc.), the way data is held depends on the application processing method and processing. The order may be affected.

  In the above description, the device ID or power strip ID and the estimated consumption wattage are stored in the tag. However, in addition to this, other numerical data, update date, remaining date, value data, and the like are stored. May be.

  Further, when the system is introduced in a company in a tenant in a building, the card ID may mean a company ID or a group ID. Also, although not specifically described in the above description, when the measured value of each temperature sensor provided in a node (power strip or outlet) exceeds a predetermined value, the power of the node is turned off on the server side. It is also possible to control the power supply system and battery.

  In the above description, for example, as illustrated in FIG. 1, in the devices such as the microwave oven 13, the dryer 14, and the electric vacuum cleaner 16 connected to the power consumption control system of the present embodiment, An example of a technique for attaching and recognizing an RFID tag such as Felica or an IC card on the side is illustrated.

  However, in this case, it is necessary to attach an RFID tag such as a Felica chip or an IC card to a plug of an existing home appliance, and it cannot be denied that the IC card can be attached to and detached from a managed device.

  When the IC card is attached or detached, there is a concern that the correspondence between the device such as home appliances and the IC card is not guaranteed, and the accuracy of power management cannot be maintained. Therefore, in the following description, as a modification of the above-described embodiment, a plug-type power supply control device that is retrofitted to a general-purpose plug of a general device and can be connected to the above-described node will be exemplified.

  An example in which a technology for preventing attachment / detachment of a recognition means such as an IC card or an IC tag and a technology for controlling power supply by the power plug itself are mounted on the plug-type power control device side will be described. Specifically, as an example, in the case of a power plug with a built-in Felica chip as an IC card or IC tag, security means that makes the Felica chip unusable due to tampering such as disassembly of the power plug, irreversible wrapping, etc. The falsification prevention technique by encapsulation is illustrated.

  FIG. 15 is a conceptual diagram showing a configuration example of the plug-type power supply control device according to this modification, and FIG. 16 is an external perspective view thereof. 17 and 18 are conceptual diagrams for explaining the operation.

  The plug type power supply control device 200 according to the present embodiment includes a plug casing 201 with a plug portion 202 protruding therefrom, as illustrated in FIG. The plug casing 201 includes a base casing 201a that supports the plug portion 202 and a cover casing 201b that is integrally fixed to the base casing 201a by a method such as screwing or bonding.

  The plug housing 201 is provided with an insertion port 204. A general-purpose plug 302 connected via a cable 301 to a device 300 such as a microwave oven 13, a dryer 14, or a vacuum cleaner 16 that consumes electric power is inserted into the insertion port 204.

  The plug-type power supply control device 200 is used by being inserted into the power management dedicated outlet 100 via the plug unit 202 and controls the supply of power output from the power management dedicated outlet 100 to the device 300.

  The power management dedicated outlet 100 is the outlet slave unit 8 or the power tap 18 illustrated in FIG. 1 described above, and is connected to each of the plug insertion ports 36-1 to 36-3 (in this case, the plug The type power supply control device 200) is recognized by each of the corresponding card reader / tag readers 37-1 to 37-3, thereby controlling the power supply availability. Accordingly, the corresponding elements are denoted by the same reference numerals, and duplicate descriptions are omitted.

  That is, inside the plug casing 201 of the plug-type power supply control device 200, as illustrated in FIG. 15, a control function including a non-contact IC tag 210, a control board 220, a relay 230, and a power supply board 240 is provided. I have.

  The non-contact IC tag 210 is composed of Felica or the like, and performs authentication of the device 300 as described above by performing non-contact information communication with the corresponding card reader / tag readers 37-1 to 37-3. Do.

  In the case of the present embodiment, the non-contact IC tag 210 is between an IC chip 210a containing a desired integrated circuit and a card reader / tag reader 37-1 to 37-3 of the power management dedicated outlet 100 as will be described later. It comprises an antenna 210b for short-range wireless communication.

  A control board 220 is connected to the non-contact IC tag 210, and a relay 230 is further connected to the control board 220. The relay 230 is arranged to open and close the internal conduction path 203 that connects the plug portion 202 and the insertion port 204.

  That is, when the control board 220 succeeds in the authentication by controlling the opening and closing of the internal conduction path 203 by the relay 230 according to whether or not the authentication result between the contactless IC tag 210 and the power management dedicated outlet 100 is acceptable. Only when the relay 230 is closed, power is supplied to the general-purpose plug 302 of the device 300.

  The power supply board 240 extracts and supplies the operating power of each part of the non-contact IC tag 210, the control board 220, and the relay 230 from the commercial power obtained in the plug part 202. In this case, the non-contact IC tag 210 is disposed on the base housing 201a side so that the antenna 210b is exposed on the mating surface with the cover housing 201b.

  When the cover housing 201b is assembled to the base housing 201a, an adhesive is disposed as a cutting material 205 between the antenna 210b and the cover housing 201b, and the antenna 210b is bonded to the cover housing 201b. To be fixed. This state is shown in FIG.

  Then, as shown in FIG. 18, when the cover housing 201b is separated from the base housing 201a for disassembling the plug-type power supply control device 200, the antenna 210b is attached to the cover housing 201b by the action of the adhesive as the cutting material 205. Are separated from the non-contact IC tag 210 side and separated from the IC chip 210a.

  For this reason, in the case of the present embodiment, when the plug-type power supply control device 200 is disassembled at one end, the non-contact IC tag 210 malfunctions due to the disconnection of the antenna 210b. Tampering such as replacement of the non-contact IC tag 210 in the control device 200 is prevented.

  That is, the cutting material 205 exhibits the security maintenance function of the plug type power supply control device 200 by disassembling the plug type power supply control device 200. Further, if necessary, the plug casing 201 of the plug-type power supply control device 200 and the general-purpose plug 302 connected to the insertion port 204 of the plug casing 201 may be irreversibly encapsulated by a wrap 206. Thus, it is possible to grasp whether or not the plug-type power supply control device 200 has been tampered with, and further whether or not the general-purpose plug 302 has been removed from the plug-type power supply control device 200.

  Here, irreversibly encapsulating means that once the wrap 206 is opened, the appearance does not return to the original state, and the opening trace remains clearly from the appearance. As an example of such an irreversible wrap 206, a shrink package is known. The wrap 206 made of resin or the like is wrapped in close contact with the plug casing 201 or the general-purpose plug 302 by heat shrinkage. When the wrap 206 is opened, the rupture trace of the wrap 206 does not return to the original, and the wrap 206 is opened from the appearance. The presence or absence of the show is clearly identified.

  The wrap 206 is provided alone without the cutting material 205 as a means for determining whether the plug-type power supply control device 200 has been tampered with, or for removing the general-purpose plug 302 from the plug-type power supply control device 200. Also good.

  Hereinafter, the operation of the plug-type power supply control device 200 of the present embodiment having the above-described configuration will be described. First, a general-purpose plug 302 of a desired device 300 is inserted into the insertion port 204 of the plug-type power supply control device 200, and is wrapped irreversibly with a wrap 206. Thereby, the correspondence relationship between the plug-type power supply control device 200 and the desired device 300 is maintained, and the plug unit 202 of the plug-type power supply control device 200 is connected to the various nodes exemplified in FIG. The device 300 is incorporated into a power management target.

  Also, it is assumed that specification information such as power consumption related to the connected device 300 is written in the non-contact IC tag 210 of the plug-type power supply control device 200 in advance. Step S101: The plug unit 202 of the plug type power supply control device 200 to which the device 300 is connected is inserted into the plug insertion port 36-1 of the power management dedicated outlet 100 (FIG. 15, (1) in FIG. 17).

  Step S102: The power is turned on to the power supply board 240 of the plug-type power supply control device 200 ((2) in FIGS. 15 and 17). Step S103: By inserting the plug type power supply control device 200 into the power management dedicated outlet 100, the card reader / tag reader 37-1 inside the power management dedicated outlet 100 and the non-contact IC tag inside the plug type power supply control device 200. 210 approaches ((3) in FIGS. 15 and 17).

  Step S104: The permission signal is output from the non-contact IC tag 210 to the control board 220 only when the card reader / tag reader 37-1 approaches the non-contact IC tag 210. Further, as described above, the registration information (in this case, the specification information of the device 300) is read from the non-contact IC tag 210 to the card reader / tag reader 37-1 ((4) in FIGS. 15 and 17).

  Step S105: The control board 220 closes the relay 230 when there is a permission signal from the non-contact IC tag 210 (ON), and opens the relay 230 when there is no permission signal (OFF) ((5 in FIGS. 15 and 17). )).

  When the plug-type power supply control device 200 is disassembled from the outside and the cover housing 201b of the non-contact IC tag 210 is destroyed, the antenna 210b is destroyed as described above. Since the communication with the reader / tag reader 37-1 is not possible and the permission signal is not sent to the control board 220, the relay 230 is not turned ON.

  Step S106: When the relay 230 is ON, power is supplied from the power management dedicated outlet 100 to the device 300, and when the relay 230 is OFF, it is not supplied ((6) in FIGS. 15 and 17).

  Step S107: When the relay 230 is turned on, the appliance 300 or the like receives power supply from the power management dedicated outlet 100 (FIG. 15, FIG. 17 (7)). Thereby, according to the plug-type power supply control device 200 of the present embodiment, the appliance 300 or the like with the plug-type power supply control device 200 attached to the general-purpose plug 302 is inserted into the power management dedicated outlet 100 only. It is energized, but it is not energized when it is inserted other than the power management outlet 100.

  As a result, the power used by the device 300 can be accurately managed in the power consumption control system in which the power management dedicated outlet 100 (node) is connected. Also, by simply mounting the plug-type power supply control device 200 on the general-purpose plug 302 of the device 300, the desired device 300 can be easily incorporated and managed in the power consumption control system of the present embodiment.

  Further, the plug-type power supply control device 200 becomes unusable when subjected to tampering such as disassembly, so that unauthorized use of power and the like can be reliably prevented. In the above description, the example in which the antenna 210b of the non-contact IC tag 210 is destroyed by the cutting material 205 when the plug-type power supply control device 200 is disassembled is shown, but the present invention is not limited thereto.

  For example, the signal line 211 between the non-contact IC tag 210 and the control board 220 is exposed on the mating surface of the base casing 201a and the cover casing 201b, and the exposed signal line 211 is covered with a cutting material 205 such as an adhesive. It may be fixed to the casing 201b and the tampering prevention may be realized by breaking the signal line 211 when the plug-type power supply control device 200 is disassembled.

  Next, an example of improving the convenience of the power management dedicated outlet will be shown. When the power management dedicated outlet 100, which is a node of the power consumption control system of the present embodiment, is installed in an existing outlet without construction, it can be easily installed anywhere, but anyone can attach and detach, and the wiring position (node (Position) cannot be specified.

  Therefore, the installation position of the power management dedicated outlet is specified by authenticating the general commercial power outlet 400 using the above-described card reader / tag reader 37-1 provided in the power management dedicated outlet.

  FIG. 19 is a conceptual diagram illustrating a configuration example of a power supply node according to still another modification of the present embodiment, and FIGS. 20 and 21 are conceptual diagrams illustrating the configuration and operation thereof. In this case, the power management dedicated outlet 101 has a structure in which a simple configuration excluding the UPS 58 is mounted inside the small outlet casing 102 in the configuration of the node illustrated in FIG.

  Further, the power plug 39 connected to the general commercial power outlet of FIG. 5 is integrally provided as the plug portion 103 in the outlet casing 102 of the power management dedicated outlet 101. In FIG. 19, the plug portion 103 is hidden behind the outlet housing 102 and is not visible, and is illustrated in FIG. 22B described later.

  Therefore, the power management dedicated outlet 101 can be attached to the general commercial power outlet 400 in a space-saving manner as if it were a general-purpose tap. In this case, the power management dedicated outlet 101 is attached to a general commercial power outlet 400 at an arbitrary location as follows.

  That is, when the outlet casing 102 of the power management dedicated outlet 101 is inserted into the plug insertion port 402 provided in the outlet casing 401 of the general commercial power outlet 400, the registered power distribution outlet 101 and the registered outlet distributed together with the power management dedicated outlet 101 are registered. The IC tag 104 is installed so as to be sandwiched between the outlet casing 401 and the outlet casing 102. 20 and 21, the IC tag 104 is exaggerated in thickness for convenience of explanation.

  The IC tag 104 is recognized by the card reader / tag reader 37-1 of the power management dedicated outlet 101. That is, in this case, the card reader / tag reader 37-1 of the dedicated power management outlet 101 recognizes the non-contact IC tag 210 in the above-described plug-type power supply control device 200 inserted / extracted from the outside, and the general commercial power outlet 400 The IC tag 104 installed between the two is also recognized.

  The IC tag 104 installed between the general commercial power outlet 400 and the power management dedicated outlet 101 is adhered and fixed to both the general commercial power outlet 400 and the power management dedicated outlet 101 with a cutting material 105 made of an adhesive. The

  In this case, the IC tag 104 has a thin seal shape, and includes an IC chip 104a positioned at the corner of the seal and an antenna 104b developed on the entire surface of the seal. A half of the IC tag 104 including the IC chip 104 a is fixed by a strong adhesive 105 a constituting the cutting material 105, and the other half is constituted by a weak adhesive 105 b constituting the cutting material 105. The adhesive strength of the strong adhesive 105a is greater than that of the weak adhesive 105b.

  Further, the seal constituting the IC tag 104 includes a perforation 104c and the like at the boundary portion so as to be divided at the boundary between the strong adhesive 105a and the weak adhesive 105b. Further, if necessary, after the power management dedicated outlet 101 is attached to the general commercial power outlet 400, a span is interposed between the outlet casing 401 of the general commercial power outlet 400 and the outlet casing 102 of the power management dedicated outlet 101. As such, the seal seal 110 may be irreversibly affixed. When the power management dedicated outlet 101 is removed from the general commercial power outlet 400, the seal seal 110 is broken so that it can be identified from the appearance.

  Thus, as illustrated in FIG. 20, after the power management dedicated outlet 101 is installed on the general commercial power outlet 400 by adhering the registered IC tag 104 with the cutting material 105, the power management dedicated outlet 101 is installed in FIG. 21. As illustrated, when the power management dedicated outlet 101 is removed from the general commercial power outlet 400, the IC tag 104 is divided at the boundary between the strong adhesive 105a and the weak adhesive 105b constituting the cutting material 105, and thereafter used. It becomes impossible to be recognized by the card reader / tag reader 37-1 of the power management dedicated outlet 101.

  Further, since the seal seal 110 is broken, the history of the removal of the general commercial power outlet 400 or the power management dedicated outlet 101 can be identified from the appearance. As a result, the power management dedicated outlet 101 prevents energization of the plug-type power supply control device 200 and the like connected from the outside.

  Therefore, once the power management dedicated outlet 101 is installed in a specific general commercial power outlet 400 using the registered IC tag 104, the power management dedicated outlet 101 becomes unusable if moved without permission. Tampering such as changing the installation position with respect to the general commercial power outlet 400 can be prevented, and power management using the power management dedicated outlet 101 can be performed accurately.

Also, unauthorized use of power due to movement of the installation position of the power management dedicated outlet 101 can be prevented.
Next, still another modification of the present embodiment will be described. In the above description, the reading function provided in the power management dedicated outlet 100 of the power management system of this embodiment recognizes plug insertion / removal by reading the non-contact IC tag 210 attached to the plug side. did.

However, in the recognition of the plug insertion / removal state by the single contactless IC tag 210 described above, the recognition of the insertion / removal state may be inaccurate depending on the situation.
Therefore, in the following, an example will be shown in which the recognition function by the non-contact IC tag 210 and the mechanical recognition of the plug insertion / removal state are combined to realize the plug / removal state more accurately. In this case, the non-contact IC tag 210 may have only an authentication function, and the above-described control function is unnecessary.

  22A and 22B are perspective views showing a configuration example of the outlet of the present modification. 23 and 24 are external views of a card reader / tag reader provided in the outlet of the present modification.

FIG. 25 and FIG. 26 are external views of an outlet equipped with a card reader / tag reader according to this modification. FIG. 27 is a side view showing a configuration example of a plastic according to this modification.
FIG. 28 is an explanatory view showing the action of mechanical insertion / removal recognition of the plug in the outlet of the present modification. FIG. 29 is an explanatory diagram showing the action of plugging / unplugging recognition by the non-contact IC tag of the plug in the outlet of the present modification.

FIG. 30 is a conceptual diagram illustrating energization control for the plug in the outlet of the present modification. FIG. 31 is a wiring diagram showing an example of wiring in the outlet of the present modification.
The power management system of this modification mechanically monitors whether or not the plug is inserted into the outlet, and after confirming the physical insertion of the plug, the reading function of the card reader / tag reader 37-1 is turned on and read. The ID number and the information set in the power management system are collated to determine whether the power is on or off. When the power is on, an energization process is performed.

  Therefore, as illustrated in FIG. 25 and FIG. 26, the outlet 33 and the card reader / tag reader 37-1 are incorporated in the power management system. 22A and 22B, the power management system-AC100V (L) terminal 36a, the power distribution-AC100V (N) terminal 36b, and the power distribution-AC100V (L) are provided on the back side of the outlet 33 in this modification. A terminal 36c and a monitor-AC100V (N) terminal 36d are provided.

  The power management system-AC100V (L) terminal 36a is an L phase that is energized / de-energized under the control of the power management system. The power distribution-AC100V (N) terminal 36b is an N-phase connected directly from the switchboard.

  The power distribution-AC100V (L) terminal 36c is an L phase connected directly from the switchboard. The monitor-AC100V (N) terminal 36d is connected to the power management system illustrated in FIG. 1, and the power management system monitors whether or not it contacts the L phase.

  The power management system-AC100V (L) terminal 36a and the power distribution-AC100V (N) terminal 36b are connected inside the outlet 33 as shown in FIG. 31 described later, and the power distribution-AC100V (L) terminal 36c and the monitor-AC100V ( N) The terminal 36d is not short-circuited.

  In the power management system-AC100V (L) terminal 36a, the above-described relay 51-1 is incorporated in series as an open / close switch, and whether the relay 51-1 is turned on or off as shown in FIG. Control.

  As shown in FIG. 30 described later, a power management system-AC100V (L) terminal 36a and a power distribution-AC100V (N) terminal 36b are connected to each of a pair of plug insertion ports 36-1 (female terminals) of the plug 200A. The actual commercial power is supplied through these two terminals.

  Further, as illustrated in FIG. 27, in the plug 200 </ b> A, the IC tag 104 is disposed on the end surface facing the outlet 33 between the pair of plug portions 202. In the case of this modification, as illustrated in FIG. 28, a pair of plug portions 202 of a plug 200A inserted from the outside is provided between the power distribution-AC100V (N) terminal 36b and the monitor-AC100V (N) terminal 36d. An insertion / removal detection switch 36e is provided at a position corresponding to the distal end of the insertion completed state.

  The insertion / extraction detection switch 36e opens in a natural state where no external force acts (upper state in FIG. 28), and closes by being pressed by the plug portion 202 that is completely inserted from the outside (lower state in FIG. 28). The distribution-AC100V (N) terminal 36b (power management system-AC100V (L) terminal 36a) and the monitor-AC100V (N) terminal 36d are short-circuited, and the potential of the distribution-AC100V (N) terminal 36b is set to a monitor signal M1 described later. , M2 from the monitor-AC100V (N) terminal 36d. Then, the control unit 40 indicates that a voltage is generated between the monitor-AC100V (N) terminal 36d (monitor signals M1, M2) and the power distribution-AC100V (L) input from the outside to the relay 51-1. Detecting that the plug portion 202 of the plug 200A has been physically and mechanically inserted into the outlet 33.

  A plug insulating piece 36f is disposed on the contact surface side of the plug portion 202 in the insertion / extraction detection switch 36e, and the monitor-AC100V (N) terminal 36d and the power distribution-AC100V (L) terminal 36c are directed to the plug portion 202 side. Is electrically insulated.

  As illustrated in the wiring diagram of FIG. 31, in the case of a two-port outlet including the outlet C <b> 1 and the outlet C <b> 2, the distribution-AC100V (L) terminal 36 c of each outlet 33 corresponds to the inside of the control unit 40. Are individually connected in parallel to the L phase (in this case, relay outputs R1, R2) of the single-phase commercial power line via two relays 51-1.

  Further, the distribution-AC100V (N) terminal 36b of one outlet 33 (outlet C1) closest to the power supply side is connected to the N phase of the single-phase commercial power line, and the other outlet 33 (outlet C2) on the downstream side. The power distribution-AC100V (N) terminal 36b is connected to the power management system-AC100V (L) terminal 36a of the upstream outlet 33 through the power line 36g, so that commercial power is supplied from the outside.

  When the insertion / extraction detection switch 36e provided in each outlet 33 (outlets C1, C2) is closed by inserting the plug 200A, the power management system-AC100V (L) terminal 36a and the monitor-AC100V (N) terminal 36d. Is conducted, and the potential of the power distribution-AC100V (N) terminal 36b is input to the control unit 40 from the monitor-AC100V (N) terminal 36d as the monitor signals M1, M2, and the control unit 40 is connected to the monitor-AC100V (N) terminal. 36 d and the relay 51-1, which is externally input to the AC-V 100 V (L), the relay 51-1 corresponding to each outlet 33 is closed and the outlet 33 is closed. The power is supplied to the plug 200A inserted in.

  As described above, the plug part 202 of the plug 200 </ b> A is mechanically inserted into the outlet 33, whereby the power distribution-AC 100 V (N) terminal 36 b (power management system—AC 100 V (L) terminal 36 a) and the monitor—AC 100 V (N). Conduction between the terminals 36d through the insertion / extraction detection switch 36e, and distribution-AC100V (N) is output as the monitor signal M1 and the monitor signal M2, which is monitored by the power management system, and inserted / extracted from the outlet 33 of the plug 200A. Is determined.

  After it is confirmed that the mechanical plug 200A is inserted into the outlet 33 by the insertion / extraction detection switch 36e, the power management system uses the card reader / tag reader 37-1 provided in the outlet 33 as shown in FIG. The ID information is read from the non-contact IC tag 210 of the plug 200A inserted into the plug 200A, and the non-contact IC tag 210 is authenticated from the registration information.

  If the reader function of the card reader / tag reader 37-1 is always ON, power consumption or the like may increase, or there may be a problem such as malfunction due to noise. Therefore, the power management system inserts the plug with the insertion / extraction detection switch 36e. When the mechanical insertion of the plug 200A is confirmed by the monitor function, the reader function of the card reader / tag reader 37-1 is turned on, and when the reading is completed, the reader function of the card reader / tag reader 37-1 is turned off.

  As illustrated in FIG. 30, the plug (equipment side) is controlled by the energization / non-energization process (the above-described relay 51-1) of the L phase (power management system-AC100V (L) terminal 36a) under the control of the power management system. ) To control ON / OFF of the power supply to.

  If the non-contact IC tag 210 of the plug 200A is authenticated by the card reader / tag reader 37-1, and the power supply is permitted to be turned on, the power management system-AC100V (L) terminal 36a is energized and the power supply is permitted to be turned on. Otherwise, the power management system-AC100V (L) terminal 36a is not energized and is not energized.

  As described above, in this modification, the card reader / tag reader 37-1 of the outlet 33 authenticates the non-contact IC tag 210 after confirming the mechanical insertion of the plug 200A into the outlet 33. It is possible to more reliably recognize that the plug 200A has been inserted into the outlet 33 as compared with the insertion / removal recognition of -1 alone.

  As a result, it is possible to reliably prevent a malfunction such as the card reader / tag reader 37-1 recognizing the non-contact IC tag 210 of the plug 200A just before the plug 200A approaches the outlet 33, and more accurately. It is possible to realize the plug 200A insertion / removal recognition and management control of power supply to the plug 200A.

DESCRIPTION OF SYMBOLS 1 Home server 2 Router 3 Server 4 Database 6, 31 Outlet parent machine 8, 10, 12, 29, 33 Outlet child machine 13 Microwave oven 14 Dryer 16 Vacuum cleaner 17, 18, 30, 32 Power supply tap 19 Status information 20 Equipment Connection state information 21 system configuration information table 27 personal computer 28 refrigerator 35-1, 35-2, 35-3 LED
36-1, 36-2, 36-3 Plug insertion port 36a Power management system-AC100V (L) terminal 36b Distribution-AC100V (N) terminal 36c Distribution-AC100V (L) terminal 36d Monitor-AC100V (N) terminal 36e Insertion / extraction detection switch 36f Plug insulation piece 36g Tail wire 37-1, 37-2, 37-3 Card reader / tag reader 38 Network connection 39 Power plug 40 Control unit 41 Relay control circuit 43 Power supply switching circuit 45 LED lighting control circuit 46 Communication Circuit 48 Transmission data generation unit 51-1, 51-2, 51-3, 62, 64, 65 Switch 53-1, 53-2, 53-3 Current sensor 55-1, 55-2, 55-3 Temperature sensor 56 Power supply circuit 58 UPS
61 inverter 80 server 81 CPU
82 Memory 83 Keyboard 84 External Storage Device 85 Possible Transport Type Recording Medium Drive Device 86 Possible Transport Type Recording Medium 87 Network Connection Device 88 Display 89 Bus 91 Power Consumption Control Program 92 System Configuration History Information 100 Power Management Dedicated Outlet 101 Power Management Dedicated Outlet DESCRIPTION OF SYMBOLS 102 Outlet case 103 Plug part 104 IC tag 104a IC chip 104b Antenna 104c Perforation 105 Cutting material 105a Strong adhesive 105b Weak adhesive 110 Sealing seal 200 Plug type power supply control device 200A Plug 201 Plug case 201a Base case 201b Cover Housing 202 Plug part 203 Internal conduction path 204 Insertion slot 205 Cutting material 206 Wrap 210 IC tag 210a IC chip 210b Antenna 21 DESCRIPTION OF SYMBOLS 1 Signal line 220 Control board 230 Relay 240 Power supply board 300 Apparatus 301 Cable 302 General purpose plug 400 General commercial power outlet 401 Outlet housing 402 Plug insertion port

Claims (7)

A plug-type power supply control device interposed between a node consisting of an outlet or a power strip having a communication function for power management and a device connected to the node,
A plug housing;
A plug portion protruding from the plug housing and connected to the node;
An insertion port provided in the plug housing and into which a general-purpose plug of the device is inserted;
A relay for opening and closing a power supply path between the plug portion and the insertion port portion;
Communication means for performing information communication with the communication function of the node;
Control means for controlling the opening / closing operation of the relay based on the information communication between the communication function of the node and the communication means;
A power supply for supplying operating power from the plug to the control means;
Security means that exhibits a security maintenance function by disassembling the plug housing;
Only including,
The communication function of the node is an IC card reader / writer,
The communication means of the plug type power supply control device is a non-contact IC card that includes an IC chip and an antenna, and that can operate without a power source by using radio waves received from the IC card reader / writer as operating power.
The security means is an adhesive that adheres at least a part of the antenna to the plug housing, and functions to disable the information communication when the antenna is destroyed by disassembling the plug housing. A plug-type power supply control device. In the plug type power supply control device according to claim 1 ,
The security means includes a wrap that irreversibly encapsulates at least a part of the plug housing and functions so that the trace of the disassembly can be visually observed by being broken along with the disassembly of the plug housing. A plug-type power supply control device. A plug-type power supply control device interposed between a node consisting of an outlet or a power strip having a communication function for power management and a device connected to the node,
A plug housing;
A plug portion protruding from the plug housing and connected to the node;
An insertion port provided in the plug housing and into which a general-purpose plug of the device is inserted;
A relay for opening and closing a power supply path between the plug portion and the insertion port portion;
Communication means for performing information communication with the communication function of the node;
Control means for controlling the opening / closing operation of the relay based on the information communication between the communication function of the node and the communication means;
A power supply for supplying operating power from the plug to the control means;
Security means that exhibits a security maintenance function by disassembling the plug housing;
Including
The security means irreversibly and integrally encapsulates at least a part of the plug housing and the general-purpose plug of the device connected to the plug housing, and removes the general-purpose plug from the plug housing. A plug-type power supply control device comprising a wrap that functions so that the presence or absence of the removal can be visually confirmed by being broken together. In the plug type power supply control device according to claim 1 ,
The security means irreversibly and integrally encapsulates at least a part of the plug housing and the general-purpose plug of the device connected to the plug housing, and removes the general-purpose plug from the plug housing. A plug-type power supply control device comprising a wrap that functions so that the presence or absence of the removal can be visually confirmed by being broken together. A power node consisting of an outlet or a power strip with a communication function for power management,
A node chassis;
A plug portion protruding from the node housing and connected to a general-purpose power outlet;
An IC tag installed so as to be sandwiched between the node housing and the general-purpose power outlet in a state where the plug portion is inserted into the general-purpose power outlet;
Security means for destroying the IC tag when the node housing is detached from the general-purpose power outlet;
A power supply node comprising: The power supply node according to claim 5, wherein
The IC tag is disposed exposed on a contact surface of the node housing with respect to the general-purpose power outlet,
The power supply node according to claim 1, wherein the security means comprises an adhesive that adheres different areas of the exposed IC tag to the general-purpose power outlet with different adhesive forces. The power supply node according to claim 5, wherein
A power supply node comprising a sealing sticker irreversibly attached between the general-purpose power outlet and the node housing.