JP2006050777A - Remote management system of independent power supplies - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a remote management system of independent power supplies capable of collectively managing a plurality of the independent power supplies. <P>SOLUTION: A plurality of the independent power supplies are connected to a host 3 portion via a network 2 and is remotely managed in batch, based on measured values and abnormal data of various sensors provided on the independent power supplies 1a and 1b. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a remote management system for an independent power supply that charges a storage battery with electric power generated using natural energy such as sunlight and wind power and supplies electric power to an external load such as lighting.

  Conventionally, this type of independent power supply device, when there is a lot of power generated using natural energy of sunlight and wind power, supplies the power to the light-emitting panel display, displays characters, and charges the storage battery with surplus power . Moreover, when there is little electric power generated, what supplies a deficit from a storage battery and displays a character on an electrical panel display is known (for example, refer patent document 1).

  Hereinafter, the independent power supply device will be described with reference to FIG.

In FIG. 11, the power source of the wind power generator that generates power by the rotation of the windmill 2 is a three-phase AC power source. The AC power source is converted to DC by the charge controller 8 and controlled to prevent overcharging. The power source of the solar cell 4 that generates light by receiving light is a direct current power source. The direct current power source is controlled by the charge / discharge controller 9 so as to prevent the backflow of current to the solar cell and to prevent overcharge and overdischarge. The configuration is described in which the wind power generator obtained by the control and the power from the solar battery are connected to each other so as to complement each other and input to the battery 7.
Utility Model Registration No. 3055028

  In such a conventional independent power supply device, in order to check the operation status of the independent power supply device, it is necessary to go to the installation location, and there is a problem that it cannot be confirmed at a remote location, and the operation status is confirmed at a remote location It is requested.

  In parks and the like, a plurality of independent power supply devices may be installed, and it is required to collectively manage a plurality of independent power supply devices.

  An object of the present invention is to solve such a conventional problem and to provide a remote management system for an independent power supply apparatus that can collectively manage a plurality of independent power supply apparatuses.

  In order to achieve the above object, the independent power supply device of the present invention connects a plurality of independent power supply devices to a host unit via a network, and the host unit transmits sensor measurement data of the plurality of independent power supply devices via the network. The plurality of independent power supply devices are collectively monitored and controlled based on abnormal data.

  In addition, the host unit controls lighting switches installed in the plurality of independent power supply devices based on illuminance sensor measurement values installed in the plurality of independent power supply devices via the network, and turns on / off the lighting equipment. It has an illuminance control means.

  Further, the host unit is characterized by having a schedule control means for controlling lighting switches installed in a plurality of independent power supply devices according to a predetermined lighting schedule and turning on / off the lighting equipment.

  The host unit includes overdischarge abnormality determining means for collecting overdischarge abnormalities of a plurality of independent power supply devices via a network and determining the abnormalities of the plurality of independent power supply devices.

  The host unit includes overcharge abnormality determining means for collecting overcharge abnormalities of a plurality of independent power supply devices via a network and determining abnormalities of the plurality of independent power supply devices.

  In addition, the host unit includes charging abnormality determination means that collects charge amounts of the storage batteries of the plurality of independent power supply devices via the network and determines abnormality of the plurality of independent power supply devices. .

  In addition, the host unit is characterized by having discharge abnormality determination means for collecting discharge amounts from storage batteries of a plurality of independent power supply devices via a network and determining abnormality of the plurality of independent power supply devices. .

  The host unit includes storage means for storing sensor measurement data and abnormality data of a plurality of independent power supply apparatuses, and has distribution means for distributing data stored in the storage means.

  Also, new data is created based on the data stored in the storage means, and data processing means for storing the storage means is added.

  Further, the data processing means has a carbon dioxide reduction amount calculating means for converting the power generation amount of the independent power supply device stored in the storage means into a carbon dioxide reduction amount.

  ADVANTAGE OF THE INVENTION According to this invention, the remote management system of an independent power supply device with the effect that a remote independent management of several independent power supply devices can be provided can be provided.

  According to a first aspect of the present invention, a plurality of independent power supply devices are connected to a host unit via a network, and the host unit detects sensor measurement data and abnormality data of the plurality of independent power supply devices via the network. The plurality of independent power supply devices are collectively monitored and controlled based on the above, and has the effect of remotely monitoring the state of the independent power supply devices.

  In addition, the host unit controls lighting switches installed in the plurality of independent power supply devices based on illuminance sensor measurement values installed in the plurality of independent power supply devices via the network, and turns on / off the lighting equipment. The illuminance control means is provided, and has the effect of collectively monitoring and controlling the lighting fixtures.

  Further, the host unit is configured to have a schedule control means for controlling lighting switches installed in a plurality of independent power supply devices according to a predetermined lighting schedule and turning on / off the lighting equipment. It has the effect of collective monitoring and control.

  Further, the host unit is configured to have overdischarge abnormality determining means for collecting overdischarge abnormalities of a plurality of independent power supply devices via a network and determining abnormalities of the plurality of independent power supply devices. It has the effect of collectively monitoring and controlling the overdischarge transition state of the independent power supply device.

  Further, the host unit is configured to have overcharge abnormality determining means for collecting overcharge abnormality of a plurality of independent power supply devices via a network and determining abnormality of the plurality of independent power supply devices. It has the effect of collectively monitoring and controlling the overcharge transition state of the independent power supply device.

  Further, the host unit is configured to have a charging abnormality determination unit that collects charge amounts to the storage batteries of the plurality of independent power supply devices via the network and determines abnormality of the plurality of independent power supply devices. This has the effect of collectively monitoring and controlling the abnormal charging status of the independent power supply apparatus.

  Further, the host unit is configured to have discharge abnormality determination means for collecting discharge amounts from storage batteries of a plurality of independent power supply devices via a network and determining abnormality of the plurality of independent power supply devices. This has the effect of collectively monitoring and controlling the abnormal discharge state of the independent power supply apparatus.

  The host unit includes a storage unit that stores sensor measurement data and abnormality data of a plurality of independent power supply devices, and includes a distribution unit that distributes data stored in the storage unit. It has the effect of distributing the operating status of the independent power supply.

  Also, new data is created based on the data stored in the storage means, and the data processing means stored in the storage means is added, and has the effect of creating new data.

  Further, the data processing means includes a carbon dioxide reduction amount calculating means for converting the power generation amount of the independent power supply device stored in the storage means into the carbon dioxide reduction amount, and contributes to the carbon dioxide reduction amount of the independent power supply device. It has the effect of providing an amount.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

Example 1
Hereinafter, a remote monitoring system for an independent power supply according to a first embodiment of the present invention will be described with reference to FIGS. In order to make the description more specific, a case where two independent power supply devices are collectively managed will be described as an example.

  FIG. 1 shows a configuration diagram of a remote monitoring system for an independent power supply device according to a first embodiment of the present invention. As shown in FIG. 1, the independent power supply devices 1 a and 1 b are connected to the host unit 3 via the network 2. The host unit 3 collectively manages the independent power supply devices 1a and 1b based on the sensor measurement data and abnormality data of the independent power supply devices 1a and 1b.

  FIG. 2 shows a configuration diagram of the host unit 3. As shown in FIG. 2, the host unit 3 includes an illuminance control unit 4, a schedule control unit 5, an overdischarge abnormality determination unit 6, an overcharge abnormality determination unit 7, a charge abnormality determination unit 8, a discharge abnormality determination unit 9, and a storage unit 10. , Distribution means 11 and data processing means 12.

  Next, the operation will be described. 3 to 10 show operation block diagrams of each component of the host unit 3 according to the first embodiment of the present invention.

As shown in FIG. 3, the illumination control unit 4 monitors independent power supply 1a and the measurement value of the illuminance sensor 13a and 13b provided in the 1b a (L _a and L _b) via the network 2, L _a and L _When both _b are less than or equal to L _on , the lighting switches 14a and 14b provided in the independent power supply devices 1a and 1b are turned on via the network 2 to turn on the lights simultaneously. At the same time turns off the illumination is turned OFF light switch 14a and 14b provided in the independent source device 1a and 1b via the network 2 when either L _a and L _b is is equal to or greater than L _off. Here, L _on and L _off are constants set in advance.

As shown in FIG. 4, the schedule control means 5 turns on the lighting switches 14a and 14b provided in the independent power supply devices 1a and 1b via the network 2 when the current time becomes the lighting time (T _on ). Light up at the same time. Further, when the current time becomes the turn-off lighting time (T _off ), the lighting switches 14a and 14b provided in the independent power supply devices 1a and 1b are turned _off via the network 2 to turn off the lighting. Here, T _on and T _off are preset constants.

As shown in FIG. 5, the overdischarge abnormality determination means 6 monitors the values (OD _a and OD _b ) of the overdischarge counters 15a and 15b provided in the independent power supply devices 1a and 1b via the network 2, and their values are monitored. It is determined that an independent power supply with an OD _ov or more is overdischarge abnormality. Here, OD _ov is a preset constant.

As shown in FIG. 6, the overcharge abnormality determination means 7 monitors the values (OC _a and OC _b ) of the overcharge counters 16a and 16b provided in the independent power supply devices 1a and 1b via the network 2, and their values There is judged the overcharge abnormality independent power supply equal to or greater than OC _ov. Here, OC _ov is a preset constant.

  As shown in FIG. 7, the charging abnormality determination means 8 monitors the values of the charge amount sensors 17a and 17b provided in the independent power supply devices 1a and 1b via the network 2, and if only one of them is zero, it is zero. It is determined that the independent power supply device is an abnormal charging.

  As shown in FIG. 8, the discharge abnormality determination means 9 monitors the values of the discharge amount sensors 18a and 18b provided in the independent power supply devices 1a and 1b via the network 2, and if only one of them is zero, it is zero. It is determined that the independent power supply device is an abnormal discharge.

  As shown in FIG. 9, the storage means 10 measures various sensors (for example, solar cell voltage, wind power generation voltage, storage battery voltage, storage battery charge / discharge current, independent power generation amount, etc.) provided in the independent power supply devices 1a and 1b. The value is acquired via the network 2 and stored. The distribution unit 11 distributes the data of the independent power supply devices 1 a and 1 b even stored in the storage unit 10 via the network 2. The data processing unit 12 creates new data based on the data stored in the storage unit 10 and stores the new data in the storage unit 10.

  FIG. 10 shows an example of the operation of the data processing means 12. In FIG. 10, based on the values of the charge amount sensor measurement values 19 a and 19 b stored in the storage unit 10, the carbon dioxide reduction amount calculation unit 20 stores the converted carbon dioxide reduction amount in the storage unit 10.

  In this way, the independent power supply can be remotely monitored by connecting the independent power supply via a network, and the operation status can be grasped without going to the installation location.

  In addition, by simultaneously managing a plurality of independent power supply devices, it is possible to simultaneously turn on / off lighting fixtures and the like.

  Moreover, the abnormality of an independent power supply device can be judged from the difference in the operating condition of each independent power supply device.

  Further, by distributing the operation status of the independent power supply device, the operation status of the independent power supply device can be confirmed anywhere.

  The present invention can be applied to the use of a power generation apparatus that is linked to a general power line in addition to the independent power supply apparatus.

1 is a configuration diagram of an independent power supply device according to a first embodiment of the present invention. Block diagram of the host unit Operation block diagram of illuminance control means of the host unit Operation block diagram of schedule control means of the host unit Operation block diagram of overdischarge abnormality determination means of the host unit Operation block diagram of overcharge abnormality determination means of the host unit Operation block diagram of charging abnormality determination means of the host unit Operation block diagram of discharge abnormality determination means of the host unit Operation block diagram of storage means, distribution means and data processing means of the host unit Operation block diagram of data processing means of the host unit Configuration diagram of conventional independent power supply

Explanation of symbols

DESCRIPTION OF SYMBOLS 1a Independent power supply device 1b Independent power supply device 2 Network 3 Host part 4 Illuminance control means 5 Schedule control means 6 Overdischarge abnormality judgment means 7 Overcharge abnormality judgment means 8 Charge abnormality judgment means 9 Discharge abnormality judgment means 10 Storage means 11 Distribution means 12 Data processing means 13a Illuminance sensor 13b Illuminance sensor 14a Illumination switch 14b Illumination switch 15a Overdischarge counter 15b Overdischarge counter 16a Overcharge counter 16b Overcharge counter 17a Charge amount sensor 17b Charge amount sensor 18a Discharge amount sensor 18b Discharge amount sensor 19a Charge amount Sensor measurement value 19a Charge amount sensor measurement value 20 Carbon dioxide reduction amount calculation means

Claims (10)

A plurality of independent power supply devices are connected to a host unit via a network, and the host unit connects the plurality of independent power supply devices based on sensor measurement data and abnormality data of the plurality of independent power supply devices via the network. A remote management system for an independent power supply, characterized by performing collective monitoring and control. The host unit controls illumination switches installed in the plurality of independent power supply devices based on illuminance sensor measurement values installed in the plurality of independent power supply devices via the network, and controls the illumination equipment to turn on / off the lighting equipment. The remote management system for an independent power supply according to claim 1, further comprising: means. 2. The independent power supply according to claim 1, wherein the host unit includes schedule control means for controlling lighting switches installed in the plurality of independent power supply devices according to a predetermined lighting schedule and turning on / off the lighting equipment. Equipment remote management system. 2. The independent unit according to claim 1, wherein the host unit includes overdischarge abnormality determining means for collecting overdischarge abnormality of the plurality of independent power supply devices via the network and determining abnormality of the plurality of independent power supply devices. Remote management system for power supply. 2. The independent unit according to claim 1, wherein the host unit includes overcharge abnormality determining means for collecting overcharge abnormality of a plurality of independent power supply devices via a network and determining abnormality of the plurality of independent power supply devices. Remote management system for power supply. The host unit includes a charging abnormality determination unit that collects charge amounts of the storage batteries of the plurality of independent power supply devices via a network and determines an abnormality of the plurality of independent power supply devices. Independent power supply remote management system. The host unit includes a discharge abnormality determination unit that collects discharge amounts from storage batteries of a plurality of independent power supply devices via a network, and determines abnormality of the plurality of independent power supply devices. Independent power supply remote management system. 2. The independent unit according to claim 1, wherein the host unit includes storage means for storing sensor measurement data and abnormality data of a plurality of independent power supply devices, and has distribution means for distributing data stored in the storage means. Remote management system for power supply. 9. The remote management system for an independent power supply apparatus according to claim 8, further comprising a data processing means for creating new data based on the data stored in the storage means and storing the data in the storage means. 10. The independent power supply apparatus according to claim 8 or 9, wherein the data processing means includes a carbon dioxide reduction amount calculating means for converting the power generation amount of the independent power supply device stored in the storage means into a carbon dioxide reduction amount. Remote management system.

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