JP2013191160A - Power information management system and power information management method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To grasp power consumption for every arbitrary power management object.SOLUTION: A power information management server 1 stores terminal data 110 in which a location identifier for identifying a location of a power management object, an identifier of a terminal 11 belonging to the location, and power consumption of the terminal per unit time are associated with one another. The power information management server 1 acquires an operation state of the terminal 11 determined based on whether or not the terminal 11 responds to an operation confirmation signal, and stores operation result data 130 in which the identifier of the terminal 11, time when the operation confirmation signal is transmitted, and the operation state in the time are associated with one another. The power information management server 1 further calculates the power consumption of the location for every location of the terminal data 110 to be stored in operation result power data 143. The terminal 11 responds, when the operation confirmation signal is received during the operation of the terminal 11, to the operation confirmation signal.

Description

  The present invention relates to a power information management system and a power information management method for managing power information of a terminal.

  Based on the current power supply situation, companies and ordinary households are calling for the promotion of power saving measures. In particular, in business offices and the like, the number of office automation equipment such as personal computers and printers is increasing with the development of computers. In addition, with the development of communication networks, the number of IP devices such as routers and servers required to maintain an IP network is increasing. Thus, the amount of power consumed by terminals such as OA devices and IP devices is also considered as a target for power saving.

  In order to save power, it is effective to grasp the amount of power currently used and manage whether or not the target amount of power has been reached. In this case, for example, in a company, it is preferable to set the target power amount in organizational units such as sections and departments. However, when there are a plurality of organizations in one office, it is difficult to grasp the power consumption in each organization even if the power consumption in each office can be grasped. Therefore, it is necessary to be able to measure the power consumption of the terminals being used in units of each organization.

  In order to realize this, a method of installing a device that grasps the amount of power for each device is conceivable (for example, see Non-Patent Document 1). In the method described in Non-Patent Document 1, when measuring the power consumption of each electrical device, one power strip for measurement is installed for each device. Further, the server acquires the power consumption status of each device acquired from the power tap for each measurement. The server creates and distributes graphs and the like on a household basis based on data such as the power supply status and power consumption status. By such a method, it is possible to grasp the power consumption of each device and realize power saving for each device.

  In addition, in order to grasp the operating state of each device, a method of checking the operating device manually can be considered.

NTT East, “With FLET'S Hikari, you can see the“ waste ”of power consumption! ", [Online], [Search March 8, 2012], Internet <URL: http://flets.com/eco/mieruka/>

  However, in order to realize the method described in Non-Patent Document 1, an increase in introduction cost can be considered, and there is a problem that it is difficult to achieve cost reduction.

  In addition, in the method of manually confirming the operating device, there is a problem that the cost of labor and time due to human confirmation is increased and the accuracy of the confirmation result is lowered. As a result, there is a problem that specific management for power saving becomes difficult in companies and the like.

  Therefore, there is a demand for a method for accurately and timely grasping the operating state of the terminal for each arbitrary power management target.

  Accordingly, an object of the present invention is to provide a power information management system and a power information management method capable of grasping power consumption for each arbitrary power management target.

  In order to solve the above problem, a first feature of the present invention relates to a power information management system including a terminal and a power information management server connected to the terminal. In the power information management system according to the first aspect of the present invention, the power information management server includes a location identifier for identifying a location to be power managed, an identifier of a terminal belonging to the location, and consumption per unit time of the terminal. A storage device that stores terminal data associated with power; and an operating state of the terminal determined based on whether or not the terminal responded to the operation confirmation signal; and an identifier of the terminal, Operation result acquisition means for storing operation result data in which the operation confirmation signal is transmitted and the operation state at the time are associated with each other, for each location of the terminal data, the operation time of the terminal belonging to the location, Calculates the power consumption of the location from the power consumption per unit time of the terminal and stores it in the actual operation power data Provided with a door. When the terminal receives an operation confirmation signal during operation of the terminal, the terminal includes response means that responds to the operation confirmation signal.

  Here, in the power information management server, the storage device further stores operation schedule data in which the identifier of the terminal, the time, and the operation schedule of the terminal at the time are associated with each other. The data and the operation schedule data may be compared, and the terminal identifier, the time, and the difference between the operation schedule and the operation state for the terminal at the time may be associated with each other and stored in the operation prediction actual difference data.

  The operation confirmation signal is transmitted to the terminal at a predetermined timing.

  Furthermore, the power information management server may further include output means for outputting the data stored by the counting means to the output device.

  A second feature of the present invention relates to a power information management method used for a power information management system including a terminal and a power information management server connected to the terminal. In the power information management method according to the second aspect of the present invention, the power information management server includes a location identifier for identifying a location of a power management target, an identifier of a terminal belonging to the location, and consumption per unit time of the terminal. A step of storing terminal data associated with power in a storage device; a step of responding to the operation confirmation signal when the terminal receives an operation confirmation signal during operation of the terminal; and a power information management server The operation status of the terminal determined based on whether the terminal responded to the operation confirmation signal is acquired, the identifier of the terminal, the time when the operation confirmation signal is transmitted, and the operation at the time Storing the operation result data in which the state is associated with the storage device and the power information management server for each location of the terminal data. Comprising the operating time of the terminals belonging to the Deployment from power consumption per unit of time the terminal, and calculates the power consumption of the location, the step of storing in the operational performance power data.

  Here, the power information management server stores operation schedule data in which the terminal identifier, time, and operation schedule of the terminal at the time are associated with each other in the storage device, and the power information management server operates. Comparing the actual data and the planned operation data, further comprising a step of storing the terminal identifier, the time, and the difference between the planned operation and the operating state for the terminal at the time and storing the difference in the predicted operation difference data Also good.

  The operation confirmation signal is transmitted to the terminal at a predetermined timing.

  Furthermore, the power information management server may include a step of outputting the operation result power data to the output device.

  ADVANTAGE OF THE INVENTION According to this invention, the power information management system and power information management method which can grasp | ascertain the power consumption for every arbitrary power management object can be provided.

It is a figure explaining the system configuration | structure of the electric power information management system which concerns on embodiment of this invention. It is a sequence diagram explaining the power information management method which concerns on embodiment of this invention. It is a figure explaining the hardware constitutions and functional block of the electric power information management server which concern on embodiment of this invention. It is a figure explaining an example of a data structure and data of terminal data of a power information management server concerning an embodiment of the invention. It is a figure explaining an example of data structure and data of operation schedule data of a power information management server concerning an embodiment of the invention. It is a figure explaining an example of the data structure and data of the performance data of the electric power information management server which concerns on embodiment of this invention. It is a figure explaining an example of the data structure and data of operation | movement estimated actual difference data of the electric power information management server which concerns on embodiment of this invention. It is a figure explaining an example of a data structure and data of operation power data of an electric power information management server concerning an embodiment of the invention. It is a figure explaining an example of the graph which compares the operation plan electric power for every location of the electric power information management server which concerns on embodiment of this invention. It is a figure explaining an example of data structure and data of operation performance electric power data of an electric power information management server concerning an embodiment of the invention. It is a figure explaining an example of the graph which compares the scheduled operation electric power of the electric power information management server which concerns on embodiment of this invention, and operation performance electric power.

  Next, embodiments of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals.

  A power information management system 5 according to an embodiment of the present invention will be described with reference to FIG.

  The power information management system according to the embodiment of the present invention easily grasps the power usage state and manages the power by acquiring the operating state of each terminal that requires power at an office or the like. In the embodiment of the present invention, “power management” means that the power state of a power management target terminal is grasped centrally from a remote location and supports efforts for power saving. A “terminal” is an information terminal connected to a communication network, such as a computer or an IP device. In the embodiment of the present invention, the “terminal” is an information terminal that can respond to the operation confirmation signal in order to grasp the operation state of the terminal according to the presence or absence of a response of the operation confirmation signal such as a PING command. Therefore, the terminal to be managed may include OA devices such as a printer and a scanner connected to a communication network as well as a computer and a router.

  In addition, the power information management system 5 according to the embodiment of the present invention makes it possible to grasp the power consumption and manage the power for each terminal at any management target location. Here, the management target location is a logical unit of power management target. When power management is performed for each department or section, the location to be managed is a set of terminals belonging to the department or section. The location to be managed can be any terminal regardless of the physical installation location of the terminal.

  A power information management system 5 illustrated in FIG. 1 includes a power information management server 1, an operating state collection server 2, a first location L1, a second location L2, a third location L3, and a fourth location L4. The power information management server 1, the operation state collection server 2, the first location L 1, the second location L 2, the third location L 3, and the fourth location L 4 are connected to each other by the communication network 3 so that they can communicate with each other.

  The power information management server 1 is a server that acquires the operating state of a terminal to be managed and grasps the power consumption in consideration of the operating state. The power information management server 1 will be described in detail later with reference to FIG.

  The operating state collection server 2 collects the operating states of the terminals belonging to each location from each location and transmits them to the power information management server 1. The operating state collection server 2 is realized by a general computer executing a program for realizing a predetermined function. In the embodiment of the present invention, the operating state collection server 2 may be installed with spreadsheet software having a macro function, and a predetermined function may be realized by the macro function of the spreadsheet software.

  The first location L1, the second location L2, the third location L3, and the fourth location L4 each indicate a set of terminals that are power management targets in the embodiment of the present invention. In the example illustrated in FIG. 1, the case where there are four locations to be managed by the power information management server 1 will be described, but the number of locations is not limited thereto.

  The first location L1 includes an operating state acquisition terminal 10 and terminals 11 to 14.

  The operation state collection terminal 10 collects the operation state of the terminal at the location and transmits it to the power information management server 1. The operating state collection terminal 10 is realized by a general computer executing a program for realizing a predetermined function. In the embodiment of the present invention, the operating state collection terminal 10 may be installed with spreadsheet software having a macro function, and a predetermined function may be realized by the macro function of the spreadsheet software.

  The operation state acquisition terminal 10 transmits an operation confirmation signal to each terminal at the timing of confirming the operation state of each terminal. Here, the operation confirmation signal is a signal that is returned when the terminal is powered on and operating, and is, for example, a PING command. The operation confirmation signal is transmitted to the terminal at a predetermined timing.

  The operating state acquisition terminal 10 transmits a PING command to the terminal 11 every hour, for example. When a response corresponding to the PING command is received from the terminal 11 within a certain time, the operating state acquisition terminal 10 determines that the terminal 11 is operating. On the other hand, when the response corresponding to the PING command is not received from the terminal 11, specifically, when the PING command does not reach the terminal 11 and times out, the operating state acquisition terminal 10 supplies power to the terminal 11. It is determined that it is in a non-operating state that has not been turned on. The operation state acquisition terminal 10 creates operation result data data in which the time when the operation confirmation signal is transmitted, the identifier of the destination terminal, and the operation state of the terminal are associated with each other, and is stored in the storage device.

  Furthermore, the operation state acquisition terminal 10 transmits operation result data toward the power information management server 1 at a predetermined timing. The operation state acquisition terminal 10 transmits operation result data to the power information management server 1 every 12 hours, for example. At this time, the operating state acquisition terminal 10 may transmit to the power information management server 1 via the operating state collection server 2.

  When receiving an operation confirmation signal from the operation state acquisition terminal 10 while the power is turned on, the terminal 11 has a response unit that responds to the operation confirmation signal. For example, when a PING command is input from the operating state acquisition terminal 10, the response unit of the terminal 11 responds to the input PING command to the transmission source of the PING command. Since the terminal 11 cannot receive the operation confirmation signal when the power is not turned on and is not operating, the terminal 11 cannot transmit a response to the operation confirmation signal while the terminal 11 is not operating.

  The first location L1 includes four terminals, but the number of terminals is not limited to this. Accordingly, the terminals 11 to 14 belonging to the first location L1 may belong to the same segment of the communication network or may belong to a plurality of segments. The second location L2, the third location L3, and the fourth location L4 are the same as the first location L1.

  With reference to FIG. 2, an outline of the power information management method according to the embodiment of the present invention will be described.

  First, in step S <b> 1, the power information management server 1 transmits a request for acquiring the operating state of the terminal to the operating state collection server 2. In step S2, the operating state collection server 2 transmits a request for acquiring the operating state of the terminal at the first location L1 to the operating state acquisition terminal 10 at the first location L1.

  The operating state acquisition terminal 10 confirms the operating state of each terminal in the first location L1 and records the result at a predetermined timing. For example, when the operation status acquisition terminal 10 confirms the operation status of each terminal every hour, in step S3, it is determined whether one hour has elapsed since the previous confirmation of the operation status, and one hour has elapsed. Check the operating status of each terminal.

  Specifically, in step S <b> 4, the operation state acquisition terminal 10 transmits an operation confirmation signal to the first terminal 11. When the first terminal 11 is in operation and receives an operation confirmation signal from the operation state acquisition terminal 10, in step S5, the first terminal 11 transmits a response to the operation confirmation signal. On the other hand, when the first terminal 11 is not in operation and the operation confirmation signal cannot be received from the operation state acquisition terminal 10, the second terminal 12 transmits a response to the operation confirmation signal in step S5. There is no.

  Similarly, the operation state acquisition terminal 10 transmits an operation confirmation signal to the second terminal 12 in step S6. When the second terminal 12 is in operation and receives the operation confirmation signal from the operation state acquisition terminal 10, in step S7, the second terminal 12 transmits a response to the operation confirmation signal. On the other hand, when the second terminal 12 is not in operation and the operation confirmation signal cannot be received from the operation state acquisition terminal 10, the second terminal 12 transmits a response to the operation confirmation signal in step S7. There is no.

  In step S8, the operation state acquisition terminal 10 grasps the operation state of each terminal and records it in the storage device. When the response signal for step S4 is received, the operating state acquisition terminal 10 stores in the storage device that the first terminal 11 is operating at this time. On the other hand, when the response signal for step S4 is not received within the predetermined time, the operating state acquisition terminal 10 stores in the storage device that the first terminal 11 is not operating at this time. Similarly, when the response signal to step S6 is received, the operating state acquisition terminal 10 stores in the storage device that the second terminal 12 is operating at this time. On the other hand, when the response signal for step S6 is not received within the predetermined time, the operating state acquisition terminal 10 stores in the storage device that the second terminal 12 is not operating at this time.

  Here, the operation state acquisition terminal 10 stores the operation state result of each terminal in the operation result data of the operation state acquisition terminal 10. At this time, the operation state acquisition terminal 10 associates the time when the operation state is confirmed, the identifier of the target terminal, and the operation state, and stores them in the operation result data. The operation result data may be stored as a data sheet of a spreadsheet software file. At this time, for example, the operating state acquisition terminal 10 may add red to the cell when the terminal is operating, and green to the cell when the terminal is not operating. In addition, the operating state acquisition terminal 10 may store a spreadsheet data file data sheet every time the operating state of each terminal is stored, or may store the data sheet at a predetermined timing.

  Although omitted in FIG. 2, the same processing as in steps S <b> 4 to S <b> 7 is performed for the third terminal 13 and the fourth terminal 14. In step S8, the operating state acquisition terminal 10 determines whether or not the third terminal 13 and the fourth terminal 14 are in the operating state and records them.

  The operation state acquisition terminal 10 transmits operation result data in which the operation state of each terminal in the first location L1 is recorded to the power information management server 1 at a predetermined timing. For example, when the operation status acquisition terminal 10 transmits the operation result data every 12 hours, it is determined whether or not 12 hours have elapsed since the previous transmission of the operation result data in step S9, and 12 hours have not elapsed. Return to step S3.

  On the other hand, when 12 hours have elapsed, in step S10, the operation state acquisition terminal 10 transmits operation result data of the first location L1 to the operation state collection server 2. Thereafter, the operating state acquisition terminal 10 returns to Step S3. In step S <b> 11, the operation state acquisition terminal 10 transmits the operation result data of the first location L <b> 1 to the power information management server 1.

  As described above, when the power information management server 1 receives the operation result data of each location, in step S12, the power information management server 1 accumulates the data in the storage device. The power information management server 1 aggregates or statistics the power consumption based on the operation result data at each location, and generates and outputs a graph or the like.

  The power information management method shown in FIG. 2 is an example, and is not limited to this. For example, the processing in steps S1 and S2 in FIG. 1 may be processing in which the operating state acquisition terminal 10 transmits a list of transmission targets of the operation confirmation signal to the operating state acquisition terminal 10. It may be set in a data sheet of calculation software.

  Further, the processing in steps S1 and S2 in FIG. 1 may be omitted. For example, the operation state acquisition terminal 10 may be implemented in any manner as long as it can grasp the timing of transmitting the operation confirmation signal to each terminal and store the result. For example, the operator executes spreadsheet software indicating the timing of transmitting the operation confirmation signal to the operation state acquisition terminal 10, and records the transmission of the operation signal and the result at a predetermined timing by the macro function. Also good.

  In the power information management method illustrated in FIG. 2, when the operation state collection server 2 receives the operation result data 130 from the operation state acquisition terminal 10, the case where the data is transmitted to the power information management server 1 has been described. Not limited. For example, the operation state collection server 2 may accumulate the operation result data received from the operation state collection terminal at each location, and the power information management server 1 may download from the operation state collection server 2 at a predetermined timing. A plurality of devices may transmit and receive data between the operating state acquisition terminal 10 and the operating state collection server 2.

  In the example illustrated in FIG. 2, the process in which the power information management server 1 acquires the operating state of the terminal at the first location L1 has been described. However, the second location L2, the third location L3, and the fourth location are described. The same process is performed for L4.

  With reference to FIG. 3, the power information management server 1 according to the embodiment of the present invention will be described. As shown in FIG. 3, the power information management server 1 is a general computer including a storage device 100, a central processing control device 200, an input / output interface 300, an input device 400, an output device 500, a communication control device 600, and the like. . The power information management server 1 is realized by a general computer executing a program for realizing a predetermined function. In the embodiment of the present invention, the power information management server 1 may be installed with spreadsheet software equipped with a macro function, and a predetermined function may be realized by the macro function of the spreadsheet software.

  The input device 400 is a mouse, a keyboard, or the like. The input device 400 inputs an operator instruction to the central processing control device 200 via the input / output interface 300. The output device 500 is a display device or the like. The central processing control device 200 outputs information to the output device 500 via the input / output interface 300 to allow the operator to recognize it. The communication control device 600 is an interface connected to the communication network 3. The communication control device 600 inputs / outputs data to be transmitted / received via the communication network 3 to / from the central processing control device 200 via the input / output interface 300.

  The storage device 100 stores a predetermined program and also stores terminal data 110, operation schedule data 120, operation result data 130, and total data 140. The terminal data 110, the operation schedule data 120, the operation result data 130, and the total data 140 are data generated by each means mounted on the central processing control device 200. The terminal data 110, the operation schedule data 120, the operation result data 130, and the total data 140 are stored. The terminal data 110, the operation schedule data 120, the operation result data 130, and the total data 140 may be mounted on a data sheet of spreadsheet software.

  When the central processing control device 200 executes a predetermined program stored in the storage device, the central processing control device 200 causes the target terminal information acquisition unit 210, the operation schedule acquisition unit 220, the operation result acquisition unit 230, and the aggregation unit 240. Is implemented. The target terminal information acquisition unit 210, the operation schedule acquisition unit 220, the operation result acquisition unit 230, and the aggregation unit 240 may be realized by a macro function of spreadsheet software.

  The target terminal information acquisition unit 210 generates terminal data 110 based on an instruction of the input device 400 by an operator, data of each terminal managed by another system, or the like. The terminal data 110 is data in which a location identifier for identifying a power management target location, an identifier of a terminal belonging to the location, and power consumption per unit time of the terminal are associated with each other.

  Specifically, as shown in FIG. 4, the terminal data 110 is data in which a location identifier, a terminal identifier, an IP address, and power consumption during operation are associated with each other. The IP address is an identifier of a terminal that is a destination when an operation confirmation signal is transmitted to each terminal. The power consumption during operation is the power consumption per unit time for calculating the power consumption with respect to the operation time of this terminal. The power consumption per unit time may be set by measuring the power consumption per unit time for each terminal. Here, the correspondence between the power management target location and the terminals belonging thereto is arbitrarily determined by, for example, an operator.

  The operation schedule acquisition unit 220 generates the operation schedule data 120 based on an instruction of the input device 400 by the operator, operation schedule data of each terminal managed by another system, and the like.

  The operation schedule data 120 is data in which a terminal identifier, a time, and an operation schedule of the terminal at the time are associated with each other. For example, as shown in FIG. 5, the operation schedule data 120 is data in which a location identifier and a terminal identifier are associated with a date and an operation schedule on that date. In the example shown in FIG. 5, when “●” is set in the column specified by the terminal and time, this indicates that the terminal is scheduled to operate at this time, and when null is set, this terminal Indicates that it will not be operational at this time. The example shown in FIG. 5 indicates that the first terminal at the first location will be operational on December 1 and December 2, and will not be operational on December 3. In the example shown in FIG. 5, a case where an operation schedule is set for each day will be described. However, an operation schedule may be set for each hour, or an operation schedule may be set for any other time unit. good. The unit for setting the operation schedule preferably corresponds to the unit for calculating the difference between the plan and the actual measurement.

  The operation record acquisition unit 230 is a unit that acquires the operation record of each terminal. There are several ways to obtain operational results. For example, as shown in FIG. 2, the timing for transmitting the operation confirmation signal for acquiring the operation result may be set in the operation state collection terminal of each location, and the operation result data may be received from this operation state collection terminal. . Further, the power information management server 1 itself may transmit an operation confirmation signal to a terminal to be managed, acquire the operation state of the terminal, and generate operation result data.

  The operation result acquisition unit 230 acquires the operation state of the terminal determined based on whether or not the terminal has responded to the operation confirmation signal, the identifier of the terminal, the time when the operation confirmation signal is transmitted, The operation result data 130 in which the operation state at the time is associated with each other is stored. The operation result acquisition unit 230 includes an operation result acquisition request transmission unit 231 and an operation result storage unit 232.

  The operation result acquisition request transmission unit 231 corresponds to the process of step S1 in FIG. When the power information management server 1 itself transmits an operation confirmation signal, the operation result acquisition request transmission unit 231 transmits an operation confirmation signal to each terminal to be managed at a predetermined timing.

  The operation record storage unit 232 corresponds to the process of step S <b> 11 of FIG. 2, receives the operation record data 130 and stores it in the storage device 100. The operation result data 130 includes a result of the operation state acquisition terminal 10 determining whether or not the terminal is operating.

  Further, when the power information management server 1 itself transmits an operation confirmation signal, the operation result storage unit 232 determines whether or not the terminal is operating at that time. At this time, the operation result storage unit 232 determines the operation state of the terminal based on whether or not a response message is received within a predetermined time with respect to the operation confirmation signal transmitted to each managed terminal at a predetermined timing. To do. Furthermore, the operation record storage unit 232 generates the operation record data 130 by associating the identifier of the terminal, the time when the operation confirmation signal is transmitted, and the operation state at the time. Further, the operation result storage unit 232 stores the generated operation result data 13 in the storage device 100.

  The operation result data 130 is data shown in FIG. The operation result data 130 shown in FIG. 5 is data obtained as a result of transmitting a PING to the terminal to be managed every hour. The operation result data 130 shown in FIG. 6A indicates that at 0 o'clock, a PING is transmitted to the first terminal and a response “Success” is received. Also, a PING is transmitted to the second terminal at 0:00, the response timed out with “Request Time Out”, indicating that the PING command has not been processed by the second terminal.

  Further, the operation result acquisition unit 230 may generate the operation result data 131 shown in FIG. The operation result data 131 shown in FIG. 6B is generated from the operation result data 130 shown in FIG. For example, consider a case where an operation schedule is compared with an actual result on a daily basis. In this case, if a response to PING is received even once in a day, “●” is set assuming that the terminal is operating on this day, and null is set if no response has been received. To do. As illustrated in FIG. 6B, when the response “Success” is received even once for the PING transmitted to the first terminal on December 1, the operation record acquisition unit 230 displays the operation record data 131. “●” is set in the first terminal and the cell corresponding to December 1st. In the operation result data 131 generated in this way, the operation result is set in the same day unit as the operation schedule data 120 shown in FIG.

  The totaling unit 240 totals data based on the terminal data 110, the operation schedule data 120, and the operation result data 130, and generates total data 140. The totaling unit 240 includes a predictive difference extracting unit 241, an operation scheduled power totaling unit 240, and an operation result power totaling unit 240. The totaling unit 240 totals desired data according to a predetermined logic.

  The predictive difference extracting unit 241 compares the operation result data 130 and the operation schedule data 120, and associates the terminal identifier, the time, and the difference between the operation schedule and the operation state for the terminal at the time, thereby determining the operation estimate. Difference data 141 is generated. Predictive difference extraction means 241 identifies the difference based on the operation schedule data 120 shown in FIG. 5 and the operation result data 131 shown in FIG.

  Predictive difference extraction means 241 specifies, for example, a terminal that was not scheduled to operate and the date of operation, and associates the terminal identifier with the date of operation to generate operational predictive difference data 141. In this operation forecast actual difference data 141, null is set in the operation schedule data 120, but “●” is set in the cell corresponding to the terminal and the day for which “●” is set in the operation record data 131. In this case, null is set in other cells. In the data shown in FIG. 5 and FIG. 6 (b), the second terminal at the first location is operating although it was not scheduled to operate on December 1, so FIG. 7 (a) In the operation actual / difference data 141 shown, “●” is set.

  Predictive difference extraction means 241 identifies, for example, a terminal that was scheduled to operate but did not operate, and the date, and generates operational predictive difference data 141 by associating the terminal identifier with the date that did not operate. In this operation forecast actual difference data 141, “●” is set in the operation schedule data 120, but “●” is set in the cell corresponding to the terminal and day for which null is set in the operation record data 131. In this case, null is set in other cells. In the data shown in FIG. 5 and FIG. 6 (b), the first terminal at the first location is operating although it was not scheduled to operate on December 2, so FIG. 7 (b) In the operation actual / difference data 141 shown, “●” is set.

  As described above, the predictive difference extracting unit 241 can indicate whether or not the terminal is operating according to a predetermined schedule by extracting the difference between the operation schedule and the operation result for each unit time and each terminal. .

  Based on the terminal data 110 and the operation schedule data 120, the operation schedule power totalization unit 242 generates the operation schedule power data 142 in which the power consumption based on the operation schedule is calculated. Here, in the monitoring of the power consumption in consideration of the power supply status, the power consumption at the peak time is generally a problem. Therefore, the scheduled operation power totaling unit 242 may calculate a planned value of power consumption at the peak time. At that time, the scheduled operation power totaling means 242 may also display whether or not the planned power consumption value at the peak exceeds a predetermined upper limit value to prompt the operator to be alerted.

  Based on the operation schedule data 120, the operation schedule power totalization unit 242 generates the operation schedule power data 142 indicating the planned power consumption value at the peak of each day for each location. The scheduled operation power totalization unit 242 acquires power consumption per unit time from the terminal data 110 for all terminals belonging to a predetermined location. Further, the scheduled operation power totaling unit 242 adds up the power consumption of the terminals operating at the peak time to calculate the planned value of the power consumption at the predetermined location. When the planned power consumption values are calculated for all the locations, as shown in FIG. 8, the scheduled operation power data 142 in which the location identifiers, the day and the peak power consumption planned values are associated with each other is generated, and the storage device 100 To remember.

  The scheduled operation power totaling unit 242 can generate a graph as shown in FIG. 9 based on the scheduled operation power data 142. The graph shown in FIG. 9 indicates whether or not the power consumption at the peak of each day exceeds a predetermined upper limit value of power consumption. The graph shown in FIG. 9 displays the power consumption of the first location L1, the second location L2, the third location L3, and the fourth location L4 in an overlapping manner with a bar graph. Furthermore, by displaying the upper limit value of power consumption, it is possible to visually display whether or not the power consumption at the peak of each day exceeds the upper limit value. In the example shown in FIG. 9, the graph of adding the power consumption at the peak time of each location and comparing it with the upper limit value has been described, but when the upper limit value of power consumption is set for each location, for each location, A graph comparing the power consumption at the peak and the upper limit value may be generated.

  For each location of the terminal data 110, the operation result power totalization unit 243 calculates the power consumption of the location from the operation time of the terminal belonging to the location and the power consumption per unit time of the terminal, and the operation result power Store in data 143. Here, in the monitoring of the power consumption in consideration of the power supply status, the power consumption at the peak time is generally a problem. Therefore, the actual operation power totalization unit 243 may calculate the actual power consumption value at the peak time. At that time, the scheduled operation power totaling unit 242 may display whether or not the actual power consumption value at the peak exceeds a predetermined upper limit value, and may prompt the operator to be alerted.

  Based on the operation record data 130, the operation record power totaling unit 243 generates operation record power data 143 indicating the record value of power consumption at the peak of each day for each location. The operation result power totalization unit 243 acquires the power consumption per unit time from the terminal data 110 for all terminals belonging to a predetermined location. Further, the actual operation power totalizing unit 243 adds the power consumption of the terminals operating at the peak time to calculate the actual power consumption value at the predetermined location. When the actual power consumption values are calculated for all locations, as shown in FIG. 10, operation actual power data 143 is generated that associates the location identifier, the actual value of the power consumption at the day and the peak, and the storage device 100. To remember.

  Furthermore, the operation result power totaling means 243 can generate a graph as shown in FIG. 11 based on the operation planned power data 142 shown in FIG. 8 and the operation result power data 143 shown in FIG. The graph shown in FIG. 11 is data of a bar graph in which the planned value and the actual value are compared for the peak power consumption of each day. In this way, by comparing the planned value with the actual value and showing it in the graph, it is possible to visually indicate to the operator whether or not the power saving target has been achieved as planned.

  The output unit 250 is a unit that displays each data of the total data 140 on the output device 500. The output means 250 may display and display each data of the total data 140 on a data sheet by using spreadsheet software, or may display a graph as shown in FIG. 9 or FIG.

  The power information management system 5 according to the embodiment of the present invention periodically transmits a PING command to the terminals used in each location and holds the result. Here, the power information management system 5 determines that the terminal that has received the PING command is powered on, and determines that the terminal that has not reached the PING command is powered off. As described above, the power information management system 5 can easily obtain the operating state of each terminal according to the arrival status of the PING command. Furthermore, the power consumption for each location can be calculated by integrating the power consumption of the operating terminals for each location.

  Furthermore, the power information management system 5 according to the embodiment of the present invention visualizes whether or not an unplanned terminal is operating by comparing the terminal operation plan and the actual result to an operator or the like. Can show.

  Thus, for example, the power information management system 5 according to the embodiment of the present invention acquires the power state of a terminal belonging to the organization for each organization, and calculates the power consumption. As a result, it is possible to promote power saving so as to suppress the upper limit value of power consumption to a predetermined value for each organization, and to specifically manage power management such as minimizing power consumption.

  In addition, it grasps the operating status of each terminal and further grasps the power consumption for each location. Accordingly, it is possible to grasp the power consumption based on the logical position of the terminal, not the physical position of the terminal. Specifically, even if there are multiple departments in one office, or even if one department exists in multiple offices, the power consumption of the terminals belonging to each department can be integrated, so that Power consumption can be calculated.

  Individual data and functions may be realized by spreadsheet software data and macro functions. By implementing using general-purpose spreadsheet software, many terminals can be managed by the power information management system. Also, many modern terminals have a mechanism for responding to a PING command by connecting to a communication network in advance. Thereby, the power information management system 5 according to the embodiment of the present invention can easily perform power management without introducing a new mechanism on the terminal side.

(Other embodiments)
As described above, the embodiments of the present invention have been described. However, it should not be understood that the descriptions and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples, and operational techniques will be apparent to those skilled in the art.

  For example, the power information management server 1 described in the embodiment of the present invention may be configured on one piece of hardware as shown in FIG. 3, or on a plurality of pieces of hardware according to the functions and the number of processes. It may be configured. Moreover, you may implement | achieve on the existing information processing system.

  Further, when the data shown in FIGS. 5 to 7 and the like are stored in the data sheets of the spreadsheet software, the cells may be colored according to the data. For example, in the operation schedule data 120 shown in FIG. 4, a cell set with “●” may be colored red and a cell set with null may be colored green. Thereby, when data is displayed on the output device 500 by spreadsheet software, the visibility of the data can be improved.

  It goes without saying that the present invention includes various embodiments not described herein. Therefore, the technical scope of the present invention is defined only by the invention specifying matters according to the scope of claims reasonable from the above description.

DESCRIPTION OF SYMBOLS 1 Power information management server 2 Operation state collection server 3 Communication network 5 Power information management system 10 Operation state acquisition terminal 11, 12, 13, 14 ... Terminal 100 Storage device 110 Terminal data 120 Operation planned data 130 Operation result data 140 Total data 141 Actual operation difference data 142 Expected operation power data 143 Actual operation power data 200 Central processing control device 210 Target terminal information acquisition means 220 Operation schedule acquisition means 230 Operation result acquisition means 231 Operation result acquisition request transmission means 232 Operation result storage means 240 Aggregation means 241 Predictive difference extraction means 242 Operation planned power totaling means 243 Operation result power totaling means 250 Output means 300 Input / output interface 400 Input device 500 Output device 600 Communication control device

Claims (8)

A power information management system comprising a terminal and a power information management server connected to the terminal,
The power information management server
A storage device for storing terminal data that associates a location identifier for identifying a location of power management, an identifier of the terminal belonging to the location, and power consumption per unit time of the terminal;
Obtaining the operating state of the terminal determined based on whether or not the terminal responded to the operation confirmation signal, the identifier of the terminal, the time when the operation confirmation signal was transmitted, and the operating state at the time And operation result acquisition means for storing operation result data in association with
For each location of the terminal data, calculating means for calculating the power consumption of the location from the operating time of the terminal belonging to the location and the power consumption per unit time of the terminal, and storing it in the operating performance power data; Prepared,
The terminal
A power information management system comprising response means for responding to the operation confirmation signal when the operation confirmation signal is received during operation of the terminal. In the power information management server,
The storage device further stores operation schedule data in which the identifier of the terminal, time, and the operation schedule of the terminal at the time are associated with each other,
The counting means further includes
Comparing the operation result data with the operation schedule data, associating the terminal identifier, the time, and the difference between the operation schedule and the operation state for the terminal at the time, and storing them in the operation prediction actual difference data The power information management system according to claim 1. The power information management system according to claim 1 or 2, wherein the operation confirmation signal is transmitted to the terminal at a predetermined timing. The power information management system according to any one of claims 1 to 3, wherein the power information management server further includes output means for outputting the data stored by the counting means to an output device. A power information management method used in a power information management system including a terminal and a power information management server connected to the terminal,
The power information management server stores, in a storage device, terminal data that associates a location identifier for identifying a location to be managed with power, an identifier of the terminal belonging to the location, and power consumption per unit time of the terminal. And steps to
When the terminal receives an operation confirmation signal during operation of the terminal, a step of responding to the operation confirmation signal;
The power information management server acquires the operating state of the terminal determined based on whether or not the terminal responds to the operation confirmation signal, and transmits the terminal identifier and the operation confirmation signal. Storing operation result data in which the time and the operation state at the time are associated with each other in the storage device;
For each location of the terminal data, the power information management server calculates the power consumption of the location from the operation time of the terminal belonging to the location and the power consumption per unit time of the terminal, and the operation actual power data And storing the information in a power information management method. The power information management server storing operation schedule data in which the identifier of the terminal, the time, and the operation schedule of the terminal at the time are associated with each other in the storage device;
The power information management server compares the operation result data with the operation schedule data, associates the identifier of the terminal, the time, and the difference between the operation schedule and the operation state for the terminal at the time, The power information management method according to claim 5, further comprising the step of storing in the actual difference data. The power information management method according to claim 5 or 6, wherein the operation confirmation signal is transmitted to the terminal at a predetermined timing. The power information management method according to any one of claims 5 to 7, further comprising: the power information management server outputting the operation result power data to an output device.

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