JP2013207917A - Power control support program, power control support device, and power control support method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make minute power control possible depending on the state of power consumption.SOLUTION: With regard to a point P_3 in a graph 102, a power control support device 101 calculates a period target value Ec_3. Further, the power control support device 101 calculates an acquisition time interval on the basis of Ec_3, E_3, and an initial acquisition time interval. At the point P_3, E_3 is larger than the period target value Ec_3 and a measurement value must be acquired minutely. Therefore, the power control support device 101 calculates the acquisition time interval to be shorter than the initial acquisition time interval. Also, at a point P_8, the power control support device 101 calculates a period target value Ec_8. Further, the power control support device 101 calculates Ec_8, and an acquisition time interval on the basis of Ec_8 and the initial acquisition time interval. At the point P_8, E_8 is smaller than the period target value Ec_8 and there is some allowance. Therefore, the power control support device 101 calculates the acquisition time interval to be longer than the initial acquisition time interval.

Description

  The present invention relates to a power control support program, a power control support device, and a power control support method.

  Conventionally, there is a technique for monitoring the amount of power consumed in a predetermined period so as not to exceed the amount of power determined by the contracted power or the upper limit determined by the customer. For example, by making the calculation cycle of the prediction calculation variable according to the input power pulse, the power consumption amount is appropriately predicted, and an alarm is issued when the power consumption amount may exceed the power amount determined by the contract power. There is a technology to output.

  In addition, there is a technique for preventing the power consumption from being exceeded by performing control to limit the power consumption, such as turning off the power to some of the electrical equipment when the power consumption is likely to exceed the upper limit. As a related technique, for example, there is a technique that varies the time interval for calculating the instantaneous power based on the remaining power amount obtained by subtracting the power consumption amount from the upper limit. There is also a technique for shortening the time interval for measuring the amount of power when the power consumption increases rapidly. In addition, there is a technique for predicting a rate of change of electric energy and shortening a time interval when a specific time in a predetermined period has elapsed.

  In addition, when the time from the current time to the end time of the predetermined period is large, the power consumption is predicted based on the first reference value that is an average value of the increase in power consumption, and the time from the current time to the end time is short There is a technique for predicting the power consumption based on a second reference value larger than the first reference value. In addition, there is a technique for measuring the power transmission end power amount from the start time of a predetermined period to the present in the power generation apparatus and predicting the power transmission end power amount at the end time of the predetermined period when the power generation device has passed as it is. (For example, see the following Patent Documents 1 to 6.)

JP 2002-277493 A Japanese Patent Publication No. 1-54932 JP 2000-184590 A JP-A-2-228218 Japanese Patent No. 4346584 JP 2002-27669 A

  However, in the above-described conventional technology, it is difficult to determine the timing for performing power control according to the power consumption state. For example, if power control is performed at time intervals based on the remaining power amount, the power use restriction timing is delayed when the power amount exceeding the upper limit is consumed in the first half of the predetermined period. In addition, if power control is performed at time intervals based on power consumption, power consumption becomes moderate after power usage restriction, and the time interval for judging becomes longer, so the timing for canceling power usage restriction is delayed. End up.

  The present invention provides a power control support program, a power control support device, and a power control support method that can determine the timing for performing power control according to the power consumption state in order to solve the above-described problems caused by the prior art. For the purpose.

  In order to solve the above-described problem and achieve the object, according to one aspect of the present invention, a period from a start time of a predetermined period to a second time after a predetermined time has elapsed from a first time within the predetermined period The measured value of the amount of power consumed in the period is acquired, and the storage unit that stores the target value that should be lower than the amount of power consumed in the predetermined period is referred to, and the period is determined based on the predetermined period, the period, and the target value. A time interval from the second time to obtaining a new measured value of electric energy based on the calculated period target value, measured value, and predetermined time based on the calculated period target value that should be less than the amount of power consumed A power control support program, a power control support device, and a power control support method are proposed that output the calculated time interval.

  Advantageous Effects of Invention According to one aspect of the present invention, there is an effect that it is possible to determine the timing for performing power control according to the power consumption state.

FIG. 1 is an explanatory diagram illustrating an operation example of the power control support apparatus according to the present embodiment. FIG. 2 is a block diagram illustrating a system configuration example of the power control system. FIG. 3 is a block diagram illustrating an example of hardware of the power control support apparatus. FIG. 4 is an explanatory diagram showing an example of the stored contents of the power amount measurement value table. FIG. 5 is an explanatory diagram illustrating an example of a variable group used in the calculation process of the acquisition time interval. FIG. 6 is a block diagram illustrating a functional configuration example of the power control support device. FIG. 7 is an explanatory diagram illustrating an example of power usage restriction using the period target value as a criterion. FIG. 8 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the period target value. FIG. 9 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the first power calculation process. FIG. 10 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the second power calculation process. FIG. 11 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the third power calculation process. FIG. 12 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the fourth power calculation process. FIG. 13 is an explanatory diagram illustrating an example of timing at which power usage restriction and power usage restriction release are performed. FIG. 14 is a flowchart illustrating an example of an overall processing procedure of the power control system. FIG. 15 is a flowchart illustrating an example of an acquisition time interval calculation processing procedure. FIG. 16 is a flowchart showing a detailed example of the T calculation process (step S1509) shown in FIG. FIG. 17 is a flowchart showing another detailed example of the T calculation process (step S1509) shown in FIG.

  Exemplary embodiments of a disclosed power control support program, power control support device, and power control support method will be described below in detail with reference to the accompanying drawings.

  FIG. 1 is an explanatory diagram illustrating an operation example of the power control support apparatus according to the present embodiment. The power control support device 101 is a device that supports a device that controls the power of a device so that the amount of power consumed by the device during a predetermined period does not exceed a target value. Specifically, the power control support apparatus 101 acquires a measured value of the amount of power consumed in a period from the start time of a predetermined period to the second time after the predetermined time has elapsed from the first time within the predetermined period. To do. From the acquired measurement value and target value, the power control support apparatus 101 determines whether to control the device, and calculates a time interval from the second time until a new measurement value is acquired.

  If the time interval for acquiring a new measurement value is too long, the power usage limit will be delayed, and the user's convenience may be impaired by strengthening the power usage limit to avoid the delay in power usage limit. End up. Furthermore, if the power usage limit is delayed and the power consumption exceeds the target value of the power consumption for a predetermined period, the basic charge for power usage increases or the penal regulations are violated. Moreover, when the time interval for acquiring new measurement values is too short, the amount of communication required to acquire the measurement values increases. The power control support apparatus 101 according to the present embodiment calculates an appropriate time interval according to the situation.

  Hereinafter, the predetermined period is referred to as a “demand time period”. Further, the target value of the electric energy for a predetermined period is referred to as “demand value”. The predetermined time is referred to as “acquisition initial time”. The predetermined time interval is referred to as “acquisition initial time interval”. A time interval from the second time until a new measurement value is acquired is referred to as an “acquisition time interval”.

  A graph 102 is an example showing the relationship between the measurement value of the electric energy acquired by the power control support apparatus 101 and the acquisition time. The horizontal axis of the graph 102 indicates time. The vertical axis of the graph 102 indicates the amount of power. Point P_1 to point P_9 are a set of a measurement value of the electric energy acquired by the power control support apparatus 101 and an acquisition time of the measurement value. In addition, the time of P_n and the amount of power are indicated as T_n and E_n, respectively. n is an integer of 1 or more.

  As a premise of the graph 102, the power control support apparatus 101 acquires the power amount from the start time 12:00 to the end time when the demand time end ends at 12:30, assuming the demand time period as 30 minutes. Then. For the point P_1, the power control support apparatus 101 calculates a period target value Ec_1 that should be less than the amount of power consumed in the period from the start time to T_1. For example, the power control support apparatus 101 calculates the period target value by Ec_1 = demand value / demand time limit × (T_1−start time). As described above, the power control support apparatus 101 calculates the period target value based on the demand time period, the period from the start time to the acquisition time, and the demand value. A line segment drawn by a period target value corresponding to each time from the start time to the end time is represented as a line segment 103 in the graph 102.

  Subsequently, the power control support apparatus 101 calculates the acquisition time interval based on the period target value Ec_1, E_1, and the acquisition initial time interval. At point P_1, since E_1 is smaller than the period target value Ec_1 and there is a margin, the power control support apparatus 101 calculates the acquisition time interval longer than the acquisition initial time interval.

  Next, for the point P_3, the power control support apparatus 101 calculates a period target value Ec_3. Furthermore, the power control support apparatus 101 calculates the acquisition time interval based on the period target value Ec_3, E_3, and the initial acquisition time interval. At point P_3, since E_3 is larger than the period target value Ec_3 and the measurement value is desired to be obtained finely, the power control support apparatus 101 calculates the acquisition time interval shorter than the acquisition initial time interval. Further, at point P_3, the power control support apparatus 101 determines to control the device.

  Subsequently, for the point P_8, the power control support apparatus 101 calculates a period target value Ec_8. Furthermore, the power control support apparatus 101 calculates the acquisition time interval based on the period target value Ec_8, E_8, and the acquisition initial time interval. At point P_8, since E_8 is smaller than the period target value Ec_8 and there is room, the power control support apparatus 101 calculates the acquisition time interval longer than the acquisition initial time interval.

  As described above, the power control support apparatus 101 calculates the time interval until a new measurement value of the electric energy is acquired based on the period target value and the measurement value based on the target value of the predetermined period. As a result, the power control support apparatus 101 can perform fine power control according to the status of the acquisition time. For example, as shown in the graph 102, the power control support apparatus 101 calculates the acquisition time interval long between P_1 to P_3 and P8_P9 where there is a margin in power use, and acquires between P3 and P8 to be measured finely. Shorten the time interval. Hereinafter, the power control support apparatus 101 will be described in detail with reference to FIGS.

  FIG. 2 is a block diagram illustrating a system configuration example of the power control system. The power control system 200 includes a power control support device 101, a power control device 201, a distribution board 202, and a distribution board 203. The power control support device 101 and the power control device 201 to the distribution board 203 are connected to each other via a network 221. Moreover, the distribution board 202 and the distribution board 203 have the measuring device 211 and the measuring device 212, respectively.

  The power control apparatus 201 is an apparatus that controls the power of a device that consumes power. For example, the power control apparatus 201 sets the power of a device to which power is supplied from the distribution board 202 or the distribution board 203 to be off. Alternatively, the power control apparatus 201 may control power by partially limiting the operation of the device to which power is supplied. For example, the power control apparatus 201 controls the illuminance to be reduced if the device is illuminated. If the device is an air conditioner, the power control apparatus 201 raises the set temperature of cooling once.

  The distribution board 202 and the distribution board 203 supply power to devices that consume power. The distribution board 202 and the distribution board 203 supply power to, for example, equipment in the factory. The measuring instrument 211 and the measuring instrument 212 measure the amount of power consumed by a device that consumes power. The measuring instrument 211 and the measuring instrument 212 measure the amount of power by, for example, counting pulses generated in proportion to the power.

  Note that the power control support apparatus 101 is not included in the power control system 200, and the power control apparatus 201 may execute software for executing a power control support program. Further, the power control support apparatus 101 may have a measuring instrument. The network 221 is, for example, a LAN (Local Area Network), a WAN (Wide Area Network), or the Internet.

(Hardware of power control support apparatus 101)
FIG. 3 is a block diagram illustrating an example of hardware of the power control support apparatus. In FIG. 3, the power control support apparatus 101 includes a CPU (Central Processing Unit) 301, a ROM (Read-Only Memory) 302, and a RAM (Random Access Memory) 303. The power control support device 101 includes a magnetic disk drive 304, a magnetic disk 305, and an IF (Interface) 306. Each unit is connected by a bus 307.

  The CPU 301 is an arithmetic processing device that governs overall control of the power control support apparatus 101. The ROM 302 is a nonvolatile memory that stores programs such as a boot program. A RAM 303 is a volatile memory used as a work area for the CPU 301. The magnetic disk drive 304 is a control device that controls reading / writing of data with respect to the magnetic disk 305 according to the control of the CPU 301. The magnetic disk 305 is a non-volatile memory that stores data written under the control of the magnetic disk drive 304. Note that the power control support program according to the embodiment may be stored in any of the storage devices of the ROM 302 and the magnetic disk 305.

  The IF 306 is connected to another device via the network 221 through a communication line. The IF 306 controls an internal interface with the network 221 and controls input / output of data from an external device. For example, a modem or a LAN adapter can be adopted as the IF 306.

  When the administrator of the power control support apparatus 101 directly operates the power control support apparatus 101, the power control support apparatus 101 is not illustrated in FIG. 3, but the power control support apparatus 101 includes an optical disc drive, an optical disc, a display, and a keyboard. And a mouse.

  The optical disc drive is a control device that controls reading / writing of data with respect to the optical disc according to the control of the CPU 301. The optical disk stores data written under the control of the optical disk drive, and allows the computer to read data stored on the optical disk.

  The display displays data such as a document, an image, and function information as well as a cursor, an icon, or a tool box. For example, a CRT, a TFT liquid crystal display, a plasma display, or the like can be adopted as the display.

  The keyboard has keys for inputting characters, numbers, various instructions, etc., and inputs data. The keyboard may be a touch panel type input pad or a numeric keypad. The mouse moves the cursor, selects a range, or moves and changes the size of the window. Further, the power control support apparatus 101 may be a trackball or a joystick as long as it has the same function as a pointing device instead of a mouse. Next, an electric energy measurement value table in a storage area such as the RAM 303 or the magnetic disk 305 will be described.

  FIG. 4 is an explanatory diagram showing an example of the stored contents of the power amount measurement value table. The electric energy measurement value table 401 is a table that stores electric energy measurement values for each time. The power amount measurement value table 401 illustrated in FIG. 4 stores records 401-1 to 401-14. The electric energy measurement value table 401 includes two fields of time and measurement value. In the time field, the time when the measured value of the electric energy is acquired is stored. In the time field, the time when the measuring device 211 or the measuring device 212 measures the amount of electric power may be stored. The measured value field stores a measured value of the electric energy within the demand time limit.

  For example, the record 401-1 indicates that the measurement value of the electric energy is 0 [W hour] at 12: 00: 00: 00 as the demand time limit start time. Further, the record 401-2 indicates that the measurement value of the electric energy is 50 [hours] at 12:01:00.

  FIG. 5 is an explanatory diagram illustrating an example of a variable group used in the calculation process of the acquisition time interval. In FIG. 5, a variable group used for the acquisition time interval calculation process will be described using a graph 501. The horizontal axis of the graph 501 indicates time. The vertical axis of the graph 501 indicates the amount of power.

  Td indicates a demand time limit. T_o indicates the start time of the current demand time period. T_n indicates the time at which the n-th power measurement is performed in the current demand period. n is an integer of 1 or more. t_n indicates T_n-T_o. tc is a time threshold value for determining whether or not the current time is an early stage of the current demand period. Ts indicates an acquisition initial time interval. For example, Ts = T_1−T_o. T represents an acquisition time interval from T_n to the next power measurement time.

  Emax indicates a demand value that is an upper limit of power consumption in the demand time period. E_n indicates the measured value of the n-th power amount in the current demand time period. Ec represents a period target value. Ec is obtained by, for example, Ec = Emax × t_n / Td. M is a power amount threshold value to be compared with the remaining power amount.

  A indicates the remaining electric energy obtained by subtracting E_n from Emax. B is the amount of change in the electric energy per unit time from the electric energy E_ (n−1) to E_n measured at the (n−1) th time. B is obtained by, for example, B = (E_n−E_ (n−1)) / (T_n−T_ (n−1)). C indicates the electric energy obtained by subtracting E_n from Ec.

(Functional configuration of power control support apparatus 101)
Next, the functional configuration of the power control support apparatus 101 will be described. FIG. 6 is a block diagram illustrating a functional configuration example of the power control support device. The power control support apparatus 101 includes an acquisition unit 601, a first calculation unit 602, a third calculation unit 603, a second calculation unit 604, and an output unit 605. The acquisition unit 601 to the output unit 605 serving as the control unit realize the functions of the acquisition unit 601 to the output unit 605 when the CPU 301 executes a program stored in the storage device. Specifically, the storage device is, for example, the ROM 302, the RAM 303, the magnetic disk 305, etc. shown in FIG. Alternatively, the functions of the acquisition unit 601 to the output unit 605 may be realized by being executed by another CPU via the IF 306.

  The acquisition unit 601 uses power consumed in a period from the start time T_o of the demand time period Td to the second time T_n when the acquisition initial time interval Ts has elapsed from the first time T_ (n−1) within the demand time period. A measurement value E_n of the quantity is acquired. For example, the acquisition unit 601 acquires the measurement value E_n of the electric energy consumed in the period from 12:00 that is the start time to 12:01:00 that is the first time and the second time T_n. To do.

  The acquisition unit 601 may acquire the measurement value by making an acquisition request to the measuring device 211 or the measuring device 212. Alternatively, the power control support apparatus 101 stores the measurement value notified by the measuring device 211 or the measuring device 212 at the acquisition initial time interval Ts in the power amount measurement value table 401, and the acquisition unit 601 measures the power amount. Measurement values may be acquired from the value table 401. Further, the acquisition unit 601 may acquire a past measurement value E_i and a past acquisition time T_i (i = 1,..., N). With the function of the acquisition unit 601, the power control support apparatus 101 can detect an acquisition time interval calculation trigger. The acquired measurement values are stored in a storage area such as the RAM 303 and the magnetic disk 305.

  The first calculation unit 602 refers to a storage unit that stores a demand value Emax that should be less than the amount of power consumed in the demand time period Td. Based on the demand time period Td, the period t_n, and the demand value Emax, A period target value Ec that should be less than the amount of power consumed is calculated. The storage unit is, for example, a RAM 303, a magnetic disk 305, or the like. For example, the first calculation unit 602 calculates the period target value Ec according to the following equation (1-1).

  Ec = Emax × t_n / Td (1-1)

  If the equation (1-1) is used, the first calculation unit 602 calculates a target value such that the power consumed during the demand time period is always constant. The calculation unit 602 may calculate according to the following equation (1-2).

  Ec = (Emax / 2) × t_n / Td + Emax / 2 (1-2)

  When the first calculation unit 602 calculates according to the equation (1-2), the target time period target value for the demand time period is calculated as Emax / 2, and the target time period end time target value is calculated as Emax. The first calculation unit 602 may also calculate according to the following formula (1-3).

  Ec = −Emax / Td ^ 2 × (t_n−Td) ^ 2 + Emax (1-3)

  When the first calculation unit 602 calculates according to the expression (1-3), the curve drawn by the period target value has a period target value of 0 at the start time of the demand time period, the end time of the demand time period as a vertex, and the end time It becomes a parabola whose period target value is Emax. With the function of the acquisition unit 601, the power control support apparatus 101 can calculate a target value corresponding to each time. The calculated period target value is stored in a storage area such as the RAM 303 and the magnetic disk 305.

  When the acquisition unit 601 acquires the measurement value E_n, the third calculation unit 603 calculates the predicted power W after the second time based on the period t_n and the measurement value E_n. For example, the third calculation unit 603 calculates the predicted power W according to the following equation (2-1).

  W = E_n / t_n (2-1)

  In addition, the third calculation unit 603 refers to the previous measurement value E_ (n−1) and the acquisition time T_ (n−1) acquired by the acquisition unit 601, and the following equation (2-2) Thus, the predicted power W may be calculated.

  W = (E_n-E_ (n-1)) / (T_n-T_ (n-1)) (2-2)

  Further, the third calculation unit 603 calculates the power of the past maximum value with reference to the past measurement value E_i and the past acquisition time T_i (i = 1,..., N) acquired by the acquisition unit 601. And it is good also as prediction electric power. In addition, the third calculation unit 603 may create a power time-series model by referring to the past measurement value and the past acquisition time, and calculate the predicted power W. Further, the third calculation unit 603 refers to the past measurement value and the past acquisition time, detects a partial data string that is similar to the end data string having a preset length, and continues to the detected partial data string. May be calculated as the predicted power W. The third calculation unit 603 can use the predicted power to calculate the acquisition time interval to a value that is more realistic. The calculated predicted power is stored in a storage area such as the RAM 303 and the magnetic disk 305.

  The second calculation unit 604 generates power from the second time T_n based on the period target value Ec calculated by the first calculation unit 602, the measurement value E_n acquired by the acquisition unit 601 and the acquisition initial time interval Ts. The acquisition time interval T until the new measurement value E_ (n + 1) of the quantity is acquired is calculated. For example, the second calculation unit 604 may calculate the acquisition time interval T according to the following equation (3-1).

  T = Ts × Ec / E_n (3-1)

  The second calculation unit 604 may calculate the acquisition time interval T shorter than the acquisition initial time interval Ts when the measurement value E_n is larger than the period target value Ec. For example, when E_n> Ec, the second calculation unit 604 may calculate the acquisition time interval T according to the following expression (3-2).

  T = Ts / (5-4 (E_n-Ec) / Ec) (3-2)

  The second calculation unit 604 may calculate the acquisition time interval T longer than the acquisition initial time interval Ts when the measurement value is smaller than the period target value. Further, the second calculation unit 604 is based on the period target value Ec, the measurement value E_n, the demand time limit Td, the demand value Emax, and the predicted power W calculated by the third calculation unit 603, which are calculated by the first calculation unit 604. Thus, the acquisition time interval T may be calculated. For example, the second calculation unit 604 may calculate the acquisition time interval T according to the following equation (3-3).

  T = (E_n−Ec) / (W− (Emax / Td)) (3-3)

  With the function of the second calculation unit 604, the power control support apparatus 101 can calculate an appropriate acquisition time interval according to the situation. The calculated acquisition time interval is stored in a storage area such as the RAM 303 and the magnetic disk 305.

  The output unit 605 outputs the calculated acquisition time interval. For example, the output unit 605 outputs the acquisition time interval T to the storage area of the power control support apparatus 101. The output unit 605 may output the acquisition time interval T to the measuring device 211 or the measuring device 212. For example, the measuring device 211 and the measuring device 212 that have received the acquisition time interval T may transmit the measurement value to the power control support apparatus 101 after the acquisition time interval T expires.

  FIG. 7 is an explanatory diagram illustrating an example of power usage restriction using the period target value as a criterion. A graph 701 shows the range of power usage restriction. For example, since the measured value E_1 is larger than the period target value Ec_1 at the point P_1, the power control support apparatus 101 determines that power control is performed, and issues a control request to the power control apparatus 201. Further, since the measured value E_2 is smaller than the period target value Ec_2 at the point P_2, the power control support apparatus 101 determines that the power control is to be released, and issues a control release request to the power control apparatus 201. As a result, the power use restriction time is from T_1 to T_2.

  FIG. 8 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the period target value. A graph 801 shows the vicinity of the nth measurement amount and the point P_n (T_n, E_n) of the measurement time. The horizontal axis of the graph 801 indicates time. The vertical axis of the graph 801 indicates the amount of power. A line 802 indicates a period target value at each time. The slope of the line 802 can be calculated by Wd = Emax / Td. A line 803 is a line indicating the electric energy when the predicted electric power after measurement of the n-th electric energy is W. At this time, the power control support apparatus 101 calculates the acquisition time interval T using the following equation (4-1).

  T = C / (γ (W−Wd)) (4-1)

  Note that γ is a constant of 1 or more. γ is a value that can be freely set by the user of the power control system 200. For example, the example of FIG. 8 shows an example of the acquisition time interval when γ = 4. As described above, since the power control support apparatus 101 can calculate an appropriate acquisition time interval T even when the change in the power amount is large, the power control system 200 weakens the power use limit or shortens the power amount limit time. You can. Next, a calculation example of the acquisition time interval using the first to fourth calculation processes of the predicted power W will be described with reference to FIGS. 9 to 12.

  FIG. 9 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the first power calculation process. The first method of the power calculation process is a method of calculating the predicted power W using the power from the previous measurement time to the current measurement time. A graph 901 shows the vicinity of P_ (n−1) (T_ (n−1), E_ (n−1)) and P_n (T_n, E_n) indicating the n−1th measurement amount and measurement time. The horizontal axis of the graph 901 indicates time. The vertical axis of the graph 901 indicates the amount of power. The power control support apparatus 101 calculates the predicted power W using the following equation (5-1).

  W = (E_n-E_ (n-1)) / (T_n-T_ (n-1)) (5-1)

  Thus, since the power control support apparatus 101 can calculate an appropriate acquisition time interval T even in the case where the amount of power increases rapidly, the power control system 200 weakens the power usage limit or limits the time limit. Can be shortened.

  FIG. 10 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the second power calculation process. The second method of the power calculation process is a method of setting the predicted power W to the past maximum power. FIG. 10A shows a method of calculating power at each time. The horizontal axis of the graph 1001 indicates time. The vertical axis of the graph 1001 indicates the amount of power. For example, the power consumption when measured i-th can be calculated by the following equation (6-1).

  W_i = (E_ (i + 1) −E_i) / (T_ (i + 1) −T_i) (i = 1,..., N−1) (6-1)

  Subsequently, the power control support apparatus 101 calculates the predicted power W using the following equation (6-2).

  W = max (W_1,..., W_ (n-1)) (6-2)

  The function max () is a function that returns the maximum value of the argument. In FIG. 10B, a graph 1002 indicates the maximum power among W_1 to W_ (n−1). The horizontal axis of the graph 1002 indicates time. The vertical axis of the graph 1002 indicates the amount of power. A graph 1002 indicates that the power is maximum at time T_a.

  A graph 1003 illustrated in FIG. 10C illustrates an example in which the acquisition time interval is calculated using the past maximum power. The horizontal axis of the graph 1003 indicates time. The vertical axis of the graph 1003 indicates the amount of power. In this way, the power control support apparatus 101 calculates the acquisition time interval using the past maximum power, so that the power control system 200 calculates the appropriate acquisition time interval T even when a sudden increase in the amount of power occurs. It is possible to reduce the power usage limit or shorten the time limit.

  FIG. 11 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the third power calculation process. The third method of the power calculation process is a method for estimating the predicted power W from the time series model. A graph 1101 shown in FIG. 11A is a graph showing a time series Wp of power for each time dt. The power control support apparatus 101 uses the following equation (7-1) to calculate the power time series Wp_1,... Wp_t for each time dt from the past measurement values (T_i, E_i) (i = 1,..., N). ,..., Wp_ (nt-1) (t = 1,..., Nt-1) are calculated.

  Wp_t = (E_ (j + 1) −E_j) / (T_ (j + 1) −T_j) (7-1)

  However, the variable of (7-1) follows the following formula (7-2), (7-3), and (7-4).

T_j ≦ T_1 + dt × (t−1) <T_ (j + 1) (7-2)
dt = min (T_2−T_1,..., T_ (i + 1) −T_i,..., T_ (nt−1) −T_ (nt−2)) (7-3)
nt = (T_n-T_1) / dt (7-4)

  However, the function min () is a function that returns the minimum value of the argument. Subsequently, the power control support apparatus 101 creates a time series model from the time series Wp_t. The time series model is, for example, an ARMA (AutoRegressive Moving Average) model. As an example using ARMA, equation (7-5) is shown below.

  Wp_t = m + Σ (φ_i × Wp_ (t−i)) + a_t + Σ (θ_j × a_ (t−j)) (7-5)

  m is an average value of electric power. φ and θ are weights. Further, a_t follows the following relational expression (7-6).

  a_t to N (0, σ ^ 2) (7-6)

  However, (sigma) shows a standard deviation and N () shows a normal distribution. Next, a graph 1102 shown in FIG. 11B is a graph obtained by calculating the predicted power Wp_nt using ARMA. In addition, a graph 1103 illustrated in FIG. 11C illustrates an example in which the acquisition time interval is calculated using ARMA. As described above, the power control support apparatus 101 predicts the power from the time series model, so that the power control system 200 can calculate an appropriate acquisition time interval T even when there is a regularity strong in the power amount change, You can weaken the usage limit or shorten the time limit.

  FIG. 12 is an explanatory diagram illustrating an example of calculating the acquisition time interval using the fourth power calculation process. The fourth method of the power calculation process is a method of calculating the predicted power W from a similar portion of the past power time series. The power control support apparatus 101 uses the equation (7-1) to calculate the power time series Wp_t (t = 1,..., Nt−) from the past measurement values (T_i, E_i) (i = 1,..., N). 1) is determined. Subsequently, the power control support apparatus 101 has a partial data sequence in which the distance D_v from the end data sequence Wp_ (nt−u),..., Wp_ (nt−1) having a predetermined length u with respect to the time series Wp_t is minimized. Wp_ (nt−v−u),..., Wp_ (nt−v−1) (v> 0) are obtained. Here, the distance D_v indicates the degree of difference between the two data strings. The power control support apparatus 101 may obtain the distance D_v by the following equation (8-1), for example.

  D_v = Σ (Wp_ (n−v−u + i) −Wp_ (n−u + i)) ^ 2 (8-1)

  FIG. 12A shows an example in which the minimum D_v is obtained on the graph 1201 using the equation (8-1). The power control support apparatus 101 calculates the next value Wp_ in Wp_t at the end Wp_ (n−v−1) of the obtained partial data string Wp_ (n−v−u),..., Wp_ (n−v−1). (N−v) is predicted to be the predicted power Wp_nt, and Wp_nt is set as the predicted power W.

  A graph 1202 illustrated in FIG. 12B illustrates an example in which the acquisition time interval is calculated using the power obtained from the most similar time series. As described above, the power control support apparatus 101 sets an appropriate acquisition time interval T even if the power amount change rarely occurs if the power amount change similar to the past has been performed. It can be calculated. Therefore, the power control system 200 can weaken the power usage limit or shorten the time limit.

  FIG. 13 is an explanatory diagram illustrating an example of timing at which power usage restriction and power usage restriction release are performed. A graph 1301 shown in FIG. 13 shows a part of a graph of time and electric energy. The horizontal axis of the graph 1301 indicates time. The vertical axis of the graph 1301 indicates the amount of power. A line 1302 is a line indicating the period target value. The upper left portion of the line 1302 is an area where the measured value exceeds the period target value and the amount of power should be limited. The lower right portion of the line 1302 is an area where the measured value is less than the period target value and the amount of power does not have to be limited. Hereinafter, the area where the amount of power should be limited is referred to as “excess area”. An area where the amount of power need not be limited is referred to as a “safe area”.

  The points P_1 and P_2 in the graph 1301 are located in the excess region. The time interval O_1 and the time interval O_2 indicate the excess detection delay time from the period target value. In addition, when the power usage restriction is performed at the time of the point P_1, two points whose measured values are below the period target value and are located in the safe area are indicated as a point P_1A and a point P_1B.

  Further, a line segment drawn by the measurement value after the power use restriction when the power use restriction is performed at the time of the point P_1 is indicated as L_1. Further, the power usage limit time from the detection of exceeding the period target value to the safety detection is indicated as D_1A at the point P_1A and as D_1B at the point P_1B. Also, the detection delay time for canceling power control at point P_1A is indicated as R_1A, and the detection delay time for canceling power control at point P_1B is indicated as R_1B.

  In addition, when the power usage restriction is performed at the time of the point P_2, the measurement value when the restriction content after the power usage restriction is the same as the restriction content performed after the power usage restriction at the time of the point P_1 is the same. The drawn line segment is indicated as L_2A. Furthermore, a point where the measured value falls below the period target value and is located in the safe region when the power usage is limited so as to be the line segment L_2A at the time of the point P_2 is indicated as a point P_2A. In addition, the power usage limit time from the detection of exceeding the period target value to the safety detection at the point P_2A is indicated as D_2A. Further, the detection delay time for canceling the power control at the point P_2A is indicated as R_2A.

  In addition, when the power usage restriction is performed at the time of the point P_2, the restriction content after the power usage restriction is stronger than the restriction content performed after the power usage restriction at the time of the point P_1. A line segment drawn by the measurement value is indicated as L_2C. Further, a point where the measured value falls below the target value for the period and is located in the safe region when the power usage is limited so as to be the line segment L_2C at the time of the point P_2 is indicated as a point P_2C. In addition, the power use limit time from the detection of exceeding the period target value to the safety detection at the point P_2C is indicated as D_2C. Further, the detection delay time for canceling the power control at the point P_2C is indicated as R_2C.

  When the restriction contents of the power use restriction are the same as indicated by L_1 and L_2A, the power use restriction time becomes shorter as O_1 with a shorter excess detection time than O_2, as can be seen from D_1A <D_2A on the graph 1301. .

  As can be seen from D_2C <D_2A on the graph 1301, the power control system 200 increases the power usage limit in order to reduce the power usage limit time when the excess detection is delayed. When the power control system 200 increases the power usage restriction, such as when the number of power-off target devices is large, the slope of the line segment drawn by the measurement value approaches horizontal. For example, when the power control system 200 turns off all power supplies, the line segment drawn by the measurement value is parallel to the time axis. As described above, if the excess detection is delayed, the power usage limit is strengthened. Therefore, if the excess detection can be performed early, the power usage limit can be weakened.

  Further, when it can be detected early that the period target value has been exceeded, as in the magnitude relationship in which R_1A <R_1B on the graph 1301, the magnitude relationship in which D_1A <D_1B on the graph 1301 is shown, The time limit for use can be shortened. Next, a flowchart of the power control system 200 is shown in FIGS.

  FIG. 14 is a flowchart illustrating an example of an overall processing procedure of the power control system. The measuring device 211 and the measuring device 212 measure the electric energy (step S1401). Next, the measuring instrument 211 and the measuring instrument 212 record the measurement value and time of the electric energy (step S1402). The recording destination may be the storage area of the measuring instrument 211 and the measuring instrument 212, or the measuring instrument 211 and the measuring instrument 212 may transmit the measured value of the electric energy and the time to the power control supporting apparatus 101, resulting in the power control supporting apparatus. 101 may be recorded in the power amount measurement value table 401 in the 101.

  Subsequently, the power control support apparatus 101 calculates the acquisition time interval T (step S1403). Details of the processing in step S1403 will be described later with reference to FIG. Next, the power control apparatus 201 controls the power of the device (step S1404). Regarding the processing in step S1404, for example, when receiving a request for restricting power use from the power control support apparatus 101, the power control apparatus 201 performs control so as to limit the power of the device. In addition, when the power control apparatus 201 receives a request for canceling the power use restriction from the power control support apparatus 101, the power control apparatus 201 performs control so as to release the restriction on the power of the device.

  Further, the power control apparatus 201 may perform control so as to limit the power of the device when the acquisition time interval T calculated by the power control support apparatus 101 is smaller than the acquisition initial time interval Ts. Further, the power control apparatus 201 may perform control so as to release the power limit of the device when the acquisition time interval T is larger than the acquisition initial time interval Ts and the power use limit is performed.

  After execution of step S1404, power control system 200 waits for time T (step S1405). After the elapse of time T, the power control system 200 proceeds to the process of step S1401. By executing the entire process of the power control system, the power control system 200 can acquire measurement values at appropriate acquisition time intervals according to the situation.

  FIG. 15 is a flowchart illustrating an example of an acquisition time interval calculation processing procedure. The acquisition time interval calculation process is a process for calculating the acquisition time interval T. The power control support apparatus 101 acquires the latest measurement time T_n and the latest measurement value E_n, and the previous time T_ (n−1) and the previous measurement value E_ (n−1) (step S1501). Next, the power control support apparatus 101 determines whether or not the remaining power amount A is smaller than the power amount threshold value M (step S1502). If the remaining power amount A is smaller than the power amount threshold value M (step S1502: Yes), the power control support apparatus 101 sets T to the return value of fa (A) (step S1503). The function fa () is a function that returns a smaller value of 0 or more as A is smaller. For example, the function fa () follows the following equation (9-1).

  fa (A) = Ts / (10−5 × A / M) (9-1)

  If the remaining power amount A is equal to or greater than the power amount threshold value M (step S1502: No), the power control support apparatus 101 continues to determine whether t_n is smaller than the time threshold value tc (step S1503). When t_n is smaller than tc (step S1504: Yes), the power control support apparatus 101 determines whether or not the power B is larger than the target power Wd (step S1505). When B is larger than Wd (step S1505: Yes), the power control support apparatus 101 sets T to the return value of fb (B, Wd) (step S1506). The function fb is a function that returns a smaller value as the difference between B and Wd is larger. For example, the function fb follows the equation (9-2) below.

  fb (B, Wd) = Ts / (B−Wd + 1) (9-2)

  When B is less than or equal to Wd (step S1505: No), the power control support apparatus 101 sets T to the acquisition initial time interval Ts (step S1507). When t_n is greater than or equal to tc (step S1504: No), the power control support apparatus 101 calculates a period target value Ec (step S1508). Subsequently, the power control support apparatus 101 calculates T based on E_n and Ec (step S1509). After completing the execution of step S1503, step S1506, step S1507, or step S1509, the power control support apparatus 101 outputs T (step S1510). After the end of step S1510, the power control support apparatus 101 ends the acquisition time interval calculation process. By executing the acquisition time interval calculation process, the power control support apparatus 101 can calculate an appropriate acquisition time interval according to the situation.

  FIG. 16 is a flowchart showing a detailed example of the T calculation process (step S1509) shown in FIG. The power control support apparatus 101 calculates C from Ec-E_n (step S1601). Next, the power control support apparatus 101 determines whether C is smaller than βEc (step S1602). β is a value that is preset between 0 and 1 by the designer of the power control system 200 or the user of the power control system 200. When C is smaller than βEc (step S1602: Yes), the power control support apparatus 101 sets T to the return value of fc (C, βEc) (step S1603). The function fc () is a function that returns a smaller value as C is smaller than βEc. For example, the function fc () may follow the following equation (10-1).

  fc (C, βEc) = Ts / (5-4 × C / (βEc)) (10-1)

  When C is equal to or greater than βEc (step S1602: No), the power control support apparatus 101 sets T to Ts (step S1604). After completing the execution of step S1603 or step S1604, the power control support apparatus 101 ends the process illustrated in FIG.

  FIG. 17 is a flowchart showing another detailed example of the T calculation process (step S1509) shown in FIG. The power control support apparatus 101 calculates C from Ec-E_n (step S1701). Next, the power control support apparatus 101 determines whether C is greater than 0 (step S1702). When C is 0 or less (step S1702: No), the power control support apparatus 101 sets T to the return value of fc (C, βEc) (step S1703). When C is larger than 0 (step S1702: Yes), the power control support apparatus 101 calculates the predicted power W (step S1704). Subsequently, the power control support apparatus 101 sets T to the result of C / (γ (W−Wd)) (step S1705). After completing the execution of step S1703 or step S1705, the power control support apparatus 101 ends the process shown in FIG.

  As described above, according to the power control support apparatus 101, the time interval until a new measurement value of power is acquired is calculated based on the period target value and the measurement value based on the target value for a predetermined period. As a result, the power control support apparatus 101 can perform fine power control according to the status of the acquisition time. The period target value may be any value as long as the period t_n increases monotonically between 0 and the demand time limit Td.

  For example, the power control support apparatus 101 may calculate the period target value according to the equation (1-1). When the equation (1-1) is followed, the power control system 200 can use power without bias within the demand time limit. Further, the power control support apparatus 101 may calculate the period target value according to the expression (1-2) or the expression (1-3). When the equation (1-2) or (1-3) is followed, the power control system 200 can consume a large amount of power in the first half of the demand time period, and uses fine power that does not exceed the demand value in the second half of the demand time period. Restrictions can be made.

  Further, according to the power control support apparatus 101, when the measured value is larger than the period target value, the acquisition time interval may be calculated to be shorter than the acquisition initial time. If the power consumption is continued while the measured value is larger than the target value for the period, the demand value is exceeded, and the power control apparatus 201 performs power limitation. By calculating the acquisition time interval shorter than the initial acquisition time, the detection timing that the measured value exceeds the target value and the detection timing that the measured value falls below the target value become early, and power usage restrictions are imposed. Since it can be shortened, a decrease in user convenience can be suppressed.

  Further, according to the power control support device 101, when the measurement value is smaller than the period target value, the acquisition time interval may be calculated to be longer than the acquisition initial time. When the measured value is smaller than the period target value, there is a margin, so the power control support apparatus 101 increases the communication amount required for acquiring the measured value by making the acquisition time interval longer than the acquisition initial time interval. Can be reduced.

  Further, according to the power control support apparatus 101, the predicted power may be calculated, and the acquisition time interval may be calculated using the period target value, the measured value, the demand time limit, the demand value, and the predicted power. As a result, the power control support apparatus 101 acquires the measurement value at a timing at which the measurement value can be predicted to exceed the period target value, and thus can be detected immediately after the measurement value exceeds the period target value. .

  The power control support method described in this embodiment can be realized by executing a program prepared in advance on a computer such as a personal computer or a workstation. The power control support program is recorded on a computer-readable recording medium such as a hard disk, a flexible disk, a CD-ROM, an MO, and a DVD, and is executed by being read from the recording medium by the computer. The power control support program may be distributed through a network such as the Internet.

  The following additional notes are disclosed with respect to the embodiment described above.

(Supplementary note 1)
Obtaining a measured value of the amount of power consumed in a period from the start time of the predetermined period to the second time after the predetermined time has elapsed from the first time within the predetermined period;
With reference to a storage unit that stores a target value that should be lower than the amount of power consumed in the predetermined period, the amount of power consumed in the period is determined based on the predetermined period, the period, and the target value. Calculate the period target value to be below,
Based on the calculated period target value, the measured value, and the predetermined time, calculate a time interval from the second time until a new measured value of the electric energy is acquired,
Outputting the calculated time interval;
A power control support program characterized by causing a process to be executed.

(Supplementary Note 2) The process of calculating the time interval is as follows:
The power control support program according to appendix 1, wherein the time interval is calculated to be shorter than the predetermined time when the measured value is larger than the period target value.

(Supplementary Note 3) The process of calculating the time interval is as follows:
The power control support program according to appendix 1, wherein the time interval is calculated to be longer than the predetermined time when the measured value is smaller than the period target value.

(Supplementary note 4)
When the measurement value is acquired, the predicted power after the second time is calculated based on the period and the measurement value,
The process for calculating the time interval includes:
4. The time interval is calculated based on the calculated period target value, the measured value, the predetermined period, the target value, and the calculated predicted power. Power control support program.

(Additional remark 5) The acquisition part which acquires the measured value of the electric energy consumed in the period from the start time of a predetermined period to the 2nd time when the predetermined time passed from the 1st time in the predetermined period;
With reference to a storage unit that stores a target value that should be lower than the amount of power consumed in the predetermined period, the amount of power consumed in the period is determined based on the predetermined period, the period, and the target value. A first calculation unit for calculating a period target value to be below;
Based on the period target value, the measurement value, and the predetermined time calculated by the first calculation unit, a time interval from the second time until a new measurement value of the electric energy is acquired is calculated. A second calculation unit that
An output unit that outputs the time interval calculated by the second calculation unit;
A power control support device comprising:

(Appendix 6)
Obtaining a measured value of the amount of power consumed in a period from the start time of the predetermined period to the second time after the predetermined time has elapsed from the first time within the predetermined period;
With reference to a storage unit that stores a target value that should be lower than the amount of power consumed in the predetermined period, the amount of power consumed in the period is determined based on the predetermined period, the period, and the target value. Calculate the period target value to be below,
Based on the calculated period target value, the measured value, and the predetermined time, calculate a time interval from the second time until a new measured value of the electric energy is acquired,
Outputting the calculated time interval;
A power control support method characterized by executing processing.

101 power control support device 601 acquisition unit 602 first calculation unit 603 third calculation unit 604 second calculation unit 605 output unit

Claims (6)

On the computer,
Obtaining a measured value of the amount of power consumed in a period from the start time of the predetermined period to the second time after the predetermined time has elapsed from the first time within the predetermined period;
With reference to a storage unit that stores a target value that should be lower than the amount of power consumed in the predetermined period, the amount of power consumed in the period is determined based on the predetermined period, the period, and the target value. Calculate the period target value to be below,
Based on the calculated period target value, the measured value, and the predetermined time, calculate a time interval from the second time until a new measured value of the electric energy is acquired,
Outputting the calculated time interval;
A power control support program characterized by causing a process to be executed. The process for calculating the time interval includes:
The power control support program according to claim 1, wherein when the measured value is larger than the period target value, the time interval is calculated to be shorter than the predetermined time. The process for calculating the time interval includes:
The power control support program according to claim 1, wherein when the measured value is smaller than the period target value, the time interval is calculated to be longer than the predetermined time. In the computer,
When the measurement value is acquired, the predicted power after the second time is calculated based on the period and the measurement value,
The process for calculating the time interval includes:
The time interval is calculated based on the calculated period target value, the measured value, the predetermined period, the target value, and the calculated predicted power. The power control support program described. An acquisition unit that acquires a measurement value of the amount of power consumed in a period from a start time of a predetermined period to a second time after a predetermined time has elapsed from a first time within the predetermined period;
With reference to a storage unit that stores a target value that should be lower than the amount of power consumed in the predetermined period, the amount of power consumed in the period is determined based on the predetermined period, the period, and the target value. A first calculation unit for calculating a period target value to be below;
Based on the period target value, the measurement value, and the predetermined time calculated by the first calculation unit, a time interval from the second time until a new measurement value of the electric energy is acquired is calculated. A second calculation unit that
An output unit that outputs the time interval calculated by the second calculation unit;
A power control support device comprising: Computer
Obtaining a measured value of the amount of power consumed in a period from the start time of the predetermined period to the second time after the predetermined time has elapsed from the first time within the predetermined period;
With reference to a storage unit that stores a target value that should be lower than the amount of power consumed in the predetermined period, the amount of power consumed in the period is determined based on the predetermined period, the period, and the target value. Calculate the period target value to be below,
Based on the calculated period target value, the measured value, and the predetermined time, calculate a time interval from the second time until a new measured value of the electric energy is acquired,
Outputting the calculated time interval;
A power control support method characterized by executing processing.

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