JP2000014003A - Demand monitor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a demand monitor which estimates consumed power accurately. SOLUTION: A demand monitor is composed of a power input unit 3 which counts power pulses, a setting unit 6 which sets a target power, a calculation processing unit 4 which samples the counted power, calculates an integrated value in a predetermined time period, calculates an estimated power from the integrated value and compares the estimated power with the target power, a memory unit 5 in which the integrated value is stored, a clock unit 7 which clocks a present time, a demand time limit and a power sampling time and a warning output unit 8 which outputs a warning signal when the estimated power exceeds the target value. The calculation processing unit 4 obtains an approximation formula from a plurality of integrated values in the predetermined time period by the method of least squares to calculate the estimated power.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a demand monitoring device, and more particularly, to a demand monitoring device for power consumption of a substation facility.

[0002]

2. Description of the Related Art In recent years, when a maximum demand power value, that is, a demand value, exceeds a contract power value L with a power company, it is violated by a power consumer, and a high violation fee can be paid. The demand value Q at the end T of the time period is predicted from the series data, and when the value Q exceeds the contract power L, an alarm is output and monitoring is performed by turning on / off the load.

In this case, referring to FIG. 7, predicted power Q is obtained by the following equation. FIG. 7 is an explanatory diagram of a demand value prediction method of a conventional demand monitoring device. In FIG. 7, the predicted power Q can be obtained by the following equation (1). Q = P + ΔP / Δt × (T−t) (1) Q: predicted power P: current power T: demand time t: current time Δt: from current time to determine the standard of average power Backward time ΔP: difference between current power and power before Δt. That is, average power ΔP / Δt between Δt is obtained,
The average power (ΔP / Δt) is multiplied by the difference between the demand time period T and the current time t to obtain the increased power in the demand time period T, and is added to the current power P.

[0004]

However, in such a conventional demand prediction monitoring device, the input electric energy data has a variation, an error, or the like.
If the values do not become continuous, the prediction becomes unstable.

If there is no power value before Δt and the power value immediately before Δt is used, the amount of change in ΔP is large, and the predicted power amount Q tends to fluctuate. There was a problem that the predicted values would be significantly different. Furthermore, when the integrated power value input from the integrated watt-hour meter with a pulse transmitter is used as the power value before Δt, and the pulse multiplier is large, the integrated power value increases stepwise. Because they tend to
There has been a problem that the amount of change in the predicted value becomes large and may be much different from the demand value at the end of the time period.

A demand monitoring apparatus according to the present invention has been made in order to solve the problems of the conventional demand monitoring apparatus.
It is an object of the present invention to provide a demand monitoring device that is not affected by the previous power value and that more accurately predicts the power consumption.

[0007]

In order to solve the above-mentioned problems, a demand monitoring apparatus according to the present invention is configured such that a power amount is input from a watt-hour meter of each load and a power amount input for counting the power amount. A setting unit that sets a target power to the arithmetic processing unit; a unit that samples the counted amount of power and calculates a plurality of integrated values of the amount of power used from a current time to a predetermined time; A calculation unit including a prediction unit that calculates a predicted power amount based on the integrated value as a prediction base, a calculation unit including the prediction result, and a comparison unit that compares the prediction result with a set target power; and a plurality of calculation units calculated by the calculation processing unit. A storage unit that stores the integrated value of the used electric energy, a clock unit that measures the current time, and determines a demand time period and a sampling time of the counted electric energy of the electric energy input unit, and a comparison between the arithmetic processing unit. Predicted power exceeds target And a warning output unit that outputs a warning signal when predicted. The prediction unit of the arithmetic processing unit is configured to calculate a plurality of power consumptions from a present time to a predetermined time stored from the storage unit. The method is characterized in that an integrated value is read, and a predicted power amount is calculated by approximating the integrated value of the plurality of used power amounts by the least squares method.

In another configuration of the demand monitoring apparatus according to the present invention, a power input unit for receiving a signal from a watt hour meter of each load and counting a power consumption, and transmitting a power consumption of the power input unit to a transmission signal A conversion unit, and a conversion transmission device including a first transmission unit that transmits an output signal of the conversion unit as a transmission signal, and the transmission signal is input from the first transmission unit,
A second transmission unit that converts the power consumption into a used amount, a setting unit that sets the target power to the processing unit, and a sampling of the converted power consumption from the second transmission unit to a predetermined time from the present time. Calculating means for calculating a plurality of integrated values of the used power amount; predicting means for calculating a predicted power amount based on the plurality of integrated values as a prediction base; and an arithmetic processing unit for comparing the predicted result with a set target power A storage unit that stores the plurality of integrated values, a clock unit that measures the current time, and determines a demand time period and a sampling time of the power consumption, and a prediction unit that performs prediction based on comparison between the arithmetic processing unit. An alarm output unit that outputs an alarm when the power amount is predicted to exceed the target value. The prediction unit of the arithmetic processing unit includes a plurality of prediction units from the present time stored in the storage unit to a predetermined time. The integrated value of the power consumption of Out look, in which approximated by the least square method from several power usage plurality, and calculates the predicted power value.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In a demand monitoring apparatus according to the present invention, a data series obtained within a predetermined time in the past from a demand value near the present is approximated by a straight line by the least square method, and the demand value at the end of the time period is calculated. This is a demand monitoring device capable of accurately predicting a demand value by performing prediction. Hereinafter, embodiments of the demand monitoring apparatus according to the present invention will be described with reference to FIGS.

[Embodiment 1] A method for predicting a demand value used in a demand monitoring apparatus according to the present invention will be described with reference to FIG. FIG. 1 is an explanatory diagram of a demand value prediction method of a demand monitoring device according to the present invention. Now, here Q: Predicted power P: Current power T: Demand period t: Current time Δt: Time going back from current time to determine the standard of average power ΔP: Difference between current power and power before Δt a: Assuming that the slope of the power when a plurality of data during Δt is approximated by a straight line by the least square method, the predicted power Q can be obtained by the following equation (2). Q = P + a × (T−t) (2) That is, the predicted power Q is obtained by calculating the slope a of the increased power, multiplying the difference between the demand time T and the current time t, and calculating the predicted power Q in the demand time T. The increased power is obtained, and the current power P is added thereto.

Next, the calculation of the inclination a will be described with reference to FIG. FIG. 2 is an explanatory diagram of a least-squares approximation algorithm in demand value prediction of the demand monitoring device of FIG. 2, the input of the known data sequence _{(x 1, y 1) (} x 2, y 2) ··· (x n, y n) when given, below those known data sequence (3 ) Is approximated by a straight line. Y = ax + b (3) The error E when approximated by the straight line Y = ax + b is given by the following (4)
Calculate by formula. ^{_{E 2 = (Y 1 -a 1}} x-b 1) 2 + (Y 2 -a 2 x-b 2) 2 ·· + (Y n -a n x-b
_n )... (4) E ^{2 in the} above equation (4), that is, a and b that minimize the square error are obtained.

In the matrix of the following equation (5),

(Equation 5) If Ap = q, then A-Ap = A-q, and p = A-q
That is, the average power ΔP / Δt during Δt is obtained, and the increase coefficient a and the constant b of the average power during Δt can be obtained.

Next, an example of the above specific configuration will be described.
FIG. 3 is a block diagram of the demand monitoring device according to one embodiment of the present invention. In FIG. 3, a watt-hour meter 2 with a transmitting device transmits a pulse signal proportional to the used power amount. First, the configuration of the demand monitoring device 1 will be described. The demand monitoring device 1 includes a watt hour meter 2 with a transmitting device for each load that transmits a power amount pulse proportional to the used power amount, a power amount input unit 3 that counts the power amount pulse, and a setting for setting a target power. A processing unit 4 for sampling the counted amount of power, calculating an integrated value of the used amount of power within a predetermined time and a predicted power amount based on the integrated value, and comparing the calculated power amount with the target power; A storage unit 5 for storing an integrated value of the calculated power consumption, and measuring a current time measurement and a demand time period;
The power input unit 3 includes a clock unit 7 that determines when the count power value is sampled, and an alarm output unit 9.

Next, the operation of the demand monitoring device 1 will be described. In the demand monitoring device 1 of FIG. 3, an electric energy pulse according to the electric energy used is transmitted from the watt hour meter 2 with the transmitting device of each load. This power amount pulse is input to the power amount input unit 3, and the power amount pulse is counted. On the other hand, the setting unit 6
Sets the target power, that is, the contract power, in the arithmetic processing unit 4. The clock unit 7 measures the demand time period, for example, 30
In addition to generating a minute demand time signal, it also outputs a signal that determines the count power value of the power input unit 3, for example, an interval at a fixed time interval or a predetermined time interval.

The arithmetic processing unit 4 samples a count value of the electric energy at the time of sampling specified by the clock unit 7 and calculates an integrated value of electric power consumption within a predetermined time.
The storage unit 5 sequentially stores the integrated value of the power consumption calculated by the arithmetic processing unit 4. The arithmetic processing unit 4 reads a plurality of integrated values of the used electric energy stored in the storage unit 5 and, from the integrated values of the plurality of used electric energy, calculates the equation (3) by the least square method as described above. Find a linear approximation of

From the demand time period from the clock unit 7, for example, a demand time period of 30 minutes, and the equation (3) of the linear approximation by the least squares method, the predicted power amount of the expression (2) is calculated. In the arithmetic processing unit 4, the set target power and the predicted power amount are compared. In this comparison, it is determined whether or not the demand exceeds the target demand set by the setting unit 6. If it is determined that the demand is exceeded, an alarm signal is generated and output to the alarm output unit 9. .

In the above description, when the predicted value is calculated, conventionally, prediction is performed using equation (1), but conventionally, power ΔP in equation (1) is calculated from current power P by Δt time from the current time. It is determined by the value obtained by subtracting the past demand value. However, in the demand monitoring device according to the present invention, the slope a of the straight line when the data series acquired from the present time to the past Δt time is approximated by a straight line by the least squares method is obtained, and the predicted power Q is calculated by the above equation (2). Ask. The description of equation (2) will be omitted since it has been described above. Q = P + a × (T−t) (2)

In the above, in the present invention, since the count power value of the power input unit 3 is sampled, for example, at intervals of a predetermined time, since it is approximated by a straight line by the least square method, this is not always necessary. Instead, the sampling time may be irregular. The storage unit 5
Although the integrated values of the plurality of used electric powers read out from within the predetermined time period are set within a predetermined time from the present time, the current values are not necessarily required.

[Embodiment 2] Another embodiment of the demand monitoring apparatus according to the present invention will be described. FIG. 4 is a block diagram of a demand monitoring device according to another embodiment of the present invention. In FIG. 4, the conversion transmission device 31 includes a watt hour meter 20.
And an input unit 21 for inputting a power output from the power input unit, counting the input signal, and outputting the power consumption as an output signal (analog or digital).
A conversion unit 22 for converting the amount of power used from No. 1 into a transmission signal suitable for long-distance transmission, and a transmission unit 23 for transmitting the transmission signal
It is composed of Further, the transmission unit 24 includes a demand monitoring device 30 for inputting a transmission signal transmitted from the conversion transmission device 31 to the transmission unit 24.

In the conversion transmission device 31, the watt hour meter 2
Since the configuration from 0 to the power input unit 21 is almost the same as the configuration from the wattmeter 2 to the power input unit 3 in the demand monitoring device of the first embodiment, the description is omitted because it is complicated. And a conversion unit 22 for converting the transmission signal into a transmission signal.
The description will focus on the transmission unit 23 that transmits the transmission signal. The conversion unit 22 can be embodied by a known direct-feeding type and transporting type. The former direct-feeding type includes a rectifying type, a thermal converter type, a Hall converter type, and the like, and is converted into a voltage or a current and transmitted. The latter transport system includes a pulse frequency, a pulse width, a pulse code system, and the like. These methods may be selected according to the transmission distance, the surrounding environment, and the like. The transmission unit 23 transmits the signal from the conversion unit 22 by wire (public communication line or dedicated communication line) or wireless communication.

In the demand monitoring device 30, the transmission unit 2
3 is converted again into the power consumption by a known inverter in accordance with the transmission method. Since the configuration and processing in the subsequent demand monitoring device 30 are the same as those in [Embodiment 1] of FIG. 3, the detailed description will be complicated, and therefore the description will be omitted and will be briefly described. As shown in the drawing, in the demand monitoring device 30, the clock unit 28 measures a demand time period, generates a demand time signal of, for example, 30 minutes, and samples the count power value of the power amount input unit 3, for example, every predetermined time. Or a signal that determines a predetermined time interval.

The arithmetic processing unit 25 samples the counted power consumption at the time of sampling specified by the clock unit 28 and calculates an integrated value of the power consumption within a predetermined time. The storage unit 26 sequentially stores the integrated value of the power consumption calculated by the arithmetic processing unit 25. The arithmetic processing unit 25 reads a plurality of integrated values of power consumption within a predetermined period from the present to the past determined by a signal from the clock unit 27 from the storage unit 26, and based on the plurality of integrated values, By the multiplication method, a straight line approximation represented by the above equation (3) is approximated, and the predicted power is calculated according to the equation (2). Then, the arithmetic processing unit 25 compares the target power set by the setting unit 27 with the predicted power, and causes the warning output unit 9 to output a warning when the predicted power exceeds the target power. .

Next, the operation of the demand monitoring device will be described with reference to the flowchart of FIG. FIG. 5 is an operation flowchart of the demand monitoring device of FIG. In FIG. 5, the demand data acquired within the past predetermined time from the present is read out from the storage unit 26 storing the demand data (step 10).
1). Next, an approximation calculation is performed from the read data string by the least square method from the arithmetic processing unit 25, and the above equation (3) is obtained.
A and b are obtained, and the predicted power value Q in the demand time period from the clock unit 28 is obtained in accordance with the equation (2) (step 102).

The obtained predicted power value Q is compared with a target power set in advance by the setting unit 27, that is, contract power L, and the former (predicted power value Q) exceeds the latter (contract power L). Is determined as Y (yes) or N (no) (step 103). In the case of Y (yes), if the predicted power value Q exceeds the contract power L, the warning output unit 28 outputs a warning (step 104). If N (No), the process ends. A countermeasure is also taken when an alarm is output, and the process ends when the alarm condition is removed. Since the demand monitoring device of the present embodiment has a separate conversion transmission unit as compared with the demand monitoring device of [Embodiment 1], the distance between the conversion transmission unit and the demand monitoring device is small. Therefore, it is effective for demand monitoring of a wide range of demand.

In the present invention, connection to conversion / transmission apparatuses of various powers other than those described above can be considered. FIG. 6 is a block diagram of a demand monitoring device according to still another embodiment of the present invention. In FIG. 6, a CT / VT not shown
, A current / voltage input unit 20, an A / D conversion unit, a power amount calculation unit 22 for calculating an integrated value of the power amount, a storage unit 23 for storing the value, and a power output unit 24 for outputting the power amount integrated value.
To the conversion transmission device 31. Such a conversion transmission device 3
1 is commercially available, and many are already delivered. The conversion transmission device 31 and the demand monitoring device according to the present invention can be connected and function as illustrated.

[0026]

As described in detail above, in the demand monitoring apparatus according to the present invention, the data series acquired within the past predetermined time including the current demand is approximated by a straight line using the least squares method, and the It is possible to provide a demand monitoring device capable of accurately predicting a demand value by predicting a demand value. Thereby, even when irregular electric energy data is input, it is possible to accurately predict the electric power consumption, and thus it is possible to prevent an unnecessary alarm from being generated.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a demand value prediction method of a demand monitoring device according to the present invention.

FIG. 2 is an explanatory diagram of a least-squares approximation algorithm in demand value prediction of the demand monitoring device of FIG. 1;

FIG. 3 is a block diagram of a demand monitoring device according to an embodiment of the present invention.

FIG. 4 is a block diagram of a demand monitoring device according to another embodiment of the present invention.

FIG. 5 is an operation flowchart of the demand monitoring device of FIG. 4;

FIG. 6 is a block diagram of a demand monitoring device according to still another embodiment of the present invention.

FIG. 7 is an explanatory diagram of a demand value prediction method of a conventional demand monitoring device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Demand monitoring device 2 ... Watt hour meter with a pulse transmission device 3 ... Power amount input unit 4 ... Calculation unit 5 ... Storage unit 6 ... Setting unit 7 ... Clock unit 8 ... Alarm output unit 20 ... Watt hour meter with a transmission device DESCRIPTION OF SYMBOLS 21 ... Electric power input part 22 ... Conversion part 23 ... First transmission part 24 ... Second transmission part 25 ... Arithmetic processing part 26 ... Storage part 27 ... Setting part 28 ... Clock part 29 ... Alarm output part 30 ... Demand monitoring Device 31 ... Conversion transmission device

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Satoko Goto 46 Tomioka, Oji, Nakajo-cho, Kitakanbara-gun, Niigata Within the Industrial Equipment Division, Hitachi, Ltd. 1 F-term in the Industrial Equipment Division of Hitachi, Ltd. (Reference) 5B049 AA00 BB00 CC31 DD00 EE02 EE03 FF00 FF07 GG02 GG03 GG04 5G064 AC09 BA01 BA07 CB08 DA05 5G066 KA12 KB01 KB07

Claims (2)

[Claims] 1. An electric energy is input from an electric energy meter of each load,
A power input unit for counting the power, a setting unit for setting the target power in the arithmetic processing unit, and a plurality of integrated values of the used power from a present time to a predetermined time by sampling the counted power. An arithmetic processing unit comprising: a calculating unit; a predicting unit that calculates a predicted power amount based on the plurality of integrated values as a prediction base; and the prediction result, and a comparing unit that compares the predicted result with a set target power. A storage unit for storing an integrated value of a plurality of used electric power amounts calculated by the arithmetic processing unit; and a clock unit for measuring a current time, and determining a demand time period and a sampling time of the counted electric energy of the electric energy input unit. And an alarm output unit that outputs an alarm signal when the predicted power amount is predicted to exceed the target value by comparison in the arithmetic processing unit. Stored from now A demand monitoring device, which reads an integrated value of a plurality of used power amounts up to a predetermined time, approximates the integrated value of the plurality of used power amounts by a least squares method, and calculates a predicted power amount. 2. A power input unit for receiving a signal from a watt-hour meter of each load and counting a power consumption, a conversion unit for converting the power consumption of the power input unit into a transmission signal, A conversion transmission device including a first transmission unit that transmits an output signal as a transmission signal, a second transmission unit that receives the transmission signal from the first transmission unit and converts the transmission signal into a used power amount, and a target power A setting unit that sets the arithmetic processing unit, and a calculating unit that samples the converted power consumption from the second transmission unit and calculates a plurality of integrated values of the power consumption from the present to a predetermined time. A prediction unit that calculates a predicted power amount based on the plurality of integrated values as a prediction base, an arithmetic processing unit that compares the predicted result with a set target power, and a storage unit that stores the plurality of integrated values, While measuring the current time,
A demand time period, a clock unit for determining the sampling time of the used electric energy, and an alarm output unit for outputting an alarm when the predicted electric energy is predicted to exceed a target value by comparison in the arithmetic processing unit. The prediction means of the arithmetic processing unit reads the integrated value of a plurality of power consumptions from the present time stored in the storage unit to a predetermined time, and from the plurality of power consumptions by the least square method. A demand monitoring device that approximates and calculates a predicted power value.