JPH0365023A - Demand controller - Google Patents

Abstract

PURPOSE:To manage electric energy to be used by measuring the electric energy to be used through a wattmeter then operating the achievement ratio between a target electric energy and an actually used electric energy thereafter controlling the demand for each time band. CONSTITUTION:Pulses fed from a watthour meter 10 provided with a transmitter are counted at an input interface section 2 connected with the watthour meter 10, and the electric energy to be used is measured for each time band. Target electric energy to be used is set, at a setting section 4, for each long term time band longer than one day. Achievement ratio between the electric energy to be used and the target electric energy to be used is operated, at a processing section 26A, for each time band. The operation results are displayed on a display section 5 or printed at a printing section 7. By such arrangement, electric energy to be used over a long term, e.g. one day or one month, can be managed for each time band.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] This invention relates to a demand control device that controls the amount of power used during a demand period so that it does not exceed a contracted maximum amount of power demand.

In particular, the present invention relates to a demand control device that is suitable for customers who have transactions with different unit electricity prices depending on the time of day or season.

[Prior Art] The configuration and operation of a conventional example will be explained with reference to FIG.

FIG. 2 is a block diagram showing a conventional demand control device disclosed, for example, in Japanese Patent Publication No. 60-53527.

In FIG. 2, (10) is a power meter with a transmitter that transmits a pulse proportional to the amount of power used, and is installed by the electric power company. (lla) is the daytime counter, (
llb) is a counter for the peak time period, (lie) is a counter for the night time period, and the pulse switch (13a) is operated by the time period signal generated by the time period signal generator (12).
= 'Among (13b) and (13c), pulses arriving via the pulse switch in the corresponding time period are counted. In other words, during the daytime, the pulse switch (1
3a) is closed, and the pulses of the power meter with transmitter (10) are counted by the daytime counter (lla).

Each of the above-mentioned counters (lla) to (lie) naturally has the same function as a time-zone transactional power demand meter (not shown) installed by an electric power company for the purpose of monitoring power demand. Therefore, like the demand power meter for transactions, one is provided for each time period, and at the end of the time period, the demand time limit counter (18a), which will be described later, is not reset.
) to (18c) are reset at the end of counting, that is, at every demand time period.

(20) is a clock unit that transmits pulses at a reference frequency for measuring the demand time limit. (18a) is a demand time limit counter for daytime hours, (18b) is a demand time limit counter for peak hours, and (18c) is a demand time limit counter for nighttime hours. Pulse switching devices (15a), (15b) and (1) that operate
Among 5c), pulses of the reference frequency arriving via the corresponding pulse switch are counted. Note that these counters are all addition/subtraction counters that subtract or add a time correction pulse in response to the advance or delay of the time limit, which will be described later. That is, if it is daytime, the pulse switch (15a) is closed and the daytime demand time limit counter (18a) counts the reference frequency pulses.

Note that the demand time counters (18a) and (18b)
) and (18c) count the remaining time of the demand period.

When the reference frequency pulses selected by the time zone signal are counted, when the counted value reaches a certain predetermined value, that is, when the demand time limit comes, it is reset to the initial value. Otherwise, the count value is retained. Therefore, even at the end of the time period, the count value is held without being reset. Since this function electronically counts the demand time period, it is immediately stopped when the time period ends, so the time does not advance.

The daytime, peak and nighttime counters (lla) (l
The count values of lb) and (llc) are calculated by the time zone signal generator (
12) A signal switcher (14a) operated by the time zone signal
), (14b) and (14c), only the data in the corresponding time period is inputted to the arithmetic circuit (26) via this.

Similarly, the daytime, peak and night count values are:
The signal switchers (16a), (16b) and (16c) allow only signals in the corresponding time period to be input to the arithmetic circuit (26).

(21a) is the target power demand setting section for daytime hours, (2
1b) is a target power demand setting unit for peak hours, (21c
) is the target power demand setting unit for the night time period, and the signal switchers (17a), (171)) and (17c) operated by the time period signal generator (12>) are used to set the target power demand for the corresponding time period. Only those signals are input to the arithmetic circuit (26) via this 6 The arithmetic circuit (26) uses these signals as input to generate a predicted value of the power demand and an adjustment value to keep the power demand to the target power demand. It is configured by, for example, a microcomputer.

The predicted value of power demand is calculated for a certain period of time (for example, 1 minute)
It is calculated by dividing the increment in power demand by the fixed time, multiplying this by the remaining time of the demand time limit at that time, and adding the power demand at that time to this value.

In addition, the adjustment value is calculated by multiplying the difference between the predicted value obtained in this way and the target power demand by the demand time interval (for example, 30 minutes if the demand time limit is measured at 30 minute intervals),
It is calculated by dividing this value by the remaining time of the demand time limit.

The calculated predicted value is stored in the predicted value storage circuit (22). Similarly, the calculated adjustment value is stored in the adjustment value storage circuit (
23).

Further, the predicted value and the target power demand are determined by a comparison circuit (24).
If the predicted value exceeds the target power demand, the alarm circuit (25) is activated to issue an external alarm to draw the attention of the supervisor.

The time signal generator (12) generates, for example, a daytime signal from 8:00 to 13:00 and from 16:00 to 22:00, a peak time signal from 13:00 to 16:00, and a night time signal from 10:00 p.m. to 8:00 the next day. A signal is generated, and pulse switchers (13a) to (13c), (15a) are operated according to the time period signal.
- (15c) and signal switch (14a) - (14e)
, (16a) to (lee), (17a) to (17c)
Switch. The arithmetic circuit (26) performs arithmetic operations based on the count values and set values corresponding to the relevant time period.

[Problem to be solved by the invention] In the conventional demand control device as described above,
The problem is that the average power consumption in short demand time intervals is managed by time zone, and it is not possible to manage the amount of power used by time zone.

This invention was made in order to solve the above-mentioned problems, and it is possible to control the power demand by time of day, and also to manage the amount of power used for a long period of time, such as a day or a month, by time of day. The purpose is to obtain a demand control device that can.

[Means for Solving the Problems] A demand control device according to the present invention includes the following means.

(i) A measuring means for counting pulses from a power meter to measure the amount of power used in each time period.

(ii) Target setting means that can set a target amount of power consumption for each time period for a long period of one day or more.

(ii) Calculating means for calculating the performance ratio for each time period based on the amount of power used and the target amount of power used.

[Operation] In the present invention, the measuring means counts the pulses from the watt-hour meter and measures the amount of power used for each time period.

Further, the target setting means sets a target amount of power consumption for each time period for a long period of one day or more.

Then, the calculation means calculates the performance ratio for each time period based on the amount of power used and the target amount of power used.

[Embodiment] The configuration of an embodiment of the present invention will be described with reference to FIG.

FIG. 1 is a block diagram showing one embodiment of the present invention.

In FIG. 1, an embodiment of the present invention shows an input interface unit <2> connected to a power meter with transmitter (10).
), an input interface section (3) connected to the time switch (12^), an arithmetic processing section (26^) connected to the input interface sections (2) and (3), and an arithmetic processing section (26^) The setting section (4) connected to An alarm output section (25^) connected to the processing section (26^>), a printer section (7) connected to the arithmetic processing section (268),
It consists of a storage section (8) connected to an arithmetic processing section (26^) and a clock section (20^) connected to the arithmetic processing section (26^).

By the way, the measuring means of the present invention is the input interface section (2) in the above-described embodiment of the present invention, the goal setting means is the setting section (4>), and the calculating means is the arithmetic processing section (26^). It is.

Next, the operation of the above embodiment will be explained.

The power meter with transmitter (10) transmits a pulse signal proportional to the amount of power used. The input interface section (2) receives and counts this pulse signal.

The clock section (20^) measures the current time, further measures the demand time limit, creates a demand time limit signal of, for example, 30 minutes, and outputs a calculation signal that determines the calculation interval at regular time intervals.

The arithmetic processing section (26^) is the input interface section (2)
A predicted value of the demand value at the end of the demand time period is calculated from the counted value of and the remaining time period of the clock section (20^), and when this predicted value exceeds the target demand value set in the setting section (4). determine whether there is. When it exceeds the limit, an alarm signal is generated and output to the alarm output section (25^).

In addition, the calculation processing unit (26^) calculates the adjusted power based on the predicted value, and when the calculated value exceeds the cutoff power value set in the setting unit (4>), generates a second alarm signal. At the same time, it generates a load cutoff signal and outputs it to the control output section (6).

Next, in order to count the amount of electricity consumed by time period, the arithmetic processing unit 〈26＾) reads the time period signal generated by the time switch (12^) via the input interface portion (3), and calculates the amount of electricity used in the corresponding time period ( For example, pulse signals arriving from the power meter with a transmitting device (10) are integrated for each daytime period, peak time period, night time period, etc.).

By setting the target power consumption for each time of day or January in the setting section (4), the actual ratio of the actual value (power consumption) to the target value (target power consumption) is calculated. Calculated in the processing unit (26^) and displayed on the display unit (5>)
Or have the printer section (7) print it.

As described above, one embodiment of the present invention includes a setting section (4) that can set the cumulative target power usage amount, that is, the target power usage amount for each time period of the day or January, and the actual ratio to the cumulative target power usage amount. Since it is equipped with a calculation processing unit (26^) that can calculate
Since the amount of power used can also be managed on a daily or monthly basis, it has the effect of contributing to reductions in electricity charges and rationalization of power management.

Note that in the above embodiment, the time zone signal is generated by a time switch configured as an external device, but a similar operation can be expected even if the time zone signal is generated by a clock section, which is an internal device.

Incidentally, in the above description, the case where the system is used for time zone transactions has been described, but it goes without saying that it can also be used for other purposes, for example, only during a specific period of time (such as one hour).

[Effects of the Invention] As explained above, the present invention includes a measuring means for counting pulses from a power meter to measure the amount of power used in each time period, and a measuring means for measuring the amount of power used in each time period for a long period of one day or more. Since it is equipped with a target setting means that can set a target amount of electricity used, and a calculation means that calculates the actual ratio for each time period based on the amount of electricity used and the target amount of electricity used,
This has the effect of being able to manage power consumption over a long period of time, such as a month.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, and FIG. 2 is a block diagram showing a conventional demand control device. In the figure, (1>... demand control device, (2)
... Input interface section, (3) ... Input interface section, (4) ... Setting section, (5) ... Display section, (6) ... Control output section, (7) ...・Printer section, (8)...Storage section, (208)...Clock section, (25^)...Alarm output section, (26^)...Arithmetic processing section. In each figure, the same reference numerals indicate the same or equivalent parts. Figure 1

Claims (1)

[Claims] A measuring means for counting pulses from a power meter to measure the amount of power used in each time period, a target setting means for setting a target amount of power used for each time period for a long period of one day or more, and the above power consumption. A demand control device comprising a calculation means for calculating the actual ratio for each time period based on the amount of power used and the target amount of power used.