JPH11332097A - Demand monitor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a demand monitor which is able to easily conduct continuous operation between the last time zone of the former time limit of a load operation pattern and the first time zone of the latter time limit. SOLUTION: A demand monitor used for operating a load of a large capacity, which cannot be operated continuously in a contract demand value range, is provided with means 30, 34, 35, 36, 37 for calculating and outputting an operation start time tst and an operation finish time tsp , and continuous operation is made possible between the last time zone (tst -T) in the former time limit and the first time zone(0-tsp ) in the latter time limit in a load operation pattern.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a demand monitoring device applied to a power monitoring system and the like.

[0002]

2. Description of the Related Art A demand monitoring apparatus applied to a power monitoring system or the like is configured to monitor actual demand so as not to exceed a contract demand value with a power company and to issue an alarm when an abnormality occurs.

FIG. 4 is a power demand prediction diagram by a conventional demand monitoring device. As shown in FIG. 4, in the conventional demand monitoring device, first, a predicted demand line 3 is obtained from the actual demand line 4 by a recursive method. Rn (7: predicted demand value) at T (9: time period) is obtained from the extension of the calculated predicted demand line 3. In the demand monitoring device, based on S (5: contract demand value), L
(6: limit demand value) and Q (8: target demand value) are set in advance.

When Rn (7: predicted demand value) is Q (8:
When the target demand value is exceeded, a first-stage alarm is output.
When Rn (7: predicted demand value) exceeds L (6: limit demand value), a second-stage alarm is output.

[0005]

In the above prior art,
There is only a function of issuing an alarm when a demand over is predicted within each time period. Even in the case of a large capacity load that exceeds the contract power in the case of continuous operation, as shown in FIG. 5, in the two continuous time periods 21 and 22, the last time period 23 of the previous time period 21 , Later time period 22
If the operation is performed using the first time zone 24, a long-time continuous operation 25 with a large capacity load can be performed.

However, since the conventional demand monitoring device does not have a function of outputting the operation start time of the load, there is a problem that the continuous operation 25 in the operation pattern shown in FIG. 5 cannot be easily performed. .

[0007] An object of the present invention is to provide a demand monitoring device capable of easily and continuously operating the last time period of a preceding time period and the first time period of a later time period in a load operation pattern. It is in.

[0008]

In order to solve the above-mentioned problems and achieve the object, a demand monitoring apparatus according to the present invention is configured as follows. (1) A demand monitoring device according to the present invention is a demand monitoring device used when operating a large-capacity load that cannot be continuously operated within a contract demand value range, and calculates an operation start time and an operation end time. And a means for outputting continuously the load in the last period of the preceding period and the first period of the following period in the load operation pattern. (2) A demand monitoring device according to the present invention is a demand monitoring device used when operating a large-capacity load that cannot be continuously operated within a contract demand value range, and includes a power amount detection unit that detects actual power. A large-capacity load input signal input section for inputting a load input signal indicating a state in which the large-capacity load is actually operated, and a large-capacity load power input for externally inputting the power amount of the large-capacity load known in advance. Unit, the actual power detected by the power amount detection unit, the signal input at the large capacity load input signal input unit,
Based on the amount of power input at the large capacity load power input unit, the operation start time and the operation end time are calculated,
A demand prediction alarm calculation unit that determines whether to output a first-stage alarm or a second-stage alarm by comparing the predicted demand value with the target demand value and the limit demand value; An operation start time output unit and an operation end time output unit that output an operation start time and an operation end time based on a calculation result; and a first-stage alarm or a second-stage alarm based on a determination result of the demand prediction alarm calculation unit. A first stage alarm output unit and a second stage alarm output unit for selectively outputting an alarm are provided.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS (First Embodiment) FIG. 1 is a block diagram showing a configuration of a demand monitoring device according to a first embodiment of the present invention. As shown in FIG. 1, this demand monitoring device mainly includes a demand prediction alarm calculation unit 30, a power amount detection unit 31, a large capacity load input signal input unit 34, a large capacity load power input unit 35, and a first stage alarm output. A section 32, a second-stage alarm output section 33, an operation start time output section 36, and an operation end time output section 37 are provided.

That is, the demand monitoring apparatus according to the present embodiment adds a large-capacity load input signal input section 34 and a large-capacity load power input section 35 to the conventional apparatus, and exercises the algorithm of the demand prediction alarm calculation section 30. A function of calculating a start time and an operation end time is added, and an operation start time output unit 36 and an operation end time output unit 37 are further added.

The power amount detecting section 31 is a section for detecting the actual power, and the large capacity load input signal input section 34 is a section for inputting a state signal that the large capacity load is actually operating.
The large-capacity load power input unit 35 is a part for externally inputting the power amount of the large-capacity load known in advance.

The demand prediction / alarm calculation unit 30 includes an actual power detected by the power amount detection unit 31, a signal input by the large-capacity load input signal input unit 34, and a large-capacity load power input unit 3.
Based on the electric energy input in step 5, t _st (41: operation start time) and t _sp (42: operation end time) are calculated in accordance with the demand prediction alarm calculation flowchart shown in FIG. It has a role of determining whether or not to output a step alarm. That is, in the demand prediction alarm calculation unit 30, the power amount detected by the power amount detection unit 31 and the known large capacity load power input by the large capacity load input signal input unit 34 and the large capacity load power input unit 35 are input. The following calculation is performed based on the value.

As shown in the load operation pattern and the power demand prediction diagram in FIG.
T _st (41: operation start time) and t _sp (4) such that (7: predicted demand value) = Q (8: target demand value)
2: The operation end time) is updated, and during the large-capacity load operation, Rn (7: predicted demand value) is updated and t
Update _sp (42: operation end time).

The operation start time output unit 36 outputs t based on the result of the calculation by the demand prediction alarm calculation unit 30.
_st (41: operation start time) is output, and t _sp (42: operation end time) is output from the operation end time output unit 37. In addition, Rn in the demand prediction alarm calculation unit 30
Based on the result of comparison between (7: predicted demand value), Q (8: target demand value) and L (6: limit demand value), the first-stage alarm output unit 32 or the second-stage alarm output unit 33
Outputs a first-stage alarm or a second-stage alarm selectively.

FIG. 3 is a flowchart showing the procedure of the demand prediction alarm calculation by the demand prediction alarm calculation unit 30. Hereinafter, the procedure of the demand prediction alarm calculation will be described with reference to this flowchart.

[Step S1] It is determined whether or not a large capacity load operation is being performed. Step S if not driving
Proceed to 2.

[Step S2] Based on the detected electric energy,
A base power demand prediction value calculation is performed, and a demand prediction value R _{TBN of} only base power excluding a large capacity load is calculated by a method similar to the conventional method.

[Step S3] The operation start time t _st is calculated. In the calculation of t _st , when a large-capacity load of known power P starts to start at time t _st under the base power demand, the total Rn (7: predicted demand value) in the time period T is Q (8). : t _st such that the target demand value) is calculated by the following equation.

T _st = T− (Q−R _TBn ) / P When a large capacity load is started at time t _st , Rn (7: predicted demand value) becomes Q at time T as shown in FIG.
(8: target demand value) is predicted, and the operation of the large capacity load can be continued even in the next time period (T → 2T).

[Step S4] During the large-capacity load operation, the large-capacity load power is subtracted from the detected power, and the base power is calculated.

[Step S5] When it is determined in step S1 that a large-capacity load operation is being performed, a base power demand prediction value calculation is performed using the base power data calculated in step S4 in the same manner as in the prior art. And the base power demand predicted value R _TBn is calculated.

[Step S6] When the large-capacity load is stopped at t _sp (42: operation end time), Rn (7: predicted demand value) is equal to Q (8: target demand value) at time T. t _sp (42: operation end time)
Is calculated by the following equation.

T _sp = (Q- _RTBn ) / P- _tst "Step S7" Rn (demand prediction value) is calculated by the following equation.

[0024] In _{Rn = R Bn + P (t} n -t st) "Step S8" following algorithm, the type of alarm is determined to be output.

Q <Rn ≦ L First-stage alarm region L <Rn Second-stage alarm region (Features of the embodiment) [1] The demand monitoring device described in the embodiment operates continuously within a contract demand value range. A demand monitoring device used when operating a large capacity load that cannot be operated, comprising means for calculating and outputting an operation start time (t _st ) and an operation end time (t _sp ). The last time period of the previous time period (t _st -T) and the first time period of the later time period
(0-t _sp ). [2] The demand monitoring device described in the embodiment is a demand monitoring device used when operating a large-capacity load that cannot be continuously operated within the range of the contract demand value, and the amount of power for detecting the actual power. A detection unit (31), a large-capacity load input signal input unit (34) for inputting a load input signal indicating a state in which the large-capacity load is actually operated, and a power amount of the large-capacity load that is known in advance. A large-capacity load power input unit (35) input from outside, the actual power detected by the power amount detection unit (31), a signal input by the large-capacity load input signal input unit (34), The operation start time (t _st ) and the operation end time (t
_sp ) and comparing the predicted demand value (Rn) with the target demand value (Q) and the limit demand value (L) to determine whether to output the first-stage alarm or the second-stage alarm. And a driving start time output unit that outputs a driving start time (t _st ) and a driving end time (t _sp ) based on the calculation result of the demand prediction alarm calculation unit (30). (36) and operation end time output part (37),
A first-stage alarm or a second-stage alarm that selectively outputs a first-stage alarm or a second-stage alarm based on the determination result of the demand prediction alarm calculation unit (30);
A second stage alarm output unit (32) and a second stage alarm output unit (33) are provided.

[0026]

According to the present invention, since means for calculating and outputting the operation start time and the operation end time are provided, the last time period of the previous time period and the first time period of the subsequent time period in the load operation pattern are provided. A demand monitoring device capable of easily and continuously operating in a time zone can be provided.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a demand monitoring device according to a first embodiment of the present invention.

FIG. 2 is a prediction diagram of a load operation pattern and a power demand in the demand monitoring device according to the first embodiment of the present invention.

FIG. 3 is a flowchart showing a procedure of a demand prediction alarm calculation of the demand monitoring device according to the first embodiment of the present invention.

FIG. 4 is a power prediction diagram of a demand monitoring device according to a conventional example.

FIG. 5 is a prediction diagram of a continuous operation pattern of a large capacity load and a power demand in a demand monitoring device according to a conventional example.

[Explanation of symbols]

 Reference numeral 30: demand prediction alarm calculation unit 31: electric energy detection unit 32: first-stage alarm output unit 32: second-stage alarm output unit 34: large-capacity load input signal input unit 35: large-capacity load power input unit 36: operation start Time output part 37… Operation end time output part

Claims (2)

[Claims] 1. A demand monitoring device used when operating a large-capacity load that cannot be continuously operated within a contract demand value range, comprising means for calculating and outputting an operation start time and an operation end time. A demand monitoring device wherein the last time period of the previous time period and the first time period of the subsequent time period in the load operation pattern can be continuously operated. 2. A demand monitoring device used when operating a large-capacity load that cannot be operated continuously within a range of a contract demand value, comprising: a power amount detection unit for detecting actual power; A large-capacity load input signal input section for inputting a load input signal indicating an operating state, a large-capacity load power input section for externally inputting the power amount of a large-capacity load known in advance, and the power amount The operation start time and the operation end time are calculated based on the actual power detected by the detection unit, the signal input at the large-capacity load input signal input unit, and the electric energy input at the large-capacity load power input unit. A demand prediction alarm calculation unit that determines which of a first-stage alarm and a second-stage alarm should be output by comparing the predicted demand value with the target demand value and the limit demand value; An operation start time output unit and an operation end time output unit that output an operation start time and an operation end time based on a calculation result of the demand prediction alarm calculation unit; A demand monitoring device comprising: a first-stage alarm output unit and a second-stage alarm output unit that selectively output a second-stage alarm or a second-stage alarm.