JPS61135337A - Dispersion type power demand control - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention performs control to suppress the overall power consumption of a plurality of distributed power load groups to within a target value at predetermined time intervals. The present invention relates to a power demand control method.

[Conventional technology]

Such power demand control is generally performed for a group of power loads within the same campus or the same building), and a control device is provided for each power load group to perform independent control for each power load group. It has become a thing.

[Problem that the invention seeks to solve]

However, in recent years, it has become necessary to perform power demand control all at once for distributed buildings owned by the same management entity, or for groups of buildings constructed on the same site. Each individual control means has the problem of not being able to meet such demands.

[Means for solving problems]

To solve the above-mentioned problem, the present invention is constructed by the following means.

That is, the total amount of power consumed by a plurality of distributed power load groups is actually measured for each unit time, the total amount of power consumed during a predetermined time is predicted based on this measured value, and based on this predicted value, The total control power is determined, the total control power is distributed according to the current controllable power for each power load group, and the power consumption of each power load group is sequentially controlled according to the control power determined by this distribution. There is.

[Effect]

Therefore, the total power consumption of each power load group is suppressed within the target value, and the control power for turning off and on by recovery for each power load group is determined according to each controllable power. Control power is not concentrated on a specific power load group, and the control status of each power load group becomes fair.

〔Example〕

Hereinafter, the present invention will be explained in detail with reference to figures showing examples.

Figure 81 is a block diagram showing the entire configuration, and shows a power load group (hereinafter referred to as load group) 1 of buildings etc. distributed in a distributed manner.
Power is supplied to the load groups 1 to 13 by a common power distribution path (not shown in the figure), and the demand wattmeter 2 connected to the base point on the power supply side connects each load group to the load groups 11 to 13.
The total power consumption of 13 is actually measured, and a pulse signal or the like is sent out every time the wattmeter 2 integrates a certain amount of power.

In addition, each of the load groups 11 to 13 includes a control unit (hereinafter referred to as DCU) 31N3 including a memory, a processor, a memory, etc.
s is provided for each, and controls on/off of power supply to each power load (hereinafter referred to as load) omitted in the diagram via data transmission lines 41 to 4n and data collection devices (hereinafter referred to as DGP) 5+ to 5m. At the same time, DCU・
31 to 33 are main control units (hereinafter referred to as McU) 6 provided in any of the load groups 11 to 13 or in a separate building.
It is commonly connected to an operating terminal device (hereinafter referred to as MMI) 7 via a communication path 8, transmits and receives data to and from the MCU 6, and also performs control according to commands from the McU 6.

The MCU 6 is equipped with a processor, memory, etc., while the W city 7 is composed of a cathode ray tube display, a keyboard, a display panel, etc., and is controlled by the operation of the MHI-7.
It is possible to issue commands to the CU-6 and DCU-31 to 3sK, and to set and update data necessary for control, as well as to monitor the control status of the MCU-6 and DCU-31 to 330.

However, DCU・31~3s and MCU・6 also have MM.
It comes with almost the same equipment as I@T.

Here, the output of the wattmeter 2 is given to the DCU 31 via the DGP 5mt.
U-3 counts the pulse signal from the wattmeter 2 every unit time of, for example, 3 minutes, sequentially measures the total power consumption of the load groups 11 to 13, and based on this actual measurement, calculates the total power consumption for 30 minutes, for example. Predict the total power consumption during a given period of time,
Based on this predicted value, the total control power to be controlled as Geo 7 or ON is calculated based on the difference from the target power consumption during a predetermined time, and the predicted value and total control power are sequentially transmitted to t-McU 6 as the prediction result. It has become something to do.

In addition, controllable power that can be turned off and turned on after being turned off is determined for each load group 11 to 13, and for each level, for example, levels 1 to 3, depending on the importance of this power. It is divided into 17ji LI KW as shown in Figure 2.

Level 2 is defined as Lz KW + Level 3 is defined as L3KW, and control is first performed from level l with low importance, and for each level L, % L, how many KW are on and how many KW are off? The data is stored sequentially in the memory as data.

Figure 3 shows the control status 7 by the processor of MCU 6.
0 - On the chart, “Receive prediction results?” 101 is Y (
YES), based on this predicted value and the total control power, it is determined whether it is necessary to turn the OFF control ON or not using the "Control required?" 102, and when this is N (NO), the "Transmission without OFF" 103 is performed, whereas if the total control power is other than zero, on or off control is required, so step 102 is Y, and 1 load status request is sent to each DCU. 104t-Do.

Next, when each DCU 31 to 33 transmits the current on and off turtles for each level in FIG. 2 as the load status, a "load status reception?" becomes Y, and this is used as the “load status store”
112 Stored in memory from K and received from 1 all DCUs?
In response to “113 becoming Y,” “control power distribution processing” 1
14t-, thereby transmitting a power command to be controlled to each DCU 31 to 33, and repeating the above operation.

FIG. 4 is a flowchart showing details of step 114, in which the power currently turned on or off for each DCU 31 to 33 and each level is added for each level to obtain "ΣLli, ΣL21+ΣL3i". 201, thereby determining the controllable power for each level, and comparing it with the total control power
2, if X is less than N than ΣL11, then
The counter provided to count the DCU number is
j=1"211, set it first and then set Cj
= (L+ j/ΣLli)φX"212, the control power CJ to be distributed to the DCU 31 is determined, and "
Cj Store "213" Store it in the memory once,
In this example, there are three DUCs, so “j=3?” 214 is N.
During this time, the DCU number counter is incremented by "j=j+t" 215, and steps 212 and subsequent steps are repeated.
If the result in step 214 is Y, a full control power command for turning off or on each DCU 31 to 33 is sent to each DCU 31 to 33 by "1 command transmission" 216.

Furthermore, if step 202 is Y, control at level 1 alone is insufficient, so level 2 is also taken into account and 1(ΣL, i+
ΣLzi)
.

= LIj + (L2 j/ΣL21)・(x−ΣLt
i)" 222 is performed, and the control power (X
-Lli) to level 2, and D
Find the control power Cj to be distributed to the CU 31, and perform step 2
In addition to performing the same < ``Cj Store'' 223 as in 13, while 1j >a'i''' 224 is N, step 2
15. Performs the same <"j=j+1" 225 and repeats steps 222 and 1liIt-, and if step 224 becomes Y, the process moves to step 216.

Regarding the above, if step 203 is also Y, including level 3'(ΣL, i+ΣL2i+ΣL31)<x? ”2
04 and “j=1” 23 as in step 211.
1t, then include ΣL31 in the same way as in step 222'Cj=Ltj+Lzj+(Lsj/ΣLs,)
(x-ΣLliXL21) ” 232
Kl/', calculate the control power Cj to be distributed to the DCU-3j, same as step 213 <"CjStore"
233, and while "j>3?" 234 is N, perform "j=j+1" 235 in the same way as step 215, and as step 234 becomes Y, step 21
Move to 6.

On the other hand, if step 204 is also Y, it is determined whether the total controllable power is in the direction of turning off or not using "Off control?" 241, and if this is Y, the current total controllable power is insufficient. , performs "all-off command transmission n242" for forcibly cutting off all of the cut-off capacity of the corresponding DCU.

In addition, at this time, the MCU 6 corresponds to each level L in FIG.
~ Turn off all the loads that are on during L3, and display the alarm by ■■・7, and turn off the DCU・31.
- 31 may be notified of an abnormality.

FIG. flcS is a flowchart showing the load control status by the processors of DC'U 31 to 33. Corresponding to step 104, if "Load status request received?" 301 is Y, then in FIG. After reading the power that is currently on and off from the memory and calculating the total power that is currently on and off as the control power that can be turned off and the control power that can be turned on, the "controllable power calculation" 302 is performed. 1 load status transmission'' 303 by MCU・6
31 in response to step 216.
If 1 becomes Y, control starts from level 1 according to 1 command "3"
12t and repeat the above operation.

It is assumed that MCU@6 transmits the control commands for each DCU as well as the total amount of controllable amount in the system in step 216'''' command transmission'' in FIG. 4, for example, DCU 3! Then, it may be provided with a function of checking the predicted result and the total controllable amount when the R is cut off, and transmitting an abnormality warning when the predicted result exceeds the predicted value.

Therefore, if the predicted value exceeds the target value, the total control power j-L33, and if the load is turned off by the distributed ratio control power CjO and the predicted value is less than the target value, the same total control power The power that is off but can be turned on and should be restored is distributed according to Llj%L3j, the load is turned on by this distributed control power cj, and the total power consumption is within the target value. are sequentially controlled.

Therefore, in each DCU 31 to 33, if the controllable power is optimally determined for each load group 11 to 13 according to levels L and -L3 in FIG. Cj is distributed and each load group 11-1
The power consumption control situation of No. 3 becomes fair, and power demand control for each load group 11 to 13 is realized.

However, if the power receiving paths for each load group 11 to 13 are individual, each 2t wattmeter is installed and the power consumption of each is measured by the MCU.
The predicted value and the total control power may be calculated in MCU 6 to obtain the total power consumption, or the predicted value and total control power may be calculated in MCU 6. May be added.

Moreover, the level division may be made into a larger number of levels depending on the conditions, or may be divided into three or less levels, and various modifications are possible.

〔Effect of the invention〕

As is clear from the above description, according to the present invention, it is possible to collectively control the power consumption of a load group distributed in a distributed manner, and the control situation becomes efficient and economical, thereby controlling the power demand of a distributed load group. Remarkable effects can be obtained.

[Brief explanation of drawings]

The figures show an embodiment of the present invention, with Fig. 1 being a block diagram showing the entire configuration, and Fig. K2 being a diagram showing the level division of controllable power.
3 and 4 are 70-charts of the control status by the MCH processor, and FIG. 5 is a 70-chart of the load control status by the DCU processor. 11-13 ...-Load group (power load group), 2.
Phase]・Power meter, 3. ~33・11@・DcU (control unit), 6...MCU (main control unit), 8...communication path.

Claims (1)

[Claims] The total power consumption by multiple power load groups distributed in a distributed manner is actually measured for each unit time, the total power consumption during a predetermined time is predicted based on the measured value, and all control is performed based on the predicted value. Determine the power, distribute the total control power according to the current controllable power for each power load group, and sequentially control the power consumption of each power load group according to the control power determined by the distribution. A distributed power demand control method characterized by: