JP2000224765A - Maximum demand controller and method for controlling the maximum demand - Google Patents

Abstract

PROBLEM TO BE SOLVED: To keep each power load operating and prevent malfunctions of the loads due to the influence by external noise by turning a power reducing signal on and off repeatedly according to set stop time and operation time to reduce power to be supplied to a corresponding load. SOLUTION: When a demand operating section 1 outputs a cut-off signal to a power load 24, a control signal outputting section 2 (a power reducing signal controller) controls the output of the cut-off signal according to a preliminarily set time. To be more specific, when the demand operating section 1 outputs a cut-off signal to a certain power load, the control signal outputting section 2 outputs the cut-off signal and stops the output of the signal to the load, each for a specified period of time set for each operation. This operation is repeated until the demand operating section 1 stops outputting the cut-off signal. By this method, each power load can be kept operating and the interference of noise, etc., can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention predicts the power consumed by all power loads in one facility or one area at the end of a predetermined time period, and adjusts the predicted value to be equal to or less than a preset target value. The present invention relates to a maximum demand power control device that controls power consumption of all power loads and a control method thereof.

[0002]

2. Description of the Related Art FIG. 5 shows an example of a schematic configuration of a conventional maximum demand power control apparatus. The maximum demand power control device illustrated in FIG. 1 is configured such that, for each predetermined time period (hereinafter, referred to as a demand time period), for example, the power value consumed by all power loads installed in a certain facility is equal to or less than a target value. Control. Here, the demand time period is, for example, 30 minutes.

[0005] Each unit shown in FIG. 5 will be described below.
Reference numeral 20 denotes a watt hour meter with a transmitting device, which is based on an applied voltage to the entire power load in the facility detected by the instrument transformer 21 and a load current detected by the instrument current transformer 22.
The amount of power consumed by the total power load is measured. And
The power meter with transmitting device 20 outputs a number of pulse signals proportional to the measured power value. Here, instead of the watt-hour meter 20 with the transmitting device, the instrument transformer 21, and the instrument current transformer 22, a transaction instrument of an electric power company and a pulse are detected from the transaction instrument, and a predetermined pulse width is detected. And a pulse detector that converts the pulse constant into a pulse constant and outputs the converted pulse constant.

Reference numeral 23 denotes a demand calculation unit which counts pulse signals output from the watt-hour meter 20 with the transmitting device and determines a predetermined amount of power consumed by all power loads at the end of the demand time period based on the counted value. The prediction is made every time (for example, every 30 seconds). Here, the predicted power is referred to as predicted power. When the predicted power exceeds a target value of power consumed by all power loads at the end of the demand time period (hereinafter, referred to as target power), the power supplied to each power load is cut off according to the excess. To output a shut-off signal.

[0005] Reference numerals 24-1 to 24-5 denote electric power loads used in a certain facility, for example, facilities such as lighting equipment, air conditioners, and various electronic devices. Although not shown, each power line for supplying power to these power loads is provided with a relay (power reduction means) corresponding to each power load. Is input, the power supplied to the corresponding power load is cut off.

The above-mentioned five power loads 24-1 to 24-1
In 24-5, priorities are set in advance in accordance with the importance of each power load, and a higher priority is set for a power load that needs to maintain power supply as much as possible. Here, the highest priority is “1”, and the priority value increases as the priority decreases, and the lowest priority is “5”. In the configuration shown in FIG. 5, the power load 24-1 has priority 1, the power load 24-2 has priority 2, the power load 24-3 has priority 3, the power load 24-4 has priority 4, and the power load 24-4 has priority 4.
-5 is set to priority 5.

[0007] In the conventional maximum demand power control device described above, the demand calculation unit 23 is provided with the watt-hour meter 2 with the transmission device.
Based on the count value of the pulse output from 0, a predicted power is obtained every 30 seconds. If the predicted power exceeds the target power, levels 1 to 5 are set according to the magnitude of the excess.
Output a cutoff signal. Here, it is assumed that the level of the cutoff signal increases as the magnitude of the excess increases, and the relationship between the magnitude of the excess and the level of the cutoff signal is appropriately set in advance by the user.

FIG. 6 shows a state of a cutoff signal output from the demand calculation unit 23 to the power loads 24-1 to 24-5. For example, when the excess of the predicted power with respect to the target power satisfies the condition for outputting the level 1 cutoff signal, the demand calculation unit 23 corresponds to the power load 24-5 having the lowest priority and the priority 5. The cutoff signal is output only to a relay (not shown). As a result, while the cutoff signal is being output, the power supplied to the power load 24-5 is cut off.

When the excess amount satisfies the condition for outputting a level 2 cut-off signal, the power load 24 of priority 5
−5 and the relays corresponding to the power loads 24-4 of the priority 4 are output the cutoff power, respectively.
The power supplied to 4-5 is cut off. In this way, as the level of the cutoff signal increases, the demand calculation unit 23 sequentially switches from the low priority to the high priority power load.
When the cutoff signal is output and the level 5 cutoff signal is output from the demand calculation unit 23, the power loads 24-1 to 24-4 are output.
A shutoff signal is output to the relay corresponding to each of 24-5, and the power supplied to all the power loads is shut off.

[0010] Further, as a result of performing the above-described power control, when there is a margin in the power that can be supplied to each power load, the power supply is restarted in order from the power load with the highest priority.
By performing the power control as described above, the maximum demand power control device controls the average power consumed by all the power loads in the facility for each demand time period to be equal to or less than a preset target power.

[0011]

In the above-described maximum demand power control apparatus, as shown in FIG. 6, when a cutoff signal is output from the demand calculation unit 23 to a certain power load, the cutoff signal is output. Until the output was stopped, the power supplied to the power load was continuously turned off. Further, the output period of the cutoff signal varies depending on the priority of the power load and the difference between the predicted power and the target power, and the time until the power supply is restarted is unknown.

For this reason, when the power load is, for example, an air conditioner, once the shutoff signal is output, the room temperature rises, the indoor comfort is impaired, and it is unknown how long the state will last. Was given the frustration to the user.

Further, the demand calculation unit 23 supplies the power load 2
Since the cutoff signals output to 4-1 to 24-5 are transmitted by the wiring laid between them, the equipment cost becomes high, and a malfunction may be caused by the influence of external noise. There was sex.

The present invention has been made in view of such circumstances, and the power consumed in a predetermined time period by the total power load in a certain facility or a certain area approaches a target power set in advance. It is an object of the present invention to provide a maximum demand power control device and a control method thereof, in which the operation state of each power load is maintained as much as possible when performing power control of each power load, and a malfunction due to the influence of external noise is unlikely to occur. .

[0015]

According to a first aspect of the present invention, at the end of a predetermined time period, a power value consumed by all power loads in one facility or one area is repeatedly predicted for each predetermined time period. In the maximum demand power control device that controls the power consumption of the entire power load so that the value is equal to or less than a preset target value, when the predicted value exceeds the target value, a level corresponding to the excess is used. Reduction signal output means for generating a power reduction signal of the above, and outputting the power reduction signal to a predetermined power load according to the level of the power reduction signal,
While the power reduction signal is being output from the reduction signal output means, the power reduction signal is repeatedly turned on / off in accordance with a stop time and an operation time set in consideration of the environment in which the power load to be controlled is installed. Reduction signal control means, and a power reduction means provided corresponding to each of the total power loads, and, when a power reduction signal is input from the reduction signal control means, reducing power supplied to the corresponding power load. It is characterized by having.

According to the first aspect of the present invention, when the predicted value of the power consumed by all the power loads in one facility or one area exceeds the target value at the end of the predetermined time period, the reduction signal output means includes: Depending on the excess, for example, level 1
-3 are generated, and the power reduction signal is output to a predetermined power load corresponding to the level of the power reduction signal. That is, for example, there are three total power loads,
When the power reduction signal of level 1 is generated, the power reduction signal is output to the power load of the lowest priority, and when the power reduction signal of level 2 is generated, the power load of the lowest priority is output. Then, the power reduction signal is output to the next lower priority power load, and when the level 3 power reduction signal is generated, the power reduction signal is output to all the power loads.

The power reduction signal output from the reduction signal output means is turned on by the reduction signal control means for a stop time set in consideration of the environment in which the power load to be controlled is installed. The power is turned off during the set operation time, and this on / off control is repeatedly performed during the output period of the power reduction signal. Then, according to the power reduction signal on / off controlled by the reduction signal control means, the power supplied to the power load is reduced by the power reduction means corresponding to a predetermined power load corresponding to the level of the power reduction signal. You.

Thus, by the reduction signal control means,
Even when the power reduction signal is output, by periodically supplying power to the power load for a predetermined time, the operation state of the power load is maintained as much as possible, and a predetermined time period by all power loads is maintained. The power control of each power load is performed so that the power consumption of the power supply approaches the preset target power.

The power reduction signal described above includes a cutoff signal for cutting off the power supplied to the power load, in addition to a signal for reducing the power consumed in the power load.

The invention described in claim 2 is the same as the invention described in claim 1.
In the maximum demand power control device according to the above, a status signal indicating an output state of the power reduction signal output from the reduction signal control unit, a status signal transmitting unit that transmits at every predetermined transmission timing, synchronized with the transmission timing And receiving the status signal, generating the power reduction signal based on the received status signal, and outputting the power reduction signal to the power reduction unit associated in advance. I have.

According to the second aspect of the present invention, the status signal is transmitted from the status signal transmitting section to the status signal receiving section at every predetermined transmission timing. Therefore, if noise or radio interference occurs during the transmission timing, the noise or radio interference is ignored, and interference due to noise, radio interference, or the like can be avoided with a high probability.

The invention described in claim 3 is the same as the invention described in claim 2.
Wherein the status signal transmitting unit and the status signal receiving unit transmit and receive the status signal wirelessly. For this reason, wiring between the status signal transmitting unit and the status signal receiving unit is not required, and the installation of the maximum demand power control device is facilitated.

The invention described in claim 4 is the same as the invention described in claim 2.
In the maximum demand power control device according to the above, the status signal transmitting unit and the status signal receiving unit, using a power line connected to the status signal transmitting unit and the status signal receiving unit as a transmission line of the status signal Features. For this reason, there is no need to separately lay a transmission line for the status signal, and it is possible to reduce the burden of installing the maximum power control device.

According to a fifth aspect of the present invention, at the end of a predetermined time period, a power value consumed by all power loads in one facility or one area is repeatedly predicted for each predetermined time period, and the predicted value is set in advance. In the distributed maximum demand power control device that controls the power consumption of the total power load so as to be equal to or less than the set target value, a predicted power information output that outputs predicted power information indicated by a numerical value corresponding to the predicted value Means, a plurality of reduction signal output means for outputting a power reduction signal to a power load previously assigned to each of the total power loads based on the predicted power information, and the plurality of reduction signal outputs While the power reduction signal is output from the corresponding reduction signal output means, the power reduction signal is provided in consideration of the environment in which the controlled power load is installed. A plurality of reduction signal control means for repeatedly turning on / off in accordance with a predetermined stop time and an operation time; And a plurality of power reduction means for reducing the power supplied to the corresponding power load when is input.

According to the fifth aspect of the present invention, each of the plurality of reduction signal output means determines whether or not to output a power reduction signal to a power load assigned to each of the plurality of reduction signal output means. Is determined based on the predicted power information output from the. Further, when a power reduction signal is output from any of the plurality of reduction signal output means, the power reduction signal is output by the reduction signal control means corresponding to the reduction signal output means, and the power load to be controlled is set. The power is turned on during a stop time set in consideration of the environment, and is turned off during an operation time similarly set, and this on / off control is repeatedly performed during the output period of the power reduction signal.

This simplifies the wiring between the above-mentioned means, does not concentrate the control load on one means, and maintains the operation state of the power load as much as possible while maintaining the operation time of the power load as long as possible. Power control of each power load is performed so that power consumption approaches a preset target power.

The invention according to claim 6 is the first invention.
6. The maximum demand power control device according to any one of items 1 to 5, further comprising a sensor that measures a state of each room where the power load is installed, wherein the reduction signal control unit performs a measurement output from the sensor. It is characterized in that the lengths of the stop time and the operation time are changed according to the values.

Here, examples of sensors for measuring the state of each room include a temperature sensor for measuring the temperature of the room, a humidity sensor for measuring humidity, and an infrared sensor for detecting whether or not a person is present. Thus, in the on / off control of the power reduction signal performed by the reduction signal control unit, the lengths of the on-period and the off-period of the power reduction signal are changed according to the measurement values of the various sensors. For this reason, it becomes possible to adjust the operation state of the power load during the output of the power reduction signal to be optimal according to the situation of each room.

Further, according to the present invention, at the end of a predetermined time period, the power value consumed by all the power loads in one facility or one area is repeatedly predicted for each predetermined time period, and the predicted value is set in advance. In the maximum demand power control method for controlling the power consumption of all the power loads so as to be equal to or less than the set target value, when the predicted value exceeds the target value, a power reduction signal of a level corresponding to the excess is provided. And outputs the power reduction signal to a predetermined power load corresponding to the level of the power reduction signal. While the power reduction signal is being output, the power reduction signal is output to the control target power load. Are repeatedly turned on / off in accordance with a stop time and an operation time set in consideration of an environment in which the power supply is installed, and the power supplied to the total power load is reduced by the on / off power reduction signal. It is characterized in.

[0030]

Embodiments of the present invention will be described below with reference to the drawings.

[First Embodiment] First, a first embodiment of the maximum demand power control apparatus according to the present invention will be described with reference to FIG. FIG. 1 is a block diagram illustrating a configuration of the maximum demand power control device according to the present embodiment. here,
In this figure, the same components as those of the maximum demand power control device shown in FIG. 5 are denoted by the same reference numerals, and description thereof will be omitted. Here, in the present embodiment, the power load 24-1
24 to 5 are air conditioners installed in separate rooms in a certain facility.

In FIG. 1, reference numeral 1 denotes a demand calculation unit (reduction signal output means) which counts pulse signals output from the watt-hour meter 20 with a transmitting device, and based on the counted value,
The predicted power of the power loads 24-1 to 24-5 at the end of the demand time period (here, 30 minutes) is calculated every predetermined time (for example, every 30 seconds). Here, the calculation method of the predicted power is to use the same calculation method as that of the conventional maximum demand power control device. Further, the demand calculation unit 1
When the target power exceeds a preset target power, a shutoff signal of level 1 to level 6 is output according to the excess.

Here, it is assumed that the target power is appropriately set, for example, based on the results of the last year's power consumption of the entire facility including the power loads 24-1 to 24-5. The relationship between the magnitude of the excess and the level of the cutoff signal is appropriately set in advance by the user. Here, the level of the cutoff signal increases as the magnitude of the excess increases. In addition, here, the number of the above levels is 6
However, it is assumed that the number of levels is appropriately set by the user.

Then, the demand calculation section 1 is set to levels 1 to 5
When the shutoff signal is output, as in the demand calculation unit 23 shown in FIG. 5, as the level of the shutoff signal increases, the shutoff signal is sequentially output from the power load having the lower priority. Also, the level 6 cutoff signal is positioned as the limit power signal LS, and the demand calculation unit 1 cannot output the limit power signal LS until 20 minutes have elapsed from the start of the demand time period. Therefore, if an excess that satisfies the output condition of the level 6 cutoff signal occurs before 20 minutes have elapsed from the start of the demand time period, the demand calculation unit 1 outputs the level 5 cutoff signal.

Here, the time from the start of the demand time period at which the output of the limit power signal LS becomes possible (hereinafter referred to as the "limit power signal valid time; 20 minutes in the above case") is the power load relative to the target power. Are appropriately set depending on how much margin is taken for an increase in power consumption due to the addition of In other words, if you take this margin a lot,
To shorten the time from the start of the demand time period and reduce the margin, set a longer time from the start of the demand time period.

2 is a control signal output section (reduction signal control means)
When a cutoff signal is output from the demand calculation unit 1 to the power load, the output control of the cutoff signal is performed according to a predetermined time. That is, as shown in FIG. 2A, when a cutoff signal is output from the demand calculation unit 1 to a certain power load, the power load is changed to t1
A cutoff signal is output for a time (for example, 3 minutes), and the output of the cutoff signal is stopped for a time t2 (for example, 7 minutes). Thereafter, the process is repeated until the cutoff signal output from the demand calculation unit 1 stops (see FIG. 2B).

When the limit power signal LS is output from the demand calculation unit 1 after 20 minutes have elapsed from the start of the demand time period, the output control of the cutoff signal is not performed, and the output of the limit power signal LS is stopped. Until the power load 24-1
Continue to output the cutoff signal to .about.24-5.

Reference numeral 3 denotes a master unit (status signal transmitting means), which is output from the control signal output unit 2 to a certain power load at predetermined time intervals Δt, as shown in FIG. A signal indicating the state of the cutoff signal (hereinafter, referred to as a status signal) is transmitted to the corresponding slave unit (described below). Here, the length of the time interval Δt is supposed to be less than the times t1 and t2, and is set to 2 seconds here. When the status signal is at a low level, it indicates that a cutoff signal is being output, and when it is at a high level, it indicates that no cutoff signal is being output.

Reference numerals 4-1 to 4-5 denote power loads 24-1 to 24-2.
4-5 are slave units (status signal receiving means) provided in correspondence with the status signals transmitted from the master unit 3 to the own unit in synchronization with the transmission timing of the status signal. Receive. And each slave unit,
Based on the received status signal, a cutoff signal is generated as shown in FIG. 2D, and is output to a relay (power reduction means, not shown) provided on a power line to a corresponding power load.

Here, in FIG.
The status signal transmitted to 4-5 is configured to be transmitted via a dedicated transmission line, but is configured to be wirelessly transmitted from master unit 3 to slave units 4-1 to 4-5. May be. Further, the status signal may be superimposed on a power line (not shown) for supplying power to the parent device 3 and the child devices 4-1 to 4-5, and transmitted to a target child device. Good. Further, the status signal may be transmitted using a telephone line.

Next, the operation of the maximum demand power control device having the above configuration will be described. First, within a certain demand time period, when the predicted power exceeds the target power and a level 1 cut-off signal is output from the demand calculation unit 1, that is, only for the priority 5 power load 24-5. When the cutoff signal is output, the control signal output unit 2 outputs the cutoff signal for 3 minutes during the output period of the cutoff signal, and then stops the output for 7 minutes.
This is repeated until the cut-off signal from is no longer output.

As for the cutoff signal output from the control signal output unit 2, a status signal indicating its output state is transmitted from the master unit 3 to the slave unit 4-5 every two seconds.
Generate a cutoff signal based on the received status signal,
Output to the power load 24-5. Thereby, the slave unit 4-5
The power supplied to the power load 24-5 is interrupted while the shutoff signal is output from the power supply, and the power is supplied to the power load 24-5 while the shutoff signal is not output.

As described above, according to the level of the cutoff signal output from the demand calculation unit 1, the power loads 24-3 to
A cutoff signal is output for each of 24-5. When 20 minutes have elapsed from the start of the demand time period and the limit power signal LS (level 6 cutoff signal) is output from the demand calculation unit 1, the control signal output unit 2 periodically outputs Without performing the control to output and stop the cutoff signal, the cutoff signal is continuously output to all of the power loads 24-1 to 24-5. In this state, the output of the limit power signal LS from the demand calculation unit 1 is stopped,
Or, it continues until the end of the demand time period, during which time,
Power supply to all power loads is shut off.

As described above, in the maximum demand power control apparatus according to the present embodiment, even when the cut-off signal is output from the demand calculation unit 1, the maximum demand power control apparatus does not apply a predetermined time to the power load.
Power is supplied intermittently at a predetermined cycle. For this reason, for example, when the power load is an air conditioner, the intermittent operation can be performed during the shutoff signal output period, and as shown in FIG. 3, the indoor temperature rise is minimized and the indoor comfort is secured. be able to.

When the demand power section 1 outputs the limit power signal LS, the control signal output section 2 does not perform the above-described control for periodically outputting and stopping the cutoff signal, but continuously cuts off. Since the signal continues to be output, power supply to all power loads is shut off during that time. As a result, even if the power consumption suddenly increases during the control due to the increase of the unscheduled power load, it is less likely that the power consumption of all the power loads at the end of the demand time period exceeds the target power.

Further, in the maximum demand power control device of the present embodiment, even when the cutoff signal is output from the demand calculation section 1, the cutoff signal output from the control signal output section 2 causes the power load to be reduced. Since the power is intermittently supplied, the power is consumed in the power load to which the cutoff signal is output even during the output of the cutoff signal.

For this reason, in the maximum demand power control device of the present embodiment, after 20 minutes have elapsed from the start of the demand time period,
If the predicted power greatly exceeds the target power, the demand computing unit 1 outputs a limit power signal LS. If the limit power signal LS is output, the control signal output unit 2 periodically The control for outputting and stopping the cutoff signal is not performed, and the cutoff signal is continuously output.

As described above, even if the power load is intermittently operated while the cutoff signal is being output, in the case of the present embodiment, the limit power signal valid time (in this embodiment, 20 minutes from the start of the demand time period) ) By setting
The power control of all the control target power loads can be performed so that the predicted value does not exceed the target value.

Further, since the status signal transmitted from the master unit 3 to the slave units 4-1 to 4-2 is always transmitted at intervals of .DELTA.t, the status signal at a certain time may be disturbed by noise or radio interference. Even if the power load is received, the control of the power load is normally performed by the status signal transmitted next.

It is to be noted that a part of the above-described embodiment may be changed to a form as described below.

(1) The output time t1 and the stop time t2 of the cutoff signal output from the control signal output unit 2 are set to fixed values set in advance. For example, when the power load is an air conditioner, outside the facility May be provided, and the control signal output unit 2 may change the lengths of the output time t1 and the stop time t2 of the cutoff signal in accordance with the measurement value of the temperature sensor. That is, the higher the value measured by the temperature sensor, the longer the stop time t2 of the cutoff signal or the shorter the output time t1 of the cutoff signal.

(2) In connection with the above mode (1), the temperature sensor is installed in a room where a power load to be controlled for power supply is installed, and the control signal output unit 2 is controlled according to the room temperature.
The lengths of the output time t1 and the stop time t2 of the cutoff signal may be changed. Further, the length of the output time t1 and the stop time t2 of the cutoff signal may be changed according to the measurement value of the humidity sensor, not limited to the temperature sensor. Also, if an infrared sensor capable of detecting whether or not a person is installed is installed in the room where the power load is installed, and a human body is detected,
For example, the cutoff signal is turned on / off according to a preset time t1 and time t2 (that is, the power load is intermittently operated), and if no human body is detected, the demand calculation unit 1 outputs the cutoff signal as it is. (That is, time t2 = 0), the same control as in the conventional maximum demand power control device may be performed.

(3) Further, a sensor for detecting the state of the power load is provided, and the length of the output time t1 and the stop time t2 of the cutoff signal may be changed according to the measurement value output from the sensor. Good. Here, as a sensor for detecting the state of the power load, for example, when the power load is a pump, there is a pressure sensor for measuring the pressure of the liquid discharged from the pump.

(4) In the configuration shown in FIG. 1, the power load is associated with the slave unit on a one-to-one basis. However, one slave unit is associated with a plurality of power loads, ie, one slave unit. A configuration may be adopted in which a plurality of power loads are connected to the slave unit and the plurality of power loads are simultaneously controlled.

(5) The demand calculation unit 1 outputs a cutoff signal for cutting off the power supplied to the power load, but outputs a power reduction signal for reducing power consumption in the power load, and outputs the power reduction signal. Control may be performed so as to limit the power consumption to a value indicated by the reduction signal.

(6) When the slave units 4-1 to 4-5 receive a status signal from the master unit 3, it indicates that the slave unit 4-1 to 4-5 has successfully received the status signal before receiving the next status signal. The reception confirmation signal may be configured to be transmitted to base unit 3. In the base unit 3, the number of status signals transmitted to the slave unit is compared with the number of received acknowledgment signals transmitted from the slave unit, and the difference is equal to or greater than a preset number. In this case, for example, a buzzer or a lamp may be driven to notify the user that a communication error has occurred.

(7) When the maximum demand power control device described above is used in an environment where the possibility of occurrence of noise or radio interference is low, or when reduction of facility costs is prioritized, etc. And the slave units 4-1 to 4-5 are deleted,
The signal output from the control signal output unit 2 is directly transmitted to the power load 2
Output may be made to 4-1 to 24-5.

(8) In the above embodiment, the case where the maximum demand power control of the power load installed in a certain facility (for example, a factory, a building, etc.) is performed, but a plurality of houses or When performing power control in a facility or the like, for example, the power amount of a generator of a power company is measured, and based on the measured power amount, the above-described demand calculation unit 1, control signal output unit 2, base unit 3, The power supplied to each house or facility may be controlled by the slave unit 4 installed corresponding to each house or facility. When the maximum demand power control is performed for each chain store in a certain area, the demand calculation unit 1, the control signal output unit 2, and the master unit 3 are installed at the head office, and the slave unit 4 is installed at each branch. Is installed. Then, the power consumption is notified from each branch to the demand calculation unit 1 via the telephone line,
Based on the notified power consumption, the power supplied to the chain store may be controlled by the demand calculation unit 1, the control signal output unit 2, the master unit 3, and each slave unit 4.

[Second Embodiment] In the above-described first embodiment, a form of a so-called centralized control type maximum demand power control device in which a plurality of power loads are controlled by one demand calculation unit will be described. However, in the present embodiment, a form of a distributed control type maximum demand power control device that performs power control of a plurality of power loads in a distributed manner by a plurality of control units will be described.

FIG. 4 is a block diagram showing the configuration of the maximum demand power control device according to the present embodiment. In this figure,
The same components as those of the maximum demand power control device shown in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. However,
In the present embodiment, it is assumed that n power loads 24 are installed, and the number given after the hyphen of reference numeral 24 is the serial number. Hereinafter, the maximum demand power control device of the present embodiment will be described with reference to FIG.

Reference numeral 10 denotes a sensor node, which counts pulse signals output from the watt-hour meter 20 with a transmitting device, and predicts the power loads 24-1 to 24-n at the end of the demand time period based on the counted value. The power is supplied every predetermined time (for example, 3
(Every 0 seconds). Here, as for the method of calculating the predicted power, a calculation method similar to that of the conventional maximum demand power control device is used as in the first embodiment.

Then, predicted power information corresponding to the calculated predicted power is transmitted to each of the control nodes 11-1 to 11-n described below via a pair of transmission lines. Here, the predicted power information is represented by, for example, a finite integer value from 0 to 100, a value from 0 to 50 indicates a degree that the predicted power is lower than the target power, and a value from 51 to 100 is:
The degree to which the predicted power exceeds the target power is shown.

The control nodes 11-1 to 11-n output cutoff signals to the corresponding power loads 24-1 to 24-n based on the predicted power information transmitted from the sensor node 10. That is, the control nodes 11-1 to 11-
In n, a threshold determined according to the importance of the corresponding power load is set in advance, and a cutoff signal is output when the value of the predicted power information exceeds the threshold. Here, the threshold set for each control node is the total power in one facility or one region as a result of each control node individually controlling the corresponding power load based on the set threshold. It is assumed that the power value consumed by the load during the demand time period is set to be limited to the target power or less.

12-1 to 12-n correspond to the control node 1
Control signal output units provided corresponding to 1-1 to 11-n, respectively, as in the case of control signal output unit 2 shown in FIG. A cutoff signal is output for a set time t1, and a time t2
Stop the output of the cutoff signal for a time. As a result, while the cutoff signal is being output from the control signal output unit 12, the power supplied to the power load 24 corresponding to the control signal output unit 12 is cut off, and the output of the cutoff signal is stopped. Is powered.

In the maximum power demand control device having the above configuration, the control nodes 11-1 to 11-n respectively
The value of the predicted power information output from the sensor node 10,
By comparing with the threshold value set for each, if the value of the predicted power information exceeds the threshold value, a cutoff signal is output, and if the value of the predicted power information falls below the threshold value, the output of the cutoff signal is stopped. .

The control signal output units 12-1 to 12-n
When the shutoff signal is output from the corresponding control node, the shutoff signal is output for a predetermined time t1, and then the output of the shutoff signal is stopped for a predetermined time t2. , Stop are repeated until the cutoff signal is no longer output from the corresponding control node. Then, according to the cutoff signals output from the control signal output units 12-1 to 12-n, respectively, the corresponding power loads 24-1 to 2-2
Power to 4-n is turned off or supplied.

According to the maximum demand power control device of the present embodiment, the effects unique to the distributed control type maximum demand power control device, such as simplification of the wiring and concentration of the control load on one device, can be obtained. The same effect as in the first embodiment, for example, when the power load is an air conditioner, the air conditioner can be operated intermittently even if a shutoff signal is output from the control node corresponding to the air conditioner, and the indoor This has the effect of minimizing the temperature rise and ensuring indoor comfort.

It is to be noted that a part of the above-described embodiment may be changed to a form described below.

(1) A relay device is provided for relaying predicted power information transmitted from the sensor node 10 via a pair of transmission lines to a transmission line different from the pair of transmission lines, and is connected to the different transmission line. The control node may further control the power of the power load. (2) A unique address is assigned to each of the control nodes 11-1 to 11-n, and the sensor node 10 transmits predicted power information only to a specific control node by designating each address. You may. At this time, a special address for designating all control nodes may be provided, and when this address is designated, predicted power information transmitted from the sensor node 10 may be simultaneously transmitted to all control nodes. . (3) The predicted power information transmitted from the sensor node 10 may be transmitted to each of the control nodes 11-1 to 11-n via a telephone line, a power line, or wirelessly.

[0070]

As described above, according to the present invention,
Even if the power reduction signal is output because the predicted value exceeds the target value, the power is intermittently supplied to the power load. It is possible to control so that the power consumed in a predetermined time period by the entire power load within the area or in a certain area approaches a preset target power.

A status signal indicating the output state of the power reduction signal output from the reduction signal control means is transmitted at predetermined transmission timings, and the status signal is received in synchronization with the transmission timing. Generating the power reduction signal based on the status signal,
Since the status signal is output to the power reduction means, even if the status signal at a certain time is disturbed by noise or radio interference, the power signal can be controlled normally by the status signal transmitted next.

[Brief description of the drawings]

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

FIG. 2 is an explanatory diagram for explaining a state of a signal output from each unit of the maximum demand power control device.

FIG. 3 is a diagram illustrating a relationship between an operating state of an air conditioner whose power supply is controlled by the maximum demand power control device and a room temperature.

FIG. 4 is a block diagram illustrating a configuration of a maximum demand power control device according to a second embodiment of the present invention.

FIG. 5 is a block diagram showing a configuration of a conventional maximum demand power control device.

FIG. 6 is an explanatory diagram for explaining a state of a signal output from the conventional maximum demand power control device to each power load.

[Explanation of symbols]

 Reference Signs List 1 demand calculation unit 2, 12-1 to 12-n control signal output unit 3 master unit 4-1 to 4-5 slave unit 10 sensor node 11-1 to 11-n control node 20 power meter with transmitter 21 meter Transformer 22 Instrument current transformer 24-1 to 24-n Power load

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[Procedure amendment]

[Submission Date] January 26, 2000 (2000.1.2
6)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claims

[Correction method] Change

[Correction contents]

[Claims]

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0020

[Correction method] Change

[Correction contents]

The invention described in claim 2 is the same as the invention described in claim 1.
In the maximum demand power control device according to the above, the reduction signal
The control means includes an excess of the predicted value with respect to the target value.
Is greater than a predetermined value,
After a predetermined time has passed since the start,
A power signal, and the reduction signal control means outputs the power signal.
While the power signal is being output,
Continuously outputting the power reduction signal.
You. In addition, the invention described in claim 3 is based on claim 1 or 2
In the maximum demand power control device according to the above, a status signal indicating an output state of the power reduction signal output from the reduction signal control unit, a status signal transmitting unit that transmits at every predetermined transmission timing, synchronized with the transmission timing And receiving the status signal, generating the power reduction signal based on the received status signal, and outputting the power reduction signal to the power reduction unit associated in advance. I have.

[Procedure amendment 3]

[Document name to be amended] Statement

[Correction target item name] 0021

[Correction method] Change

[Correction contents]

According to the third aspect of the present invention, the status signal is transmitted from the status signal transmitting unit to the status signal receiving unit at every predetermined transmission timing. Therefore, if noise or radio interference occurs during the transmission timing, the noise or radio interference is ignored, and interference due to noise, radio interference, or the like can be avoided with a high probability.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0022

[Correction method] Change

[Correction contents]

The invention described in claim 4 is the third invention.
Wherein the status signal transmitting unit and the status signal receiving unit transmit and receive the status signal wirelessly. For this reason, wiring between the status signal transmitting unit and the status signal receiving unit is not required, and the installation of the maximum demand power control device is facilitated.

[Procedure amendment 5]

[Document name to be amended] Statement

[Correction target item name] 0023

[Correction method] Change

[Correction contents]

[0023] The invention described in claim 5 is the same as the invention described in claim 3.
In the maximum demand power control device according to the above, the status signal transmitting unit and the status signal receiving unit, using a power line connected to the status signal transmitting unit and the status signal receiving unit as a transmission line of the status signal Features. For this reason, there is no need to separately lay a transmission line for the status signal, and it is possible to reduce the burden of installing the maximum power control device.

[Procedure amendment 6]

[Document name to be amended] Statement

[Correction target item name] 0024

[Correction method] Change

[Correction contents]

According to a sixth aspect of the present invention, at the end of a predetermined time period, a power value consumed by all power loads in one facility or one area is repeatedly predicted for each predetermined time period, and the predicted value is set in advance. In the distributed maximum demand power control device that controls the power consumption of the total power load so as to be equal to or less than the set target value, a predicted power information output that outputs predicted power information indicated by a numerical value corresponding to the predicted value Means, a plurality of reduction signal output means for outputting a power reduction signal to a power load previously assigned to each of the total power loads based on the predicted power information, and the plurality of reduction signal outputs While the power reduction signal is output from the corresponding reduction signal output means, the power reduction signal is provided in consideration of the environment in which the controlled power load is installed. A plurality of reduction signal control means for repeatedly turning on / off in accordance with a predetermined stop time and an operation time; and a power reduction signal provided from the reduction signal control means provided in advance corresponding to each of the total power loads. And a plurality of power reduction means for reducing the power supplied to the corresponding power load when is input.

[Procedure amendment 7]

[Document name to be amended] Statement

[Correction target item name] 0025

[Correction method] Change

[Correction contents]

According to the sixth aspect of the present invention, each of the plurality of reduction signal output means determines whether or not to output a power reduction signal to a power load assigned to each of the plurality of reduction signal output means. Is determined based on the predicted power information output from the. Further, when a power reduction signal is output from any of the plurality of reduction signal output means, the power reduction signal is output by the reduction signal control means corresponding to the reduction signal output means, and the power load to be controlled is set. The power is turned on during a stop time set in consideration of the environment, and is turned off during an operation time similarly set, and this on / off control is repeatedly performed during the output period of the power reduction signal.

[Procedure amendment 8]

[Document name to be amended] Statement

[Correction target item name] 0027

[Correction method] Change

[Correction contents]

The invention described in claim 7 is the first invention.
7. The maximum power demand control device according to any one of items 1 to 6 , further comprising a sensor for measuring a state of each room where the power load is installed, wherein the reduction signal control unit performs a measurement output from the sensor. It is characterized in that the lengths of the stop time and the operation time are changed according to the values.

[Procedure amendment 9]

[Document name to be amended] Statement

[Correction target item name] 0029

[Correction method] Change

[Correction contents]

Furthermore, the invention according to claim 8, repeatedly predicts the power value consumed by the total power load in one facility or a region at a predetermined time period ending at each said predetermined fixed time limit, set the predicted value is previously In the maximum demand power control method for controlling the power consumption of all the power loads so as to be equal to or less than the set target value, when the predicted value exceeds the target value, a power reduction signal of a level corresponding to the excess is provided. And outputs the power reduction signal to a predetermined power load corresponding to the level of the power reduction signal. While the power reduction signal is being output, the power reduction signal is output to the control target power load. Are repeatedly turned on / off in accordance with a stop time and an operation time set in consideration of an environment in which the power supply is installed, and the power supplied to the total power load is reduced by the on / off power reduction signal. It is characterized in. Claim 9
The maximum demand power control method according to claim 8 is provided.
In, the excess of the predicted value with respect to the target value,
When the value exceeds a predetermined value, the predetermined time starts.
From the point at which a predetermined time has passed since
Signal, and while the limit power signal is being output,
Cutting off the power supplied to the total power load.
And

[Procedure amendment 10]

[Document name to be amended] Statement

[Correction target item name] 0064

[Correction method] Change

[Correction contents]

12-1 to 12-n correspond to the control node 1
Control signal output units provided corresponding to 1-1 to 11-n, respectively, as in the case of control signal output unit 2 shown in FIG. A cutoff signal is output for a set time t1, and a time t2
Stop the output of the cutoff signal for a time. Thus, while the cut-off signal from the control signal output section 12 is output, power supplied to power load 24 corresponding to the control signal output unit 12 is cut off, the output of the blocking signal is stopped Power is supplied during this time.

Claims (7)

[Claims] At the end of a predetermined time period, a power value consumed by all power loads in one facility or one area is repeatedly predicted for each of the predetermined time periods, and the predicted value becomes equal to or less than a preset target value. In the maximum demand power control device for controlling power consumption of all the power loads, when the predicted value exceeds the target value, a power reduction signal of a level corresponding to the excess is generated, and the power reduction signal Reduction signal output means for outputting the power reduction signal to a predetermined power load according to the level; and while the power reduction signal is being output from the reduction signal output means, the power reduction signal is output to the power load to be controlled. Signal reduction means for repeatedly turning on / off according to a stop time and an operation time set in consideration of an environment in which the power supply is installed; and a reduction signal control means provided for each of the total power loads. And a power reduction unit configured to reduce power supplied to a corresponding power load when a power reduction signal is input from a stage. 2. A status signal transmitting unit that transmits a status signal indicating an output state of a power reduction signal output from the reduction signal control unit at a predetermined transmission timing, and the status signal in synchronization with the transmission timing. And a status signal receiving unit that generates the power reduction signal based on the received status signal and outputs the power reduction signal to the power reduction unit. apparatus. 3. The maximum demand power control device according to claim 2, wherein the status signal transmitting unit and the status signal receiving unit transmit and receive the status signal wirelessly. 4. The status signal transmitting unit and the status signal receiving unit use a power line connected to the status signal transmitting unit and the status signal receiving unit as a transmission line of the status signal. 3. The maximum demand power control device according to 2. 5. A power value consumed by all power loads in one facility or one area at the end of a predetermined time period is repeatedly predicted for each predetermined time period so that the predicted value becomes equal to or less than a preset target value. In the distributed maximum demand power control device that controls the power consumption of all of the power loads, a predicted power information output unit that outputs predicted power information indicated by a numerical value corresponding to the predicted value, based on the predicted power information Out of the total power load
A plurality of reduction signal output means for outputting a power reduction signal to a power load assigned to each of them in advance; provided in correspondence with each of the plurality of reduction signal output means; A plurality of reduction signal control means for repeatedly turning on / off the power reduction signal in accordance with a stop time and an operation time set in consideration of an environment in which the power load to be controlled is installed while the reduction signal is output; A plurality of power reduction units provided corresponding to each of the total power loads and configured to reduce the power supplied to the corresponding power load when a power reduction signal is input from the reduction signal control unit associated in advance; Means for controlling maximum demand power. 6. A sensor for measuring a state of each room in which the power load is installed, wherein the reduction signal control unit controls the stop time and the operation time according to a measurement value output from the sensor. 6. The method according to claim 1, wherein the length is changed.
Maximum demand power control device according to the paragraph. 7. A power value consumed by all power loads in one facility or one area at the end of a predetermined time period is repeatedly predicted for each of the predetermined time periods so that the predicted value becomes equal to or less than a preset target value. A maximum power demand control method for controlling power consumption of all power loads, wherein when the predicted value exceeds the target value, a power reduction signal of a level corresponding to the excess is generated, and the power reduction signal is generated. The power reduction signal is output to a predetermined power load according to the level of the power load signal. While the power reduction signal is being output, the power reduction signal is output in consideration of the environment in which the power load to be controlled is installed. Maximum demand power control characterized by repeatedly turning on / off according to a set stop time and operation time, and reducing the power supplied to each of the power loads by the turned on / off power reduction signal. Method.