JP4603992B2 - Power consumption control device - Google Patents

Description

  The present invention provides a control means capable of determining a power consumption command value based on a target power consumption command value and controlling power consumption of a power load device that consumes power from a commercial system according to the power consumption command value. The present invention relates to a power consumption control device provided.

  As power supply devices connected to the commercial grid, power companies (general electric utilities) and specific-scale electric utilities, etc. installed as commercial power sources, individuals and groups other than electric utilities, There are distributed power supplies installed in various facilities. When power supply power is output from these power supply devices to a commercial system, the frequency of the power supply power is sent to match the reference frequency (50 Hz or 60 Hz). As a result, when the total power load by the power load device connected to the commercial system is balanced with the total power source power sent from the power unit, the frequency of power in the commercial system (hereinafter referred to as “commercial system frequency”) (Which may be described) is maintained at the reference frequency.

  In the commercial system as described above, when the total power source power and the total power load are not balanced, the commercial system frequency deviates from the reference frequency. Specifically, when the total power load is greater than the total power supply power, the commercial grid frequency is smaller than the reference frequency, and when the total power supply power is greater than the total power load, the commercial grid frequency is greater than the reference frequency. A frequency deviation occurs.

  Maintaining the commercial grid frequency at the reference frequency to prevent the occurrence of frequency deviations as described above is necessary to protect the benefits of power users, so the deviation of the commercial grid frequency from the reference frequency is acceptable. In order to be within the range, the electric power company performs frequency control such that the power source power output from the power plant is increased or decreased to balance the total power source power and the total power load (for example, see Non-Patent Document 1). .

Supervised by Ryuichi Yokoyama, “Liberalization of Electricity and Technology Development”, Tokyo Denki University Press, September 20, 2001, p. 133-135

  As described above, conventionally, when adjusting the balance between the total power supply power and the total power load in the commercial system, the power supplied to the commercial system using a power generator that can supply power to the commercial system A technique to vary the value is being implemented. However, the commercial system is also connected to a power load device that consumes the power of the commercial system, and the balance between the total power supply power and the total power load in the commercial system changes due to fluctuations in the power load caused by the power load device. Will do. However, conventionally, no contribution has been made to balance the total power supply power and the total power load in the commercial system by changing the power load of the power load device connected to the commercial system.

  Furthermore, even if there is no frequency deviation from the reference frequency of the commercial system frequency, if the commercial system frequency changes, frequency control can be performed to pull back the change in order to stabilize the commercial system frequency. preferable.

  This invention is made | formed in view of said subject, The objective is to provide the power consumption control apparatus which can contribute to the frequency control of a commercial system frequency.

The characteristic configuration of the power consumption control device according to the present invention for achieving the above object is to determine a power consumption command value based on a target power consumption command value,
Control means capable of controlling power consumption of a power load device that consumes power from a commercial system according to the power consumption command value ;
The control means is a power consumption control device configured to vary the power consumption command value based on a monitoring result of a frequency monitoring means for monitoring a commercial system frequency in the commercial system ,
When the control means has a change in the commercial system frequency and a frequency deviation from a reference frequency of the commercial system frequency is generated,
After operating the power load device by changing the power consumption command value according to a setting relationship that increases the power consumption command value as the commercial system frequency increases,
Determining whether the actual power consumption value is equal to the sum of the variable power consumption value for reducing the frequency deviation and the target power consumption command value;
When the actual power consumption value is not equal to the sum of the variable power consumption value and the target power consumption command value,
Using the sum of the variable power consumption value and the target power consumption command value as the power consumption command value, frequency change and frequency deviation corresponding control for operating the power load device is executed.
It is in the point comprised as follows.

The control means is configured to vary the power consumption command value based on the monitoring result of the frequency monitoring means for monitoring the commercial system frequency in the commercial system, so that the control means is controlled by the frequency monitoring means. Based on the monitoring result of the commercial system frequency to be monitored, the power consumption command value is changed. As a result, since the total power source power and the total power load in the commercial system approach each other, the standard of the commercial system frequency in the commercial system that occurred when the total power source power and the total power load were deviated. Deviations from frequency will be compensated.
Therefore, a power consumption control device that can contribute to frequency control in a commercial system can be provided.

According to the characteristic configuration , when the commercial system frequency increases (that is, in the commercial system) , the control unit varies the power consumption command value in accordance with a setting relationship that increases the power consumption command value as the commercial system frequency increases. When the power consumption command value increases and the commercial system frequency decreases (that is, when the total power supply power in the commercial system decreases with respect to the total power load) The power consumption command value becomes smaller. Further, when the actual power consumption value is not equal to the sum of the variable power consumption value and the target power consumption command value, the actual power consumption value is the difference between the variable power consumption value and the target power consumption command value. The power consumption command value is changed so as to be equal to the sum. As a result, even if the commercial system frequency changes, it is possible to contribute to stabilization of the commercial system frequency by performing frequency control that pulls back the change.
Thereafter, when the actual power consumption value is not equal to the sum of the variable power consumption value and the target power consumption command value, the power load device is set with the sum of the variable power consumption value and the target power consumption command value as the power consumption command value. By operating, it is possible to perform frequency control to compensate for the generated frequency deviation and bring the commercial system frequency close to the reference frequency.
Further, the control means executes normal control for operating the power load device using the target power consumption command value as the power consumption command value when there is no change in the commercial system frequency and no frequency deviation occurs.

  Still another characteristic configuration of the power consumption control device according to the present invention is that the control means has a variable power consumption for reducing the frequency deviation when a frequency deviation from a reference frequency of the commercial system frequency occurs. The frequency deviation corresponding control for operating the power load device is executed using the sum of the value and the target power consumption command value as the power consumption command value.

According to the above characteristic configuration, when the frequency deviation of the commercial system frequency from the reference frequency occurs, the control means calculates the sum of the variable power consumption value for reducing the frequency deviation and the target power consumption command value. The power load device is operated as the power consumption command value. In other words, by changing the actual power consumption value using the sum of the variable power consumption value for reducing the frequency deviation and the target power consumption command value as the power consumption command value, the total power supply power and the total power load in the commercial system Adjust to balance.
That is, when a positive frequency deviation has occurred (that is, when the commercial system frequency is higher than the reference frequency), the fluctuation power consumption value and the target power consumption command value for changing the power consumption value to increase Is derived as the power consumption command value, and on the other hand, when a negative frequency deviation occurs (that is, when the commercial system frequency is smaller than the reference frequency), the power consumption value is varied so as to decrease. The sum of the variable power consumption value and the target power consumption command value is derived as the power consumption command value. As a result, the deviation from the reference frequency of the commercial system frequency in the commercial system, which occurred when the total power source power and the total power load in the commercial system were deviated, is compensated.
The control means executes normal control for operating the power load device with the target power consumption command value as the power consumption command value when no frequency deviation occurs.

Still another characteristic configuration of the power consumption control device according to the present invention is that, when the control means has a change in the commercial system frequency and a frequency deviation from a reference frequency of the commercial system frequency occurs, After operating the power load device by changing the power consumption command value according to a setting relationship that increases the power consumption command value as the commercial system frequency increases, the actual power consumption value decreases the frequency deviation. To determine whether or not it is equal to the sum of the variable power consumption value and the target power consumption command value, and the actual power consumption value is equal to the sum of the variable power consumption value and the target power consumption command value When there is not, frequency change and frequency deviation corresponding control for operating the power load device is performed using the sum of the variable power consumption value and the target power consumption command value as the power consumption command value. The line,
When there is no change in the commercial grid frequency and a frequency deviation from a reference frequency of the commercial grid frequency occurs, a fluctuation power consumption value for reducing the frequency deviation and the target power consumption command value Using the sum as the power consumption command value, performing frequency deviation corresponding control for operating the power load device, and
When there is a change in the commercial grid frequency and no frequency deviation from a reference frequency of the commercial grid frequency occurs, the consumption according to a setting relationship that increases the power consumption command value as the commercial grid frequency increases. After operating the power load device by varying the power command value, it is determined whether or not the actual power consumption value is equal to the target power consumption command value, and the actual power consumption value is the target power consumption command. When the power consumption command value is not equal to the value, the target power consumption command value is used as the power consumption command value, and frequency change control for operating the power load device is executed.

According to the above characteristic configuration, as in the operation and effect of the above characteristic configuration, when the commercial system frequency changes and a frequency deviation from the reference frequency of the commercial system frequency occurs, the change in the commercial system frequency is performed. By performing frequency control such as pulling back, it is possible to contribute to stabilization of the commercial system frequency, and by performing frequency control to compensate for the generated frequency deviation, the commercial system frequency is brought close to the reference frequency. Can do.
Further, when the commercial system frequency does not change and a frequency deviation from the reference frequency of the commercial system frequency occurs, frequency control is performed so as to compensate for the generated frequency deviation. The frequency can be brought close to the reference frequency.
Furthermore, when the commercial system frequency changes and no frequency deviation from the reference frequency of the commercial system frequency occurs, frequency control is performed to pull back the change in the commercial system frequency to stabilize the commercial system frequency. Can contribute.

  Still another characteristic configuration of the power consumption control device according to the present invention is that the power load device is an electric heater capable of heating hot water for hot water storage.

According to the above characteristic configuration, since the electric energy corresponding to the fluctuating power consumption value is converted into thermal energy as hot water for hot water storage and stored, even if electric energy is forcibly consumed in the power load device, A large loss can be prevented from occurring for the installer of the load device.
In addition, although the power consumption of the power load device is variably controlled by the power consumption control device, it may affect the power consumption of the user, but the hot water storage device uses the stored hot water (thermal energy) as a buffer. It can be made to have little influence on the user's use of hot water.

<First Embodiment>
Below, the power consumption control apparatus 10 of 1st Embodiment of this invention is demonstrated with reference to drawings.
In the schematic diagram of the commercial system shown in FIG. 1, a power plant 30 and power load devices 2 and 40 that consume power in the commercial system 50 are connected to the commercial system 50. Further, a power consumption control device 10 capable of controlling the power consumption of the power load device 2 is provided. Note that a larger number of power consumption control devices 10, power plants 30, power load devices 2, 40, and the like may be connected to the commercial system 50.

  The power plant 30 connected to the commercial system 50 is, for example, a thermal power plant installed by an electric power company (general electric utility) or the like. Some of such power plants 30 have a frequency deviation that occurs when the commercial system frequency deviates from the reference frequency (50 Hz or 60 Hz), so that its output is immediately changed to compensate for the frequency deviation. An operation (a so-called governor characteristic) is performed. For example, when the commercial grid frequency is lower than the reference frequency (that is, when the total power supply power in the commercial grid 50 is smaller than the total power load), the power output from the power plant 30 to the commercial grid 50 is increased. Further, when the commercial system frequency increases from the reference frequency (that is, when the total power supply power in the commercial system 50 becomes larger than the total power load), the power output from the power plant 30 to the commercial system 50 is decreased.

  The power consumption control device 10 includes a frequency monitoring unit 11 that monitors a commercial system frequency in the commercial system 50 and a control unit 12 that can control the power consumption of the power load device 2. And the control means 12 is comprised so that the said power consumption command value may be fluctuate | varied based on the monitoring result of the frequency monitoring means 11. FIG. Furthermore, the power consumption control device 10 has a function of measuring the actual power consumption value of the power load device 2 (may be described as “actual power consumption value”).

  The power load device 2 to be controlled by the power consumption control device 10 includes a plurality of loads 2a to 2d. The control means 12 of the power consumption control device 10 has a target value of power consumption of the power load device 2 (hereinafter referred to as “target power consumption command value”). Therefore, when the power consumption command value based on the target power consumption command value is output from the control unit 12 to the power load device 2, the power load device 2 determines that the commercial system 50 is in accordance with the commanded power consumption command value. Consume power from. For example, when the power consumption control value is commanded to the power load device 2, the power consumption control device 10 loads the load necessary for consuming the commanded power consumption command value. Is energized. Therefore, the power consumption in the power load device 2 can be varied by varying the power consumption command value for the power load device 2.

The plurality of loads 2a to 2d constituting the power load device 2 can be realized by using various electric devices such as electric lamps, fans and heaters, storage batteries, and the like. Further, it may be a load including an inverter.
As an example, FIG. 1 illustrates a case where the load 2 d is an electric heater capable of heating hot water for hot water storage of the hot water storage device 60.
The hot water storage device 60 includes a hot water storage tank 61 for storing hot water for hot water storage. A hot water circulation path 62 is provided for circulating the hot water for hot water storage through the load 2d and the hot water storage tank 61. Further, a water supply line 63 for supplying water to the hot water storage tank 61 and a hot water supply line 64 for supplying hot water in the hot water storage tank 61 for various hot water supply applications are provided. In addition, you may further provide auxiliary heating means (not shown), such as a boiler which can heat the hot water flowing through the hot water supply line 64.

  The control means 12 included in the power consumption control device 10 is configured to vary the power consumption command value based on the monitoring result of the frequency monitoring means 11 as described above. Specifically, the control unit 12 executes any one of normal control, frequency change and frequency deviation correspondence control, frequency deviation correspondence control, and frequency change correspondence control, which will be described later, based on the monitoring result of the frequency monitoring unit 11. To do.

  The control means 12 indicates that the monitoring result of the frequency monitoring means 11 has no change in the commercial system frequency (as will be described later, the commercial system frequency has not changed from the set target frequency which is the current commercial system frequency). When the frequency deviation from the reference frequency of the commercial system frequency does not occur, normal control for operating the power load device 2 is executed with the target power consumption command value as the power consumption command value.

  When the monitoring result of the frequency monitoring unit 11 indicates that the commercial system frequency has changed and a frequency deviation from the reference frequency of the commercial system frequency has occurred, the control unit 12 After the power load apparatus 2 is operated by changing the power consumption command value according to a setting relationship (corresponding to a “droop characteristic” described later with reference to FIG. 7) that increases the power consumption command value as the frequency increases, Is determined to be equal to the sum of the variable power consumption value for reducing the frequency deviation and the target power consumption command value, and the actual power consumption value is the above-mentioned variable power consumption value and the target power consumption. When it is not equal to the sum of the command value, the frequency change and frequency deviation corresponding control for operating the power load device 2 is performed using the sum of the variable power consumption value and the target power consumption command value as the power consumption command value. Row.

The variable power consumption value is derived based on the frequency bias characteristic shown in FIG. The frequency bias characteristic illustrated in FIG. 8 has a variable power consumption value according to the frequency deviation, when the frequency deviation is between the set lower limit value: Δf _L and the set upper limit value: Δf _H or less. Is determined in a relationship that monotonically increases at a predetermined change rate (C1, C2) as the value increases. Further, in this frequency bias characteristic, dead band widths A1 and A2 of frequency deviation are set between −Δf _L and Δf _L , and an upper limit width B1 and a lower limit width B2 of the variable power consumption value are set.
Thus, when a positive frequency deviation occurs (that is, when the total power load in the commercial system 50 is smaller than the total power supply power), the power consumption value of the power load device 2 is increased to increase the commercial system 50. The variable power consumption value is set to zero or a positive value to contribute to increase the total power load at. Further, when a negative frequency deviation occurs (that is, when the total power load in the commercial system 50 is larger than the total power supply power), the power consumption value of the power load device 2 is reduced to reduce the power load in the commercial system 50. In order to contribute to reducing the total power load, the variable power consumption value is set to zero or a negative value.

  Furthermore, when the monitoring result of the frequency monitoring unit 11 indicates that the commercial system frequency has not changed and the frequency deviation from the reference frequency of the commercial system frequency has occurred, the control unit 12 Frequency deviation correspondence control for operating the power load device 2 is executed using the sum of the variable power consumption value for reducing the deviation and the target power consumption command value as the power consumption command value.

  Further, when the monitoring result of the frequency monitoring unit 11 indicates that the commercial system frequency has changed and the frequency deviation from the reference frequency of the commercial system frequency has not occurred, the control unit 12 Whether or not the actual power consumption value is equal to the target power consumption command value after the power load device 2 is operated by changing the power consumption command value according to the setting relationship in which the power consumption command value is increased as the frequency increases. When it is determined that the actual power consumption value is not equal to the target power consumption command value, frequency change control for operating the power load device 2 is executed using the target power consumption command value as the power consumption command value.

Next, referring to the main control flow shown in FIG. 2, the sub-control flow shown in FIGS. 3 to 5, and the graph of the transition of the commercial system frequency and the power consumption value shown in FIG. 6, the power consumption of the first embodiment. The operation of the control device will be described.
As shown in the main control flow of FIG. 2, in step S1, the control means 12 determines whether or not the commercial system frequency has changed from the set target frequency based on the monitoring result of the frequency monitoring means 11, that is, the commercial system frequency. Determine if there is a change. When the commercial system frequency has changed from the set target frequency, the process proceeds to step S2, and when the commercial system frequency has not changed from the set target frequency, the process proceeds to step S3.
In step S <b> 2, the control unit 12 determines whether or not a frequency deviation from the reference frequency (60 Hz in the present embodiment) of the commercial system frequency has occurred based on the monitoring result of the frequency monitoring unit 11. Then, the control means 12 shifts to step S10 when the frequency deviation occurs, and executes frequency and frequency deviation correspondence control described later with reference to FIG. 3, and when the frequency deviation does not occur, the control means 12 performs step S20. Then, the frequency change handling control described later with reference to FIG. 4 is executed.

  In step S3, the control means 12 determines whether or not a frequency deviation from the reference frequency of the commercial system frequency has occurred based on the monitoring result of the frequency monitoring means 11. Then, the control means 12 shifts to step S30 when the frequency deviation occurs, executes frequency deviation correspondence control described later with reference to FIG. 5, and shifts to step S4 when the frequency deviation does not occur. Then, the power load device 2 is operated with the target power consumption command value as the power consumption command value (normal control).

  In the specific example shown in FIG. 6, the target power consumption command value is maintained at P1, and the power consumption command value and the actual power consumption value correspond to changes in the commercial system frequency from time t1 to time t6. P1 → P2 → P3 → P4 → P1.

The frequency change and frequency deviation corresponding control (step S10) executed when there is a change in the commercial system frequency and a frequency deviation from the reference frequency of the commercial system frequency is generated (step S10) will be described below. This will be described with reference to the control flow.
First, the transition of the commercial system frequency up to time t3 shown in FIG. 6 and the transition of the actual power consumption value (power consumption command value) will be described.
Until time t1 in FIG. 6, as in step S4 described above, the control means 12 operates the power load device 2 with the target power consumption command value: P1 as the power consumption command value.
Then, in step S11 of FIG. 3, when the commercial system frequency changes from f1 (reference frequency: 60 Hz), which is the set target frequency at this time, to f2, based on the drooping characteristic A shown in FIG. The power consumption command value P2 corresponding to the commercial system frequency f2 after the change is derived. This drooping characteristic A is set by a straight line having a predetermined slope passing through the set target frequency: f1 and the power consumption command value: P1, and a setting relationship is set for increasing the power consumption command value as the commercial system frequency increases. It is. Specifically, when the commercial system frequency is maintained at the set target frequency: f1, the power consumption command value is the target power consumption command value: P1, but when the commercial system frequency changes to f2, the control means 12 Based on the drooping characteristic A, the power consumption command value is derived as P2. In step S12, the control means 12 controls the operation of the power load device 2 according to the power consumption command value: P2. Further, in step S13, the control means 12 sets the changed commercial system frequency: f2 to the set target frequency thereafter.
In step S14, the control means 12 derives a variable power consumption value ΔP for reducing the frequency deviation: (f2-60) Hz based on the frequency bias characteristic shown in FIG.

  When the control means 12 performs the above control, the power consumption command value changes from P1 to P2 after the commercial system frequency changes from f1 to f2 at time t1, as shown in FIG. The power value also becomes P2 at time t2.

  Next, in step S15, the control means 12 determines whether or not the actual power consumption value is equal to the target power consumption command value: P1 and the sum of the variable power consumption value: ΔP: P3. When the actual power consumption value is not equal to the target power consumption command value: P1 and the sum of the variable power consumption value: ΔP: P3, the process proceeds to step S16. On the other hand, when the actual power consumption value is equal to the target power consumption command value: P1 and the sum of the variable power consumption value: ΔP: P3, the main control flow of FIG. 2 is performed without changing the power consumption command value. Return to

In step S16, the control means 12 determines the sum P3 of the target power consumption command value: P1 and the variable power consumption value: ΔP as the power consumption command value. In step S17, the control means 12 operates the power load device 2 according to the power consumption command value P3 determined in step S16.
In step S18, the control means 12 changes and sets the drooping characteristic to the drooping characteristic B that passes through the set target frequency: f2 and the power consumption command value: P3 at that time.

  When the control means 12 performs the above control, the actual power consumption value changes from P2 to P3 after the actual power consumption value becomes P2 at time t2 shown in FIG. Also becomes P3 at time t3.

Next, the transition of the commercial system frequency from time t3 to time t4 in FIG. 6 and the transition of the actual power consumption value (power consumption command value) will be described.
When the sub-control flow of the frequency change and frequency deviation corresponding control shown in FIG. 3 is completed at time t3 in FIG. 6, there is no change in the commercial system frequency and a frequency deviation from the reference frequency of the commercial system frequency occurs. Therefore, the control means 12 executes frequency deviation corresponding control (sub-control flow shown in FIG. 5) in step S30 (step S1, step S3, step S30 in FIG. 2).

  In step S31 of FIG. 5, the control unit 12 derives a variable power consumption value: ΔP for reducing the frequency deviation: (f2-60) Hz based on the frequency bias characteristic shown in FIG. Next, in step S32, the control means 12 determines whether or not the actual power consumption value is equal to the target power consumption command value: P1 and the sum of the variable power consumption value: ΔP: P3. When the actual power consumption value is not equal to the target power consumption command value: P1 and the sum of the variable power consumption value: ΔP: P3, the process proceeds to step S33. On the other hand, when the actual power consumption value is equal to the target power consumption command value: P1 and the variable power consumption value: ΔP: P3, the main control flow of FIG. 2 is performed without changing the power consumption command value. Return to

  In step S33, the control means 12 determines the sum of the target power consumption command value: P1 and the variable power consumption value: ΔP: P3 as the power consumption command value. In step S34, the control unit 12 operates the power load device 2 in accordance with the power consumption command value P3 determined in step S33.

  When the control means 12 performs the above control, the power consumption command value is maintained at P3 from time t3 to time t4 shown in FIG. 6, and the actual power consumption value is also maintained at P3. .

Next, the transition of the commercial system frequency from time t4 to time t6 in FIG. 6 and the transition of the actual power consumption value (power consumption command value) will be described.
When time t4 in FIG. 6 is reached, since there is a change in the commercial system frequency and no frequency deviation from the reference frequency of the commercial system frequency has occurred, the control means 12 performs the frequency change control (step S20) in FIG. 4 is executed (step S1, step S2, step S20 in FIG. 2).

  In step S21 of FIG. 4, when the commercial system frequency changes from f2 (set target frequency at this time) to f1, the control unit 12 changes the commercial system frequency after the change: f1 based on the drooping characteristic B shown in FIG. A power consumption command value P4 corresponding to is derived. This drooping characteristic B is set by a straight line that passes through the set target frequency: f2 and the power consumption command value: P3 at this time, and a setting relationship is set for increasing the power consumption command value as the commercial system frequency increases. It is. In step S22, the control means 12 controls the operation of the power load device 2 according to the power consumption command value: P4. Further, in step S23, the control means 12 sets the changed commercial system frequency: f1 to the set target frequency thereafter.

  When the control means 12 performs the control as described above, the power consumption command value changes from P3 to P4 after the commercial system frequency changes from f2 to f1 at time t4 as shown in FIG. The power value also becomes P4 at time t5.

  Next, in step S24, the control means 12 determines whether or not the actual power consumption value is equal to the target power consumption command value: P1. When the actual power consumption value is not equal to the target power consumption command value: P1, the process proceeds to step S25. On the other hand, when the actual power consumption value is equal to the target power consumption command value: P1, the process returns to the main control flow of FIG. 2 without changing the power consumption command value.

In step S25, the control means 12 determines the target power consumption command value: P1 as the power consumption command value. In step S26, the control means 12 operates the power load device 2 according to the power consumption command value P1 determined in step S25.
In step S27, the control means 12 changes and sets the drooping characteristic to the drooping characteristic A passing through the set target frequency: f1 and the power consumption command value: P1 at that time.

  When the control means 12 performs the control as described above, after the actual power consumption value becomes P4 at time t5 shown in FIG. 6, the power consumption command value changes from P4 to P1, and the actual power consumption value. Also becomes P1 at time t6.

<Second Embodiment>
As shown in the main control flow of FIG. 9, the power consumption control device 10 of the second embodiment determines whether or not a frequency deviation has occurred (step S3), and the monitoring result of the frequency monitoring means 11 is When it indicates that a frequency deviation from the reference frequency of the commercial system frequency has occurred, the power consumption command value is the sum of the variable power consumption value and target power consumption command value for reducing the frequency deviation. Frequency deviation corresponding control for operating the load device 2 is executed (step S30). In other words, in the second embodiment, the control means 12 uses the power consumption value of the power load device 2 regardless of whether there is a change in the commercial grid frequency (whether the commercial grid frequency is different from the set target frequency). Execute the control. Hereinafter, the power consumption control device 10 of the second embodiment will be described, but the description of the same configuration as that of the first embodiment will be omitted.

  Below, referring to the main control flow shown in FIG. 9, the sub-control flow shown in FIG. 5, and the graph of the transition of the commercial system frequency and the power consumption value shown in FIG. 10, the power consumption control device of the second embodiment The operation will be described.

  As shown in the main control flow of FIG. 9, in step S3, the control means 12 determines whether or not a frequency deviation from the reference frequency of the commercial system frequency has occurred based on the monitoring result of the frequency monitoring means 11. . Then, the control means 12 shifts to step S30 when the frequency deviation occurs, executes frequency deviation correspondence control described later with reference to FIG. 5, and shifts to step S4 when the frequency deviation does not occur. Then, the power load device 2 is operated with the target power consumption command value as the power consumption command value (normal control).

  When the commercial system frequency is changed from f1 (reference frequency 60 Hz) to f2 at time t10 shown in FIG. 10 to generate a frequency deviation from the reference frequency of the commercial system frequency, the control unit 12 in step S31 of FIG. Derives a variable power consumption value: ΔP for reducing the frequency deviation: (f2-60) Hz, based on the frequency bias characteristic shown in FIG. Next, in step S32, the control means 12 determines whether or not the actual power consumption value is equal to the target power consumption command value: P1 and the sum of the variable power consumption value: ΔP: P3. When the actual power consumption value is not equal to the target power consumption command value: P1 and the sum of the variable power consumption value: ΔP: P3, the process proceeds to step S33. On the other hand, when the actual power consumption value is equal to the target power consumption command value: P1 and the variable power consumption value: ΔP: P3, the main control flow of FIG. 9 is performed without changing the power consumption command value. Return to

  In step S33, the control means 12 determines the sum of the target power consumption command value: P1 and the variable power consumption value: ΔP: P3 as the power consumption command value. In step S34, the control unit 12 operates the power load device 2 in accordance with the power consumption command value P3 determined in step S33. When the control unit 12 performs the control as described above, the power consumption command value is set to P3 from time t11 shown in FIG. 10, and the actual power consumption value also varies from P1 to P3 between time t11 and time t12. Will do.

While the frequency deviation is occurring, the power consumption command value is maintained at P3, and the actual power consumption value is also maintained at P3.
On the other hand, when the commercial system frequency changes from f2 to f1 at time t13 shown in FIG. 10 and the frequency deviation from the reference frequency of the commercial system frequency disappears, step S4 of the main control flow shown in FIG. 9 is executed. Will be. That is, the control means 12 sets the target power consumption command value: P1 as the power consumption command value, and operates the power load device 2 according to the power consumption command value: P1. As a result, as shown in FIG. 10, the actual power consumption value also changes from P3 to P1 between time t14 and time t15.

<Third Embodiment>
As shown in the main control flow of FIG. 11, the power consumption control device 10 of the third embodiment determines whether there is a change in the commercial system frequency (that is, whether the commercial system frequency is different from the set target frequency). A determination is made (step S1), and when the monitoring result of the frequency monitoring unit 11 indicates that the commercial system frequency has changed, the control unit 12 increases the power consumption command value as the commercial system frequency increases. After operating the power load device 2 by changing the power consumption command value according to the setting relationship, it is determined whether the actual power consumption value is equal to the target power consumption command value, and the actual power consumption value is the target power consumption. When it is not equal to the command value, frequency change corresponding control for operating the power load device 2 is executed using the target power consumption command value as the power consumption command value (step S20). That is, in the present embodiment, the control unit 12 controls the power consumption value of the power load device 2 regardless of the frequency deviation of the commercial system frequency from the reference frequency. Hereinafter, the power consumption control device 10 of the third embodiment will be described, but the description of the same configuration as that of the first embodiment will be omitted.

  Below, referring to the main control flow shown in FIG. 11, the sub-control flow shown in FIG. 4, and the graph of the transition of the commercial system frequency and the power consumption value shown in FIG. 12, the power consumption control device of the third embodiment is described. The operation will be described.

  As shown in the main control flow of FIG. 11, in step S1, the control means 12 determines whether or not the commercial system frequency has changed from the set target frequency, that is, whether or not the commercial system frequency has changed. Then, when the commercial system frequency has changed from the set target frequency, the routine proceeds to step S20, where frequency change control described later with reference to FIG. 4 is executed, and when no frequency change has occurred, the routine proceeds to step S4. Then, the power load device 2 is operated with the target power consumption command value as the power consumption command value (normal control).

  When the commercial system frequency changes from f1 to f2 at time t21 shown in FIG. 12, in step S21 of FIG. 4, the control means 12 responds to the changed commercial system frequency: f2 based on the drooping characteristic A shown in FIG. The power consumption command value: P2 is derived. This drooping characteristic A is set by a straight line that passes through the set target frequency: f1 and the power consumption command value: P1 at this time, and a setting relationship is defined in which the power consumption command value increases as the commercial system frequency increases. It is. In step S22, the control means 12 controls the operation of the power load device 2 according to the power consumption command value: P2. Further, in step S23, the control means 12 sets the changed commercial system frequency: f2 to the set target frequency thereafter.

  When the control means 12 performs the control as described above, the power consumption command value changes from P1 to P2 after the commercial system frequency changes from f1 to f2 at time t21 as shown in FIG. The power value also becomes P2 at time t22.

  Next, in step S24, the control means 12 determines whether or not the actual power consumption value is equal to the target power consumption command value: P1. When the actual power consumption value is not equal to the target power consumption command value: P1, the process proceeds to step S25. On the other hand, when the actual power consumption value is equal to the target power consumption command value: P1, the process returns to the main control flow of FIG. 11 without changing the power consumption command value.

In step S25, the control means 12 determines the target power consumption command value: P1 as the power consumption command value. In step S26, the control means 12 operates the power load device 2 according to the power consumption command value P1 determined in step S25.
In step S27, the control means 12 changes and sets the drooping characteristic to the drooping characteristic C that passes through the set target frequency: f2 and the power consumption command value: P1 at that time.

  When the control means 12 performs the control as described above, the actual power consumption value changes from P2 to P1 after the actual power consumption value becomes P2 at time t22 shown in FIG. 12, and the actual power consumption value. Also becomes P1 at time t23.

  Thereafter, when the commercial system frequency changes from f2 (set target frequency at this time) to f1 at time t24 shown in FIG. 12, the control means 12 in step S21 of FIG. 4 based on the drooping characteristic C shown in FIG. The power consumption command value P5 corresponding to the commercial system frequency f1 after the change is derived. This drooping characteristic C is set by a straight line passing through the set target frequency: f2 and the power consumption command value: P1 at this time, and a setting relationship is defined in which the power consumption command value increases as the commercial system frequency increases. It is. In step S22, the control means 12 controls the operation of the power load device 2 according to the power consumption command value: P5. Further, in step S23, the control means 12 sets the changed commercial system frequency: f1 to the set target frequency thereafter.

  When the control means 12 performs the control as described above, the power consumption command value changes from P1 to P5 after the commercial system frequency changes from f2 to f1 at time t24 as shown in FIG. The power value also becomes P5 at time t25.

  Next, in step S24, the control means 12 determines whether or not the actual power consumption value is equal to the target power consumption command value: P1. When the actual power consumption value is not equal to the target power consumption command value: P1, the process proceeds to step S25. On the other hand, when the actual power consumption value is equal to the target power consumption command value: P1, the process returns to the main control flow of FIG. 11 without changing the power consumption command value.

In step S25, the control means 12 determines the target power consumption command value: P1 as the power consumption command value. In step S26, the control means 12 operates the power load device 2 according to the power consumption command value P1 determined in step S25.
In step S27, the control means 12 changes and sets the drooping characteristic to the drooping characteristic A passing through the set target frequency: f1 and the power consumption command value: P1 at that time.

  When the control means 12 performs the control as described above, after the actual power consumption value becomes P5 at time t25 shown in FIG. 12, the power consumption command value changes from P5 to P1, and the actual power consumption value. Is also P1 at time t26.

<Fourth embodiment>
As shown in the control flow of FIG. 13, the power consumption control device 10 of the fourth embodiment determines whether or not the commercial system frequency has changed (step S41), and is obtained as a monitoring result of the frequency monitoring unit 11. When the commercial system frequency is changed, the frequency change control is performed to change the power consumption command value in accordance with the setting relation of increasing the power consumption command value as the commercial system frequency increases. That is, in 4th Embodiment, the control means 12 controls the electric power load apparatus 2 based on the power consumption command value as a function of the commercial system frequency shown in FIG. Therefore, in the present embodiment, there is no target power consumption command value as in the first to third embodiments.

The operation of the power consumption control apparatus according to the fourth embodiment will be described below with reference to the control flow shown in FIG.
As shown in the control flow of FIG. 13, in step S41, the control means 12 determines whether or not there is a change in the commercial system frequency. Then, when there is a change in the commercial system frequency, the control means 12 proceeds to step S42, and in step S42, based on the drooping characteristics shown in FIG. 7, the power consumption command value corresponding to the changed commercial system frequency is set. To derive. Next, in step S43, the control means 12 operates the power load device 2 according to the derived power consumption command value.

<Another embodiment>
<1>
In the above embodiment, the drooping characteristic and the frequency bias characteristic have been described with reference to FIGS. 7 and 8. However, the slope (change rate) of the straight line representing the drooping characteristic and the dead band width representing the frequency bias characteristic: A1, A2, upper limit Width: B1 and lower limit width: B2, change rate: C1, C2 can be changed as appropriate.

<2>
In the above embodiment, among the plurality of loads 2 a to 2 d included in the power load device 2, the load in the non-energized state is set in the energized state and the load in the energized state is set in the non-energized state. Although the example in which the power consumption of the load device 2 is fluctuated is described, the power consumption of the power load device 2 can be fluctuated and controlled by changing the energization amount for one load.

  The power consumption control device of the present invention can be used to stabilize the commercial system frequency in the commercial system near the reference frequency.

Schematic diagram of commercial system Main control flow of the first embodiment Sub-control flow of the first embodiment Sub-control flow of the first embodiment Sub-control flow of the first embodiment The graph which shows transition of the commercial system frequency of 1st Embodiment, and actual power consumption value Graph showing drooping characteristics Graph showing frequency bias characteristics Main control flow of the second embodiment The graph which shows transition of the commercial system frequency of 2nd Embodiment, and actual power consumption value Main control flow of the third embodiment The graph which shows transition of the commercial system frequency of 3rd Embodiment, and actual power consumption value Control flow of the fourth embodiment

Explanation of symbols

2 Power load device 10 Power consumption control device 11 Frequency monitoring means 12 Control means 50 Commercial system

Claims (4)

Determine the power consumption command value based on the target power consumption command value,
Control means capable of controlling power consumption of a power load device that consumes power from a commercial system according to the power consumption command value ;
The control means is a power consumption control device configured to vary the power consumption command value based on a monitoring result of a frequency monitoring means for monitoring a commercial system frequency in the commercial system ,
When the control means has a change in the commercial system frequency and a frequency deviation from a reference frequency of the commercial system frequency is generated,
After operating the power load device by changing the power consumption command value according to a setting relationship that increases the power consumption command value as the commercial system frequency increases,
Determining whether the actual power consumption value is equal to the sum of the variable power consumption value for reducing the frequency deviation and the target power consumption command value;
When the actual power consumption value is not equal to the sum of the variable power consumption value and the target power consumption command value,
Using the sum of the variable power consumption value and the target power consumption command value as the power consumption command value, frequency change and frequency deviation corresponding control for operating the power load device is executed.
A power consumption control device configured as described above. Determine the power consumption command value based on the target power consumption command value,
Control means capable of controlling power consumption of a power load device that consumes power from a commercial system according to the power consumption command value ;
The control means is a power consumption control device configured to vary the power consumption command value based on a monitoring result of a frequency monitoring means for monitoring a commercial system frequency in the commercial system ,
When the control means has a frequency deviation from a reference frequency of the commercial system frequency, a sum of a variable power consumption value for reducing the frequency deviation and the target power consumption command value is calculated as the power consumption command. A power consumption control device configured to execute frequency deviation control for operating the power load device as a value . Determine the power consumption command value based on the target power consumption command value,
Control means capable of controlling power consumption of a power load device that consumes power from a commercial system according to the power consumption command value ;
The control means is a power consumption control device configured to vary the power consumption command value based on a monitoring result of a frequency monitoring means for monitoring a commercial system frequency in the commercial system ,
The control means increases the power consumption command value as the commercial system frequency increases when there is a change in the commercial system frequency and a frequency deviation from a reference frequency of the commercial system frequency occurs. After operating the power load device by changing the power consumption command value according to the setting relationship, the actual power consumption value is the difference between the variable power consumption value for reducing the frequency deviation and the target power consumption command value. It is determined whether or not the actual power consumption value is equal to the sum, and when the actual power consumption value is not equal to the sum of the variable power consumption value and the target power consumption command value, the variable power consumption value and the target power consumption command value Using the sum of the above as the power consumption command value, the frequency load and frequency deviation corresponding control for operating the power load device is executed,
When there is no change in the commercial grid frequency and a frequency deviation from a reference frequency of the commercial grid frequency occurs, a fluctuation power consumption value for reducing the frequency deviation and the target power consumption command value Using the sum as the power consumption command value, performing frequency deviation corresponding control for operating the power load device, and
When there is a change in the commercial grid frequency and no frequency deviation from a reference frequency of the commercial grid frequency occurs, the consumption according to a setting relationship that increases the power consumption command value as the commercial grid frequency increases. After operating the power load device by varying the power command value, it is determined whether or not the actual power consumption value is equal to the target power consumption command value, and the actual power consumption value is the target power consumption command. When not equal to the value, the power consumption control device is configured to execute frequency change response control for operating the power load device using the target power consumption command value as the power consumption command value .   The power consumption control device according to any one of claims 1 to 3, wherein the power load device is an electric heater capable of heating hot water for hot water storage.

Images