JP2018152965A - Generator operation control apparatus and generator operation control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a generator operation control apparatus and a generator operation control method that can efficiently operate a generator even when a variation in load power is large.SOLUTION: The generator operation control apparatus includes: a storage unit that stores achievement information on load power; a load power prediction unit that predicts a variation pattern of the load power based on the achievement information; a reference power calculation unit that calculates a reference power indicating a reference value for controlling a generator based on a variation pattern of the load power estimated by the load power prediction unit; and a generator control unit that controls the generator based on a comparison result between the variation pattern of the load power estimated by the load power prediction unit and the reference power calculated by the reference power calculation unit.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a generator operation control device and a generator operation control method.

  Large equipment such as air conditioners in buildings such as factories consumes a large amount of power compared to air conditioning for home use. In such a factory, a generator may be operated separately from the purchased power in order to cover power consumption. By operating the generator, the power consumption of the entire building is prevented from exceeding the contracted power, thereby suppressing an increase in the utility cost of the building. On the other hand, although the cost for operating the generator is generated, Patent Document 1 discloses a generator operation control method capable of operating the generator efficiently.

JP 2005-333773 A

  Such a large-scale facility may be operated in a form such as being operated at a required time zone such as a working daytime and not being operated at night. FIG. 9 is a first diagram illustrating an example of a variation pattern of load power of a large facility. FIG. 9 shows time on the horizontal axis and load power on the vertical axis. As shown in FIG. 9, the load power increases during the time period when the large facility is operated. Moreover, in the time slot | zone which waits for a large sized facility, since the large sized facility is not operated, load electric power becomes small and it will be in the state of a low load. When a large facility is operated in such a form, fluctuations in load power (load fluctuations) increase. In such a building, when the generator is operated regardless of fluctuations in the load power, the generator becomes a low-load operation when the load power decreases. A generator such as a diesel generator may cause a failure if low load operation continues. In addition, the generator has good power generation efficiency when operated near the rated output, and when operated with power lower than the rated output, the efficiency becomes poor and the fuel consumption rate increases.

  The present invention has been made in view of such circumstances, and a purpose thereof is a generator operation control device capable of operating a generator efficiently even when the fluctuation of load power is large, and It is to provide a generator operation control method.

  In order to solve the above-described problem, a generator operation control device according to an embodiment of the present invention includes a storage unit that stores track record information about load power, and a load that predicts a variation pattern of load power based on the track record information. Based on the fluctuation pattern of the load power predicted by the load power prediction unit, the load power prediction unit, the reference power calculation unit that calculates the reference power indicating the reference value for controlling the generator, and the load power prediction unit predicted A generator control unit that controls the generator based on a comparison result between a variation pattern of load power and the reference power calculated by the reference power calculation unit.

  Moreover, the generator operation control method of one embodiment of the present invention is a load in which a load power control device including a storage unit that stores track record information related to load power predicts a variation pattern of load power based on the track record information. Predicting by a power prediction step, a reference power calculation step for calculating a reference power indicating a reference value for controlling the generator based on a load power fluctuation pattern predicted by the load power prediction step, and a prediction by the load power prediction step And a generator control step of controlling the generator based on a comparison result between the fluctuation pattern of the load power thus generated and the reference power calculated by the reference power calculation step.

  As described above, according to the present invention, it is possible to provide a generator operation control device and a generator operation control method capable of operating a generator efficiently even when the load power fluctuation is large. Can do.

It is a lineblock diagram of operation control device 1 of an embodiment. It is a 1st figure which shows an example of the fluctuation pattern of the load electric power which the operation control apparatus 1 of embodiment predicted. It is a block diagram of the reference | standard electric power calculation part 14 of embodiment. It is FIG. 1 which shows an example of control of the generator 2 which the operation control apparatus 1 of embodiment performs. It is FIG. 2 which shows an example of control of the generator 2 which the operation control apparatus 1 of embodiment performs. It is a flowchart which shows the flow of the process which the driving | running control apparatus 1 of embodiment performs. It is FIG. 3 which shows an example of control of the generator 2 which the operation control apparatus 1 of embodiment performs. It is a 2nd figure which shows an example of the fluctuation pattern of the load electric power which the operation control apparatus 1 of embodiment predicted. It is a figure which shows an example of the fluctuation pattern of the load electric power of a large sized facility.

  Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention according to the claims. In addition, not all the combinations of features described in the embodiments are essential for the solving means of the invention. In the drawings, the same or similar parts may be denoted by the same reference numerals and redundant description may be omitted. In addition, the shape and size of elements in the drawings may be exaggerated for a clearer description.

  In the entire specification, when a part includes a component, “includes”, “have”, or “comprises”, this does not exclude other components unless otherwise stated. This means that it can further include the following components.

  Hereinafter, a generator operation control device (hereinafter simply referred to as “operation control device”) 1 according to an embodiment will be described with reference to the drawings.

FIG. 1 is a configuration diagram of the operation control device 1. As shown in FIG. 1, the operation control device 1 includes a storage unit 10, a load power prediction unit 12, a reference power calculation unit 14, and a generator control unit 16.
The storage unit 10 includes a record information storage unit 100, a season information storage unit 101, a production information storage unit 102, and a generator information storage unit 103.
The performance information storage unit 100 stores information related to past load power (result information). The performance information storage unit 100 stores time-series changes (variation patterns) of past load power in buildings such as factories. The fluctuation pattern of the load power is, for example, a fluctuation pattern that indicates the fluctuation of the daily load power in units of one second. The performance information storage unit 100 stores the variation pattern of the load power together with the date of the day that was the variation pattern.
The season information storage unit 101 stores information (season information) such as past outside air temperature and humidity. Season information is stored in the season information storage unit 101 together with the date.
The production information storage unit 102 stores information (production information) such as the number of products produced in the factory in the past and the time the equipment has been operated. In the production information storage unit 102, production information is stored together with the date.

  The generator information storage unit 103 stores information for controlling the generator 2, for example, information on the rated output of the generator 2 and information on a load factor when operating the generator 2. Here, the rated output of the generator 2 is the electric power output to the generator 2, and the load factor of the generator 2 is the ratio of the load permitted with respect to the rated output. For example, there is a load factor range recommended by the manufacturer that manufactured the generator 2, and it can be expected that efficient operation is performed by operating the generator 2 so as not to fall below the load factor. Generally, the load factor of the generator is 50 to 80% or more.

  The load power prediction unit 12 predicts a variation pattern of the load power based on the result information. Specifically, first, the load power prediction unit 12 acquires seasonal information predicted on the next day (hereinafter referred to as predicted seasonal information) and production information predicted on the next day (hereinafter referred to as production seasonal information). For example, the load power prediction unit 12 acquires predicted season information based on information such as a weather forecast and an estimated temperature obtained via a network. In addition, the load power prediction unit 12 acquires, as predicted production information, production information input from a user or the like via an external input device such as a keyboard or a mouse (not shown) connected to the operation control device 1, for example.

Further, the load power prediction unit 12 refers to the season information storage unit 101 based on the predicted season information. Specifically, the load power prediction unit 12 acquires the date of the day corresponding to the season information that matches or is similar to the predicted season information from the season information stored in the season information storage unit 101.
Further, the load power prediction unit 12 refers to the production information storage unit 102 based on the predicted production information. Specifically, the load power prediction unit 12 acquires the date of the day corresponding to the production information that matches or is similar to the predicted production information from the production information stored in the production information storage unit 102.

  Then, the load power prediction unit 12 selects the next day from the performance information stored in the season information storage unit 101 based on the date acquired from the season information storage unit 101 and the date acquired from the production information storage unit 102. The fluctuation pattern (predicted fluctuation pattern) of the load power that is predicted to be acquired is acquired. For example, if there is a date common to the dates acquired from the season information storage unit 101 and the production information storage unit 102, the load power prediction unit 12 determines the load power fluctuation pattern of the day corresponding to the date as the predicted fluctuation pattern. To do. For example, if there is no date common to the acquired dates, the load power prediction unit 12 widens the similar range and changes the season information stored in the season information storage unit 101 to the season information similar to the predicted season information. Get the date of the corresponding day again. Similarly for the production information, the load power prediction unit 12 expands the similar range, and the date corresponding to the production information similar to the predicted production information from the production information stored in the production information storage unit 102. Get it again. Then, if there is a date common to the dates acquired from each of the season information storage unit 101 and the production information storage unit 102, the load power prediction unit 12 determines the load power fluctuation pattern of the day corresponding to the date as the predicted fluctuation pattern. And

  In this way, the load power prediction unit 12 predicts the variation pattern of the load power. Note that, in the above, the load power prediction unit 12 stores the past load power stored in the performance information storage unit 100 based on the date common to the dates acquired from the season information storage unit 101 and the production information storage unit 102, respectively. Although the predicted variation pattern is obtained from the variation pattern, the present invention is not limited to this. The load power prediction unit 12 may generate, for example, a prediction model in which the past load power fluctuation pattern and its date, season information corresponding to the date, and production information are machine-learned by artificial intelligence. In this case, the load power prediction unit 12 outputs a prediction pattern obtained by inputting predicted season information, predicted production information, and the like to the prediction model as a predicted fluctuation pattern of load power.

  Here, the predicted fluctuation pattern of the load power predicted by the load power prediction unit 12 will be described with reference to FIG. FIG. 2 is a first diagram illustrating an example of a variation pattern of load power predicted by the operation control apparatus 1. In FIG. 2, the horizontal axis represents time, and the vertical axis represents load power. In the example of the predicted fluctuation pattern of the load power shown in FIG. 2, the load power increases from about 340 [kW] to around 400 [kW] between 8 o'clock and 9 o'clock. From 9 o'clock to 9:30, the load power is maintained at a value around 400 [kW], and hardly changes. The load power decreased from 400 [kW] to about 340 [kW] around 9:30 and returned to the load power level at around 8 o'clock, and thereafter between 340 [kW] and 350 [kW] until after 12:00. The load power changes little. The load power is about 200 [kW] around 13:00, and the load power is a value around 200 [kW] as it is until 17:00 after 13:00. Almost no change occurs.

For example, in this building, for example, the daily operation when the operation of the air conditioner or the like starts at 8 o'clock, and the load power prediction unit 12 is configured to increase the temperature of the air conditioner to increase the temperature of the building from about 8 o'clock tomorrow. This shows that the load power is expected to increase as a result of operating the load. Moreover, since the temperature of the building reaches a predetermined set value after 9:30 on the basis of the predicted temperature of the next day, the load power prediction unit 12 has a low load for air conditioning to maintain the temperature after 9:30. As a result of the operation, the load power is predicted to be constant.
Moreover, in this building, for example, after 12:00, it is a daily routine in which the building temperature is switched to a setting value lower than the setting value in the morning, and the load power prediction unit 12 operates the air conditioning after 12:00. Indicates that the load power has been predicted to decrease due to, for example, being stopped. Further, based on the predicted temperature of the next day, the building temperature reaches the set value in the afternoon around 13:00. Therefore, the load power prediction unit 12 has a low load for maintaining the temperature after 13:00. It shows that the load power was predicted to be constant as a result of operation.

  Returning to FIG. 1, the reference power calculation unit 14 calculates reference power that serves as a reference when the generator 2 is controlled based on the load power fluctuation pattern predicted by the load power prediction unit 12. As shown in FIG. 2, the load power fluctuation pattern of the next day predicted by the load power predicting unit 12 gradually increases or decreases in load power little by little while the value changes from moment to moment. That is, the fluctuation pattern of the load power includes a movement with a relatively fast change and a movement with a relatively slow change. For this reason, it is difficult for the reference power calculation unit 14 to acquire substantial load power from individual values indicated by the load power fluctuation pattern predicted by the load power prediction unit 12.

  In the change in the value of the load power from 8 o'clock to 9 o'clock in FIG. 2, as described above, the load power increases from about 340 [kW] to around 400 [kW]. Slow movement. If the change in the value of the load power from 8 o'clock to 9 o'clock is viewed locally, a relatively fast change in which a low value and a high value of the load power are repeated is included. For this reason, the reference power calculation unit 14 obtains a substantial load power from the load power fluctuation pattern predicted by the load power prediction unit 12, so that the component with a relatively fast change included in the load power and a relatively change. To separate the slow components. Specifically, the reference power calculation unit 14 performs frequency analysis on the load power predicted by the load power prediction unit 12 and calculates a reference power by calculating a component in the vicinity of a frequency of 0 [Hz].

  FIG. 3 is a configuration diagram of the reference power calculation unit 14. As shown in FIG. 3, the reference power calculation unit 14 includes a Fourier transform unit 140 and a DC component detection unit 141.

  The Fourier transform unit 140 performs discrete Fourier transform on the time-series load power predicted by the load power prediction unit 12 and calculates a frequency response of the load power. For example, the Fourier transform unit 140 performs discrete Fourier transform by FFT (fast Fourier transform). In FFT, the number of time-series data to be input is set to a power of 2, so that the discrete Fourier transform is calculated faster than the case where the number of time-series data is not limited to a power of 2. Can do.

  When there is load power data at intervals of 1 second in the load power fluctuation pattern shown in FIG. 2, the Fourier transform unit 140, for example, data from 8 o'clock to 17: 6: 7, 2 to the 15th power (= 32768) The frequency response of the load power is calculated using time series data of the load power. As a result, among the load power fluctuation patterns predicted by the load power predicting unit 12, it is possible to separate a component having a relatively fast change (high frequency) and a component having a relatively slow change (low frequency). . The Fourier transform unit 140 outputs the calculated frequency response of the load power to the DC component detection unit 141. Note that the discrete Fourier transform performed by the Fourier transform unit 140 is not limited to FFT, and any process may be used as long as the process can convert time series data of the discretized load power into a frequency. Further, the number of data subjected to frequency conversion by the Fourier transform unit 140 may be an arbitrary positive integer.

  The DC component detection unit 141 acquires a component (DC component) whose frequency corresponds to 0 [Hz] from the frequency response of the load power from the Fourier transform unit 140. The component corresponding to the frequency of 0 [Hz] is the whole of the time series data (data from 8 o'clock to 17: 6: 7) of the load power used by the Fourier transform unit 140 for frequency conversion ( From 8 o'clock to 17: 6: 7), the load power value is substantially unchanged. Specifically, the direct current component DC is represented by the following equation (1). Here, N is the number of data used for the discrete Fourier transform (for example, 32768), R (0) is the value of the real part corresponding to the frequency 0 [Hz], and I (0) is equivalent to the frequency 0 [Hz]. Indicates the value of the imaginary part.

DC = 1 / N × √ (R (0) ² + I (0) ² ) (1)

  In the above equation (1), when the imaginary part corresponding to the frequency 0 [Hz] is 0 (I (0) = 0), the DC component DC is treated as a real part in the discrete Fourier transform, so the frequency 0 [ The imaginary part corresponding to [Hz] is 0. By substituting I (0) = 0 into the equation (1), the direct current component DC is expressed by the following equation (1). Here, N is the number of data used for the discrete Fourier transform.

  DC = R (0) / N (2)

  In the example of the load power in FIG. 2, N is 32768, R (0) is 9076238, and I (0) is 0. In this case, the DC component DC is 277.0 according to the equations (1) and (2). That is, in the example of FIG. 2, the reference power X calculated by the direct current component detection unit 141 is 277.0 [kW]. The DC component detection unit 141 outputs the calculated reference power X to the generator control unit 16.

  Here, the reference power calculation unit 14 calculates the reference power X using the discrete Fourier transform, but is not limited thereto. For example, the reference power calculation unit 14 obtains a low frequency component (for example, a component corresponding to 0 [Hz]) by passing an LPF (low pass filter) through time series data of load power, and outputs the LPF. May be the reference power X. Further, the reference power calculation unit 14 may calculate the reference power X by an addition average obtained by dividing a value obtained by adding all time series data of load power by the number of data. The reference power calculation unit 14 may calculate the effective value of the time series data of the load power, and may use the calculated effective value as the reference power X.

  Returning to FIG. 1, the generator control unit 16 controls the generator 2 based on the load power fluctuation pattern predicted by the load power prediction unit 12 and the reference power X calculated by the reference power calculation unit 14. Specifically, the generator control unit 16 calculates the average power Y for each predetermined time of the load power based on the load power predicted by the load power prediction unit 12. And the generator control part 16 stops the generator 2, when the following (3) Formula is satisfy | filled. That is, the generator control unit 16 stops the generator 2 when the reference power X is larger than the average power Y.

  Y <X (3)

  Moreover, the generator control part 16 operates the generator 2 when satisfy | filling the following (4) Formula. That is, the generator control unit 16 operates the generator 2 when the reference power X is smaller than the average power Y.

  Y ≧ X (4)

  FIG. 4 is a first diagram illustrating an example of the control of the generator 2 performed by the generator control unit 16. FIG. 4 includes items “time zone”, “average power”, and “operation / stop of generator” from the left. In the example of FIG. 4, the item “time zone” describes a time zone in which the time between 8 o'clock and 16:59 is divided every 30 minutes. In the item “average power”, the average power in the time zone is described. In addition, the item “operation / stop of generator” describes the control state (operation or stop) of the generator 2 in that time zone.

  In the example of FIG. 4, the generator control unit 16 calculates the average power Y of the load power every 30 minutes. Further, in the example of FIG. 4, the generator control unit 16 adds all the values of the load power in the time zone, and divides the added value by the number of data used for the addition (addition average), thereby averaging power Y Is calculated. However, the calculation process of the average electric power Y which the generator control part 16 performs is not limited to this. For example, the generator control unit 16 may calculate the average power Y every 10 minutes, or may calculate the average power Y every hour. For example, the generator control unit 16 sets the time interval for calculating the average power Y as an arbitrary interval based on the time required from when the generator 2 starts to operate until a predetermined voltage can be output. Good. Further, the generator control unit 16 may calculate the average power Y by an effective value instead of the addition average.

  As shown in FIG. 4, the generator control unit 16 operates the generator 2 when the average power Y exceeds the reference power X (= 277.0). Moreover, the generator control part 16 stops the generator 2, when the average electric power Y is less than the reference electric power X (= 277.0).

  Further, when operating the generator 2, the generator control unit 16 determines a command value Z for the generator 2 based on the rated output and the load factor of the generator 2. Specifically, the generator control unit 16 determines whether to operate or stop the generator 2 based on the load power predicted by the load power prediction unit 12 and the reference power X calculated by the reference power calculation unit 14. Then, when the generator 2 is operated, the generator information (rated output and load factor) is acquired with reference to the generator information. Then, the generator control unit 16 determines a command value Z for the generator 2 based on the relationship among the rated output A, the load factor B, the reference power X, and the average power Y. The command value Z to the generator 2 is a power value output by the generator 2.

  More specifically, the generator control unit 16 sets the command value to the generator 2 to 0 when both the following expressions (5) and (6) are satisfied. In this case, the generator control unit 16 causes the generator 2 to output 0 [kW]. That is, the generator control unit 16 stops the generator 2.

A>Y> X (5)
X <A × B / 100 (6)

  Moreover, the generator control part 16 makes X the command value to the generator 2, when satisfy | filling both the following (7) and (8) Formula. In this case, the generator control unit 16 causes the generator 2 to output X (= 277.0) [kW]. That is, the generator control unit 16 causes the generator 2 to output the reference power X.

A>Y> X (7)
X ≧ A × B / 100 (8)

  Moreover, the generator control part 16 sets the command value to the generator 2 to A, when satisfy | filling any one of the following (9) Formula or (10) Formula. In this case, the generator control unit 16 sets A as the power to be output to the generator 2. That is, the generator control unit 16 causes the generator 2 to output the rated output A.

Y>X> A (9)
Y>A> X (10)

FIG. 5 is a second diagram illustrating an example of the control of the generator 2 performed by the generator control unit 16. FIG. 5 shows, from the left, “time zone”, “A = 200 kW, B is an arbitrary value”, “A = 300 kW, B is an arbitrary value”, “A = 400 kW, B = 50%”, and “A = 400 kW, B = 80% ”.
In the example of FIG. 5, the item “time zone” includes each time zone from 8 o'clock to 12:59 when the generator 2 is operated and from 13 o'clock to 16:59 when the generator 2 is stopped. Is described. The item “A = 200 kW, B is an arbitrary value” describes the power output to the generator 2 when the rated output A of the generator 2 is 200 [kW] and the load factor B is an arbitrary value. Has been. The item “A = 300 kW, B is an arbitrary value” describes the power output to the generator 2 when the rated output A of the generator 2 is 300 [kW] and the load factor B is an arbitrary value. Has been. The item “A = 400 kW, B = 50%” describes the power output to the generator 2 when the rated output A of the generator 2 is 400 [kW] and the load factor B is 50%. Yes. The item “A = 400 kW, B = 80%” describes the power to be output to the generator 2 when the rated output A of the generator 2 is 400 [kW] and the load factor B is 80%. Yes.

  Here, in each item of “A = 200 kW, B is an arbitrary value” and “A = 300 kW, B is an arbitrary value”, the load factor B is an arbitrary value. This is because it is sufficient to operate at the rated output A (200 or 300 [kW]) and it is not necessary to consider the load factor. In FIG. 2, the average power Y is a value between 344.2 and 401.0 [kW] in the time zone from 8 o'clock to 12:59 when the generator 2 is operated. Any of these average powers Y exceeds the rated output A (200 [kW] or 300 [kW]). That is, when the generator 2 is operated at the rated output A during this time period, all the power output from the generator 2 is consumed as load power. Therefore, it is not necessary to operate the generator 2 at a load lower than the rated output A during this time period.

  In addition, in each of the items “A = 400 kW, B = 50%” and “A = 400 kW, B = 80%”, the case where the load factor B is 50% and 80% is divided into cases. This is because if the generator 2 is operated at the rated output A (400 [kW]), the power supply becomes excessive. In FIG. 2, in the time zone from 8 o'clock to 12:59 when the generator 2 is operated, the average power Y is a value between 344.2 and 401.0 [kW], and most of the average power Y Is also lower than the rated output A (400 [kW]). If the generator 2 is operated at the rated output A (400 [kW]) during this time period, surplus power is output from the output power from the generator 2. Therefore, it is necessary to operate the generator 2 with output power lower than the rated output A in this time zone.

As shown in FIG. 5, when the rated output A of the generator 2 is 200 [kW], the generator control unit 16 satisfies the above equation (9) in the time zone from 8:00 to 12:59. The command value to the generator 2 is determined to be 200 [kW] corresponding to the rated output A. In addition, when the rated output A of the generator 2 is 200 [kW], the generator control unit 16 satisfies the above expression (4) in the time zone from 13:00 to 16:59. 2 is stopped.
In addition, when the rated output A of the generator 2 is set to 300 [kW], the generator control unit 16 satisfies the above expression (10) in the time zone from 8:00 to 12:59. Is determined to be 300 [kW] corresponding to the rated output A. In addition, when the rated output A of the generator 2 is 300 [kW], the generator control unit 16 satisfies the above expression (4) in the time zone from 13:00 to 16:59. 2 is stopped.

In addition, when the rated output A of the generator 2 is 400 [kW], the generator control unit 16 satisfies the above expression (7) in the time zone from 8:00 to 12:59, and the load factor B is Since it is 50%, in order to satisfy the above equation (8), the command value to the generator 2 is determined to be 277.0 [kW] corresponding to the reference power X. In addition, when the rated output A of the generator 2 is 400 [kW], the generator control unit 16 satisfies the above expression (4) in the time zone from 13:00 to 16:59. 2 is stopped.
Further, when the rated output A of the generator 2 is 400 [kW], the generator control unit 16 satisfies the above equation (5) in the time zone from 8:00 to 12:59, and the load factor B is Since it is 80%, in order to satisfy the above equation (6), the command value for the generator 2 is determined to be 0 [kW]. That is, the generator control unit 16 stops the generator 2. In addition, when the rated output A of the generator 2 is 400 [kW], the generator control unit 16 satisfies the above expression (4) in the time zone from 13:00 to 16:59. 2 is stopped.

Here, the flow of processing for controlling the operation of the generator 2 performed by the operation control device 1 will be described with reference to FIG. FIG. 6 is a flowchart showing a flow of processing performed by the operation control device 1.
First, as a premise for processing, the track record information storage unit 100 of the storage unit 10 stores track record information on load power, the season information store unit 101 stores seasonal information associated with load power, and the production information store unit 102 stores load power. It is assumed that production information associated with each is stored. The generator information storage unit 103 stores the rated output A and load factor B of the generator 2.
The load power prediction unit 12 predicts the fluctuation pattern of the load power of the next day by referring to the storage unit 10 based on the next season information and production information (step S1). The reference power calculation unit 14 performs discrete Fourier transform on the load power predicted by the load power prediction unit 12 and calculates the frequency response of the load power (step S2). Then, the reference power calculation unit 14 outputs, as the reference power X, power corresponding to a frequency of 0 [Hz] among the calculated frequency response of the load power (step S3). That is, the reference power calculation unit 14 calculates the reference power X that serves as a reference when controlling the generator 2 based on the load power predicted by the load power prediction unit 12.

  The generator control unit 16 calculates the average power Y every 30 minutes of the load power predicted by the load power prediction unit 12 (step S4). The generator control unit 16 compares the reference power X and the average power Y (step S5). When the reference power X exceeds the average power Y (step S5, YES), the generator control unit 16 refers to the generator information storage unit 103 and acquires the rated output A and the load factor B of the generator 2 ( Step S6). The generator control unit 16 determines that the rated output A exceeds the average power Y (step S7, YES), and the reference power X falls below a value obtained by multiplying the rated output A by the load factor B (step S8, YES). ), The command value Z to the generator 2 is set to 0 (step S9). Then, this flowchart ends.

On the other hand, when the rated output A exceeds the average power Y (step S7, YES), the generator controller 16 determines that the reference power X exceeds the value obtained by multiplying the rated output A by the load factor B (step S7). (S8, NO), the command value Z to the generator 2 is set as the reference power X (step S10). Then, this flowchart ends.
Further, when the rated output A is lower than the average power Y (step S7, NO), the generator control unit 16 sets the command value Z to the generator 2 as the rated output A (step S11). Then, this flowchart ends.
When the reference power X is lower than the average power Y (step S5, NO), the generator control unit 16 sets the command value Z to the generator 2 to 0 (step S9). That is, in this case, the generator control unit 16 stops the generator 2. Then, this flowchart ends.

  As described above, in the operation control device 1 of the present embodiment, the record information storage unit 100 (an example of “storage unit”) has a past load power fluctuation pattern (an example of “result information related to load power”). Is stored. Further, the load power prediction unit 12 predicts the load power fluctuation pattern of the next day based on the past load power fluctuation pattern. Further, the reference power calculation unit 14 calculates a reference power X indicating a reference value for controlling the generator 2 based on the fluctuation pattern of the load power of the next day predicted by the load power prediction unit 12. Further, the generator control unit 16 controls the generator 2 based on the variation pattern of the load power predicted by the load power prediction unit 12 and the reference power X calculated by the reference power calculation unit 14.

  Thereby, in the operation control apparatus 1 of this embodiment, the reference electric power X of the predicted load electric power can be calculated. The reference power X is a constant value that serves as a reference when the generator 2 is controlled. The operation control device 1 can control the generator 2 based on the calculated reference power. For this reason, the operation control apparatus 1 according to the present embodiment operates the generator 2 as a result of operating the generator 2 even when the fluctuation of the predicted fluctuation pattern of the load power is large, even though the load power has decreased. The generator 2 can be efficiently operated without causing the generator 2 to operate at a low load.

  Moreover, in the operation control apparatus 1 of this embodiment, the generator control part 16 is every 30 minutes (an example of "every predetermined time") based on the fluctuation pattern of the load electric power which the load electric power prediction part 12 estimated. An average power Y (an example of “average power that is an average value of load power”) is calculated, and the generator 2 is operated by comparing the calculated average power Y and the reference power X calculated by the reference power calculation unit 14. Or decide to stop. Thereby, in the operation control apparatus 1 of this embodiment, the average electric power Y for every 30 minutes is computable. Then, the generator control unit 16 can determine whether to operate or stop the generator 2 by comparing the average power Y and the reference power X. That is, the operation control device 1 can control the operation of the generator 2 only by performing a simple process of comparing two values (reference power X and average power Y), and the generator 2 can be efficiently operated. Can be driven.

  Further, in the operation control device 1 of the present embodiment, when the generator 2 is operated, the generator controller 16 instructs the generator 2 based on the rated output A and the load factor B of the generator 2. Z is determined. Thereby, in the operation control apparatus 1 of this embodiment, when the rated output A of the generator 2 exceeds the average power Y, that is, when the generator 2 is operated, the power is lower than the rated output of the generator 2. It is necessary to drive in. Even in this case, the generator control unit 16 can efficiently determine the command value of the generator 2 according to the load factor B without the operation of the generator 2 becoming too low. Therefore, the operation control apparatus 1 can operate the generator 2 efficiently.

  The effect mentioned above is demonstrated using FIG. FIG. 7 is a third diagram illustrating an example of control of the generator 2 performed by the operation control apparatus 1 of the embodiment. In FIG. 7, the horizontal axis represents time, and the vertical axis represents load power. FIG. 7 shows the load power, the output power of the generator 2, and the purchased power when the operation control device 1 controls the operation of the generator 2 with respect to the load power fluctuation pattern shown in FIG. In the example shown in FIG. 7, the rated output A of the generator 2 is 400 [kW], and the load factor B is 50%. That is, the above expressions (7) and (8) are satisfied. Therefore, the operation control apparatus 1 controls the generator 2 with the content described in the item “A = 400 kW, B = 50%” in FIG. 5. Specifically, the operation control apparatus 1 causes the generator 2 to output with the reference power X (= 277.0 [kW]) in the time period from 8:00 to 12:59. The purchased power in this time zone is a value obtained by subtracting the reference power X (= 277.0 [kW]) from the load power. This indicates that the purchased power supplements the power shortage from the output power from the generator 2, and the generator 2 is operated efficiently without being operated at a low load. Moreover, the operation control apparatus 1 stops the generator 2 in the time slot | zone from 13:00 to 16:59. Then, the purchased power at this time is equivalent to the load power. This is because when the power is supplied from the generator 2, the generator 2 is stopped when the power is excessively supplied, and the generator 2 is operated efficiently without being operated at a low load. Show.

Moreover, the example which has the effect mentioned above is demonstrated using FIG. FIG. 8 is a second diagram illustrating an example of a variation pattern of the load power predicted by the operation control device 1. FIG. 8 shows a typical daily load power fluctuation pattern in each of the four seasons in a certain printing factory. In FIG. 8, the horizontal axis represents time, and the vertical axis represents load power. As shown in the respective representative daily load power fluctuation patterns in FIG. 8, even when the load power rises or falls many times during the day, the operation of this embodiment is performed. The generator 2 can be effectively operated using the control device 1. For example, in a typical fluctuation pattern of a day in spring, the load power increases rapidly when the printing machine is fully operated from around 23:00 at night to around 4:00 in the next morning. Also, printing is completed from about 5 o'clock to about 9 o'clock immediately after that, and the load power decreases. Then, the load power gradually increases from 10:00 to around 12:00, and the load power increases slightly rapidly from around 13:00 to around 16:00. The load power is almost constant from 17:00 to 22:00.
In such a case, for example, the rated output A of the generator 2 can select 400 [kW], 300 [kW], 200 [kW], and 100 [kW], respectively, and the load factor B is 50% to 80%. When the reference power is 300 [kW], the operation control device 1 operates the generator 2 at 400 [kW] from around 23:00 at night to around 4 am the next morning. Moreover, the generator 2 is stopped from 5:00 to 13:00.
In addition, for 2 hours from 13:00 to 15:00, the generator 2 generates electric power increased by 50 [kW] every 30 minutes. Specifically, “A = 100 kW, B = 50%” from 13:00 to 13:30, “A = 200 kW, B = 50%” from 13:30 to 14:00, “A” from 14:00 to 14:30 = 200 kW, B = 75% ”, and“ A = 300 kW, B = 67% ”from 14:30 to 15:00, respectively. Further, for 2 hours from 15:00 to 17:00, the generator 2 generates power that is reduced by 50 [kW] every 30 minutes. Specifically, “A = 300 kW, B = 67%” from 15:00 to 15:30, “A = 200 kW, B = 75%” from 15:30 to 16:00, “A from 16:00 to 16:30” = 200 kW, B = 50% ”, and“ A = 100 kW, B = 50% ”from 16:30 to 17:00. Thereby, the operation control apparatus 1 of this embodiment can generate the electric power corresponding to the load electric power which changes every 30 minutes, without causing deterioration of the fuel consumption of the generator 2 or failure. Therefore, the operation control apparatus 1 can operate the generator 2 efficiently.
Further, in the representative day of autumn in FIG. 8, there is no increase or decrease in load power in 4 hours from 13:00 to 17:00 as compared to the representative day of spring. In this case, the operation control apparatus 1 stops the generator 2 from 13:00 to 17:00. As described above, the operation control device 1 of the present embodiment can efficiently operate the generator 2 in correspondence with each variation pattern even when the variation pattern of the load power is different in each of the four seasons. it can.

  Further, in the operation control device 1 of the present embodiment, the reference power calculation unit 14 calculates the reference power X by performing FFT (an example of “frequency analysis”) on the variation pattern of the load power predicted by the load power prediction unit 12. calculate. Thereby, in the operation control apparatus 1 of the present embodiment, a component having a high frequency (fast change) and a component having a low frequency (no change or slow even if there is a change) in the load power fluctuation pattern. Can be separated. As a result, substantial power (DC component) that hardly changes in the variation pattern of the load power can be used as the reference power X. That is, the operation control apparatus 1 of the present embodiment can calculate a substantial DC component as the reference power X even when the fluctuation pattern of the load power includes a fast fluctuation, and efficiently generates power. The machine 2 can be operated.

  You may make it implement | achieve the operation control apparatus 1 in embodiment mentioned above with a computer. In that case, a program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on this recording medium may be read into a computer system and executed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory inside a computer system serving as a server or a client in that case may be included and a program held for a certain period of time. Further, the program may be a program for realizing a part of the above-described functions, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system. You may implement | achieve using programmable logic devices, such as FPGA (Field Programmable Gate Array).

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

  The execution order of each process such as operation, procedure, step, and stage in the apparatus, system, program, and method shown in the claims, the description, and the drawings is particularly “before” or “prior to”. It should be noted that the output can be realized in any order unless the output of the previous process is used in the subsequent process. Regarding the operation flow in the claims, the specification, and the drawings, even if it is described using “first”, “next”, etc. for the sake of convenience, it means that it is essential to carry out in this order. It is not a thing.

DESCRIPTION OF SYMBOLS 1 ... Operation control apparatus, 2 ... Generator, 10 ... Storage part, 100 ... Performance information storage part, 101 ... Seasonal information storage part, 102 ... Production information storage part, 103 ... Generator information storage part, 12 ... Load electric power prediction 14, reference power calculation unit 140, Fourier transform unit 141, DC component detection unit 16, generator control unit

Claims (5)

A storage unit for storing performance information related to load power;
A load power prediction unit that predicts a variation pattern of load power based on the record information;
A reference power calculation unit that calculates a reference power indicating a reference value for controlling the generator based on a variation pattern of the load power predicted by the load power prediction unit;
A generator control unit that controls the generator based on a comparison result between the load power fluctuation pattern predicted by the load power prediction unit and the reference power calculated by the reference power calculation unit;
A generator operation control device comprising: The generator control unit calculates an average power that is an average value of the load power for each predetermined time based on a load power fluctuation pattern predicted by the load power prediction unit, and calculates the calculated average power and the reference Compare the reference power calculated by the power calculator to determine whether to operate or stop the generator,
The generator operation control apparatus according to claim 1. The generator control unit determines the command value to the generator based on the rated output and load factor of the generator when operating the generator.
The generator operation control device according to claim 1 or 2. The reference power calculation unit calculates the reference power by performing frequency analysis on the variation pattern of the load power predicted by the load power prediction unit,
The generator operation control device according to any one of claims 1 to 3. A generator operation control device including a storage unit that stores performance information related to load power,
A load power prediction step for predicting a variation pattern of load power based on the result information;
A reference power calculation step of calculating a reference power indicating a reference value for controlling the generator based on a variation pattern of the load power predicted by the load power prediction step;
A generator control step of controlling the generator based on a comparison result between the load power predicted by the load power prediction step and the reference power calculated by the reference power calculation step;
A generator operation control method comprising: