JP2018137844A - Power generation planning device, power generation planning method, and power generation planning program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power generation planning device, a power generation planning method, and a power generation planning program that can provide a power generation plan that reflects the features and/or situations of real power generation facilities appropriately.SOLUTION: According to an embodiment, a power generation planning device comprises a data receiving unit for receiving power generation achievement data transmitted from power generation facilities, and showing power generation achievements for power generated by the power generation facilities. The power generation planning device also comprises a power generation planning unit for creating or modifying power generation plans for power generated by the power generation facilities based on the power generation achievement data. In addition, the power generation planning device comprises a command sending unit for sending power generation commands to the power generation facilities on the basis of the power generation plans.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a power generation plan formulation device, a power generation plan formulation method, and a power generation plan formulation program.

  In the power generation department of an electric power company, predicting future power demand and making a power generation plan so as to satisfy the predicted power demand is one of important tasks. For example, when formulating a power generation plan for a generator group including a plurality of generators (power generation facilities), it is desirable to formulate a power generation plan so that these generators are optimally operated. For this reason, various proposals have been made regarding methods for formulating power generation plans.

  For example, a method has been proposed in which the output of each generator is set in consideration of the balance of power flow and compression of fuel costs. In addition, a method has been proposed in which a first index relating to output control of the entire generator group that maximizes total profit while satisfying the total power generation amount and a second index for each generator are linked. In addition, various methods have been proposed that make it possible to formulate a rational power generation plan by modeling a generator.

  The optimization of power generation plans not only brings economic benefits of reducing power generation costs, but also contributes to global environmental issues such as reduction of carbon dioxide emissions and energy consumption. There are great expectations for progress.

Japanese Patent No. 3753113 WO2016 / 139781 Special table 2015-530652 gazette JP 2004-211587 A JP 2012-238308 A

  However, when trying to formulate a power generation plan that optimally operates multiple generators, the characteristics and status of the generator indicated by the data used for formulating the power generation plan deviate from the characteristics and status of the actual generator. There is a case. In this case, if this deviation is large, it may not be possible to formulate a power generation plan that achieves optimal operation.

  Therefore, an embodiment of the present invention has an object to provide a power generation plan formulation device, a power generation plan formulation method, and a power generation plan formulation program that can provide a power generation plan that appropriately reflects characteristics and conditions of actual power generation facilities. To do.

  According to one embodiment, the power generation plan formulation device includes a data receiving unit that receives power generation result data that is transmitted from the power generation facility and indicates a power generation result of power generation by the power generation facility. The apparatus further includes a power generation plan formulation unit that formulates or corrects a power generation plan for power generation by the power generation facility based on the power generation result data. The apparatus further includes a command transmission unit that transmits a power generation command to the power generation facility based on the power generation plan.

It is a schematic diagram which shows the structure of the electric power generation system of 1st Embodiment. It is the graph which showed the operation example of the electric power generation plan formulation apparatus of 1st Embodiment. It is the graph which showed another example of operation of the power generation plan formulation device of a 1st embodiment. It is the graph which showed another example of operation of the power generation plan formulation device of a 1st embodiment. It is the graph which showed another example of operation of the power generation plan formulation device of a 1st embodiment. It is the graph which showed another example of operation of the power generation plan formulation device of a 1st embodiment. It is a schematic diagram which shows the structure of the electric power generation system of 2nd Embodiment. It is the flowchart which showed the operation example of the electric power generation system of 2nd Embodiment. It is the flowchart which showed another example of operation | movement of the electric power generation system of 2nd Embodiment.

  Embodiments of the present invention will be described below with reference to the drawings. 1 to 9, the same or similar components are denoted by the same reference numerals, and redundant description is omitted.

(First embodiment)
Drawing 1 is a mimetic diagram showing the composition of the power generation system of a 1st embodiment.

The power generation system of FIG. 1 includes a power generation plan formulation device 1 and a plurality of power plants 2 ₁ to 2 _n (n is an integer of 2 or more). Hereinafter, each of the power plants 2 ₁ to 2 _n is referred to as a power plant 2.

  Each power plant 2 includes a power generation facility 21 including a power generation device control device 21a and a power generation device 21b. The power generation device 21b is a device that generates power, and includes, for example, a generator and a device associated therewith. The power generation device control device 21a is a device that controls the operation of the power generation device 21b, and includes, for example, a computer or an electric circuit. Each power plant 2 can perform communication processing with the power generation plan formulation device 1.

  The power generation equipment control device 21 a receives a power generation command that is a command related to the power generation operation of each power plant 2 from the power generation plan formulation device 1. Then, the power generation device control device 21a transmits a control instruction for realizing the power generation command to the power generation device 21b.

  The power generation device 21b operates according to the control instruction to generate power. In the present embodiment, the power generation result data indicating the power generation result of power generation by the power generation facility 21 is measured by various sensors in the power generation device 21b. Examples of power generation result data are the power generation output of the power generation facility 21, power generation efficiency, fuel consumption, and the like. The power generation result data measured by the power generation device 21b is transmitted to the power generation plan formulation device 1. The power generation plan formulation device 1 can grasp the power generation results of the power generation equipment 21 of each power plant 2 in real time from the power generation result data periodically received from each power plant 2.

The power generation plan formulation device 1 includes a power generation control unit 11 including a data reception unit 11a, a power generation plan formulation unit 11b, and a command transmission unit 11c. Hereinafter will be described the power generation planning unit 1 exchanges data between the two power plants, as an example exchange of data between the power generation planning unit 1 and power plant 2 _1.

Data receiver 11a receives the power generation performance data transmitted from the power plant 2 ₁ of power generation equipment 21. Power generation planning unit 11b, based on the power generation performance data, to formulate or modify the power generation plan for power generation by the power generation facility 21 of the power plant 2 _1. For example, a new power generation plan is formulated or an existing power generation plan is modified so that the power generation plan is suitable for the power generation result data. Command transmitting unit 11c, based on such power program, transmits a power generation instruction to the power generation facility 21 of the power plant 2 _1. Specifically, a power generation command that instructs an operation in accordance with the power generation plan is created and transmitted. Thus, power generation equipment 21 of the power plant 2 ₁ will operate in accordance with the power generation planning.

The power generation plan formulation device 1 of the present embodiment periodically repeats the operations of receiving power generation result data, formulating or correcting a power generation plan, and transmitting a power generation command. Therefore, according to this embodiment, it is possible to be reflected in the power generation plan of the power generation performance of the power plant 2 ₁ of power generation equipment 21 in real time. Thereby, the deviation from the actual power generation performance of the power generation facility 21 is small, and it is possible to provide a power generation plan in which the actual power generation facility 21 can be optimally operated. Hereinafter, various specific examples of such a power generation plan will be described.

  FIG. 2 is a graph showing an operation example of the power generation plan formulation device 1 of the first embodiment.

FIG. 2 (a) shows the power generation efficiency of the power plant ₂ 1 to 2 _n (power generation facility 21) at time _{t 1.} The power generation plan formulation device 1 receives the power generation efficiency (actual efficiency) as power generation result data. The power plant 2 _i represents one of the power plants 2 ₁ to 2 _n (i is an integer satisfying 1 ≦ i ≦ n).

Power planning apparatus 1, based on the power generation efficiency of the power plant ₂ 1 to 2 _n at time _{t 1,} 'develop a power generation plan of the power plant ₂ 1 to 2 _n in the _{(t 1'} time _{t 1> t 1} ). FIG. 2B shows an example of such a power generation plan, specifically, a power generation output distribution plan for the power plants 2 ₁ to 2 _n . The power generation plan formulation device 1 formulates such a plan based on the power generation result data, the power demand, and the operation constraints, and outputs a power generation command for executing this plan. For example, the plan is formulated so that the power generation efficiency of the power plants 2 ₁ to 2 _{n at} the time t ₁ ′ is maximized. Examples of operational constraints include regular inspection periods, power constraints, reserve capacity, etc. for power plants 2 ₁ to 2 _n .

FIG. 2 (c) shows a change in the power generation efficiency of the power plant _{2 i} at time _{t 1 ~t 2 (t 2>} t 1 '> t 1). Power generation efficiency of the power plant 2 _i at time t ₂ corresponds to the latest proven efficiency of the power plant 2 _i. As shown in FIG. 2 (c), the power generation efficiency of the power plant 2 _i is the degradation in performance of the power plant 21 in power plant 2 _i, is reduced between times t ₁ ~t _2.

FIG. 2 (d) shows the power generation efficiency of the power plant ₂ 1 to 2 _n (power generation facility 21) at time _{t 2.} The power generation plan formulation device 1 receives the power generation efficiency (actual efficiency) as power generation result data. FIG. 2 (d) shows that the power generation efficiency of the power plant 2 _i has decreased by Δ ₁ between times t _{1 and} t ₂ .

In this case, the power generation planning unit 1, based on the power generation efficiency of the power plant _{2 i} at time _{t 2,} 'corrects the power generation plan of the plant _{2 i} in _{(t 2'} time _{t 2> t 2).} FIG. 2E shows an example of such a correction plan, in which the power generation output of the power plant 2 _i is reduced by Δ ₂ compared to FIG. 2B. The power generation plan formulation device 1 outputs a power generation command for implementing such a correction plan. As a result, the operation of the power plant 2 _i is a reflection of the real-time power generation performance of the power plant 2 _i. The power generation plan can be corrected based on, for example, the characteristic curve described with reference to FIGS.

  FIG. 3 is a graph showing another operation example of the power generation plan formulation device 1 of the first embodiment.

FIG. 3A shows a “power generation output-power generation efficiency” characteristic curve of the power plants 2 ₁ to 2 _n at time t ₁ . The power generation plan formulation device 1 receives the power generation output and power generation efficiency of the power plants 2 ₁ to 2 _n at time t ₁ as power generation result data, and creates these characteristic curves based on the power generation result data or the design data.

3 (a) is further power plant 2 _i at time t ₂ - shows a "power-power efficiency" characteristic curve. Symbol L1 indicates a characteristic curve of the power plant 2 _i at time t ₁ , and symbol L2 indicates a characteristic curve of the power plant 2 _i at time t ₂ . The power generation plan formulation device 1 receives the power generation output and power generation efficiency of the power plant 2 _i at time t ₂ as power generation result data, and updates the characteristic curve of the power plant 2 _i from L1 to L2 based on the power generation result data. FIG. 3A shows a state where the characteristic curve of the power plant 2 _i is updated and the characteristic curves of the other power plants 2 are not updated. The update from L1 to L2 is performed using, for example, an interpolation process for the characteristic curve of the power plant 2 _i .

FIG. 3 (b), by using the characteristic curve of the power plant ₂ 1 to 2 _n in the time _{t 2, the} shows how to modify the power generation plan of the power plant ₂ 1 to 2 _n at time _{t 2} '. In FIG. 3 (b), the output distribution of the power plant _{2 1} is modified from X1 to X2, the output distribution of the power plant _{2 i} is modified from Y1 to Y2, modifications output distribution of the power plant _{2 n} is from Z1 Z2 Has been. In this case, L2 is used as the characteristic curve of the power plant 2 _i. FIG. 3B shows a state where the output distribution is corrected so that the power generation efficiency of the power plants 2 ₁ to 2 _{n at} the time t ₂ ′ is maximized.

FIG. 3 (c) shows a change in the power generation efficiency of the power plant _{2 i} at time _t 1 ~t _2. FIG. 3D shows a change in fuel consumption of the power plant 2 _{i from} time t _{1 to} time t ₂ . As shown in FIG. 3 (c) and FIG. 3 (d), the power plant 2 _i power generation efficiency of each combustion consumption, due to the deterioration of the performance of the power generation facility 21 of the power plant 2 _i, the time t ₁ ~t ₂ reduced by delta ₃ during has increased by delta _4. The correction from L1 to L2 in FIG. 3B reflects these phenomena in real time.

  FIG. 4 is a graph showing another operation example of the power generation plan formulation device 1 of the first embodiment.

FIG. 4A shows the “power generation output-power generation efficiency” characteristic curve of the power plants 2 ₁ to 2 _n at time t ₁ . However, A1 and A2, respectively, showing a characteristic curve in the case where power output of the power plant 2 ₁ is lowered to the case of rise. Similarly, B1 and B2 indicate characteristic curves when the power generation output of the power plant 2 _i rises and falls, respectively. Similarly, C1 and C2 indicate characteristic curves when the power generation output of the power plant _2n increases and decreases, respectively. Thus, the characteristic curves when the power generation output of each power plant 2 rises and falls show hysteresis in this operation example.

FIG. 4 (b), by using the characteristic curve of the power plant ₂ 1 to 2 _n in the time _{t 2, the} shows how to modify the power generation plan of the power plant ₂ 1 to 2 _n at time _{t 2} '. Here, the power generation output of the power plant _{2 1} to increase between times _t 1 ~t _2, the characteristic curve A1 are used. Further, since the power generation output of the power plant 2 _i falls during the time t _{1 to} t ₂ , the characteristic curve B2 is used. Further, since the power generation output of the power plant 2 _n rises between times t _{1 and} t ₂ , the characteristic curve C1 is used. X1, X2, and X3 in FIG. 4B show how the output distribution is corrected so that the power generation efficiency of the power plants 2 ₁ to 2 _n is maximized while satisfying the power demand.

Thus, according to this operation example, it is possible to provide a power generation plan reflecting the hysteresis of the characteristic curves of the power plants 2 ₁ to 2 _n .

  FIG. 5 is a graph showing another operation example of the power generation plan formulation device 1 of the first embodiment.

FIG. 5 (a) shows temporal change in the power generation efficiency of the power plant ₂ 1 to 2 _n to the time point _{t 0.} The power generation plan formulation device 1 receives the power generation outputs of the power plants 2 ₁ to 2 _n as power generation performance data at various times up to time t _0, and creates these time change curves based on the power generation performance data.

FIG. 5A further shows predicted values of power generation efficiency of the power plants 2 ₁ to 2 _n at times t ₁ and t ₂ . Based on the power generation efficiency before time t _0, which is a past performance change of the power plants 2 ₁ to 2 _n , the power generation plan formulation device 1 is after the time t ₀ which is a future performance change of the power plants 2 ₁ to 2 _n. Estimate (calculate) power generation efficiency. The power generation plan formulation device 1 calculates a predicted value of the power generation efficiency of the power plants 2 ₁ to 2 _n at times t ₁ and t ₂ by using a statistical method such as a least square method. Examples of time _{t 1} is a 1 month after the time _{t 0,} examples of the time _{t 2} is one year after the time _{t 0.}

Power planning apparatus 1, based on the predicted value of the power generation efficiency of the power plant ₂ 1 to 2 _n at time _{t 1,} to formulate or modify the power generation plan of the power plant ₂ 1 to 2 _n at time _{t 1.} FIG. 5B shows an example of such a power generation plan, specifically, a power generation output distribution plan for the power plants 2 ₁ to 2 _n at time t ₁ . This is the same for the time t _2. FIG. 5 (c) shows the power output distribution plan of the plant ₂ 1 to 2 _n at time _{t 2.}

FIG.5 (d) is an enlarged view of the time change of the power generation efficiency of the power plant _2i in Fig.5 (a). The power generation efficiency of the power plant 2 _i is the degradation in performance of the power plant 21 in power plant 2 _i, has decreased by time t _0, also the time t ₀ thereafter is expected decreases. According to this operation example, it is possible to provide a long-term power generation plan by using such prediction results.

  FIG. 6 is a graph showing another operation example of the power generation plan formulation device 1 of the first embodiment.

6 (a) to 6 (d) are graphs corresponding to FIGS. 5 (a) to 5 (d), respectively. However, symbol R shown in FIG. 6 (a) and Figure 6 (d) by the maintenance work of the power generation facility 21 of the power plant 2 _i that are already planned at time t ₀ (restoration work), power plants 2 shows that the power generation efficiency of _i has been recovered.

The power generation plan formulation device 1 calculates the predicted value of power generation efficiency after time t _{0 as} shown in FIG. 5 (a), and then calculates this predicted value based on information on the future maintenance plan of the power plant 2 _i. Correction is made as indicated by reference symbol R (FIG. 6A). The power generation plan formulation device 1 further formulates or corrects the power generation plans for the power plants 2 ₁ to 2 _{n at} the times t ₁ and t ₂ based on the corrected predicted values. According to this operation example, it is possible to provide a long-term power generation plan that takes into consideration the maintenance plan by using such a prediction result.

  As described above, the power generation plan formulation device 1 of the present embodiment receives the power generation result data transmitted from each power plant 2, formulates or corrects the power generation plan based on the power generation result data, Based on this, a power generation command is transmitted to each power plant 2. Therefore, according to the present embodiment, it is possible to provide a power generation plan that appropriately reflects the actual characteristics and conditions of the power generation facility 21.

(Second Embodiment)
FIG. 7 is a schematic diagram showing the configuration of the power generation system of the second embodiment.

  Each power plant 2 of the present embodiment includes a trial power generation facility 22 including a control characteristic reflection unit 22a, a device characteristic reflection unit 22b, a power generation device control device model 22c, and a power generation device model 22d in addition to the components shown in FIG. It has. The control characteristic reflection unit 22a and the device characteristic reflection unit 22b are examples of reflection units, and the power generation device control device model 22c and the power generation device model 22d are examples of power generation equipment models. The trial power generation facility 22 is provided to try the power generation by the power generation facility 21, and corresponds to a power generation simulation device.

  The control characteristic reflecting unit 22a controls the operation of the power generation device control device model 22c based on the control logic information and control parameters acquired from the power generation device control device 21a. Thereby, the characteristics of the power generation equipment control device 21a are reflected in the power generation equipment control device model 22c, and the operation of the power generation equipment control device 21a can be simulated by the power generation equipment control device model 22c.

  The device characteristic reflection unit 22b controls the operation of the power generation device model 22d based on the state quantities measured by various sensors in the power generation device 21b. Thereby, the characteristics of the power generation device 21b are reflected in the power generation device model 22d, and the operation of the power generation device 21b can be simulated by the power generation device model 22d.

  The power generation equipment control device model 22 c receives from the power generation plan formulation device 1 a trial power generation command that is a command related to a power generation operation trial of each power plant 2. Then, the power generation equipment control device model 22c transmits a trial control instruction for realizing the trial power generation instruction to the power generation equipment model 22d.

  The power generation device model 22d operates according to the trial control instruction and performs trial power generation. In the present embodiment, trial result data indicating the power generation result of the trial power generation is calculated in the power generation equipment model 22 d and transmitted to the power generation plan formulation device 1. Examples of trial performance data are power generation output, power generation efficiency, fuel consumption, and the like of trial power generation. The power generation plan formulation device 1 can grasp the power generation result of the trial power generation facility 22 of each power plant 2 in real time from the trial result data periodically received from each power plant 2.

  The trial power generation facility 22 performs trial power generation by simulating the operation of the power generation facility 21 using the power generation device control device model 22c and the power generation device model 22d, and outputs trial result data. In this case, the control characteristic reflecting unit 22a controls the operation of the power generation equipment control device model 22c based on the information acquired from the power generation equipment control device 21a. The device characteristic reflecting unit 22b controls the operation of the power generation device model 22d based on information acquired from the power generation device 21b. This makes it possible to perform a simulation reflecting the characteristics of the power generation facility 21.

The power generation plan formulation apparatus 1 of the present embodiment includes a trial power generation control unit 12 including a trial data receiving unit 12a, a trial power generation plan formulation unit 12b, and a trial command transmission unit 12c, in addition to the components shown in FIG. Yes. Hereinafter will be described the power generation planning unit 1 exchanges data between the two power plants, as an example exchange of data between the power generation planning unit 1 and power plant 2 _1.

Trial data receiving unit 12a receives the trial record data transmitted from the power plant 2 ₁ trial power plant 22. Trial power generation planning unit 12b, based on the trial result data, to formulate or modify the attempted power generation plan for trial generation by the power plant 2 ₁ trial power plant 22. For example, a new trial power generation plan or a modification of an existing trial power generation plan is performed so that the trial power generation plan is suitable for the trial result data. Trial command transmitting unit 12c, on the basis of such trials power program, transmits a trial power generation command to the power plant 2 ₁ trial power plant 22. Specifically, a trial power generation command that instructs an operation in accordance with the trial power generation plan is created and transmitted. Thus, it attempts generation facility 22 of the power plant 2 ₁ will operate in accordance with trial power program.

The power generation plan formulation device 1 of the present embodiment periodically repeats the operations of receiving trial performance data, formulating or correcting a trial power generation plan, and transmitting a trial power generation command. Therefore, according to this embodiment, it is possible to be reflected in its attempt power program the power generation performance of the power plant 2 ₁ trial power plant 22 in real time. Thereby, it is possible to provide a trial power generation plan in which the trial power generation facility 22 can be optimally operated with little deviation from the power generation performance of the trial power generation facility 22.

In addition, the trial power generation plan formulation unit 12b provides the trial power generation plan formulated or modified to the power generation plan formulation unit 11b. Thereby, the power generation plan formulation unit 11b can obtain a trial power generation plan that can be optimally operated and is formulated or modified based on the trial power generation. In this case, the power generation plan formulation unit 11b provides the command transmission unit 11c with the trial power generation plan provided from the trial power generation plan formulation unit 12b, instead of the power generation plan formulated or modified in the power generation plan formulation unit 11b. Also good. In this case, the command transmitting unit 11c, based on the trial power program, transmits a power generation instruction to the power generation facility 21 of the power plant 2 _1.

  In addition, although the trial power generation equipment 22 which tries the power generation by the power generation equipment 21 is provided in the same power plant 2 as the power generation equipment 21 in this embodiment, it may be provided in other places. For example, the function of the trial power generation facility 22 may be implemented in the power generation plan formulation device 11.

  FIG. 8 is a flowchart illustrating an operation example of the power generation system of the second embodiment.

In step S1, a trial power generation plan for trial power generation by the trial power generation facilities 22 of the power plants 2 ₁ to 2 _n is formulated or corrected, and a trial power generation command is output thereto. Next, the processes of steps S2 to S7 are executed at each of the power plants 2 _{1 to} 2 _n . Hereinafter, the process of steps S3 to S5 for an arbitrary power plant 2 _i will be described.

First, matching the model characteristics of the plant 2 _i attempt power generation facility 22, the actual characteristics of the power generation facility 21 of the power plant 2 _i (step S3). Then, by controlling the power generation equipment model 22d by the power generation device controller model 22c power plant _{2 i,} operating the power generation equipment model 22d of the plant _{2 i} (step S4, S5). Such a process is performed in each of the power plants 2 ₁ to 2 _n .

Next, the trial power generation plan formulation unit 12b of the power generation plan formulation apparatus 1 aggregates objective functions based on the trial performance data from the power plants 2 ₁ to 2 _n (step S8). The objective function is a function for calculating an objective value related to the power generation plan, for example, a function for calculating the fuel cost of the entire power plants 2 ₁ to 2 _n . The trial power generation plan formulation unit 12b formulates or corrects the trial power generation plan of the power plants 2 ₁ to 2 _n so that the value of the target function becomes the minimum value (target value), and converts this trial power generation plan into the power generation plan formulation unit 11b. (Step S10). Steps S1 to S8 may be retried after correcting various conditions (step S9).

  The power generation plan formulation unit 11b can provide the command transmission unit 11c with the trial power generation plan provided from the trial power generation plan formulation unit 12b instead of the power generation plan formulated or modified in the power generation plan formulation unit 11b. In this case, the command transmission unit 11c can transmit the power generation command to the power generation equipment 21 of each power plant 2 based on the trial power generation plan that can be optimally operated.

  FIG. 9 is a flowchart illustrating another operation example of the power generation system according to the second embodiment.

In FIG. 9, step S3 described above is replaced with step S3 ′. Step S3 in the flow of FIG. 9 'illustrates a process in accordance with a change in the actual characteristics of the power generation facility 21 of the power plant 2 _i, models the characteristics of the power plant 2 _i attempt power plant 22 is changed. As a result, changes in actual machine characteristics can be reflected in model characteristics in real time, and a power generation plan or trial power generation plan that appropriately reflects actual machine characteristics can be provided.

  As described above, the power generation system according to the present embodiment provides a power generation plan and a power generation command using the trial power generation facility 22 that tries power generation by the power generation facility 21. Therefore, according to this embodiment, it is possible to provide a power generation plan that appropriately reflects the characteristics and status of the actual power generation facility 21 by simulation.

  The processing of the power generation control unit 11 of the first embodiment and the processing of the power generation control unit 11 and the trial power generation control unit 12 of the second embodiment are stored in, for example, an HDD (Hard Disc Drive) of the power generation plan formulation device 1. This can be realized by executing the generated power generation plan formulation program by a CPU (Central Processing Unit) of the power generation plan formulation apparatus 1. In these embodiments, a computer-readable recording medium in which this program is recorded may be inserted into the memory interface of the power generation plan formulation apparatus 1 and this program may be installed from the recording medium into the HDD.

  Although several embodiments have been described above, these embodiments are presented as examples only and are not intended to limit the scope of the invention. The novel devices, methods, and programs described herein can be implemented in various other forms. In addition, various omissions, substitutions, and changes can be made to the forms of the apparatuses, methods, and programs described in the present specification without departing from the spirit of the invention. The appended claims and their equivalents are intended to include such forms and modifications as fall within the scope and spirit of the invention.

1: Power generation plan development device, 2: Power plant,
11: Power generation control unit, 11a: Data reception unit,
11b: power generation plan formulation unit, 11c: command transmission unit,
12: Trial power generation control unit, 12a: Trial data receiving unit,
12b: Trial power generation plan formulation unit, 12c: Trial command transmission unit,
21: Power generation equipment, 21a: Power generation equipment control device, 21b: Power generation equipment,
22: trial power generation equipment, 22a: control characteristic reflecting unit, 22b: equipment characteristic reflecting unit,
22c: Power generation equipment control device model, 22d: Power generation equipment model

Claims (11)

A data receiving unit that receives power generation result data transmitted from the power generation facility and indicating a power generation result of power generation by the power generation facility;
A power generation plan formulation unit that formulates or corrects a power generation plan of power generation by the power generation facility based on the power generation result data;
Based on the power generation plan, a command transmission unit that transmits a power generation command to the power generation facility,
A power generation plan development device comprising:   The power generation plan formulation apparatus according to claim 1, wherein the power generation result data includes at least one of a power generation output, power generation efficiency, and fuel consumption of the power generation facility.   The power generation plan formulation unit formulates or corrects the power generation plan that reflects the hysteresis of the power generation efficiency of the power generation facility when the power generation output of the power generation facility increases and decreases. Power generation plan development device.   4. The power generation plan formulation unit according to claim 1, wherein the power generation plan formulation unit formulates or corrects the power generation plan based on a future performance change of the power generation facility predicted from a past performance change of the power generation facility. The described power generation plan development device.   The power generation plan formulation unit according to any one of claims 1 to 4, wherein the power generation plan formulation unit formulates or corrects the power generation plan based on information on a future maintenance plan of the power generation facility. A trial data receiving unit that is transmitted from a trial power generation facility that attempts power generation by the power generation facility, and that receives trial result data indicating a power generation result of trial power generation by the trial power generation facility;
A trial power generation plan formulation unit that formulates or corrects a trial power generation plan of trial power generation by the trial power generation facility based on the trial result data;
The said command transmission part is a power generation plan formulation apparatus of any one of Claim 1 to 5 which transmits the said power generation command to the said power generation equipment based on the said trial power generation plan.   The power generation plan formulation device according to claim 6, further comprising a trial command transmission unit that transmits a trial power generation command to the trial power generation facility based on the trial power generation plan.   The power generation plan formulation device according to claim 6 or 7, wherein the trial power generation facility is provided in the same power plant as the power generation facility, and trials power generation by the power generation facility based on data received from the power generation facility. The trial power generation facility is:
A power generation facility model that performs the trial power generation by simulating the operation of the power generation facility and outputs the trial performance data;
A reflecting unit that controls the operation of the power generation facility model based on information acquired from the power generation facility, and reflects the characteristics of the power generation facility in the power generation facility model;
The power generation plan formulation device according to any one of claims 6 to 8. The data receiving unit receives power generation result data transmitted from the power generation facility and indicating a power generation result of power generation by the power generation facility,
A power generation plan formulation unit formulates or corrects a power generation plan for power generation by the power generation facility based on the power generation result data,
The command transmission unit transmits a power generation command to the power generation facility based on the power generation plan.
A power generation plan formulation method. The data receiving unit receives power generation result data transmitted from the power generation facility and indicating a power generation result of power generation by the power generation facility,
A power generation plan formulation unit formulates or corrects a power generation plan for power generation by the power generation facility based on the power generation result data,
The command transmission unit transmits a power generation command to the power generation facility based on the power generation plan.
A power generation plan formulation program that causes a computer to execute a power generation plan formulation method.

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