JP6957138B2 - Power generation planning equipment, power generation planning method, and power generation planning program - Google Patents

Description

An embodiment of the present invention relates to a power generation plan formulation device, a power generation plan formulation method, and a power generation plan formulation program.

The performance of a generator changes depending on the natural environment such as the weather.

Regarding the maximum output, in a combined cycle power generator that combines a gas turbine and a steam turbine, the maximum output changes depending on the temperature. Specifically, when the temperature rises, the density of the atmosphere decreases and the amount of oxygen taken into the combustor for the gas turbine decreases, so the amount of fuel input to the combustor corresponding to it decreases, and for the gas turbine. The maximum output of the generator is reduced. Generally, when the temperature rises from 5 ° C. to 40 ° C., the maximum output of the generator for the gas turbine decreases by about 20 to 30%. The maximum output of steam power generation and nuclear power generation generators is relatively less affected by the natural environment than combined cycle power generation.

Regarding thermal efficiency, steam turbines are equipped with a condenser for returning steam to water, but the lower the temperature of the seawater for cooling the steam, the more efficient the condenser, and the higher the temperature, the more the boiler enters. Since the amount of heat is large, efficiency is improved.

In addition, there is a method of collecting a plurality of generators and controlling the load as a group of generators.

This method is called series load control (GLC). In this case, the power generation command is issued in units of this one group.
LNG (fuel) used at the power plant is stored at the base, vaporized from the liquid at the base, and sent to the power plant through a conduit. However, the size of the conduit limits the flow rate. For a group of generators in a power plant or across power plants, the total output may be limited due to the flow rate limitation of the fuel gas conduit or the like for the above reason. Therefore, this generator is treated as a fuel-restricted generator group.

Further, in a single-shaft combined cycle machine, there is a case where a method is adopted in which a plurality of generators are grouped and one load command is distributed to a plurality of generators. The generators in the group were started and stopped, and the load was changed as if they were one generator.

On the other hand, at present, the output per axis is increased, and load commands and operation mode commands are individually issued as one generator, and operability is improved by detailed commands. In some cases, the load command is issued directly when the capacity of the generator is increased. Therefore, the members of the group may change.

As described above, regarding the generator, there are events such as a decrease in maximum output or a change in thermal efficiency due to the natural environment, and an event related to a group.

Power generation companies are required to generate the planned amount of power generation, which is called the simultaneous planned amount. The generator must pay a penalty based on the imbalance difference if the amount of electricity generated is less than or too much of the amount of electricity committed.

For power generation companies, it is necessary to understand how the amount of power generated by their own generators changes due to changes in the natural environment and reflect this in the power generation plan in order to achieve the same amount of planned values at the same time. Become.

In the power generation plan, the amount of power generation is planned over a certain period (for example, one day, one week, one month) in units of a certain time. For example, in order to meet the demand and the committed power generation amount, the start timing and the power generation amount are planned for each of the plurality of generators of the plurality of power generation types. In that case, it is also required to formulate a plan that considers an economical combination with low power generation costs.

Japanese Unexamined Patent Publication No. 2009-22137

Various methods are known for formulating power generation plans. For example, there is known a method of distributing generator output by interlocking a plurality of generators. In addition, a method is known in which a plurality of generators are divided into groups (groups), and the output of one group is increased and the output of the other group is decreased in a certain demand phase to perform flexible dynamic load distribution. ing.

However, no method has been considered to reflect the performance of each generator, which changes depending on the natural environment, in these distributions. As described above, in the conventional method, it is not possible to perform load distribution that reflects the performance of individual generators, for example, the performance that changes depending on the natural environment. Furthermore, when grouping generators and performing load distribution, it is not possible to perform load distribution that reflects the performance and grouping of individual generators.

In order to minimize the above-mentioned imbalance, it is necessary to precisely reflect the performance of each generator in the power generation plan. In addition, when a plurality of generators are controlled as a group, it is required to formulate a power generation plan capable of responding to changes in the member composition of the group and the performance of each member of the group from a certain point in time.

Therefore, it is an object of the present embodiment of the present invention to provide a power generation plan formulation device capable of formulating a power generation plan in consideration of the performance and group of power generation facilities, a power generation plan formulation method, and a power generation plan formulation program.

According to one embodiment, the power generation planning apparatus is a power generation information processing unit that processes information about the performance or group of power generation equipment, and predicts the performance of the power generation equipment based on data about the natural environment. Alternatively, as a definition of the group of power generation facilities, a power generation information processing unit for registering data about the power generation facilities belonging to the group and data about restrictions on the group is provided. The device further creates a power generation plan for the power generation facility based on the performance of the power generation facility predicted by the power generation information processing unit or the definition of the group registered by the power generation information processing unit. It has a creation unit.

It is a block diagram which shows the structure of the power generation plan formulation apparatus of 1st Embodiment. It is a figure which showed the example of the performance matrix map of 1st Embodiment. It is a block diagram which shows the structure of the power generation plan formulation apparatus of 2nd Embodiment. It is a figure which showed the example of the group definition data of 2nd Embodiment. It is a schematic diagram which showed the example of the group composition of 2nd Embodiment. It is a schematic diagram which showed the example of the group composition of 2nd Embodiment. It is a block diagram which shows the structure of the power generation plan formulation apparatus of 3rd Embodiment. It is a block diagram which shows the structure of the power generation plan formulation apparatus of 4th Embodiment. It is a graph which showed the example of the load distribution of 4th Embodiment. It is a block diagram which shows the structure of the power generation plan formulation apparatus of 5th Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In FIGS. 1 to 10, the same or similar configurations are designated by the same reference numerals, and redundant description will be omitted.

(First Embodiment)
FIG. 1 is a block diagram showing a configuration of a power generation plan formulation device according to the first embodiment. The power generation plan formulation device of FIG. 1 formulates a power generation plan of when to start the generator and how much power generation output to operate in response to the demand and the committed power generation amount. A generator is an example of a power generation facility.

The power generation plan formulation device of FIG. 1 includes a forecast demand data input unit 1, a power generation equipment data input unit 2, a forecast weather data input unit 3, a power generation equipment performance prediction unit 4, a power generation plan creation unit 5, and a forecast demand. It includes a data storage unit 11, a power generation equipment data storage unit 12, a predicted weather data storage unit 13, a power generation equipment performance data storage unit 14, and a power generation plan data storage unit 15. The power generation equipment performance prediction unit 4 of the present embodiment is an example of the power generation information processing unit.

The forecast demand data input unit 1 inputs forecast demand data, which is time-series data related to the forecast of electric power demand, into the power generation plan formulation device. The power demand predicted from this data is also the power supply that the generator, which is the subject of the power generation plan, should meet. The forecast demand data storage unit 11 stores the forecast demand data input from the forecast demand data input unit 1 in a table in chronological order.

The power generation facility data input unit 2 inputs the power generation facility data, which is data on the characteristics and operation of the generator (power generation facility), to the power generation plan formulation device. Examples of power generation equipment data include the code name of the generator, basic conditions such as the rated MW and the minimum MW of the generator, and information on the constraints imposed on the generator (types of constraint conditions and constraint period). The power generation equipment data storage unit 12 stores the power generation equipment data input from the power generation equipment data input unit 2 in a table. The power generation facility data storage unit 12 further stores a calculation range required when the power generation plan creation unit 5 creates a power generation plan.

The predicted weather data input unit 3 inputs the predicted weather data, which is time-series data related to the prediction of the weather in the vicinity of the generator on the scheduled power generation date and time, into the power generation plan formulation device. Predicted weather data is an example of data about the natural environment. The predicted weather data of the present embodiment is predicted data of the air temperature (atmospheric temperature) and the seawater temperature (seawater temperature) in the vicinity of the generator. The predicted weather data storage unit 13 stores the predicted weather data input from the predicted weather data input unit 3 in a table. Predicted weather data is stored in a table every unit time.

The power generation equipment performance prediction unit 4 predicts the performance of the generator based on the predicted weather data acquired from the predicted weather data storage unit 13 and the power generation equipment data acquired from the power generation equipment data storage unit 12. Specifically, the power generation facility performance prediction unit 4 calculates prediction data of the performance of the generator, which changes depending on the weather, for each unit time. Examples of such performance are the maximum power of the generator, which varies with air temperature, and the thermal efficiency, which varies with air temperature and seawater temperature. The performance prediction result by the power generation equipment performance prediction unit 4 is stored in the performance matrix map of the power generation equipment performance data storage unit 14 as the power generation equipment performance data.

For example, the power generation facility performance prediction unit 4 uses the reference thermal efficiency η [%], the correction coefficient α [%] based on the seawater temperature, the correction coefficient β [%] based on the temperature, and the temperature of the maximum thermal power output of the combined cycle power generation as the power generation facility data. Correction coefficient k ₁ [MW / ° C ³ ], k ₂ [MW / ° C ² ], k ₃ [MW / ° C], k ₄ [MW], calorific value unit price Fv [yen / MJ], power generation output P [MW] , Fuel cost Y [yen / h] and the like are taken out from the power generation facility data storage unit 12. Further, the power generation facility performance prediction unit 4 extracts the temperature Ta [° C.] and the seawater temperature Tw [° C.] from the power generation facility data storage unit 12 as the predicted weather data. Then, the power generation equipment performance prediction unit 4 substitutes the power generation equipment data and the predicted weather data into the equations (1) to (8).

Equation (1) represents the maximum output Px [MW] of combined cycle power generation after temperature correction. Equation (2) represents the thermal efficiency η'[%] of combined cycle power generation after temperature correction. Equation (3) represents the thermal efficiency η'[%] of thermal power generation after temperature correction.

Further, the equation (4) expresses the relationship between the seawater temperature Tw [° C.] and the degree of vacuum V [hPa] (a _{1 to} a ₄ are correction coefficients of the sea water temperature). Equation (5) represents the relationship between the degree of vacuum V [hPa] and correction coefficient _{α [%] (b 1 ~b} 4 is the correction factor of the degree of vacuum). Equation (6) expresses the relationship between the air temperature Ta [° C.] and the correction coefficient β [%] (c _{1 to} c ₄ are the air temperature correction coefficients).

Further, the equation (7) expresses the relationship between the power generation output P [MW] and the fuel cost Y [yen / h] (Kf [J / Wh] in the equation is a calorific value conversion coefficient). Equation (8) represents an approximate equation based on the least squares method of the relationship between the power generation output P [MW] and the fuel cost Y [yen / h].

The reference numeral i is used to distinguish the generators from each other. For example, P (1) = 500 MW, P (2) = 375 MW, P (3) = 250 MW, P (4) = 125 MW. Further, the symbols a, b, and c of the formula (8) are referred to as a quadratic coefficient, a linear coefficient, and a constant term of the fuel cost function, respectively. It can be said that the smaller the Y of the calculation result obtained by using the values of a, b, and c, the cheaper the fuel cost can be operated by the generator, and the higher the economical performance is.

When handling a generator for combined cycle power generation, the power generation equipment performance prediction unit 4 calculates the maximum output Px from the formula (1), and formulates the calculation results obtained by correcting the thermal efficiency of the formulas (2) and (4) to (7). By substituting into (8), the quadratic coefficient a, the linear coefficient b, and the constant term c of the fuel cost function are calculated (see FIG. 2).

FIG. 2 is a diagram showing an example of a performance matrix map of the first embodiment.

FIG. 2 shows the air temperature Ta and the seawater temperature Tw given for each unit time. The power generation facility performance prediction unit 4 calculates the maximum output Px of each generator, the secondary coefficient a, the primary coefficient b, and the constant term c based on these temperature Ta and seawater temperature Tw, and creates a performance matrix map. Store every unit time. FIG. 2 shows an example of time series data of Px, a, b, c of generators 1, 2, ..., N.

FIG. 2 shows changes in air temperature Ta and seawater temperature Tw from 0:00 to 14:00 on a sunny day. As can be seen from FIG. 2, the temperature Ta rises from midnight to noon on a sunny day. On the other hand, the maximum output Px of the combined cycle power generator decreases as the temperature Ta rises (see the maximum output Px of the generators 1 to n in FIG. 2). Therefore, the output of the combined cycle power generator may not be increased to the rated value when the temperature Ta rises from midnight to noon.

Therefore, when creating the power generation plan in the present embodiment, for example, the power generation plan is created in consideration of the maximum output Px of the performance matrix map. As a result, it is possible to realize power generation with a small discrepancy between the power generation amount of the power generation plan and the actual power generation amount.

Further, in combined cycle power generation and steam power generation, the power generation efficiency of the generator changes due to the influence of the temperature Ta and the seawater temperature Tw. Therefore, if you want to distribute the output of multiple generators so that the fuel cost is cheaper, calculate the relationship between the total output of these generators and the temperature Ta and seawater temperature Tw, and based on this calculation result. By determining the output distribution, the fuel cost can be reduced.

Therefore, the power generation facility performance prediction unit 4 of the present embodiment calculates the quadratic coefficient a, the linear coefficient b, and the constant term c of the approximate expression (fuel cost function) of the relationship between the power generation output P and the fuel cost Y. These calculation results are stored in the performance matrix map. As a result, the power generation planning unit 5 can grasp the relationship between the power generation output P of each generator and the fuel cost Y, and allocates the output so that the total fuel cost of the plurality of generators is reduced. It becomes possible to create a power generation plan.

Hereinafter, the configuration and operation of the power generation planning apparatus of the present embodiment will be described with reference to FIG. 1 again.

The power generation plan creation unit 5 acquires data related to the performance of the generator (power generation equipment performance data) from the performance matrix map in the power generation equipment performance data storage unit 14, and acquires the forecast demand data from the forecast demand data storage unit 11. .. Then, the power generation plan creation unit 5 creates a power generation plan for the generator based on the acquired power generation equipment performance data and forecast demand data. This makes it possible to create a power generation plan that takes into account the forecast of power demand and the appropriate output allocation. The power generation plan created by the power generation plan creation unit 5 is stored as power generation plan data in the power generation plan data storage unit 15 for each unit time.

For example, the power generation plan creation unit 5 acquires the maximum output Px of a plurality of generators from the performance matrix map, and distributes the outputs of these generators so that the difference between the power generation amount of the power generation plan and the actual power generation amount becomes small. To create a power generation plan. This makes it possible to create a power generation plan that meets demand and committed power generation.

Further, the power generation planning unit 5 acquires the quadratic coefficient a, the linear coefficient b, and the constant term c of the fuel cost functions of the plurality of generators from the performance matrix map, and the total fuel cost of these generators is low. Create a power generation plan by allocating output so that This makes it possible to create an economical power generation plan with low power generation costs.

As described above, the power generation plan formulation device of the present embodiment predicts the performance of the generator based on the data on the natural environment such as the temperature and the seawater temperature, and creates the power generation plan based on the predicted performance. Therefore, according to the present embodiment, it is possible to formulate a suitable power generation plan in consideration of changes in the performance of the generator due to the natural environment, and formulate a power generation plan having excellent predictability of the amount of power generation and economic efficiency of power generation. It becomes possible to do.

(Second Embodiment)
FIG. 3 is a block diagram showing the configuration of the power generation planning apparatus of the second embodiment.

The power generation plan formulation device of FIG. 3 is a group definition data input unit instead of the predicted weather data input unit 3 of FIG. 1, the power generation equipment performance prediction unit 4, the predicted weather data storage unit 13, and the power generation equipment performance data storage unit 14. 6, a group constraint changing unit 7, a group definition changing unit 8, a group definition data storage unit 16, and a group constraint data storage unit 17 are provided. The group definition data input unit 6, the group constraint change unit 7, and the group definition change unit 8 of the present embodiment are examples of the power generation information processing unit. Further, the group definition data input unit 6 and the group definition data storage unit 16 of the present embodiment are examples of an input unit and a storage unit, respectively.

The group definition data input unit 6 inputs and registers the group definition data, which is the data related to the definition of the generator group, in the power generation plan formulation device. The group definition data is composed of data on generators belonging to the group and data on constraints on the group. The former data shows which generator belongs to which group. The latter data show what constraints are imposed on which groups. The group definition data storage unit 16 stores (registers) the group definition data input from the group definition data input unit 6 in a table.

A part of the group definition data in the group definition data storage unit 16 is created by using the power generation equipment data in the power generation equipment data storage unit 12. Examples of such group definition data are code names, basic conditions, constraint information, and the like of generators belonging to the group. The restrictions on the group may be input from the power generation equipment data input unit 2 instead of the group definition data input unit 6, or can be input from both the group definition data input unit 6 and the power generation equipment data input unit 2. You may do so. In this case, the power generation equipment data input unit 2 is an example of a power generation information processing unit and an input unit.

FIG. 4 is a diagram showing an example of group definition data of the second embodiment.

FIG. 4 shows groups A to C, which are the same intermediate operation group, groups D and E, which are determination utilization rate groups, groups F and G, which are output restriction groups, and groups H to J, which are GLC groups. Shown. For example, generators 1 and 2 belong to group A, and generators 3 and 4 belong to group B.

The same middle operation group is a group of generators belonging to the same power plant middle operation. The removal / stop utilization rate group is a group for limiting the removal / stop utilization rate of generators belonging to the group. The output limiting group is a group for limiting the output of the generators belonging to the group. The GLC group is a group for allocating one load command to generators belonging to the group. Other examples include a simultaneous start restriction group that restricts the simultaneous start of generators belonging to the group, a power plant group consisting of generators belonging to the same power plant, and the like. Examples of the output limiting group include a system constraint group and a gas conduit flow rate constraint group.

Further, the simultaneous start restriction group is subject to a restriction (restriction) that the number of generators that can be started at the same time is, for example, one. In this case, two or more generators belonging to this group cannot be activated at the same time while this group is active.

As described above, the restrictions on the group include restrictions on conditions such as output restrictions and simultaneous start restrictions, and restrictions on periods such as the valid period and invalid period of the group. The group definition data storage unit 16 stores data on such conditions and restrictions on the period as group definition data.

There are two types of restrictions on the group of the present embodiment. One is when the constraints on the group are determined first, and then the generators that are members of the group are determined. In this case, when a generator is determined to be a member of a group, the constraints imposed on that generator are automatically determined. The other is when the members of the group are determined first, and then the constraints on the group are determined. In this case, the constraints placed on the generators belonging to a group are determined after the generator becomes a member of that group.

FIG. 5 is a schematic diagram showing an example of the group configuration of the second embodiment.

FIG. 5 shows that the generators 1 to 3 belong to the output limit group, the generators 2 to 4 belong to the same intermediate operation group, the generators 3 to 6 belong to the simultaneous start limit group, and the generators 5 and 6 are present. It shows that it belongs to a certain phylogenetic constraint group.

Here, the generator 2 belongs to the output restriction group and the same intermediate operation group, and the generator 5 belongs to the simultaneous start restriction group and the fishery agreement A target group. As described above, the group of the present embodiment is defined so that one generator is allowed to belong to a plurality of groups in an overlapping manner.

FIG. 6 is a schematic diagram showing an example of the group configuration of the second embodiment. FIG. 6 corresponds to an abstraction of FIG.

In FIG. 6, generators U _{1 to} U ₄ belong to group G ₁ , generators U ₄ and U ₅ belong to group G ₂ , generators U _{5 to} U ₉ belong to group G ₃ , and generator U ₈ show _{that U 9} belongs to the group _{G 4.} Group G ₁ ~G ₄ may be one generator belongs redundantly in a plurality of groups are defined as permitted.

In this case, since each generator can belong to a plurality of groups, it is possible to change the restrictions imposed on the generators in various ways and freely distribute the load. On the other hand, if there are many types of restrictions imposed on the generator, it may be difficult to operate the generator flexibly due to competition between the restrictions.

Therefore, in the power generation plan formulation device of the present embodiment, data relating to various groups is provided to the power generation plan creation unit 5, and the power generation plan creation unit 5 creates a power generation plan so as to balance the restrictions of these groups as much as possible. .. That is, the power generation plan creation unit 5 creates a power generation plan in the form of finding a solution of information processing in which a plurality of restrictions are imposed. This makes it possible to formulate a suitable power generation plan while handling various groups.

Hereinafter, the configuration and operation of the power generation planning apparatus of the present embodiment will be described with reference to FIG. 3 again.

The group constraint changing unit 7 and the group definition changing unit 8 are blocks for changing (updating) the group definition data in the group definition data storage unit 16. In the present embodiment, the group definition data input unit 6 can continuously change the group definition data, and the group definition change unit 8 can temporarily change the group definition data. The user of the power generation plan formulation device can change the group definition data by performing an operation of continuously or temporarily changing the group definition data on the UI (User Interface) of the power generation plan formulation device.

The group constraint changing unit 7 inputs the group constraint data for temporarily changing the group constraint included in the group definition data to the power generation plan formulation device. The group constraint data input from the group definition change unit 7 is stored in the group constraint data storage unit 17. This group constraint data is an example of change data.

The group definition changing unit 8 temporarily changes the group definition data in the group definition data storage unit 16 based on the group constraint data in the group constraint data storage unit 17. For example, when the group constraint data of a certain group is read from the group constraint data storage unit 17, the group definition data in the group definition data storage unit 16 is rewritten so that the definition (constraint) of the group is changed.

The group constraint data includes, for example, data regarding the change period and change contents of the constraint imposed on the group. The group definition change unit 8 changes the group definition data in the group definition data storage unit 16 according to the change contents during this change period. After this change period has elapsed, the group definition data in the group definition data storage unit 16 returns to the original contents.

The power generation plan creation unit 5 acquires data (group definition data) related to the definition of the generator group from the group definition data storage unit 16, and acquires the forecast demand data from the forecast demand data storage unit 11. Then, the power generation plan creation unit 5 creates a power generation plan for the generator based on the acquired group definition data and the forecast demand data. This makes it possible to create a power generation plan that takes into account the forecast of power demand and the constraints of individual groups, and it is possible to generate power according to the power demand while satisfying the constraints of individual groups. .. The power generation plan created by the power generation plan creation unit 5 is stored as power generation plan data in the power generation plan data storage unit 15 for each unit time.

When the group definition data in the group definition data storage unit 16 is temporarily changed by the group definition change unit 8, the power generation plan creation unit 5 creates a power generation plan based on the changed group definition data. do. On the other hand, when the group definition data in the group definition data storage unit 16 is not changed by the group definition change unit 8, the power generation plan creation unit 5 is the group definition data input unit 6 (or the power generation equipment data input unit 2). Create a power generation plan based on the group definition data input by.

As described above, the power generation plan formulation device of the present embodiment registers data related to the group definition, such as group members and constraints, in the group definition data registration unit 16, and creates a power generation plan based on the registered definitions. .. Therefore, according to the present embodiment, it is possible to formulate a suitable power generation plan in consideration of the members and restrictions of individual groups, and it is possible to formulate a power generation plan having excellent power generation economic efficiency and operational flexibility. It will be possible.

The group constraint changing unit 7 inputs change data (group constraint data) for temporarily changing the group constraint, and inputs change data for temporarily changing the group definition. It may be replaced with the changed part. That is, the change target by the change data is not limited to the restrictions of the group, but may be expanded to the members of the group. In this case, the group definition changing unit 8 can temporarily change not only the restrictions of the group included in the group definition data but also the members of the group included in the group definition data. For example, the number of generators belonging to a certain group will temporarily increase or decrease due to a change in the group definition data.

(Third Embodiment)
FIG. 7 is a block diagram showing the configuration of the power generation plan formulation device of the third embodiment.

Similar to the power generation plan formulation device of FIGS. 1 and 3, the power generation plan formulation device of FIG. 7 includes a forecast demand data input unit 1, a power generation facility data input unit 2, a forecast weather data input unit 3, and a power generation facility performance. Prediction unit 4, power generation plan creation unit 5, group definition data input unit 6, group constraint change unit 7, group definition change unit 8, forecast demand data storage unit 11, power generation equipment data storage unit 12, and so on. It includes a predicted weather data storage unit 13, a power generation facility performance data storage unit 14, a power generation plan data storage unit 15, a group definition data storage unit 16, and a group constraint data storage unit 17.

Further, the power generation planning apparatus of FIG. 7 includes a group performance prediction unit 9 and a group performance data storage unit 18. The power generation equipment performance prediction unit 4, the group definition data input unit 6, the group constraint change unit 7, the group definition change unit 8, and the group performance prediction unit 9 of the present embodiment are examples of the power generation information processing unit. Further, the group definition data input unit 6 and the group definition data storage unit 16 of the present embodiment are examples of an input unit and a storage unit, respectively.

As described above, the power generation equipment performance prediction unit 4 predicts the performance of the generator based on the predicted weather data acquired from the predicted weather data storage unit 13 and the power generation equipment data acquired from the power generation equipment data storage unit 12. do. Specifically, the power generation facility performance prediction unit 4 calculates prediction data of the performance of the generator, which changes depending on the weather, for each unit time. An example of such performance is the maximum output of a generator that changes with temperature. The performance prediction result by the power generation equipment performance prediction unit 4 is stored in the performance matrix map of the power generation equipment performance data storage unit 14 as the power generation equipment performance data.

On the other hand, the group performance prediction unit 9 predicts the performance of the generator group based on the group definition data acquired from the group definition data storage unit 16 and the power generation equipment data acquired from the power generation equipment data storage unit 12. An example of such performance is the total output of each group. For example, if the total output of a group is limited to 1000 MW or less, the total output of that group is expected to be 1000 MW or less during the period in which the group is active. In addition, if a generator of combined cycle power generation belongs to this group, the maximum output of each generator in this group is predicted to change depending on the weather (the specific content of the change is the power generation facility performance prediction). Predicted by Part 4). The performance prediction result by the group performance prediction unit 9 is stored in the group performance data storage unit 18 as group performance data.

The power generation plan creation unit 5 acquires data on the performance of the generator (power generation equipment performance data) from the power generation equipment performance data storage unit 14, and collects data on the performance of the generator group (group performance data) in the group performance data storage unit. It is acquired from 18, and the forecast demand data is acquired from the forecast demand data storage unit 11. Then, the power generation plan creation unit 5 creates a power generation plan for the generator based on the acquired power generation equipment performance data, group performance data, and forecast demand data. This makes it possible to create a power generation plan that takes into account the forecast of power demand, the constraints of individual groups, and the appropriate output allocation. The power generation plan created by the power generation plan creation unit 5 is stored as power generation plan data in the power generation plan data storage unit 15 for each unit time.

For example, when the total output of a combined group having a plurality of combined cycle power generators is limited to 500 MW or less, the total output of this one axis group is predicted to be 500 MW or less within the valid period. In this case, the power generation planning unit 5 determines the output distribution so that the output of each generator in one group is set to the maximum output or less and the upper limit of the total output of the generators in one group is set to 500 MW. , Create a power generation plan according to this output distribution. In this output distribution, start / stop of some generators belonging to one group may be specified.

As described above, the power generation planning apparatus of the present embodiment predicts the performance of the generator based on the data on the natural environment, and predicts the performance of the group of generators based on the data on the definition of the group. Create a power generation plan based on these performances. Therefore, according to the present embodiment, it is possible to formulate a suitable power generation plan in consideration of changes in the performance of the generator due to the natural environment and the restrictions imposed on the group, and the predictability of the amount of power generation and the economy of power generation. It is possible to formulate a power generation plan with excellent characteristics and operational flexibility.

(Fourth Embodiment)
FIG. 8 is a block diagram showing the configuration of the power generation plan formulation device of the fourth embodiment.

The power generation planning apparatus of FIG. 8 includes a load distribution determination unit 10 in addition to the components shown in FIG.

The load distribution determination unit 10 is a block that determines the load distribution for the GLC group. The GLC group is a group for allocating one load command to generators belonging to the group. The load distribution determination unit 10 determines the load distribution of the generators belonging to the GLC group based on the group definition data acquired from the group definition data storage unit 16.

The power generation plan creation unit 5 acquires the load distribution determination result (load distribution data) of the generator belonging to the GLC group from the load distribution determination unit 10, and acquires the forecast demand data from the forecast demand data storage unit 11. Then, the power generation plan creation unit 5 creates a power generation plan for the generator based on the acquired load distribution data and the forecast demand data. This makes it possible to create a power generation plan that takes into account the forecast of power demand and the load distribution of the GLC group, and it is possible to generate power according to the power demand while achieving the load command. The power generation plan created by the power generation plan creation unit 5 is stored as power generation plan data in the power generation plan data storage unit 15 for each unit time.

Next, the details of the load distribution of the present embodiment will be described.

When the GLC group includes a plurality of generators having different unit prices for power generation, the load allocation determination unit 10 selects, for example, parallel generators so that the generators having a low unit price for power generation operate as much as possible. Specifically, when the power demand is low, the load allocation determination unit 10 determines the load allocation so as to disassemble the generator having the highest unit price of power generation in the GLC group. On the other hand, when there is a large demand for electric power, the load allocation determination unit 10 determines the load allocation so that the generators in the GLC group, which have the lowest unit price of power generation, are arranged in parallel. do.

Further, if the amount of change in the electric power demand is within a range that does not require the arrangement or parallelization of the generators, the load allocation determination unit 10 may use a plurality of GLC groups so as to cope with the subsequent increase or decrease in the electric power demand. The load distribution is determined so that the outputs of the generators of the above are equal to each other. In this case, when any of the generators reaches the maximum output, the load distribution determination unit 10 keeps the output of this generator at the maximum output and makes the outputs of the remaining generators equal to each other. Determine the load distribution. Further, when the next generator reaches the maximum output, the load distribution determination unit 10 maintains the output of these two generators at the maximum output, and the outputs of the remaining generators are equal to each other. Determine the load distribution so that. The load distribution determination unit 10 repeats such processing until the outputs of all the generators in the GLC group reach the maximum output.

On the contrary, when the power demand decreases when the outputs of all the generators in the GLC group are the maximum outputs, the output of the generator having the largest maximum output is gradually reduced. Next, when the output of this generator drops to the output of the generator with the second largest output, the outputs of these two generators are adjusted to the same value and gradually reduced, or one of the generators is stopped. The load is distributed including the other generator. At this time, the load distribution determination unit 10 determines the economic efficiency of whether the load distribution of these two generators is specified as the former or the latter, and determines the more economical load distribution. Decide to adopt. The load distribution determination unit 10 repeats such a process for all the generators in the GLC group.

In the present embodiment, a plurality of GLC groups can be registered in the group definition data storage unit 16. For these GLC groups, the members and validity period can be changed each time. As described above, in the present embodiment, it is possible to flexibly operate a plurality of GLC groups.

The power generation planning unit 5 acquires load distribution data defining the relationship between power demand and load distribution from the load distribution determination unit 10, and acquires forecast demand data from the forecast demand data storage unit 11. Then, the power generation plan creation unit 5 creates time-series data of the load distribution by applying the predicted demand data to the relationship between the power demand and the load distribution, and creates a power generation plan based on the time-series data.

FIG. 9 is a graph showing an example of load distribution according to the fourth embodiment.

FIG. 9 shows the time change of the output of the 1-axis generator, the 2-axis generator, and the 3-axis generator of the combined cycle power generation belonging to a certain GLC group, and the time change of the electric power demand. FIG. 9 further shows the maximum output of the 1-axis generator, the 2-axis generator, and the 3-axis generator at a certain temperature. The maximum output of the combined cycle power generator is given by the above equation (1).

Reference numeral K ₁ and reference numeral K ₅ indicate a case where a 3-axis generator having a high power generation unit price is started / stopped. On the other hand, reference numeral K ₂ and reference numeral K ₄ indicate a case where the outputs of the three generators are made the same value. Further, reference numeral K _3, the output of the three generators have shown when it reaches the maximum output. As described above, the load distribution determination unit 10 of the present embodiment can change the load distribution in various forms according to the change in the electric power demand.

As described above, the power generation plan formulation device of the present embodiment determines the load distribution of the generators belonging to the GLC group based on the data about the definition of the GLC group, and creates the power generation plan based on this load distribution. Therefore, according to the present embodiment, it is possible to formulate a suitable power generation plan based on the load distribution in consideration of the members of the group and the constraints, and formulate a power generation plan excellent in the economic efficiency of power generation and the flexibility of operation. It becomes possible to do.

(Fifth Embodiment)
FIG. 10 is a block diagram showing a configuration of a power generation plan formulation device according to a fifth embodiment.

The power generation planning device 21 of FIG. 10 includes a processor 22 such as a CPU (Central Processing Unit), a main storage device 23 such as a RAM (Random Access Memory), an auxiliary storage device 24 such as an HDD (Hard Disc Drive), and the like. It includes a network interface 25 such as a LAN (Local Area Network) board, a device interface 26 such as a memory slot and a memory port, and a bus 27 that connects these devices to each other. The power generation planning device 21 is, for example, a computer such as a PC (Personal Computer), and includes an input device such as a keyboard and a mouse, and a display device such as an LCD (Liquid Crystal Display) monitor.

In the present embodiment, a power generation plan formulation program for causing the computer to execute information processing of the power generation plan formulation device according to any one of the first to fourth embodiments is installed in the auxiliary storage device 24. The power generation planning device 21 deploys this program in the main storage device 23 and executes it by the processor 22. As a result, the functions of the blocks shown in FIGS. 1, 3, 7, or 8 can be realized in the power generation plan formulation device 21, and the power generation plan described in the first to fourth embodiments can be created. It becomes. The data generated by this information processing is temporarily stored in the main storage device 23 or stored in the auxiliary storage device 24.

The power generation planning program can be installed, for example, by attaching an external device 28 recording this program to the device interface 26 and storing this program from the external device 28 in the auxiliary storage device 24. An example of the external device 28 is a computer-readable recording medium or a recording device incorporating such a recording medium. An example of a recording medium is a CD-ROM or a DVD-ROM, and an example of a recording device is an HDD. Further, the power generation planning program can be installed, for example, by downloading this program via the network interface 25.

According to this embodiment, it is possible to realize the function of the power generation planning apparatus according to any one of the first to fourth embodiments by software.

Although some embodiments have been described above, these embodiments are presented only as examples and are not intended to limit the scope of the invention. The novel devices, methods, and programs described herein can be implemented in a variety of other forms. In addition, various omissions, substitutions, and changes can be made to the forms of the apparatus, method, and program described in the present specification without departing from the gist of the invention. The appended claims and their equivalent scope are intended to include such forms and variations contained within the scope and gist of the invention.

1: Predicted demand data input unit 2: Power generation equipment data input unit 3: Predicted weather data input unit 4: Power generation equipment performance prediction unit 5: Power generation plan creation unit 6: Group definition data input unit 7: Group constraint change unit 8: Group Definition change unit 9: Group performance prediction unit 10: Load distribution determination unit 11: Forecast demand data storage unit 12: Power generation equipment data storage unit 13: Forecast weather data storage unit 14: Power generation equipment performance data storage unit 15: Power generation plan data storage unit Unit 16: Group definition data storage unit 17: Group constraint data storage unit 18: Group performance data storage unit 21: Power generation planning device 22: Processor 23: Main storage device 24: Auxiliary storage device 25: Network interface 26: Device interface 27 : Bus 28: External device

Claims (10)

A power generation information processing unit that processes information about the performance or group of power generation equipment, and predicts the performance of the power generation equipment based on data about the natural environment, or defines the group of power generation equipment as the group. A power generation information processing unit that registers data about the power generation equipment belonging to the above group and data about restrictions on the group.
A power generation plan creation unit that creates a power generation plan for the power generation facility based on the performance of the power generation facility predicted by the power generation information processing unit or the definition of the group registered by the power generation information processing unit.
With
The power generation information processing unit calculates the maximum output of the power generation facility based on the temperature which is the data about the natural environment, and the power generation facility is based on the temperature and the seawater temperature which are the data about the natural environment. calculating the approximate expression coefficient and constant term of the relationship between power output and fuel costs, and predict the performance of the previous SL generation facilities in the form of the power generation planning unit, the power generation plan based on the maximum output It is possible to create the power generation plan based on the coefficient and the constant term.
or,
The power generation information processing unit determines the constraint on the group and then determines the power generation facility belonging to the group, and determines the power generation facility belonging to the group and then determines the constraint on the group. it is possible, and a method comprising continuously change the definition of the group, it is possible and to temporarily change the definition of the group,
Power generation planning equipment. The power generation information processing unit
A power generation facility performance prediction unit that predicts the performance of the power generation facility based on the data on the power generation facility and the data on the natural environment is provided.
The power generation plan formulation device according to claim 1, wherein the power generation plan creation unit creates the power generation plan based on the performance of the power generation facility predicted by the power generation facility performance prediction unit. The power generation information processing unit
An input unit that inputs the definition of the group and registers it in the storage unit,
A group constraint changing unit for inputting change data for changing the constraint of the group included in the definition of the group registered in the storage unit, and a group constraint changing unit.
A group definition change unit that changes the definition of the group registered in the storage unit based on the change data is provided.
The power generation plan formulation device according to claim 1, wherein the power generation plan creation unit creates the power generation plan based on the definition of the group registered in the storage unit. The power generation information processing unit
A power generation facility performance prediction unit that predicts the performance of the power generation facility based on the data on the power generation facility and the data on the natural environment.
A group performance prediction unit that predicts the performance of the group based on the definition of the group is provided.
The power generation plan creation unit creates the power generation plan based on the performance of the power generation facility predicted by the power generation facility performance prediction unit and the performance of the group predicted by the group performance prediction unit. The power generation plan formulation device according to item 1. The power generation information processing unit further
An input unit that inputs the definition of the group and registers it in the storage unit,
A group constraint changing unit for inputting change data for changing the constraint of the group included in the definition of the group registered in the storage unit, and a group constraint changing unit.
A group definition change unit that changes the definition of the group registered in the storage unit based on the change data, and a group definition change unit.
The power generation planning apparatus according to claim 4. Further, a load distribution determining unit for determining the load distribution of the power generation equipment belonging to the group is provided based on the definition of the group registered by the power generation information processing unit.
The power generation plan formulation device according to any one of claims 1 to 5, wherein the power generation plan creation unit creates the power generation plan based on the load distribution of the power generation facility determined by the load distribution determination unit. .. The power generation planning apparatus according to any one of claims 1 to 6, wherein the data on the natural environment is prediction data of the temperature and seawater temperature in the vicinity of the power generation facility on the scheduled power generation date and time. The power generation planning apparatus according to any one of claims 1 to 7, wherein the group is defined so that one power generation facility is allowed to belong to a plurality of groups in an overlapping manner. The power generation information processing unit that processes information about the performance or group of power generation equipment predicts the performance of the power generation equipment based on the data about the natural environment, or belongs to the group as the definition of the group of power generation equipment. Register the data about the power generation facility and the data about the constraints on the group,
The power generation plan creation unit creates a power generation plan for the power generation facility based on the performance of the power generation facility predicted by the power generation information processing unit or the definition of the group registered by the power generation information processing unit.
Be prepared
The power generation information processing unit calculates the maximum output of the power generation facility based on the temperature which is the data about the natural environment, and the power generation facility is based on the temperature and the seawater temperature which are the data about the natural environment. calculating the approximate expression coefficient and constant term of the relationship between power output and fuel costs, and predict the performance of the previous SL generation facilities in the form of the power generation planning unit, the power generation plan based on the maximum output It is possible to create the power generation plan based on the coefficient and the constant term.
or,
The power generation information processing unit determines the constraint on the group and then determines the power generation facility belonging to the group, and determines the power generation facility belonging to the group and then determines the constraint on the group. it is possible, and a method comprising continuously change the definition of the group, it is possible and to temporarily change the definition of the group,
Power generation plan formulation method. The power generation information processing unit that processes information about the performance or group of power generation equipment predicts the performance of the power generation equipment based on the data about the natural environment, or belongs to the group as the definition of the group of power generation equipment. Register the data about the power generation facility and the data about the constraints on the group,
The power generation plan creation unit creates a power generation plan for the power generation facility based on the performance of the power generation facility predicted by the power generation information processing unit or the definition of the group registered by the power generation information processing unit.
It is a power generation plan formulation program that allows a computer to execute a power generation plan formulation method that prepares for this.
The power generation information processing unit calculates the maximum output of the power generation facility based on the temperature which is the data about the natural environment, and the power generation facility is based on the temperature and the seawater temperature which are the data about the natural environment. calculating the approximate expression coefficient and constant term of the relationship between power output and fuel costs, and predict the performance of the previous SL generation facilities in the form of the power generation planning unit, the power generation plan based on the maximum output It is possible to create the power generation plan based on the coefficient and the constant term.
or,
The power generation information processing unit determines the constraint on the group and then determines the power generation facility belonging to the group, and determines the power generation facility belonging to the group and then determines the constraint on the group. it is possible, and a method comprising continuously change the definition of the group, it is possible and to temporarily change the definition of the group,
Power generation planning program.

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