JP3765926B2 - Power generation operation management system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power generation operation management system that collectively manages a plurality of power plants each having an operation monitoring device (or unit control device, signal input / output control device) in each power generation unit.
[0002]
[Prior art]
In a hydroelectric power plant, there is an example of a power generation operation management system in which a general control station that controls a plurality of power plants is provided, and operation management is performed in a centralized location different from the power plant. However, this is a combination of a monitoring and control device for a small power plant of about tens of thousands of kW, including upstream and downstream self-flow types, or a plurality of small and medium capacity monitoring and control devices. However, it is just a simple start / stop control from a distance.
[0003]
In the first place, a hydropower plant has a small number of devices to be controlled and a small number of objects to be monitored (for example, about 100 points), and the operation of controlled devices (gates, valves, etc.) is relatively simple. There are few control steps such as opening the generator and inserting a generator, and it can be handled in a short time (for example, about 10 minutes). In the event of a failure, the generator can be stopped by closing the gate.
[0004]
For these technical reasons, driving from a distance has been performed. Note that maintenance has not been distant.
In contrast, thermal power plants and nuclear power plants have a large number of controlled devices and monitoring points (approximately tens of thousands), and the operation of controlled devices (boilers, turbines, etc.) is complicated due to various factors. It was a simple structure, and driving was not performed concentrated from a distance. Also, from the viewpoint of handling combustion raw materials, the operation was not concentrated from a distance.
[0005]
[Problems to be solved by the invention]
Conventionally, power plants such as nuclear power and thermal power have a plurality of power generation units (units), and an operation monitoring device (comprising a computer system) is provided for each unit, and operation monitoring is performed for each unit.
[0006]
And the output control command of the power generation unit is performed between the central power supply command station and each power generation unit.
For this reason, the amount of information communication between the central power supply command center and each power generation unit becomes enormous, and the computer at the central power supply command center distributes the load according to the status of each power generation unit. It was unavoidable.
[0007]
In addition, detailed control is impossible, power generation efficiency, economy, energy resource saving, consideration for the global environment, power failure during power plant trouble, frequency fluctuation suppression, rapid load fluctuation There was a lot of room for improvement in terms of delays in response to.
[0008]
In addition, for power generation units that have multiple power generation shafts from the central power supply command center, it is necessary to distribute the load to each power generation shaft on the power plant side. There was a lot of time for the operator to wait for the response.
[0009]
In addition, each unit always requires 5 to 6 operators (duty staff), and about 5 times as many resident workers as replacement personnel for 24-hour operation and emergency personnel for handling accidents.
[0010]
However, with regard to normal operation monitoring, since different operators are monitoring the same monitoring in each power generation unit, there has been a strong demand for labor saving.
Therefore, an object of the present invention is to provide a power generation operation management system that further saves labor in operation management while maintaining the safety and reliability of power plant operation.
[0011]
A power generation operation management system that gives each power generation unit a power generation plan for each unit that takes into account the economics, operational efficiency, regular inspection plan, global environment, and the stability of the power system in the event of a unit failure. It is an object to provide an output control method.
[0012]
[Means for Solving the Problems]
(1) A general operation management device (hereinafter referred to as the operation management center) that operates multiple power plant groups consisting of a plurality of power generation units at one location is provided. In the power generation operation management system that receives and outputs the output command to each power generation unit, this operation management center automatically generates power by means of a telemeter, telephone line, wireless communication, etc. according to the procedure determined by each unit. Enter the capacity, the power generation planning department calculates the total power generation capacity in the pipe, and automatically communicates by means of telemeter, telephone line, wireless communication, etc. according to the procedure specified by the central power supply command center, and received by the communication means An output command input / time unit command conversion unit for all power generation units from the central power supply command center is provided, and the power generation unit price, thermal efficiency, And a power generation plan section that calculates a power generation plan for each unit from these databases, and each unit has output command transmission means automatically according to procedures determined by means such as a telemeter, telephone line, and wireless communication. It is characterized by.
(2) The power generation plan section of the operation management center has a database of output versus unit price of each unit, and the power generation plan for each unit is calculated based on this database so that the power generation cost is minimized. .
(3) The power generation planning section of the operation management center has a database of output versus heat efficiency of each unit, and the power generation plan for each unit is calculated based on this database so that the amount of generated heat is minimized.
(4) In the power generation planning section of the operation management center, input the fuel reserve amount of each unit, compare the reserve amount with the planned value, enter the fuel carry-in plan or regular inspection plan from the unit with less than the planned value, On the other hand, it is characterized in that a power generation plan is calculated with an output restriction according to these conditions.
(5) The power generation plan section of the operation management center has an output-to-output response database for each unit. According to the load change prediction, the output response database of each unit distributes the power generation plan between the slow output unit and the fast unit. It is characterized by calculating.
(6) A power generation unit that has a database of output responsiveness and unit price of power generation in the power generation planning section of the operation management center, and ranks in order from the unit with the highest power generation unit price and the unit with the fast output response, and is predicted in advance in the operation of the power system It is characterized by calculating an emergency output response width (output width and rate of change) due to an emergency stop, an accident in a transmission line / substation, and setting an output upper limit lower than the maximum output for a specific unit.
(7) In the power generation plan section of the operation management center, when a unit abnormality occurs, the operation continuation time of the unit is input, the power generation capacity margin is obtained from the power supply plan and the total power generation capacity, and the unit is allowed to stop according to this And has means for contacting the unit.
(8) The power generation plan section of the operation management center in (7) has means for making a stop allowance plan for each unit axis and contacting the unit when an abnormality occurs in a unit having a plurality of power generation axes in the unit. It is characterized by that.
(9) The power generation planning unit of the operation management center of the above (2) to (7) and the following (28) to (31) makes a power generation plan for each unit for a unit having a plurality of power generation shafts in the unit. It is characterized by.
(10) The power generation planning section of the operation management center receives output commands for all power generation units in the jurisdiction from the central power supply command center in the form of a medium- to long-term power generation plan, and outputs output in real time at the output command input / time unit command conversion section. It is characterized by converting to a required value.
(11) The power generation plan section of the operation management center receives output commands for all power generation units in the jurisdiction from the central power supply command center in the form of a time-series power generation plan for the next day, and at the output command input / time unit command conversion section in real time. It is characterized in that it is converted into a required output value.
(12) The power generation plan section of the operation management center receives the output command for all power generation units in the jurisdiction from the central power supply command center in the form of a time-series power generation request for the day, and the output command input / time unit command conversion section performs real time. It is characterized in that it is converted into a required output value.
(13) The power generation planning department of the operation management center gives a command for output of all the power generation units in the jurisdiction from the central power supply command center to a time series power generation request in a fixed time unit on the day and an output adjustment value within a shorter range within a shorter period of time. The received output command input / time unit command conversion unit converts the output request value to a real time.
(14) The power generation planning section of the operation management center is characterized in that the power generation capacity is notified in time series from each unit and the total power generation capacity is calculated.
(15) The power generation planning unit of the operation management center is characterized in that the power generation capacity is notified from each unit in time series in units of shafts and the total power generation capacity is calculated.
(16) The power generation planning section of the operation management center is characterized in that the power generation capacity of the next day / time series is received from each unit and the total power generation capacity is calculated.
(17) The power generation planning section of the operation management center is characterized in that the power generation capacity of the next day / time series is received from each unit and the total power generation capacity is calculated in response to each shaft unit.
(18) The power generation planning section of the operation management center is characterized in that it receives weekly and time-series power generation capacity from each unit and calculates the total power generation capacity.
(19) The power generation planning section of the operation management center is characterized in that it receives the weekly / time-series power generation capacity from each unit and calculates the total power generation capacity.
(20) The power generation planning section of the operation management center is characterized in that it receives monthly and time-series power generation capacity from each unit and calculates the total power generation capacity.
(21) The power generation planning section of the operation management center is characterized in that it receives the monthly and time-series power generation capacity from each unit and calculates the total power generation capacity.
(22) The means for issuing the output command of the operation management center is a unit unit, and the unit having a plurality of power generation shafts in the unit has a means for converting the output command into an axis unit.
(23) The means for issuing an output command from the operation management center includes means for a unit unit or a unit for a unit having a plurality of power generation shafts in the unit.
(24) The power generation planning section of the operation management center is characterized in that the total power generation capacity of the power plant group in the pipe is communicated to the central power supply command center in time series.
(25) The power generation planning section of the operation management center is characterized by notifying the central power supply command center of the total power generation capacity for the next day and time series of the power plant group in the jurisdiction.
(26) The power generation planning section of the operation management center is characterized by notifying the central power supply command center of the total power generation capacity in weekly and time series of the power plant group in the jurisdiction.
(27) The power generation planning section of the operation management center is characterized by notifying the central power supply command center of the monthly and time-series total power generation capacity of the power plant group in the jurisdiction.
(28) The power generation planning section of the operation management center has a database of output vs. seawater temperature rise of each unit, and based on this database, calculates a power generation plan for each unit so that the total seawater temperature rise is minimized. Features.
(29) The power generation plan section of the operation management center has a database of output vs. seawater temperature rise of each unit, and the first priority is given to the output value upper limit determined from the seawater temperature rise allowable upper limit of each power generation unit based on this database Based on this, the power generation plan for each unit is calculated so that the total seawater temperature rise is minimized.
(30) The power generation plan section of the operation management center has a database of output to exhaust gas of each unit, and based on this database, calculates a power generation plan for each unit so that the total exhaust gas emission amount is minimized. Features.
(31) The power generation planning section of the operation management center has a database of output to exhaust gas of each unit. Based on this database, the output value upper limit determined from the upper limit of the exhaust gas emission amount of each power generation unit is given first priority. Based on this, the power generation plan for each unit is calculated so as to minimize the total exhaust emission amount.
(32) The output to exhaust gas database of each unit in the power generation planning section of the operation management center of 30 and 31 is weighted and evaluated according to the type of emission gas.
(33) The power generation planning section of the 32 operation management centers evaluates the influence of exhaust gas on the surroundings based on the output-to-exhaust gas and terrain database of each unit and ambient weather data input from each power generation unit. The maximum allowable output of the unit is calculated in time series.
(34) The power generation planning functions 3, 4, 29 and 33 are provided at the central power supply command station.
(35) The power generation planning functions 4, 29 and 33 are provided in the power generation unit.
(36) The power generation capacities of the units 14 to 21 are aggregated by a power plant generalization device (hereinafter referred to as a power plant monitoring center) installed for each power plant and transmitted to the power generation planning unit of the operation management center.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described with reference to the drawings.
(1) FIG. 1 is a configuration diagram of a power generation operation management system according to a first embodiment of this invention.
[0014]
In FIG. 1, the operation management center 1 inputs the power generation capacity from each unit 2 through a communication means 3 such as a telemeter, a telephone line, and wireless communication, and calculates the total power generation capacity in the pipe in the power generation planning unit 4 and the central power supply commander. A communication means 6 such as a telemeter, a telephone line, and wireless communication is connected to the station 5, and an output command input / time unit command conversion unit 7 for all power generation units from the central power supply command center received by the communication means is provided. It has a database 8 of power generation unit price, heat efficiency, output response, etc. inputted in advance, and a power generation planning unit 4 for calculating a power generation plan for each unit from these, and each unit by means of communication means 3 such as a telemeter, telephone line, wireless communication, etc. Output command transmission means.
[0015]
An operation management center that operates multiple power plant groups consisting of multiple power generation units at one location is established. This operation management center receives output commands for all power generation units from the central power supply command center and distributes them to each power generation unit. The operation management center inputs the power generation capacity from each unit by means of a telemeter, telephone line, wireless communication, etc., and calculates the total power generation capacity in the pipe at the power generation planning department and central power supply An output command input / time unit command conversion unit for all power generation units from the central power supply command center received from the central power supply command center by means of telemeter, telephone line, wireless communication, etc. is provided to the command center, and input in advance. Power generation unit price, thermal efficiency, output response, etc., and a power generation plan section that calculates the power generation plan for each unit from these. Line by having an output command transmitting means to each unit by means of wireless communication such as, economic by the operator of the fewer people, the operation efficient and has a stable effect on system operation.
(2) In FIG. 2, the power generation plan unit 4 of the operation management center has a database 8 of the output versus unit price of each unit, and the power generation plan for each unit so that the power generation cost is minimized by 9 based on this database. Is calculated.
[0016]
Thereby, there is an economic effect that electric power can be sold at a minimum power generation cost.
(3) In FIG. 3, the power generation planning unit 4 of the operation management center has a database 8 for the output-to-heat efficiency of each unit. Based on this database, a power generation plan for each unit is generated so that the amount of generated heat is minimized by 10. calculate.
[0017]
This has the effect of not consuming wasteful energy and polluting the global environment.
(4) In FIG. 4, the fuel storage amount 12 of each unit is input in the power generation planning unit 4 of the operation management center, and the storage amount is compared with the planned value of the database 8 by 11. 13 or the regular inspection plan 14 is input, and the power generation plan is calculated by 11 according to the output restriction corresponding to these conditions for the unit.
[0018]
As a result, the fuel is burned systematically, and there is an effect of keeping the fuel carry-in plan or regular inspection plan of the power plant.
(5) In FIG.
The power generation plan section 4 of the operation management center has an output-to-output response database 8 for each unit, and according to the load change prediction 7, the power generation plan distribution 15 of the units having a slow output response and the fast units by the output response database of each unit. Is calculated.
[0019]
This has the effect of stabilizing the frequency of the power system.
(6) In FIG. 6, the power generation planning unit 4 of the operation management center has a database 8 of output responsiveness and unit price of power generation, and ranks the unit from the unit with the highest unit price of power generation and the unit with the fast output response. Calculate the emergency output response width (output width and rate of change) due to the emergency stop of the power generation unit and the transmission line / substation accident that are predicted in the operation of the system, and set an output upper limit lower than the maximum output for a specific unit.
[0020]
Thereby, there is an effect of stabilizing the frequency of the electric power system that does not generate useless power generation costs.
(7) In FIG.
In the power generation plan section 4 of the operation management center, when a unit abnormality occurs, the operation continuation possible time 18 is input, and a power generation capacity margin is obtained from the power supply plan and the total power generation capacity according to 17, and the unit is allowed to stop accordingly. Have means to plan and contact the unit.
[0021]
This has the effect of avoiding damage to power plant equipment and suppressing power outages and frequency fluctuations in the power system.
(8) In FIG. 8, the power generation planning unit 4 of the operation management center described in item 7 sets a stop allowable plan 20 for each unit shaft 21 when an abnormality occurs in the unit 19 having a plurality of power generation shafts in the unit. Means for contacting the unit;
[0022]
Thus, the power generation plan section of the operation management center in (7) has means for making a stop allowance plan for each unit axis and contacting the unit when an abnormality occurs in a unit having a plurality of power generation axes in the unit. As a result, the power plant side has the effect of saving labor by eliminating the trouble of making an operation plan for each shaft.
(9) In FIG. 9, the power generation planning unit 4 of the operation management center of (2) to (7) and (28) to (31) has 21 shafts for a unit 19 having a plurality of power generation shafts in the unit. Make a power generation plan.
[0023]
As a result, the power plant side has the effect of saving labor by eliminating the trouble of making an operation plan for each shaft.
(10) In FIG. 10, the power generation planning unit 4 of the operation management center receives an output command for all the power generation units in the pipe from the central power supply command center 5 in the form of a medium to long-term power generation plan 22 and converts the output command input / time unit command. The unit 7 converts the output request value 26 in real time.
[0024]
Accordingly, there is an effect that a power generation plan that is economical, has good operation efficiency, and is stable in terms of system operation can be set in advance in accordance with the operation plan of the power generation unit in the pipe.
(11) In FIG. 10, the power generation planning unit 4 of the operation management center receives an output command for all the power generation units in the pipe from the central power supply command center 5 in the form of a time series power generation plan 23 on the next day, and an output command input / time unit. The command conversion unit 7 converts the output request value 26 in real time.
[0025]
As a result, there is an effect that a power generation plan that is economical, has good operation efficiency, and is stable in terms of system operation can be set in advance in accordance with the operation plan of the power generation unit in the pipe.
(12) In FIG. 10, the power generation planning unit 4 of the operation management center receives the output command for all the power generation units in the pipe from the central power supply command center 5 in the form of the time-series power generation request 24 of the day, and the output command input / time unit The command conversion unit 7 converts the output request value 26 in real time.
[0026]
Accordingly, there is an effect that a power generation plan that is economical, has good operation efficiency, and is stable in terms of system operation can be set in advance in accordance with the operation plan of the power generation unit in the pipe.
(13) In FIG. 10, the power generation planning unit 4 of the operation management center limits the output command for all the power generation units in the jurisdiction from the central power supply command center 5 in a shorter period than the time-series power generation request for a fixed time unit on the day. The received output command input / time unit command conversion unit 7 converts the output adjustment value into a real time output request value 26 in the form 25 of the output adjustment value.
[0027]
As a result, there is an effect that a power generation plan that is economical, good in operation efficiency, and stable in system operation can be established in accordance with the actual load fluctuation in accordance with the operation plan of the power generation unit in the pipe.
(14) In FIG. 11, the power generation planning unit 4 of the operation management center receives the power generation capacity from each unit in time series 28 and calculates 27 the total power generation capacity.
[0028]
This has the effect of sending the value to the central power supply command center and enabling the time series power generation plan of the central power supply command center.
(15) In FIG. 11, the power generation planning unit 4 of the operation management center calculates the total power generation capacity 27 by receiving the power generation capacity from each unit in time series to the shaft unit 29.
[0029]
This has the effect of sending the value to the central power supply command center and enabling the time series power generation plan of the central power supply command center.
(16) In FIG. 11, the power generation planning unit 4 of the operation management center calculates the total power generation capacity 27 by receiving the power generation capacity 30 of the next day and time series from each unit.
[0030]
This has the effect of sending the value to the central power supply command center and enabling the power generation plan for the next day of the central power supply command center.
(17) In FIG. 11, the power generation planning unit 4 of the operation management center calculates the total power generation capacity 27 by receiving the power generation capacity of the next day and time series from each unit to the shaft unit 31.
[0031]
This has the effect of sending the value to the central power supply command center and enabling the power generation plan for the next day of the central power supply command center.
(18) In FIG. 11, the power generation planning unit 4 of the operation management center receives the weekly / time-series power generation capacity 32 from each unit and calculates 27 the total power generation capacity.
[0032]
As a result, the value is sent to the central power supply command center, which enables the central power supply command center to make a weekly and time-series power generation plan.
(19) In FIG. 11, the power generation planning unit 4 of the operation management center receives the weekly / time-series power generation capacity from each unit to the shaft unit 33 and calculates 27 the total power generation capacity.
[0033]
As a result, the value is sent to the central power supply command center, which enables the central power supply command center to make a weekly and time-series power generation plan.
(20) In FIG. 11, the power generation planning unit 4 of the operation management center receives the monthly / time series power generation capacity 34 from each unit and calculates 27 the total power generation capacity.
[0034]
This has the effect of sending the value to the central power supply command center and enabling the monthly power supply plan of the central power supply command center.
(21) In FIG. 11, the power generation planning unit 4 of the operation management center receives the monthly and time-series power generation capacity from each unit to the shaft unit 35 and calculates 27 the total power generation capacity.
[0035]
This has the effect of sending the value to the central power supply command center and enabling the monthly power supply plan of the central power supply command center.
(22) In FIG. 12, the means for issuing the output command of the operation management center is the unit unit 36, and the unit having a plurality of power generation shafts in the unit has means 37 for converting the output command to the unit of shaft.
[0036]
This has the effect of reducing the burden on the power generation unit and enabling optimal output distribution for each axis determined on the unit side.
(23) In FIG. 12, the means for issuing the output command of the operation management center has means 38 for the unit unit or for the unit having a plurality of power generation shafts in the unit.
[0037]
This has the effect of reducing the burden on the power generation unit side.
(24) In FIG. 13, the power generation planning unit 4 of the operation management center notifies the central power supply command center 5 of the total power generation capacity of the power plant group in the pipe in a time series 39.
[0038]
As a result, there is an effect of enabling the power generation plan for the time unit of the central power supply command center.
(25) In FIG. 13, the power generation planning unit 4 of the operation management center notifies the central power supply command center 5 of the total power generation capacity 40 for the next day and time series of the power plant group in the pipe.
[0039]
This has the effect of enabling a daily power generation plan at the central power supply command center.
(26) In FIG. 13, the power generation planning unit 4 of the operation management center informs the central power supply command center 5 of the total power generation capacity 41 in weekly and time series of the power plant group in the jurisdiction.
[0040]
This has the effect of enabling weekly and time-series power generation plans at the central power supply command center.
(27) In FIG. 13, the power generation planning unit 4 of the operation management center informs the central power supply command center 5 of the monthly and time-series total power generation capacity 42 of the power plant group in the jurisdiction.
[0041]
This has the effect of enabling a monthly and time-series power generation plan at the central power supply command center.
(28) In FIG. 14, the power generation planning unit 4 of the operation management center has a database 8 for the output to seawater temperature rise of each unit, and each unit so that the total seawater temperature rise is minimized by 43 based on this database 8. Calculate each power generation plan.
[0042]
This has the effect of providing so-called earth-friendly power plant operations that minimize the impact on the surrounding seawater resource environment.
(29) In FIG. 14, the power generation planning unit 4 of the operation management center has a database 8 of the output vs. seawater temperature rise of each unit. The first priority is the output value upper limit determined from the above, and based on this, the power generation plan for each unit is calculated so that the total seawater temperature rise is minimized.
[0043]
This has the effect of providing so-called earth-friendly power plant operations that minimize the impact on the surrounding seawater resource environment.
(30) In FIG. 15, the power generation planning unit 4 of the operation management center has an output-to-exhaust gas database 8 of each unit, and each unit is configured so that the total exhaust gas emission amount is minimized by 45 based on this database 8. Calculate each power generation plan.
[0044]
Thereby, there is an effect that it is possible to provide a so-called earth-friendly power plant operation that minimizes the influence on air pollution and global warming.
(31) In FIG. 16, the power generation planning unit 4 of the operation management center has an output-to-exhaust gas database 8 for each unit. The power output plan determined for each unit is calculated so that the total exhaust gas emission amount is minimized based on the upper limit of the output value determined from the above.
[0045]
Thereby, there is an effect that it is possible to provide a so-called earth-friendly power plant operation that minimizes the influence on air pollution and global warming.
(32) In FIGS. 15 and 16, the output-to-exhaust gas database 8 of each unit in the power generation planning unit 4 of the operation management center of (30), (31) indicates the type of emission gas (SOX, NOX, Co2, etc.). The weight is evaluated accordingly.
[0046]
As a result, the impact on air pollution and global warming can be obtained by weighting and evaluating the output versus exhaust gas database of each unit in the power generation planning section of the operation management center of (30) and (31) according to the type of emission gas. There is an effect that it is possible to provide a so-called earth-friendly power plant operation.
(33) In FIG. 17, the power generation planning unit 4 of the operation management center 1 in (32) is for the output-to-exhaust gas and terrain database 8 of each unit and the ambient weather data (temperature, air volume, wind direction) of each power generation unit. The series predicted value 48 is input, and the influence of the exhaust gas on the periphery is evaluated by considering the surrounding terrain data at 47 to calculate the allowable maximum output of each unit in time series.
[0047]
As a result, an output upper limit value corresponding to an allowable upper limit value for surrounding life forms and structures is set in time series, and there is an effect that it is possible to provide operation of a power plant in consideration of the surrounding environment.
(34) In FIGS. 18 to 21, the power generation plan function 4 taking into account the thermal efficiency 10, the fuel storage amount 11, the seawater temperature rise 44, and the exhaust gas amount 46 around the power plant in (3), (4), (29), and (33). Is provided in the central power supply command station 5 or the power generation unit.
[0048]
As a result, even in an electric power system that does not have the operation management center described above, the same finely detailed power operation can be performed, and there is an effect that it is possible to perform a power generation business in consideration of the surrounding environment.
(35) In FIGS. 22 to 24, the power generation unit 2 is provided with a power generation planning function 4 that takes into account the fuel reserve amount 11, seawater temperature rise 44, and exhaust gas amount 46 around the power plant in (4), (29), and (33). .
[0049]
As a result, it is possible to set the upper limit of output on the unit that finally generates power, and it is possible to reliably limit the output, and there is an extra database in the upper operation management center, power plant monitoring center, central power supply command center And there is no need to exchange information with them, which increases efficiency.
(36) In FIG. 25, the power generation capacities of the units (14) to (21) are aggregated at the power plant monitoring center 49 installed for each power plant and transmitted to the power generation planning unit 27 of the operation management center 1.
[0050]
This makes it possible to centrally manage the maintenance information and power generation capacity of the power plant. When a failure occurs in a power generation unit, when the failure will recover, when the total power generation capacity of the power plant will recover, etc. By contacting important information on power supply and demand to the operation management center on behalf of the unmanned power generation unit, the power generation plan of the operation management center can be made more efficient.
[0051]
【The invention's effect】
Based on the command of the central power supply command center by the output control system of the power generation operation management system, multiple groups of power plants consisting of a plurality of power generation units can be efficiently and economically operated at each power generation unit at a single location by a small number of operators. In consideration of the regular inspection plan, fine control is possible, and it is possible to supply inexpensive electricity, save energy resources, and minimize pollution to the global environment.
[0052]
Or, in the event of a failure on the unit side, give consideration to the stability of the power system such as power failure to the power system and suppression of frequency fluctuations, and command a power generation plan for each unit that can respond quickly to sudden load fluctuations. be able to.
[0053]
According to the present invention, the central power supply command center of the power company will communicate with the power generation operation management system that collectively manages a plurality of power plant groups consisting of a plurality of power generation units. The burden can be reduced and the size can be reduced.
[0054]
Or, the power plant side basically basically exchanges information, and load distribution is automated up to each power generation shaft, reducing the burden on the operator and reducing the number of operators, that is, inexpensive and good quality. Electricity can be supplied.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a power generation operation management system according to a first embodiment of this invention.
FIG. 2 is a configuration diagram of a power generation operation management system according to a second embodiment of this invention.
FIG. 3 is a configuration diagram of a power generation operation management system according to a third embodiment of the present invention.
FIG. 4 is a configuration diagram of a power generation operation management system according to a fourth embodiment of the present invention.
FIG. 5 is a configuration diagram of a power generation operation management system according to a fifth embodiment of the present invention.
FIG. 6 is a configuration diagram of a power generation operation management system according to a sixth embodiment of the present invention.
FIG. 7 is a configuration diagram of a power generation operation management system according to a seventh embodiment of the present invention.
FIG. 8 is a configuration diagram of a power generation operation management system according to an eighth embodiment of the present invention.
FIG. 9 is a configuration diagram of a power generation operation management system according to a ninth embodiment of this invention.
FIG. 10 is a configuration diagram of a power generation operation management system according to a tenth embodiment of the present invention.
FIG. 11 is a configuration diagram of a power generation operation management system according to an eleventh embodiment of the present invention.
FIG. 12 is a configuration diagram of a power generation operation management system according to a twelfth embodiment of the present invention.
FIG. 13 is a configuration diagram of a power generation operation management system according to a thirteenth embodiment of the present invention.
FIG. 14 is a configuration diagram of a power generation operation management system according to a fourteenth embodiment of the present invention.
FIG. 15 is a configuration diagram of a power generation operation management system according to a fifteenth embodiment of the present invention.
FIG. 16 is a configuration diagram of a power generation operation management system according to a sixteenth embodiment of the present invention.
FIG. 17 is a configuration diagram of a power generation operation management system according to a seventeenth embodiment of the present invention.
FIG. 18 is a configuration diagram of a power generation operation management system according to an eighteenth embodiment of the present invention.
FIG. 19 is a configuration diagram of a power generation operation management system according to a nineteenth embodiment of the present invention.
FIG. 20 is a configuration diagram of a power generation operation management system according to a twentieth embodiment of the present invention.
FIG. 21 is a configuration diagram of a power generation operation management system according to a twenty-first embodiment of the present invention.
FIG. 22 is a configuration diagram of a power generation operation management system according to a twenty-second embodiment of the present invention.
FIG. 23 is a configuration diagram of a power generation operation management system according to a twenty-third embodiment of the present invention.
FIG. 24 is a configuration diagram of a power generation operation management system according to a twenty-fourth embodiment of the present invention.
FIG. 25 is a configuration diagram of a power generation operation management system according to a twenty-fifth embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... General operation management apparatus (operation management center), 2 ... Power generation unit, 3, 6 ... Communication means, 4 ... Power generation plan means, 5 ... Central power supply command station, 7 ... Output command input / time unit command conversion part, 8 ... Database, 49 ... Power plant management device (Power plant monitoring center)

Claims (36)

A general operation management device is provided to monitor the operation of multiple power plant groups consisting of multiple power generation units at one location. The general operation management device receives an output command for all the power generation units in the pipe from the central power supply command station. A power generation operation management system that distributes and commands each power generation unit,
Means for receiving said overall operation management apparatus communication generation capacity than each of the power generation units, and means for receiving an output command of all generating units collectively fraction of tube than the central feed command post, from said power generating capacity of each of the power generation units in the tube Power generation planning means for calculating the total power generation capacity of all the units, calculating a power generation plan for each power generation unit based on a database of power generation units input in advance, and means for issuing an output command based on the power generation plan to each power generation unit A power generation operation management system comprising: The overall operation management apparatus includes a database unit for output power generation unit price of each unit, and a power generation plan unit that calculates a power generation plan for each unit based on the database unit so that the power generation cost is minimized. The power generation operation management system according to claim 1. The overall operation management apparatus has a database means for output-to-heat efficiency of each unit, and has a power generation plan section for calculating a power generation plan for each unit so that the amount of generated heat is minimized based on the database means. The power generation operation management system according to claim 1. The overall operation management device inputs the fuel reserve amount of each unit, the fuel carry-in plan, and the regular inspection plan, compares the reserve amount with the plan value of the database, and responds to the fuel reserve amount for units smaller than the plan value. The power generation operation management system according to claim 1, further comprising a power generation planning unit that calculates an output limit. The overall operation management apparatus has an output-to-output response database unit for each unit, and a power generation plan for a unit with a slow output response and a unit with a fast unit based on the output response of each unit according to a load change prediction based on this database unit The power generation operation management system according to claim 1, further comprising a power generation planning unit that calculates distribution. The general operation management device has a database means for output responsiveness and unit price of power generation, and ranks the unit from the unit with the highest unit price of power generation and the unit with the fast output response, and emergency stop of the power generation unit predicted in advance in the operation of the power system 2. The power generation operation according to claim 1, wherein an emergency output response width (output width and rate of change) due to an accident in a transmission line / substation is calculated, and an output upper limit lower than the maximum output is set for a specific unit. Management system. The overall operation management device inputs an operation continuation possible time of the unit when an abnormality occurs in the unit, obtains a power generation capacity margin from the power supply plan and the total power generation capacity, makes a stop allowance plan for the unit accordingly, 2. The power generation operation management system according to claim 1, further comprising means for contacting the unit. The overall operation management apparatus according to any one of claims 1 to 7, wherein when an abnormality occurs in a unit having a plurality of power generation shafts in the unit, a stop allowance plan is made for each unit shaft and the unit is notified. A power generation operation management system comprising: 8. The overall operation management apparatus according to claim 1, further comprising: a power generation planning unit that sets a power generation plan for each shaft for a unit having a plurality of power generation shafts in the unit. Management system. The general operation management device receives output commands for all power generation units in the jurisdiction from the central power supply command center in the form of a medium to long-term power generation plan, and converts them into real time output request values at the output command input / time unit command conversion unit. The power generation operation management system according to claim 1, further comprising a power generation planning unit that performs the operation. The general operation management device receives an output command for all the power generation units in the jurisdiction from the central power supply command center in the form of a time-series power generation plan for the next day, and an output command input / time unit command conversion unit for a real time output request value The power generation operation management system according to claim 1, further comprising: a power generation planning unit that converts the power generation plan into a power generation plan. The general operation management device receives an output command for all the power generation units in the jurisdiction from the central power supply command center in the form of a time-series power generation request for the day, and an output command input value / time unit command conversion unit in real time. The power generation operation management system according to claim 1, further comprising: a power generation planning unit that converts the power generation plan into a power generation plan. The general operation management device receives an output command for all power generation units in the jurisdiction from the central power supply command center in the form of a time series power generation request for a fixed time unit on the day and an output adjustment value within a limited range in a shorter period of time. The power generation operation management system according to claim 1, further comprising a power generation planning unit that converts an output command input / time unit command conversion unit into an output request value in real time. 14. The general operation management apparatus according to claim 1, wherein the power generation operation management system receives the power generation capacity from each unit in time series and calculates the total power generation capacity. 15. The overall operation management system according to claim 14, wherein the power generation capacity is reported from each unit in time series in units of shafts and the total power generation capacity is calculated. 2. The power generation operation management system according to claim 1, wherein the overall operation management apparatus includes a power generation planning unit that receives a power generation capacity for the next day and time series from each unit and calculates a total power generation capacity. 17. The overall operation management system according to claim 16, wherein the power generation planning unit calculates the total power generation capacity by receiving the power generation capacity of the next day and time series from each unit in units of shafts. 2. The power generation operation management system according to claim 1, wherein the overall operation management apparatus includes a power generation planning unit that receives a weekly and time-series power generation capacity from each unit and calculates a total power generation capacity. 19. The general operation management system according to claim 18, wherein the power generation planning unit receives a weekly / time-series power generation capacity from each unit and calculates a total power generation capacity. 2. The power generation operation management system according to claim 1, wherein the overall operation management apparatus includes a power generation planning unit that receives a monthly and time-series power generation capacity from each unit and calculates a total power generation capacity. 21. The overall operation management system according to claim 20, wherein the power generation planning unit calculates a total power generation capacity by receiving a report on a monthly unit and a time series power generation capacity from each unit in units of axes. 2. The power generation according to claim 1, wherein the overall operation management device includes a unit for generating an output command, and a unit for converting the output command into an axis unit in a unit having a plurality of power generation shafts in the unit. Operation management system. 23. The overall operation management apparatus according to claim 22, wherein the means for issuing an output command includes means for a unit unit or a unit for a unit having a plurality of power generation shafts in the unit. 2. The power generation operation management system according to claim 1, wherein the overall operation management apparatus includes a power generation planning unit that communicates the total power generation capacity of the power plant group in the pipe to the central power supply command center in time series. 2. The power generation operation management system according to claim 1, wherein the overall operation management apparatus includes a power generation planning unit that communicates the total power generation capacity for the next day and time series of the power plant group in the pipe to the central power supply command center. 2. The power generation operation management system according to claim 1, wherein the overall operation management apparatus includes a power generation planning unit that communicates a weekly and time-series total power generation capacity of a group of power plants within a jurisdiction to a central power supply command center. 2. The power generation operation management system according to claim 1, wherein the overall operation management device includes a power generation planning unit that communicates the monthly and time-series total power generation capacity of the power plant group in the pipe to the central power supply command center. The overall operation management device has a database means for increasing the output of each unit with respect to the seawater temperature, and a power generation plan unit for calculating a power generation plan for each unit based on the database means so as to minimize the increase in the total seawater temperature. The power generation operation management system according to claim 1, further comprising: The overall operation management device has a database means for the output of each unit to the seawater temperature rise, and the output value upper limit determined from the seawater temperature rise allowable upper limit of each power generation unit based on the database means is given first priority, The power generation operation management system according to claim 1, further comprising a power generation plan unit that calculates a power generation plan for each unit so that the total seawater temperature rise is minimized based on this. The overall operation management device includes a power generation planning unit for calculating a power generation plan for each unit so that the total exhaust gas emission amount is minimized based on the database unit, including a database unit for output to exhaust gas of each unit. The power generation operation management system according to claim 1, further comprising a power generation planning unit for calculating. The overall operation management apparatus has an output-to-exhaust gas database unit of each unit, and the output value upper limit determined from the upper limit of the exhaust gas discharge amount of each power generation unit based on the database unit is given first priority. 2. The power generation operation management system according to claim 1, further comprising a power generation plan unit that calculates a power generation plan unit for calculating a power generation plan for each unit so as to minimize the total exhaust gas emission amount. 32. The power generation operation management system according to claim 30, wherein the power generation planning unit performs weighted evaluation according to the type of output versus exhaust gas. The overall operation management device evaluates the influence of the exhaust gas on the periphery based on the output of each unit against the exhaust gas and terrain database means and the ambient weather data input from each power generation unit, and determines the maximum allowable output of each unit. The power generation operation management system according to claim 1, further comprising a power generation planning unit that calculates in time series. 34. The power generation operation management system according to claim 3, 4, 29, or 33, wherein the power generation planning unit is provided in a central power supply command station. 34. The power generation operation management system according to claim 4, 29 or 33, wherein the power generation planning unit is provided in a power generation unit. The power generation operation management system according to any one of claims 14 to 21, wherein the power generation capacity of each unit is aggregated by a power plant general device installed for each power plant and transmitted to a power generation planning unit of the general operation management device. Power generation operation management system.

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