JP2002233058A - Generator operation control method and system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To contrive economic optimization when a generator is operated and controlled in an electric power system having a continuous water system and a heating power system. SOLUTION: In the electric power system having the continuous water system and the heating power system, real time information is taken in from the continuous water system and the heating power system on-line, in the case that a power generation instruction value (heating power and pumping generation instruction value 31 and continuous water system power generation instruction value 32) due to integral calculation from a water and heating integral power generation instruction value calculation part 12 is requested, these power generation instruction values 31, 32 are employed, and in the case that it is not requested, a heating power and pumping power generation instruction value 33 found by a heating power and pumping power generation instruction value calculation part 13 and a continuous water system power generation instruction value calculation result 34 found by a continuous water system power generation instruction value calculation part 14 are employed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a generator operation control method for controlling on-line operation of a generator installed in a connected water system and a thermal power system when the power system has a connected water system and a thermal power system, and a generator. It relates to an operation control system.

[0002]

2. Description of the Related Art The optimal operation plan of a hydro / thermal power system including a connected water system is described in IEEJ, Vol. 119, No. 1, 1999.
"The weekly power generation planning method for water and thermal power systems including pumped storage power plants" discussed in IEEJ, pp. 109-116, and IEEJ B, 119 (10), 1999
"The weekly optimal operation plan of the power system in the connected water district" discussed in IEEJ, pages 1049 to 1055.
In these papers, there is proposed a method of minimizing power generation costs by finding a thermal power, pumping, and hydro power generation plan in order.

[0003]

However, in the above-mentioned prior art, the economic efficiency is optimized while satisfying the operation constraints of the generator and the dam for the purpose of applying to the weekly plan or the next day plan. However, it was not assumed that the integrated water system and the thermal power system would be integrated to control the operation of the generator.

[0004] Further, in the systems which have been put into practical use so far, the articulated water system and the thermal power system are separately and independently controlled online, and there is no system which integrates the articulated water system and the thermal power system to perform online control. .

[0005] The stream flow of a river changes in real time due to the rainfall upstream of the dam and the like. In an electric power system having a connecting water system and a thermal power system, it is necessary to cope with a change in the power demand situation and a real-time change in the river stream flow. Although it is essential, none of the prior arts takes into account this point.

An object of the present invention is to provide a generator operation control method and a generator operation control system capable of optimizing economy in a power system having a connecting water system and a thermal power system.

[0007]

In order to achieve the above-mentioned object, according to the generator operation control method of the present invention, when controlling the operation of a generator installed in a connecting water system and a thermal power system, the connecting water system and the generator are controlled. In addition to taking real-time information online from the thermal power system and evaluating the system reliability of the power system including the connecting water system and the thermal power system, calculating the most economical generator output command value when integrating hydropower and thermal power The operation of the generator is controlled based on the generator output command value.

[0008] According to the above configuration, the optimum generator output command value integrating hydro and thermal power in consideration of the evaluation of the system reliability of the power system is used in accordance with the generator command cycle using online real-time information. It is possible to optimize economy.

Further, in the present invention, in order to calculate the generator output command value, a process of calculating an optimum generator output command value by integrating hydraulic power and thermal power, and an optimum generator output command value in the thermal power / pumping generator group are performed. It is characterized in that the calculation processing of the value and the calculation processing of the optimum generator output command value in the connected hydroelectric generator group are performed in parallel, and the execution results are comprehensively determined.

Further, the generator operation control system of the present invention is provided in an electric power system having a connecting water system and a thermal power system, and real-time information is taken online from the connecting water system and the thermal power system. Calculating means for evaluating the system reliability of the power system including, and calculating the most economical generator output command value when integrating hydropower and thermal power, based on the generator output command value calculated by the calculation means And control means for controlling the operation of the generators of the connection water system and the thermal power system.

[0011] In the present invention, the calculating means may calculate an optimal generator output command value by integrating hydraulic power and thermal power.
The calculation processing of the optimum generator output command value in the thermal power / pumping generator group and the calculation processing of the optimum generator output command value in the connected hydropower generator group are performed in parallel, and the execution results are comprehensively determined. It is characterized in that the generator output command value is calculated.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows the overall configuration of a generator operation control system according to the present invention. The power system equipment 1 and the dam water system equipment 2 are connected to the online input processing unit 11, and the online information (system monitoring information, generator operation information, supply and demand information, etc.) 3 from the power system equipment 1 and the dam water system equipment 2 Online information (mountain discharge to dam, dam water level, amount of water used by generator, etc.) 4 is always inputted.
Then, the online input processing unit 11 outputs the latest online information 21 of the target plant. Further, a condition setting input unit 16 is provided, and when information that cannot be collected online is set and input by the human system to the condition setting input unit 16, the condition setting input unit 16 outputs the setting information 22. The information set and input to the condition setting input unit 16 includes prediction information such as power demand and mountain stream in several hours ahead.

The integrated water / fire power generation command value calculation unit 12, thermal power /
A pumped water power generation command value calculation unit 13 and a concatenated water system power generation command value calculation unit 14 are provided, and the latest online information 21 from the online input processing unit 11 and the setting information 22 from the condition setting input unit 16 are used for integrated water and fire power generation. The command value calculation unit 12, the thermal power / pumping power generation command value calculation unit 13, and the connected water system power generation command value calculation unit 14 are respectively input. The condition setting input unit 16 is also capable of setting conditions for calculation by the water / fire integrated power generation command value calculation unit 12, the thermal power / pumping power generation command value calculation unit 13, and the connected water system power generation command value calculation unit 14. Has become.

A calculation result storage section 18 is provided, and the calculation result storage section 18 stores the results obtained by the calculation in the past. The results 23 obtained in the past from the calculation result storage unit 18 are combined with the water / fire integrated power generation command value calculation unit 12, the thermal power / pumping power generation command value calculation unit 13, and the connected water system power generation command value calculation unit 14 Respectively. Also,
Result 2 obtained in the past from calculation result storage unit 18
3 is also input to the condition setting input unit 16 and the result display output unit 17.

The water / fire integrated power generation command value calculation unit 12, thermal power /
In the pumped water power generation command value calculation unit 13 and the connected water system power generation command value calculation unit 14, based on the latest online information 21, the setting information 22, and the result 23 obtained by the past calculation, usually, every several minutes. The power generation command values are calculated in parallel in response to the cycle start requests of the timers T1, T2, T3, respectively, and the thermal power / pumping power generation command value 31 by the integrated calculation, the connected water system power generation command value 32 by the integrated calculation, and the thermal power / pumping power generation command value 33 , And outputs the result as the calculation result 34 of the connected water system power generation command value. These obtained results are stored in the calculation result storage unit 18 and are used as initial values in the convergence calculation at the next calculation.

The water / fire integrated power generation command value calculation unit 12,
Regarding the content of each processing of the thermal power / pumped power generation command value calculation unit 13 and the connected water system power generation command value calculation unit 14,
It will be described later.

Thermal power / pumped power generation command value 3 by integrated calculation
1. Each command value of the combined water system power generation command value 32, thermal power / pumping power generation command value 33, and connected water system power generation command value calculation result 34 by integrated calculation is normally a power generation command value determination process periodically started by a timer T4 at intervals of several minutes. In the section 15, the overall judgment is made as the online power generation command value. The result is stored in the calculation result storage unit 18.

Next, the determination method will be described with reference to FIG. First, in step 51, whether the thermal power / pumping power generation command value by the integrated calculation has been obtained, that is, from the water / fire integrated power generation command value calculating unit 12, the thermal power / pumping power generation command value 31 by the integrated calculation and the connection by the integrated calculation It is determined whether or not the water-based power generation command value 32 has been output. If the output is "yes", the process proceeds to step 52, and the thermal power / pumping power generation command value 31 based on the integrated calculation and the connected water system power generation command value 32 based on the integrated calculation are adopted as the optimum command values.

However, since the integrated calculation has many constraints and is repeatedly performed, depending on the system operation situation,
Since the convergence calculation may take several minutes or more in the case of no convergence or a convergence calculation, a solution may not be obtained by the next power generation limit output. In this case, the output is “none”, but the command value must be calculated in the online control. Therefore, in step 53, the thermal power / pumping power generation command value obtained by the thermal power / pumping power generation command value calculation unit 13 is calculated. 33 as a sub-optimal command value, and
In 4, the connected water system power generation command value calculation result 34 obtained by the connected water system power generation command value calculation unit 14 is adopted as a sub-optimal command value.

Thermal power / pumped water power generation command value 3 by integrated calculation
1. As shown in FIG. 1, the combined water system power generation command value 32, the thermal power / pumping power generation command value 33, and the connected water system power generation command value calculation result 34 obtained by the integrated calculation are output to the power generation command value determination processing unit 15 as shown in FIG.
Is input to Then, the power generation command value determination processing unit 15
The operation of the generator is controlled by sending the thermal power / pumping power generation output command value 43 to the thermal power / pumping power generation output command device 41 and the connecting water system power generation output command value 44 to the connecting water system power generation output command device 42, respectively. The power generation command value determination processing unit 15
Are output to the result display output section 17 and displayed on the result display output section 17.
Then, the operator can monitor the operation state of the generator by looking at the display result.

Next, the processing of the water / fire integrated power generation command value calculation unit 12 will be described with reference to FIG. First, in step 61, a water system plan calculation is performed to create a total power generation curve of the water system. Here, in the water system planning calculation, it is most economical as a whole to decide to reduce the thermal fuel cost while satisfying the amount of water used at each connected dam, the restriction on the discharge rate of the gate, the flow delay time, etc. Generator operation. This can be determined using an optimization technique.

Next, in step 62, a demand / supply balance calculation is performed to obtain a total power generation curve of thermal power / pumping. Then, in step 63, the thermal power / pumping start / stop plan 6
3. Make the most economical thermal and pumped generator operation plan. This also needs to satisfy the generator operation constraint, but it is possible to find this using an optimization method.

The results obtained so far are the most economical for the water system and the thermal power, respectively. However, since only the generator operation restriction is considered, even if the total power generation and the total demand are the same, If there is an imbalance in the power system, such as uneven power generation, the power system will not be able to operate normally due to power flow and voltage violations. Therefore, in order to apply the present invention to online real-time control, it is necessary to calculate the system reliability in step 65 and verify whether there is any problem in the power system.

Next, using the generator output obtained in step 65 as an initial value, steps 71, 72, 73, and 75 are again performed.
The optimization of thermal and water systems is repeated until the total power generation cost is no longer improved. Here, step 71
The re-water supply plan calculation in step 61 is the water-system plan calculation in step 61, the re-supply / supply balance calculation in step 72 is the supply-demand balance calculation in step 62, and the reheat / pump start / stop plan in step 73 is the heat / pump start / stop plan in step 63. And the re-system reliability calculation at step 75 is the same as the system reliability calculation at step 65, respectively.

When the total power generation cost is no longer improved in step 76, the output of all generators integrating the water system and the thermal power becomes the most economical command value.

The processing of the thermal power / pumping power generation command value calculation section 13 corresponds to 64 (or 74) of the above processing, which is a combination of step 62 and step 63. The equal λ method or the like is usually used in actual real-time control.

Further, the processing of the connected water system power generation command value calculation unit 14 is the same as that of step 61 (or step 7) of the above processing.
The processing of 1) corresponds to this. Actual real-time control is realized by integrated control of dams by water system simulation.

The water / fire integrated power generation command value calculation unit 12,
The respective processes of the thermal power / pumped power generation command value calculation unit 13 and the connected water system power generation command value calculation unit 14 may be performed simultaneously and in parallel by the same computer, or a part or all of the processing may be performed by one or more other computers. It is also possible to disperse and implement.

Normally, the control of the thermal power / pumping power generation output command device and the articulated water system power generation output command device are conventionally performed separately, and a method of realizing these systems in cooperation with each other may be considered. FIG. 4 shows an example.

When applied to an actual system, reference numeral 81 corresponds to a part of the function of the middle pay system. Reference numeral 82 corresponds to a part of the function of the water system monitoring and control system. The two systems are connected by a communication network (network) 83. In this example, FIG.
According to the processing flow shown in FIG.
1 and a partial function 82 of the water system monitoring and control system, and finally, a total cost evaluation is performed in the partial function 81 of the middle supply system to determine a power generation output command value.

According to the present embodiment, calculation corresponding to real-time changes in optimal calculation convergence / demand status and demand and river valley flow, which are indispensable for application as an online generator output command value, and processing For the reliability evaluation of the entire power system, the most economical online generator output command value can be calculated by considering both at the same time.

[0032]

As described above, according to the present invention,
In an electric power system having a connecting water system and a thermal power system, it is possible to optimize economy.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of a generator operation control system according to the present invention.

FIG. 2 is a diagram showing a flow of a power generation command value determination process.

FIG. 3 is a diagram showing a processing flow in a water / fire integrated power generation command value calculation unit.

FIG. 4 is a diagram showing an example in the case of being configured with a distributed system.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Power system equipment 2 Dam water system equipment 3 and 4 Online information 11 Online input processing unit 12 Integrated water / fire power generation command value calculation unit 13 Thermal power / pumping power generation command value calculation unit 14 Connected water system power generation command value calculation unit 15 Power generation command value judgment Processing unit 16 Condition setting input unit 17 Result display output unit 18 Calculation result storage unit 21 Online latest information 22 Setting information 23 Result obtained by past calculation 31 Thermal power / pumping power generation command value by integrated calculation 32 Connected water system power generation by integrated calculation Command value 33 Thermal power / pumped power generation command value 34 Result of calculation of connected water system power generation command value 41 Thermal power / pumped power generation output command device 42 Connected water system power generation output command device 43 Thermal power / pumped power generation output command value 44 Connected water power generation output command value 81 Partial function of system 82 Partial function of water monitoring and control system 83 Communication network

Claims (4)

[Claims] 1. An electric power system including the connected water system and the thermal power system while real-time information is taken online from the connected water system and the thermal power system when the operation of the generators installed in the connected water system and the thermal power system is controlled. The system reliability is evaluated, the most economical generator output command value when hydropower and thermal power are integrated is calculated, and the operation control of the generator is performed based on the generator output command value. Generator operation control method. 2. The generator operation control method according to claim 1, further comprising the steps of: calculating an optimal generator output command value obtained by integrating hydraulic power and thermal power; and calculating the optimum generator output command value in the thermal power / pumping generator group. The calculation processing and the calculation processing of the optimum generator output command value in the connected hydroelectric generator group are performed in parallel, the execution result is comprehensively determined, and the generator output command value is calculated. Generator operation control method. 3. A system provided in a power system having a connecting water system and a thermal power system, real-time information is taken online from the connecting water system and the thermal power system, and system reliability of the power system including the connecting water system and the thermal power system is evaluated. Calculating means for calculating the most economical generator output command value when the hydropower and the thermal power are integrated; and the generator for the connecting water system and the thermal power system based on the generator output command value calculated by the calculating means. Control means for controlling the operation of the generator, and a generator operation control system comprising: 4. The generator operation control system according to claim 3, wherein said calculating means calculates an optimal generator output command value by integrating hydraulic power and thermal power, and performs optimal power generation in the thermal / pumping generator group. The calculation process of the generator output command value and the calculation process of the optimum generator output command value in the connected hydroelectric generator group are performed in parallel, the execution result is comprehensively determined, and the generator output command value is calculated. A generator operation control system, characterized in that: