JPS61150619A - Power system simulation system - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention relates to a power system simulation method, and in particular to an active power control method of a computer system delivered to a central power dispatch center, etc. that controls the entire power system of a power company (user). This relates to a power system simulation method in which functions are removed from actual equipment (user grid, generator) and simulated verification tests are conducted at the system manufacturer.

[Background technology problem 1 Active power control is one of the important controls in electric power companies, and is a system for supplying stable power to the demand side.
IIIa ability.

In order to conduct a strict verification test of the active power control 1 function, it is necessary to simulate the generator and the power system, which are the targets of the user's electric power, in a state that most closely resembles the actual equipment. It is also necessary to connect this to a computer system in a closed loop to verify the system's operation and finished state.

Conventionally, when verifying active power control mta capability at manufacturers, various power parameters were manually set to simulate the power system (user system, generator).

[Problem in the background art 1] In the conventional method described above, the electric power system does not automatically change in response to the TIIIII Directive, so sufficient verification tests are not conducted, and the system does not include factors that may cause problems after it is delivered to the user. It was.

Furthermore, each user has different power system characteristics, generator capacities, etc., and it has been difficult to easily simulate these. Furthermore, it has been nearly impossible to conduct a verification test of the effective power consumption RAM capacity using actual equipment due to the huge demand for electric power in recent years and also due to the security of the electric power system.

[Purpose of the Invention] The present invention was made to solve the above problems, and its purpose is to provide a power system simulation method that allows manufacturers to accurately verify computer systems in a state that approximates the actual system. It is said that

[Summary of the Invention] The present invention attempts to verify the effective power charge m function in a state that approximates the actual equipment by simulating a power system and a generator.

[Embodiments of the Invention] Examples will be described below with reference to the drawings. FIG. 1 is an embodiment diagram showing the overall configuration of a power system simulation method according to the present invention. In Figure 1, 1 is a power control simulator and a computer system? connected to. The power control simulator section includes a control receiving section 3 and a calculation and output section 4.
and a setting section 5. Furthermore, its main functions are simulating power system characteristics and simulating generators.

On the other hand, the computer system 2 is a general example and consists of equipment 6 installed at the central dispatch center and equipment 7 installed at the power plant. It consists of an arithmetic processing unit, peripheral equipment 8, and information transmission device 9, and further comprises an information transmission device 10 as equipment installed in the power plant.

FIG. 2 is a diagram mainly showing a power control simulator. That is, the computer system 2 is provided with the electric power system simulator section 11 of the own gravity company, and furthermore, the electric power system simulator section 11 of the own gravity company has interconnection lines with other electric power companies that are accommodating power. A tidal flow section 12 is provided.

Reference numeral 13 denotes a generator simulator, which responds to the raising and lowering control commands from the computer system 2, and the rate of change can be arbitrarily set according to the generator concerned by the user. , the initial value and rating of the generator output can also be set arbitrarily. In this case, the number of generators is not particularly limited. 14 is a system load, which is the total system load of the corresponding user. Note that noise elements are also included in order to approximate the actual system.

15 is a system characteristic, which is a system characteristic constant of the corresponding user. Here, a frequency ΔF corresponding to the difference ΔP between power demand and supply is created. Reference numeral 16 is a reference frequency, which is a frequency setting unit that becomes a base in active power control. 17
is an interconnection line schedule, which is a schedule setting part for interconnection line power flow.

Next, in the interconnection line power flow unit 12 with other power companies, interconnection line power flow values are created based on the frequency ΔF obtained by the own power company. It consists of an integral valve, a proportional valve, and a -order lag element.

The data obtained from each of these parts is transmitted to the computer system Z, and in the computer system, active power control is performed based on these data.

Note that the active power control function has the following three control methods.

■FFC method; Flat Frequency Co
ntrol (frequency-constant control method) ■TLB method; Tie Line Bias Con
trol (frequency power flow control method) ■FTL method; Flat Tie Line Con
trol (constant power flow control method) Among the above control methods, the FFC method is used as an example to explain the operation of power system simulation.

Assume that the power system is now maintaining a stable state at a frequency χ. First, the frequency is set to χ using the reference frequency 16.
When set to +α, for the computer system 2, the reference frequency is increased by +α compared to the current frequency.
This will require an increase in power. Therefore, the computer system 2 requests the generator simulator 13 to increase the power until the target frequency χ+α is reached.

Here, assuming that there are no changes in the grid load 14 and the interconnection line schedule 17, the power difference ΔP between demand and supply increases. As ΔP increases, the frequency ΔFffill corresponding to the system characteristic 15 is increased. The above operations are repeated until ΔF reaches 1 shift corresponding to +α.

Since the frequency becomes χ+ΔF, the power flow in interconnection lines with other power companies increases toward other power companies.

Here, when the frequency is stable at χ + α, the system load 1
Suppose that 4 increases. As a result, ΔP decreases and ΔF decreases to α. Computer system 2 according to paper of ΔF
is the generator simulator 13 until the frequency reaches χ+α.
increase the power of

When the frequency is set to χ-α, the content up to now appears as a reverse effect.

As described above, by performing the 10 operations, it is possible to understand what kind of action the computer system must have on the power system.

In short, the interconnection between the electric power system simulator department of the own power company and other power companies! Through simulation with the power flow section, the effective power III Ill m function of the computer system is
Moreover, sufficient verification tests can be conducted repeatedly in a state that approximates the actual system.

[Effects of the Invention] As explained above, according to the present invention, the system functions can be verified with high accuracy before the computer system is delivered to the user, and it can be said to be a very effective invention.

[Brief explanation of drawings]

FIG. 1 is a diagram of an embodiment showing the overall configuration of a power system simulation method according to the present invention, and FIG. 2 is a diagram of an embodiment mainly showing the power system simulator section. 1...Power control simulator? ...Computer system 3...Control receiving section 4
...Calculation and output section 5...Setting section 6...
Equipment 7 installed in the central power dispatch center...Equipment 8 installed in the power plant...Central processing unit and peripheral equipment 9.10...Information transmission device 11...Power system simulator unit 12 ... Interconnection line power flow part 13 ... Generator simulator 14 ... System load 15 ... System characteristics 16 ... Reference frequency 17 ... Interconnection line schedule (T31γ) Agent Patent attorney Norichika Kensuke (1 other person)

Claims (1)

[Claims] In a power system simulation method for verifying and testing active power control functions using a computer system, a power control simulator is a power system simulation method characterized by having a function of simulating power system characteristics and a generator.