CN114243805A

CN114243805A - Synchronous machine system frequency response analysis calculation method considering speed regulator amplitude limiting

Info

Publication number: CN114243805A
Application number: CN202111593772.7A
Authority: CN
Inventors: 王程; 杨牧青; 毕天姝; 胥国毅
Original assignee: North China Electric Power University
Current assignee: North China Electric Power University
Priority date: 2021-12-20
Filing date: 2021-12-20
Publication date: 2022-03-25
Anticipated expiration: 2041-12-20
Also published as: CN114243805B

Abstract

The invention discloses a synchronous machine system frequency response analysis calculation method considering speed regulator amplitude limiting, which comprises the following steps: acquiring all frequency modulation parameters of the whole network synchronous machine, including spare capacity, inertia, difference adjustment coefficients, reheating time constants and the like; the amplitude limiting time of full generation of mechanical power is calculated through speed regulator parameters of a synchronous machine, the frequency response process of a system is segmented according to the amplitude limiting time, the synchronous machines participating in frequency response of all the segments are aggregated into a single-machine equivalent model according to capacity, the non-zero initial state of the frequency response process of all the segments is calculated, and the transfer function of the inertial center frequency is subjected to inverse Laplace transform through a non-zero initial state analysis method to obtain a frequency response segmented time domain analysis model of the whole network inertial center. The invention can more accurately analyze and calculate the frequency response of the inertia center of the whole network under the premise of considering the amplitude limit of the speed regulator, and simultaneously, the calculation effect of the invention is further close to the real power grid, thereby better making day-ahead scheduling plan service for the power grid.

Description

Synchronous machine system frequency response analysis calculation method considering speed regulator amplitude limiting

Technical Field

The invention belongs to the field of frequency modulation of power systems, and particularly relates to a frequency response analysis calculation method of a synchronous machine system considering amplitude limiting of a speed regulator.

Background

With the gradual exploitation of fossil energy and the gradual increase of the demand for energy, the relationship between human beings and the nature is increasingly tense. Under the background, constructing a novel power system mainly based on new energy, and considering new energy grid connection and related technologies thereof has become an important direction for future power technology development.

The new energy occupation ratio of China increases year by year, but due to the characteristics of the fluctuation and weak inertia of the new energy, the new energy has poor supporting effect on the system frequency after the regional power grid generates load disturbance, and therefore the synchronous machine still plays a main role in frequency modulation.

Although the frequency response of the synchronous machine system is studied more deeply at present, the influence of reserve capacity cannot be considered by the mainstream frequency response calculation method at present, the modeling of a nonlinear amplitude limiting link of a speed regulator is still to be perfected, and how to better establish day-ahead scheduling plan service with strong disturbance rejection capability for a power grid is still to be studied.

Object of the Invention

The invention aims to solve the problems and provides a synchronous machine system frequency response analysis and calculation method considering the amplitude limit of a speed regulator, which can accurately analyze and calculate the frequency response of the inertia center of the whole network on the premise of considering the amplitude limit of the speed regulator and simultaneously ensure that the calculation effect of the frequency response is further close to the real power grid, thereby better establishing day-ahead scheduling plan service for the power grid.

Disclosure of Invention

The invention provides a synchronous machine system frequency response analysis and calculation method considering speed regulator amplitude limiting, which comprises the following steps:

step 1, acquiring key frequency modulation parameters of a whole network synchronous machine, including spare capacity P_mgInertia piece, difference adjustment coefficient R and reheating time constant T_RHigh pressure turbine power fraction F_HDamping coefficient xi and mechanical gain coefficient K_mDisturbance power P_Step；

Step 2, calculating a transfer function of the output mechanical power of each synchronizer according to the key frequency modulation parameters of each synchronizer in the whole-network synchronizer obtained in the step 1, and judging the amplitude limiting time of each synchronizer;

and step 3: according to the amplitude limiting time of each synchronous machine, the frequency response process of the system is segmented, and the mechanical gain coefficient K of each segment of synchronous machine participating in the frequency response is set according to the installed capacity and the total system capacity of the synchronous machine_mUsing the adjusted mechanical gain coefficient K of the synchronous machine_mgSetting the reserve capacity P_mgInertia piece, difference adjustment coefficient R and reheating time constant T_RHigh pressure turbine power fraction F_HFinally, aggregating the frequency modulation parameters to obtain a single-machine equivalent model of each period of time;

and 4, step 4: and calculating the non-zero initial state of the transfer function of each time frequency response segment, and performing inverse Laplace transform on the transfer function of the inertia center frequency by using a non-zero initial state analysis method to obtain a frequency response segmented time domain analysis model of the whole network inertia center.

Preferably, in step 1, the key frequency modulation parameters are acquired by a human-computer interface according to specific operation requirements of the whole network synchronous machine.

Preferably, the governor output mechanical power transfer function of each synchronous machine in step 2 is calculated by equation (1):

wherein L is_i、R、F_H、T_R、H、K_m、P_StepThe power division coefficient, the difference adjustment coefficient, the power fraction of the high-pressure turbine, the reheating time constant, the inertia, the mechanical gain coefficient and the unbalanced power of the single-machine equivalent model are respectively, xi is a damping ratio, omega is_nIs the natural frequency of the second order model;

calculating the time for the mechanical power to reach the amplitude limit value; calculating the fractional power coefficient according to the speed regulator parameters of each synchronous machine, wherein the calculation formula is shown as formulas (2) to (4):

preferably, the mechanical gain coefficient K of each synchronous machine after being set in the step 3_mgCalculated from equation (5):

wherein S is_gThe installed capacity of each synchronous machine;

the equivalent frequency modulation parameters of the single-machine equivalent model are calculated by the following formulas (6) to (10):

wherein R is_g、F_Hg、T_Rg、H_gRespectively is the difference adjustment coefficient, the high-pressure turbine power fraction, the reheating time constant, the inertia and lambda of the set synchronous machine_gAre intermediate variables that assist in the computation.

Preferably, the frequency response segmented time domain analytical model of the inertia center of the whole network obtained in the step 4 is expressed as shown in equations (11) to (15):

wherein, ω is₁、ω₂、A₁、A₂、A₇、A₈、K₁、K₅The intermediate variables of the formula are conveniently written in columns, and no specific physical significance is realized.

Drawings

Fig. 1 is a topology diagram of a 3-machine 9-node synchronous machine system according to an embodiment of the present invention.

Fig. 2 is a simulation experiment diagram of the synchronous machine G1 for verifying the correctness of the mechanical power calculated by the algorithm.

Fig. 3 is a simulation experiment diagram of a synchronous machine G2 for verifying the correctness of the mechanical power calculated by the algorithm.

Fig. 4 is a simulation experiment diagram of the synchronous machine G3 for verifying the correctness of the mechanical power calculated by the algorithm.

Fig. 5 is a comparison graph of the effectiveness of the verification algorithm.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

The invention provides a synchronous machine system frequency response analysis and calculation method considering speed regulator amplitude limiting, which comprises the following specific steps:

step 1: and acquiring key frequency modulation parameters.

According to specific operation requirements, key frequency modulation parameters are obtained through a human-computer interface, such as: spare capacity P_mgInertia H, difference adjustment coefficient R and reheating time constant T_RHigh pressure turbine power fraction F_HDamping coefficient xi and mechanical gain coefficient K_mDisturbance power P_StepAnd entering the step 2 after the completion.

Step 2: clipping time calculation

Calculating the transfer function of the output mechanical power of each synchronous machine according to the frequency modulation parameters of the speed regulators of each synchronous machine, and judging the amplitude limiting time of the speed regulators of each synchronous machine, wherein the transfer function of the output mechanical power of the speed regulators of each synchronous machine is calculated by the formula (1):

and (4) entering the step 3 after the completion.

And step 3: multi-machine polymerization;

mechanical gain coefficient K of each set synchronous machine_mgCalculated from equation (5):

wherein S is_gThe installed capacity of each synchronous machine;

according to the set mechanical gain coefficient of the synchronous machine, setting inertia H, difference adjustment coefficient R and reheating time constant T_RHigh pressure turbine power fraction F_HAnd finally, aggregating the key frequency modulation parameters to obtain a single-machine equivalent model, wherein the equivalent frequency modulation parameters of the single-machine equivalent model are calculated by the following formulas (6) to (10):

And 4, step 4: non-zero initial state analysis.

Performing inverse Laplace transform on the transfer function of each frequency response segment by using a non-zero initial state analysis method to obtain a frequency response segmented time domain analysis model of the whole network inertia center, which is expressed as formulas (11) to (15):

Examples

The process of the invention is illustrated below by means of a specific example. Fig. 1 is a topological diagram of a 3-machine 9-node synchronous machine system, which includes three synchronous machines G1, G2 and G3 and 9 nodes. The system voltage class in the region is 220kV, the total capacity of the synchronous machine is 402MW, the total load is 350MW, and the key frequency modulation parameters of the system are as follows:

the key frequency modulation parameters are brought into the mechanical power output power as shown in figures 2-4, the frequency response of the system after disturbance obtained by the existing method and the method provided by the invention is shown in figure 5, and the comparison shows that the frequency response of the system after disturbance can be calculated by the model of the invention on the basis of considering the amplitude limit of the speed regulator.

The invention has the following beneficial effects:

the method can carry out multi-machine aggregation according to the installed capacity of the synchronous machine and the total system capacity on the basis of the known key frequency modulation parameters of the power grid, consider the influence of the spare capacity in a single-machine equivalent model, and calculate and obtain a frequency response time domain analysis model of the whole-network inertia center by using a non-zero initial state analysis method, wherein the model can calculate and consider the power grid frequency response after the amplitude limiting disturbance of the speed regulator.

Claims

1. A synchronous machine system frequency response analysis calculation method considering speed regulator amplitude limiting is characterized by comprising the following steps:

step 1, acquiring key frequency modulation parameters of a whole network synchronous machine, including spare capacity P_mgInertia H,Difference adjustment coefficient R and reheating time constant T_RHigh pressure turbine power fraction F_HDamping coefficient xi and mechanical gain coefficient K_mDisturbance power P_Step；

Step 2, calculating a transfer function of the output mechanical power of each synchronizer according to the key frequency modulation parameters of each synchronizer in the whole-network synchronizers obtained in the step 1, and judging the amplitude limiting time of each synchronizer:

and step 3: according to the amplitude limiting time of each synchronous machine, the frequency response process of the system is segmented, and the mechanical gain coefficient K of each segment of synchronous machine participating in the frequency response is set according to the installed capacity and the total system capacity of the synchronous machine_mUsing the adjusted mechanical gain coefficient K of the synchronous machine_mgSetting the reserve capacity P_mgInertia H, difference adjustment coefficient R and reheating time constant T_RHigh pressure turbine power fraction F_HFinally, aggregating the frequency modulation parameters to obtain a single-machine equivalent model of each period of time;

2. The method for analyzing and calculating the frequency response of the synchronous machine system considering the amplitude limit of the speed regulator according to claim 1, wherein in the step 1, the key frequency modulation parameters are acquired by a human-computer interface according to specific operation requirements of the whole-network synchronous machine.

3. The method for analyzing and calculating the frequency response of the synchronous machine system considering the amplitude limit of the speed regulator according to claim 1, wherein the speed regulator output mechanical power transfer function of each synchronous machine in the step 2 is calculated by the formula (1):

4. the method for analyzing and calculating the frequency response of the synchronous machine system considering the amplitude limit of the speed regulator according to claim 1, wherein the mechanical gain coefficient K of each synchronous machine after the setting in the step 3_mgCalculated from equation (5):

wherein S is_gThe installed capacity of each synchronous machine;

5. The method for analyzing and calculating the frequency response of the synchronous machine system considering the amplitude limit of the speed regulator according to claim 1, wherein the frequency response segmented time domain analysis model of the inertia center of the whole network obtained in the step 4 is expressed as shown in the formulas (11) to (15):