CN110350587A - Double-fed blower sub-synchronous oscillation suppression method and its system based on converter Control - Google Patents

Abstract

The present invention relates to a kind of double-fed fan motor sub-synchronous oscillation suppression method based on converter Control, belongs to double-fed blower technical field, solves the problems, such as that the prior art can not effectively inhibit sub-synchronous oscillation.This method comprises the following steps: when sub-synchronous oscillation occurs for double-fed blower grid-connected system, acquiring the operation data of double-fed blower grid-connected system；Mechanism is dissipated according to the response process of double-fed blower grid-connected system under grid disturbance and double-fed blower sub-synchronous oscillation, the mapping relations between blower dynamic power variable quantity and pusher side converter Control parameter are obtained, and then obtain the aperiodic change rate of blower dynamic power；It is up to target with above-mentioned aperiodic change rate, establishes optimization model, collaboration optimization is carried out to the pusher side inverter inner loop control parameter of each blower in double-fed blower grid-connected system, to inhibit to the sub-synchronous oscillation.The present invention optimizes adjustment to double-fed fan parameter under multi-constraint condition, can effectively active control sub-synchronous oscillation generate.

Description

Double-fed blower sub-synchronous oscillation suppression method and its system based on converter Control

Technical field

The present invention relates to double-fed blower technical field more particularly to a kind of double-fed blower based on converter Control are subsynchronous Oscillation suppression method and its system.

Background technique

When sub-synchronous oscillation phenomenon occurs in traditional double-fed blower grid-connected system, passive measures such as " cutting machine " is used mostly.With The progress of technology, Guyuan wind field be directed to sub-synchronous oscillation, using exit in due course string mend measure destroy oscillation circuit.But it is this Method, which needs frequently to throw, moves back string benefit, greatly reduces the service life of equipment.

Double-fed blower oscillating characteristic is influenced by many factors such as wind speed, blower position, converter Control parameters, due to wind Speed is generally viewed as uncontrollable amount with blower position, proves through researcher's a large number of experiments, converter Control is in sub-synchronous oscillation master Dynamic control process plays decisive role.

But according to existing research achievement, domestic and international expert inhibits the research of strategy to be concentrated mainly on benefit for sub-synchronous oscillation Inhibit sub-synchronous oscillation with power electronic equipment, or inhibits secondary by redesigning or improving itself inverter of double-fed blower Synchronized oscillation, the latter need not add other equipment, be a kind of very economical method, but effect is not satisfactory.

Summary of the invention

In view of above-mentioned analysis, it is subsynchronous that the embodiment of the present invention is intended to provide a kind of double-fed blower based on converter Control Oscillation suppression method and its system, to solve the problems, such as that the prior art can not effectively inhibit sub-synchronous oscillation.

On the one hand, the embodiment of the invention provides a kind of double-fed fan motor sub-synchronous oscillation inhibition side based on converter Control Method includes the following steps:

When sub-synchronous oscillation occurs for double-fed blower grid-connected system, the operation data of double-fed blower grid-connected system is acquired；

According to the response process of double-fed blower grid-connected system under grid disturbance and double-fed blower sub-synchronous oscillation transmitter Reason obtains the mapping relations between blower dynamic power variable quantity and pusher side converter Control parameter, and then obtains blower dynamic The aperiodic change rate of energy and the relationship of the operation data；

It is up to target with the aperiodic change rate of blower dynamic power, establishes optimization model, simultaneously to double-fed blower The pusher side inverter inner loop control parameter of each blower carries out collaboration optimization in net system, to press down to the sub-synchronous oscillation System.

Above-mentioned technical proposal has the beneficial effect that: for by key parameter (pusher side converter Control parameter) and it is random because Plain (operation data of double-fed blower grid-connected system) is introduced into blower dynamic power, and the double-fed blower constructed under multi-constraint condition changes Flow device parameter optimization strategy, the final active control for realizing sub-synchronous oscillation.It is proved through a large number of experiments, above-mentioned technical proposal can Collaboration optimization properly and efficiently is carried out to all blower inverter parameters in wind power plant inside, effectively inhibits the grid-connected system of double-fed blower There is sub-synchronous oscillation in system.

Further improvement based on the above method, the operation data of the double-fed blower grid-connected system include: stator side sense Answer the virtual value I of electric current₀, stator side induced voltage virtual value U₀, stator self inductance L_s, rotor self-induction L_r, rotor mutual inductance L_m, wind Machine rotor rotational speed omega_r, blower grid entry point voltage phasor U, blower grid entry point electric current phasor I, blower grid entry point useful work P, blower Grid entry point idle work Q, blower generator rotor angle δ, blower grid entry point fundamental frequency f；

The pusher side inverter inner loop control parameter includes: pusher side Inverter circuit inner ring integral coefficient K_I2And proportionality coefficient K_P2。

The beneficial effect of above-mentioned further improvement scheme is: abundant to examine in the case where sub-synchronous oscillation signal disturbance Consider the influence of converter Control link, emphasis carries out collaboration optimization to each blower pusher side inverter inner loop control parameter.

Further, the mapping relations between the blower dynamic power variable quantity and pusher side converter Control parameter

Wherein

ω₂=ω₁+ω_r-ω_s, ω₃=ω_s-ω_r, ω_s=2 π f

In formula, U_s、Respectively to blower grid entry point voltage phasor U carry out Harmonic Decomposition acquisition fundamental frequency voltages amplitude, Initial phase,For the Fundamental-frequency Current initial phase for carrying out Harmonic Decomposition acquisition to blower grid entry point current vector I, K_I1、K_P1Respectively Pusher side converter power outer ring integral coefficient and proportionality coefficient, K_I2、K_P2Respectively pusher side Inverter circuit inner ring integral coefficient and Proportionality coefficient, ω_rFor fan rotor rotation speed, R_rFor fan rotor resistance.

The beneficial effect of above-mentioned further improvement scheme is: above-mentioned blower dynamic power variable quantity and pusher side converter Control Mapping relations between parameter are a set of empirical equations that inventor passes through that a large number of experiments sums up, and the formula is simple and easy, can It is contacted with accurately and effectively setting up blower dynamic power variable quantity with pusher side converter Control parameter.

Further, the aperiodic change rate of the blower dynamic power is

The beneficial effect of above-mentioned further improvement scheme is: the aperiodic change rate of above-mentioned blower dynamic power is inventor The empirical equation summed up by a large number of experiments, control effect is good, can sufficiently meet design requirement.Also, blower dynamic energy The aperiodic change rate of amount can also be further used as whether capableing of the judgment basis of active control sub-synchronous oscillation, i.e., described non- , can be with active control when periodic component change rate is less than 0, it, can not active control when being more than or equal to 0.

Further, the optimization model includes wind power plant parameter optimization objective function and the constraint of wind power plant parameter optimization Condition, wherein

The wind power plant parameter optimization objective function is

The wind power plant parameter optimization constraint condition is

In formula, h is system variable, including blower grid entry point voltage phasor U, blower grid entry point useful work P, blower grid entry point Idle work Q, blower generator rotor angle δ, blower grid entry point fundamental frequency f；h_min、h_maxFor system variable upper and lower limit；K is control to be adjusted Variable processed, including pusher side Inverter circuit inner ring integral coefficient K_I2And Proportional coefficient K_P2；K_min、K_maxIt is upper and lower for control variable Limit, P_iIndicate the useful work of connected i-th branch of blower grid entry point；Q_iIndicate the nothing of connected i-th branch of blower grid entry point Hard.

The beneficial effect of above-mentioned further improvement scheme is: to inhibit sub-synchronous oscillation as target, having fully considered decision The constraint condition that the constraint condition and system operational parameters met needed for variable itself should meet is guaranteeing to adjust control ginseng While number is to inhibit oscillation, blower fundamental frequency characteristic is not deteriorated.

Further, the pusher side inverter inner loop control parameter to each blower in double-fed blower grid-connected system is assisted Further comprise following steps with optimization:

Using control variable to be adjusted as set element, decision set is established；

Decision set initial value is obtained, determines whether to meet wind power plant parameter optimization constraint condition；If conditions are not met, pressing Preset rules in the formula of face change decision set initial value, judge again, and acquisition meets wind power plant parameter optimization constraint condition All decision set numerical value

K_P2-n+1=K_P2-n-ε_P

K_I2-n+1=K_I2-n-ε_I

In formula, K_P2-n+1Indicate K next time_P2, K_P2-nIndicate last K_P2, n expression the number of iterations；ε_PFor K_P2Change Change step-length, ε_IFor K_P2Change step；

According to wind power plant parameter optimization objective function, following broad object function p is established_i

It finds out in all decision set of above-mentioned acquisition, so that broad object function p_iMaximum, and p_iThe decision set of > 0 Numerical value, as pusher side inverter inner loop control parameter to be asked.

The beneficial effect of above-mentioned further improvement scheme is: using iterative algorithm, enables decision variable in decision set not Break towards the maximum direction change of objective function value is made, improves the performance of optimization algorithm, improve user satisfaction.

On the other hand, the embodiment of the invention provides a kind of, and the double-fed blower sub-synchronous oscillation based on converter Control inhibits System, comprising:

Data acquisition module, for when sub-synchronous oscillation occurs for double-fed blower grid-connected system, acquisition double-fed blower to be grid-connected The operation data of system, and transmit it to energy-parameters relationship module and parameter optimization module；

Energy-parameters relationship module, for according to the response process of double-fed blower grid-connected system under grid disturbance and double It presents blower sub-synchronous oscillation and dissipates mechanism, obtain the mapping between blower dynamic power variable quantity and pusher side converter Control parameter Relationship, and then obtain the aperiodic change rate of blower dynamic power and the relationship of the operation data；

Parameter optimization module establishes optimization model, to double-fed for being up to target with above-mentioned aperiodic change rate The pusher side inverter inner loop control parameter of each blower carries out collaboration optimization in blower grid-connected system, to the sub-synchronous oscillation Inhibited.

The beneficial effect of above-mentioned technical proposal is: being used for key parameter (pusher side converter Control parameter) and enchancement factor (operation data of double-fed blower grid-connected system) is introduced into blower dynamic power, constructs the double-fed blower change of current under multi-constraint condition Device parameter optimization strategy, the final active control for realizing sub-synchronous oscillation.It is proved through a large number of experiments, above-mentioned technical proposal can be just Collaboration optimization really and effectively is carried out to all blower inverter parameters in wind power plant inside, effectively inhibits double-fed blower grid-connected system There is sub-synchronous oscillation.

Further improvement based on above system, the energy-parameters relationship module further comprises:

Frequency analysis module is obtained for carrying out Harmonic Decomposition respectively to blower grid entry point voltage phasor U and current vector I Obtain the amplitude U of fundamental frequency voltages_s, initial phaseAnd the initial phase of Fundamental-frequency CurrentThe result of acquisition is transmitted to disturbance point Measure analysis module；

Disturbance component analysis module, for according to stator side induced current virtual value I in double-fed blower grid-connected system₀And sense Answer voltage effective value U₀, in conjunction with the U of above-mentioned acquisition_s、Blower dynamic power variation delta W is obtained by following formula With the mapping relations between pusher side converter Control parameter, the mapping relations are transmitted to sub-synchronous oscillation control module

Wherein

ω₂=ω₁+ω_r-ω_s, ω₃=ω_s-ω_r, ω_s=2 π f, ω₁=2 π f₁

In formula, K_I1、K_P1Respectively pusher side Inverter circuit outer ring integral coefficient and proportionality coefficient, K_I2、K_P2Respectively pusher side Inverter circuit inner ring integral coefficient and proportionality coefficient；ω_rFor fan rotor rotation speed, R_rFor fan rotor resistance；f₁For to blower Grid entry point current vector I carries out the frequency of the sub-synchronous oscillation current disturbing signal of Harmonic Decomposition acquisition；

Sub-synchronous oscillation control module, for obtaining the aperiodic variation of blower dynamic power according to above-mentioned mapping relations Rate, the aperiodic change rate can be characterized by following formula

And then according to formula above judge whether can active control sub-synchronous oscillation sentence when the formulae results are less than 0 Surely can active control sub-synchronous oscillation, be transmitted to parameter optimization module for the formulae results as aperiodic change rate, it is no Then, judgement can not active control, change pusher side inverter inner loop control parameter values, judge again.

Beneficial effect using above-mentioned further improvement scheme is: above-mentioned blower dynamic power variation delta W is changed with pusher side The aperiodic change rate of mapping relations, blower dynamic power between stream device control parameter is that inventor is total by a large number of experiments The empirical equation born, control effect is good, can sufficiently meet design requirement, promotes user satisfaction.Also, blower dynamic energy The aperiodic change rate of amount as whether capableing of the judgment basis (sub-synchronous oscillation stability criterion) of active control sub-synchronous oscillation, Determine very effect it is good, solve the problems, such as in the prior art to can active control sub-synchronous oscillation be not easy to judge.

Further, the parameter optimization module further comprises:

Decision set generation module, for being set with control variable to be adjusted in pusher side inverter inner loop control parameter Element establishes decision set, generates decision set initial value and is transmitted to preliminary screening module；

Preliminary screening module, for according to the decision set initial value of acquisition and the operation number of double-fed blower grid-connected system According to determining whether following wind power plant parameter optimization constraint condition is true

In formula, h is system variable, including blower grid entry point voltage phasor U, blower grid entry point useful work P, blower grid entry point Idle work Q, blower generator rotor angle δ, blower grid entry point fundamental frequency f；h_min、h_maxFor system variable upper and lower limit；K is control to be adjusted Variable processed, including pusher side Inverter circuit inner ring integral coefficient K_I2And Proportional coefficient K_P2；Subscript n indicates the number of iterations； K_P2,min、K_P2,max、K_I2,min、K_I2,maxTo control variable upper and lower limit；P_iIndicate having for connected i-th branch of blower grid entry point Hard；Q_iIndicate the idle work of connected i-th branch of blower grid entry point；

If invalid, change decision set initial value by preset rules, resurvey data, judge again, until obtaining All decision set numerical value that wind power plant parameter optimization constraint condition must be met, transmit it to optimized parameter module；

Optimized parameter module, for establishing following broad object function p according to wind power plant parameter optimization objective function_i

It finds out in all decision set of above-mentioned acquisition, so that the p_iMaximum and p_iThe decision set numerical value of > 0, as Pusher side inverter inner loop control parameter to be asked.

Beneficial effect using above-mentioned further improvement scheme is: using iterative algorithm, the decision in decision set is enabled to become Amount improves the performance of optimization algorithm, improves user satisfaction constantly towards the maximum direction change of objective function value is made.

Further, the preset rules are

K_P2-n+1=K_P2-n-ε_P

K_I2-n+1=K_I2-n-ε_I

In formula, K_P2-n+1For K next time_P2, K_P2-nFor last K_P2, n is the number of iterations, ε_PFor K_P2Change step, ε_IFor K_P2Change step.

Beneficial effect using above-mentioned further improvement scheme is: decision variable can be searched for by assigned direction meets constraint item Thus the value of part reduces algorithm operation time and improves computational efficiency.

It in the present invention, can also be combined with each other between above-mentioned each technical solution, to realize more preferred assembled schemes.This Other feature and advantage of invention will illustrate in the following description, also, certain advantages can become from specification it is aobvious and It is clear to, or understand through the implementation of the invention.The objectives and other advantages of the invention can pass through institute in specification and attached drawing It is achieved and obtained in the content particularly pointed out.

Detailed description of the invention

Attached drawing is only used for showing the purpose of specific embodiment, and is not to be construed as limiting the invention, in entire attached drawing In, identical reference symbol indicates identical component.

Fig. 1 is double-fed blower grid-connected system composition schematic diagram；

Fig. 2 is 1 double-fed fan motor sub-synchronous oscillation suppression method step schematic diagram of the embodiment of the present invention；

Fig. 3 is that 3 double-fed fan motor sub-synchronous oscillation of the embodiment of the present invention inhibits composition schematic diagram；

Fig. 4 is 4 energy of the embodiment of the present invention-parameters relationship module composition schematic diagram；

Fig. 5 is 4 parameter optimization module composition schematic diagram of the embodiment of the present invention.

Specific embodiment

Specifically describing the preferred embodiment of the present invention with reference to the accompanying drawing, wherein attached drawing constitutes the application a part, and Together with embodiments of the present invention for illustrating the principle of the present invention, it is not intended to limit the scope of the present invention.

It may include that more sets form identical blower fan control system by taking double-fed blower grid-connected system as shown in Figure 1 as an example (illustratively being depicted in Fig. 1 a set of).Every set blower fan control system includes that double-fed blower (including stator, rotor), pusher side change Device, net side inverter, step-up transformer, capacitor, transmission line of electricity, Infinite bus system are flowed, connection relationship is as shown in Figure 1.

Double-fed blower grid-connected system sub-synchronous oscillation dissipates mechanism: when double-fed blower is concatenated, compensation is grid-connected, and string is reissued out Sub-synchronous oscillation energy be greater than blower consumption sub-synchronous oscillation energy when, double-fed blower be concatenated compensation grid-connected system it is equivalent To continuously send out sub-synchronous oscillation energy, sub-synchronous oscillation will be induced at this time, and equivalent system shows as negative resistance character.

The effect of generator-side converter wear: by stator-flux-oriented vector control, to control having for generator unit stator side output Function power and reactive power, with realize maximal power point tracking and guarantee institute simultaneously power grid it is stable.

The effect of grid-side converter: grid-side converter is by being taken based on voltage, the current double closed-loop of grid voltage orientation Control, to control the waveform of generator port voltage, electric current, makes it keep sinusoidal waveform as far as possible.

The effect of step-up transformer: blower output voltage is boosted into network voltage.

The effect of phaselocked loop: acquisition network voltage frequency (it is equivalent to blower grid entry point fundamental frequency f), phase and amplitude, Realize that blower is synchronous between power grid.

Embodiment 1

A specific embodiment of the invention discloses a kind of double-fed fan motor sub-synchronous oscillation suppression based on converter Control Method processed, as shown in Figure 1, including the following steps:

S1. when sub-synchronous oscillation occurs for double-fed blower grid-connected system, the operation data of double-fed blower grid-connected system is acquired；

S2. it is dissipated according to the response process of double-fed blower grid-connected system under grid disturbance and double-fed blower sub-synchronous oscillation Mechanism obtains the mapping relations between blower dynamic power variable quantity and pusher side converter Control parameter, and then it is dynamic to obtain blower The aperiodic change rate of state energy and the relationship of the operation data；

S3. target is up to the aperiodic change rate of blower dynamic power, establishes optimization model, to double-fed blower The pusher side inverter inner loop control parameter of each blower carries out collaboration optimization in grid-connected system, to carry out to the sub-synchronous oscillation Inhibit.

Compared with prior art, method provided in this embodiment is by key parameter (pusher side converter Control parameter) and random Factor (operation data of double-fed blower grid-connected system) is introduced into blower dynamic power, constructs the double-fed blower under multi-constraint condition Inverter parameter optimization strategy, the final active control for realizing sub-synchronous oscillation.It is proved through a large number of experiments, above-mentioned technical proposal energy It is enough that collaboration optimization properly and efficiently is carried out to all blower inverter parameters in wind power plant inside, effectively inhibit double-fed blower grid-connected There is sub-synchronous oscillation in system.

Embodiment 2

It improves on that basis of example 1, the operation data of double-fed blower grid-connected system includes: stator side induced current Virtual value I₀, stator side induced voltage virtual value U₀, stator self inductance L_s, rotor self-induction L_r, rotor mutual inductance L_m, fan rotor Rotational speed omega_r, blower grid entry point voltage phasor U, blower grid entry point electric current phasor I, blower grid entry point useful work P, blower grid entry point Idle work Q, blower generator rotor angle δ, blower grid entry point fundamental frequency f.

Wherein, stator side induced current virtual value I₀, stator side induced voltage virtual value U₀, the two can pass through prony algorithm Handle stator side voltage and current instantaneous value, extract subsynchronous frequency current, voltage magnitude again divided byIt obtains.Useful work P and Idle work Q can be measured by power meter, and blower generator rotor angle δ can be measured by generator built-in potential tester, blower grid entry point fundamental frequency Frequency f can be measured with phaselocked loop.

Preferably, pusher side inverter inner loop control parameter includes: pusher side Inverter circuit inner ring integral coefficient K_I2And ratio COEFFICIENT K_P2。

Preferably, the mapping relations between the blower dynamic power variable quantity and pusher side converter Control parameter

Wherein

ω₂=ω₁+ω_r-ω_s, ω₃=ω_s-ω_r, ω_s=2 π f, ω₁=2 π f₁

In formula, U_s、Respectively to blower grid entry point voltage phasor U carry out Harmonic Decomposition acquisition fundamental frequency voltages amplitude, Initial phase,For the Fundamental-frequency Current initial phase for carrying out Harmonic Decomposition acquisition to blower grid entry point current vector I, K_I1、K_P1Respectively Pusher side converter power outer ring integral coefficient and proportionality coefficient, K_I2、K_P2Respectively pusher side Inverter circuit inner ring integral coefficient and Proportionality coefficient, ω_rFor fan rotor rotation speed, R_rFor fan rotor resistance, f₁To carry out harmonic wave to blower grid entry point current vector I Decompose the frequency of the sub-synchronous oscillation current disturbing signal obtained.

It should be noted that f₁Mechanism of production be: occur sub-synchronous oscillation when, fan stator winding is by pusher side inverter The effect of disturbance quantity can generate secondary frequencies electric current, i.e. sub-synchronous oscillation current disturbing signal.It can be by acquiring blower grid entry point The electric current at place, then processing acquisition is carried out by prony algorithm.The frequency range of the sub-synchronous oscillation current disturbing signal exists 2.5~50Hz.

Preferably, the aperiodic change rate of blower dynamic power can be characterized by following formula

Preferably, optimization model includes wind power plant parameter optimization objective function and wind power plant parameter optimization constraint item Part.It is further explained below.

Wind power plant parameter optimization objective function is

Wind power plant parameter optimization constraint condition is

In formula, h is system variable, including blower grid entry point voltage phasor U, blower grid entry point useful work P, blower grid entry point Idle work Q, blower generator rotor angle δ, blower grid entry point fundamental frequency f；h_min、h_maxFor system variable upper and lower limit；K is control to be adjusted Variable processed, including pusher side Inverter circuit inner ring integral coefficient K_I2And Proportional coefficient K_P2；K_min、K_maxIt is upper and lower for control variable Limit, P_iIndicate the useful work of connected i-th branch of blower grid entry point, Q_iIndicate the nothing of connected i-th branch of blower grid entry point Hard.

Preferably, in step S3, the pusher side inverter inner loop control to each blower in double-fed blower grid-connected system Parameter carries out collaboration optimization, further comprises following steps:

S31. using control variable to be adjusted as set element, decision set is established.

S32. decision set initial value is obtained, determines whether to meet wind power plant parameter optimization constraint condition；If conditions are not met, Change decision set initial value by the preset rules in following formula, judge again, acquisition meets the constraint of wind power plant parameter optimization All decision set numerical value of condition

K_P2-n+1=K_P2-n-ε_P

K_I2-n+1=K_I2-n-ε_I (6)

In formula, K_P2-n+1Indicate K when (n+1)th iteration_P2, K_P2-nIndicate K when nth iteration_P2, K_I2-n+1Expression n-th+ K when 1 iteration_I2, K_I2-nIndicate K when nth iteration_I2, n expression the number of iterations；ε_PFor K_P2Change step, ε_IFor K_P2's Change step.

S33. according to wind power plant parameter optimization objective function, following broad object function p is established_i

It finds out in all decision set of above-mentioned acquisition, so that broad object function p_iMaximum, and p_iThe decision set of > 0 Numerical value, as pusher side inverter inner loop control parameter to be asked.

Compared with Example 2, method provided in this embodiment considers sub-synchronous oscillation disturbance on the basis of energy model Signal function analyzes the relationship between blower dynamic power variable quantity and pusher side inverter parameter, it is steady to have obtained sub-synchronous oscillation Determine boundary condition.Double-fed blower converter Control parameter is optimized under multi-constraint condition, can effectively inhibit secondary same Step oscillation, and it is suitable for complicated multi-computer system.

Embodiment 3

The present invention also provides a kind of double-fed blower sub-synchronous oscillations using 1 the method for embodiment to inhibit system, such as Shown in Fig. 3 comprising data acquisition module, energy-parameters relationship module, parameter optimization module.Wherein, data acquisition module Output end is separately connected with energy-parameters relationship module input, parameter optimization module input one, energy-parameters relationship Module output end is connect with parameter optimization module input two.

Data acquisition module, for when sub-synchronous oscillation occurs for double-fed blower grid-connected system, acquisition double-fed blower to be grid-connected The operation data of system, and transmit it to energy-parameters relationship module and parameter optimization module.

Energy-parameters relationship module, for according to the response process of double-fed blower grid-connected system under grid disturbance and double It presents blower sub-synchronous oscillation and dissipates mechanism, obtain the mapping between blower dynamic power variable quantity and pusher side converter Control parameter Relationship, and then obtain the aperiodic change rate of blower dynamic power and the relationship of the operation data.

Parameter optimization module establishes optimization model, to double-fed for being up to target with above-mentioned aperiodic change rate The pusher side inverter inner loop control parameter of each blower carries out collaboration optimization in blower grid-connected system, to the sub-synchronous oscillation Inhibited.

Compared with prior art, system provided in this embodiment is by key parameter (pusher side converter Control parameter) and random Factor (operation data of double-fed blower grid-connected system) is introduced into blower dynamic power, constructs the double-fed blower under multi-constraint condition Inverter parameter optimization strategy, the final active control for realizing sub-synchronous oscillation.It is proved through a large number of experiments, above-mentioned technical proposal energy It is enough that collaboration optimization properly and efficiently is carried out to all blower inverter parameters in wind power plant inside, effectively inhibit double-fed blower grid-connected There is sub-synchronous oscillation in system.

Embodiment 4

Optimize on the basis of embodiment 3, the present invention also provides a kind of double-fed blowers using 2 the method for embodiment Sub-synchronous oscillation inhibits system, as shown in figure 4, energy-parameters relationship module further comprises sequentially connected frequency analysis mould Block, disturbance component analysis module, sub-synchronous oscillation control module.

Frequency analysis module is obtained for carrying out Harmonic Decomposition respectively to blower grid entry point voltage phasor U and current vector I Obtain the amplitude U of fundamental frequency voltages_s, initial phaseAnd the initial phase of Fundamental-frequency CurrentThe result of acquisition is transmitted to disturbance point Measure analysis module.Optionally, the realization of prony algorithm can be used in the Harmonic Decomposition method.

Disturbance component analysis module, for according to stator side induced current virtual value I in double-fed blower grid-connected system₀And sense Answer voltage effective value U₀, in conjunction with the U of above-mentioned acquisition_s、Blower dynamic power variation delta W is obtained by following formula With the mapping relations between pusher side converter Control parameter, the mapping relations are transmitted to sub-synchronous oscillation control module

Wherein

In formula, K_I1、K_P1Respectively pusher side Inverter circuit outer ring integral coefficient and proportionality coefficient, K_I2、K_P2Respectively pusher side Inverter circuit inner ring integral coefficient and proportionality coefficient；ω_rFor fan rotor rotation speed, ω₁For sub-synchronous oscillation current disturbing signal Frequency；R_rFor fan rotor resistance.

Sub-synchronous oscillation control module, for obtaining the aperiodic variation of blower dynamic power according to above-mentioned mapping relations Rate, the aperiodic change rate can be characterized by following formula

And then according to formula above judge whether can active control sub-synchronous oscillation sentence when the formulae results are less than 0 Surely can active control sub-synchronous oscillation, be transmitted to parameter optimization module for the formulae results as aperiodic change rate, it is no Then, judgement can not active control, change pusher side inverter inner loop control parameter values, judge again.

Preferably, as shown in figure 5, parameter optimization module further comprise sequentially connected decision set generation module, just Walk screening module, optimized parameter module.

Decision set generation module, for being set with control variable to be adjusted in pusher side inverter inner loop control parameter Element establishes decision set, generates decision set initial value and is transmitted to preliminary screening module.

Preliminary screening module, for according to the decision set initial value of acquisition and the operation number of double-fed blower grid-connected system According to determining whether following wind power plant parameter optimization constraint condition is true, filters out and meets wind power plant parameter optimization constraint condition Decision set numerical value

In formula, h is system variable, including blower grid entry point voltage phasor U, blower grid entry point useful work P, blower grid entry point Idle work Q, blower generator rotor angle δ, blower grid entry point fundamental frequency f；h_min、h_maxFor system variable upper and lower limit；K is control to be adjusted Variable processed, including pusher side Inverter circuit inner ring integral coefficient K_I2And Proportional coefficient K_P2；Subscript n indicates the number of iterations； K_P2,min、K_P2,max、K_I2,min、K_I2,maxTo control variable upper and lower limit；P_iIndicate having for connected i-th branch of blower grid entry point Hard, Q_iIndicate the idle work of connected i-th branch of blower grid entry point.

Optimized parameter module, for establishing following broad object function p according to wind power plant parameter optimization objective function_i

It finds out in all decision set of above-mentioned acquisition, so that the p_iMaximum and p_iThe decision set numerical value of > 0, as Pusher side inverter inner loop control parameter to be asked.

Preferably, the preset rules are

K_P2-n+1=K_P2-n-ε_P

K_I2-n+1=K_I2-n-ε_I (13)

In formula, K_P2-n+1For K next time_P2, K_P2-nFor last K_P2, n is the number of iterations, ε_PFor K_P2Change step, ε_IFor K_P2Change step.

Compared with Example 3, double-fed blower sub-synchronous oscillation provided in this embodiment inhibits system under multi-constraint condition Double-fed blower converter Control parameter is optimized, sub-synchronous oscillation can be effectively inhibited, and is suitable for complicated multimachine system System.

It will be understood by those skilled in the art that realizing all or part of the process of above-described embodiment method, meter can be passed through Calculation machine program is completed to instruct relevant hardware, and the program can be stored in computer readable storage medium.Wherein, institute Stating computer readable storage medium is disk, CD, read-only memory or random access memory etc..

The foregoing is only a preferred embodiment of the present invention, but scope of protection of the present invention is not limited thereto, In the technical scope disclosed by the present invention, any changes or substitutions that can be easily thought of by anyone skilled in the art, It should be covered by the protection scope of the present invention.

Claims (10)

1. a kind of double-fed fan motor sub-synchronous oscillation suppression method based on converter Control, which comprises the steps of:

When sub-synchronous oscillation occurs for double-fed blower grid-connected system, the operation data of double-fed blower grid-connected system is acquired；

Mechanism is dissipated according to the response process of double-fed blower grid-connected system under grid disturbance and double-fed blower sub-synchronous oscillation, is obtained The mapping relations between blower dynamic power variable quantity and pusher side converter Control parameter are obtained, and then obtain blower dynamic power The relationship of aperiodic change rate and the operation data；

It is up to target with the aperiodic change rate of blower dynamic power, establishes optimization model, to the grid-connected system of double-fed blower The pusher side inverter inner loop control parameter of each blower carries out collaboration optimization in system, to inhibit to the sub-synchronous oscillation.

2. the double-fed fan motor sub-synchronous oscillation suppression method according to claim 1 based on converter Control, feature exist In the operation data of the double-fed blower grid-connected system includes: the faradic virtual value I of stator side₀, stator side induced voltage Virtual value U₀, stator self inductance L_s, rotor self-induction L_r, rotor mutual inductance L_m, fan rotor rotation speed ω_r, blower grid entry point voltage phase Measure U, blower grid entry point electric current phasor I, blower grid entry point useful work P, blower grid entry point idle work Q, blower generator rotor angle δ, blower simultaneously Site fundamental frequency f；

The pusher side inverter inner loop control parameter includes: pusher side Inverter circuit inner ring integral coefficient K_I2And Proportional coefficient K_P2。

3. the double-fed fan motor sub-synchronous oscillation suppression method according to claim 2 based on converter Control, feature exist In mapping relations between the blower dynamic power variable quantity and pusher side converter Control parameter

Wherein

ω₂=ω₁+ω_r-ω_s, ω₃=ω_s-ω_r, ω_s=2 π f, ω₁=2 π f₁

In formula, U_s、Fundamental frequency voltages amplitude, the first phase of Harmonic Decomposition acquisition are respectively carried out to blower grid entry point voltage phasor U Position,For the Fundamental-frequency Current initial phase for carrying out Harmonic Decomposition acquisition to blower grid entry point current vector I, K_I1、K_P1Respectively pusher side Converter power outer ring integral coefficient and proportionality coefficient, K_I2、K_P2Respectively pusher side Inverter circuit inner ring integral coefficient and ratio Coefficient, ω_rFor fan rotor rotation speed, R_rFor fan rotor resistance, f₁To carry out Harmonic Decomposition to blower grid entry point current vector I The frequency of the sub-synchronous oscillation current disturbing signal of acquisition.

4. the double-fed fan motor sub-synchronous oscillation suppression method according to claim 3 based on converter Control, feature exist In the aperiodic change rate of the blower dynamic power is

5. the double-fed fan motor sub-synchronous oscillation suppression method according to claim 4 based on converter Control, feature exist In the optimization model includes wind power plant parameter optimization objective function and wind power plant parameter optimization constraint condition, wherein

The wind power plant parameter optimization objective function is

The wind power plant parameter optimization constraint condition is

In formula, h is system variable, including blower grid entry point voltage phasor U, blower grid entry point useful work P, blower grid entry point are useless Function Q, blower generator rotor angle δ, blower grid entry point fundamental frequency f；h_min、h_maxFor system variable upper and lower limit；K is that control to be adjusted becomes Amount, including pusher side Inverter circuit inner ring integral coefficient K_I2And Proportional coefficient K_P2；K_min、K_maxTo control variable upper and lower limit, P_iTable Show the useful work of connected i-th branch of blower grid entry point, Q_iIndicate the idle work of connected i-th branch of blower grid entry point.

6. the double-fed fan motor sub-synchronous oscillation suppression method according to claim 5 based on converter Control, feature exist In the pusher side inverter inner loop control parameter to each blower in double-fed blower grid-connected system carries out collaboration optimization, into one Step includes the following steps:

Using control variable to be adjusted as set element, decision set is established；

Decision set initial value is obtained, determines whether to meet wind power plant parameter optimization constraint condition；If conditions are not met, pressing following public affairs Preset rules in formula change decision set initial value, judge again, obtain the institute for meeting wind power plant parameter optimization constraint condition There is decision set numerical value

K_P2-n+1=K_P2-n-ε_P

K_I2-n+1=K_I2-n-ε_I

In formula, K_P2-n+1Indicate K next time_P2, K_P2-nIndicate last K_P2, n expression the number of iterations；ε_PFor K_P2Variation step It is long, ε_IFor K_P2Change step；

According to wind power plant parameter optimization objective function, following broad object function p is established_i

It finds out in all decision set of above-mentioned acquisition, so that broad object function p_iMaximum, and p_iThe decision set numerical value of > 0, As pusher side inverter inner loop control parameter to be asked.

7. a kind of double-fed blower sub-synchronous oscillation based on converter Control inhibits system characterized by comprising

Data acquisition module, for acquiring double-fed blower grid-connected system when sub-synchronous oscillation occurs for double-fed blower grid-connected system Operation data, and transmit it to energy-parameters relationship module and parameter optimization module；

Energy-parameters relationship module, for the response process and double-fed wind according to double-fed blower grid-connected system under grid disturbance Machine sub-synchronous oscillation dissipates mechanism, and the mapping obtained between blower dynamic power variable quantity and pusher side converter Control parameter is closed System, and then obtain the aperiodic change rate of blower dynamic power and the relationship of the operation data；

Parameter optimization module establishes optimization model, to double-fed blower for being up to target with above-mentioned aperiodic change rate The pusher side inverter inner loop control parameter of each blower carries out collaboration optimization in grid-connected system, to carry out to the sub-synchronous oscillation Inhibit.

8. the double-fed blower sub-synchronous oscillation according to claim 7 based on converter Control inhibits system, feature exists In the energy-parameters relationship module further comprises:

Frequency analysis module obtains base for carrying out Harmonic Decomposition respectively to blower grid entry point voltage phasor U and current vector I The amplitude U of frequency voltage_s, initial phaseAnd the initial phase of Fundamental-frequency CurrentSub-synchronous oscillation current disturbing signal frequency f₁, The result of acquisition is transmitted to disturbance component analysis module；

Disturbance component analysis module, for according to stator side induced current virtual value I in double-fed blower grid-connected system₀And induced electricity It is pressed with valid value U₀, in conjunction with the U of above-mentioned acquisition_s、Blower dynamic power variation delta W and machine are obtained by following formula The mapping relations are transmitted to sub-synchronous oscillation control module by the mapping relations between the converter Control parameter of side

Wherein

ω₂=ω₁+ω_r-ω_s, ω₃=ω_s-ω_r, ω_s=2 π f, ω₁=2 π f₁

In formula, K_I1、K_P1Respectively pusher side Inverter circuit outer ring integral coefficient and proportionality coefficient, K_I2、K_P2The respectively pusher side change of current Device current inner loop integral coefficient and proportionality coefficient；ω_rFor fan rotor rotation speed；R_rFor fan rotor resistance.

Sub-synchronous oscillation control module, for obtaining the aperiodic change rate of blower dynamic power, institute according to above-mentioned mapping relations Stating aperiodic change rate can be characterized by following formula

And then according to formula above judge whether can active control sub-synchronous oscillation determine energy when the formulae results are less than 0 Enough active control sub-synchronous oscillations, are transmitted to parameter optimization module for the formulae results as aperiodic change rate, otherwise, sentence It is disconnected can not active control, change pusher side inverter inner loop control parameter values, judge again.

9. the double-fed blower sub-synchronous oscillation according to claim 8 based on converter Control inhibits system, feature exists In the parameter optimization module further comprises:

Decision set generation module, for being set member with control variable to be adjusted in pusher side inverter inner loop control parameter Element establishes decision set, generates decision set initial value and is transmitted to preliminary screening module；

Preliminary screening module, for according to the decision set initial value of acquisition and the operation data of double-fed blower grid-connected system, Determine whether following wind power plant parameter optimization constraint condition is true

In formula, h is system variable, including blower grid entry point voltage phasor U, blower grid entry point useful work P, blower grid entry point are useless Function Q, blower generator rotor angle δ, blower grid entry point fundamental frequency f；h_min、h_maxFor system variable upper and lower limit；K is that control to be adjusted becomes Amount, including pusher side Inverter circuit inner ring integral coefficient K_I2And Proportional coefficient K_P2；Subscript n indicates the number of iterations；K_P2,min、 K_P2,max、K_I2,min、K_I2,maxTo control variable upper and lower limit；P_iIndicate the useful work of connected i-th branch of blower grid entry point；Q_i Indicate the idle work of connected i-th branch of blower grid entry point；

If invalid, change decision set initial value by preset rules, resurvey data, judge again, until being expired All decision set numerical value of sufficient wind power plant parameter optimization constraint condition, transmit it to optimized parameter module；

Optimized parameter module, for establishing following broad object function p according to wind power plant parameter optimization objective function_i

It finds out in all decision set of above-mentioned acquisition, so that the p_iMaximum and p_iThe decision set numerical value of > 0, as wait ask Pusher side inverter inner loop control parameter.

10. the double-fed blower sub-synchronous oscillation according to claim 9 based on converter Control inhibits system, feature exists In the preset rules are

K_P2-n+1=K_P2-n-ε_P

K_I2-n+1=K_I2-n-ε_I

In formula, K_P2-n+1For K next time_P2, K_P2-nFor last K_P2, n is the number of iterations, ε_PFor K_P2Change step, ε_IFor K_P2Change step.