阅读说明：本技术 压缩机的控制方法、装置、制冷设备和可读存储介质 (Control method and device of compressor, refrigeration equipment and readable storage medium ) 是由 李太龙 王世超 于 2020-12-28 设计创作，主要内容包括：本发明提出了一种压缩机的控制方法、装置、制冷设备和可读存储介质,压缩机的控制方法包括：获取压缩机的回转速度信号；根据回转速度信号,确定压缩机的转速谐波；根据转速谐波,对压缩机进行前馈补偿和反馈补偿。本发明提出的压缩机的控制方法,对压缩机的补偿方式,为前馈补偿和反馈补偿共同进行,一方面克服了单独的反馈补偿的动态过程响应慢的问题,另一方面也避免只使用前馈补偿的参数依赖和鲁棒性差的问题,通过合理的设计融合策略,可以极大的结合这两种方法的优点,实现高响应速度和高鲁棒性,极大的优化系统性能,有效抑制压缩机的振动谐波,改善压缩机的噪音问题。(The invention provides a control method and a control device of a compressor, refrigeration equipment and a readable storage medium, wherein the control method of the compressor comprises the following steps: acquiring a rotation speed signal of a compressor; determining the rotating speed harmonic wave of the compressor according to the rotating speed signal; and performing feedforward compensation and feedback compensation on the compressor according to the rotating speed harmonic waves. The control method of the compressor provided by the invention carries out the compensation mode of the compressor together with feedforward compensation and feedback compensation, on one hand, the problem of slow response of the dynamic process of the independent feedback compensation is solved, on the other hand, the problems of parameter dependence and poor robustness of only using the feedforward compensation are also avoided, and through a reasonable design and fusion strategy, the advantages of the two methods can be greatly combined, the high response speed and the high robustness are realized, the system performance is greatly optimized, the vibration harmonic wave of the compressor is effectively inhibited, and the noise problem of the compressor is improved.)

1. A control method of a compressor, characterized by comprising:

acquiring a rotation speed signal of a compressor;

determining the rotating speed harmonic of the compressor according to the rotating speed signal;

and performing feedforward compensation and feedback compensation on the compressor according to the rotating speed harmonic.

2. The method for controlling a compressor according to claim 1, wherein the step of determining a rotational speed harmonic of the compressor based on the rotation speed signal comprises:

and inputting the rotation speed signal into a preset transformation model, and extracting the rotation speed harmonic wave through a filter.

3. The method for controlling a compressor according to claim 2, further comprising, before the step of obtaining a rotation speed signal of the compressor:

constructing a rotation speed reference coordinate system and a harmonic synchronous shaft reference coordinate system;

and establishing the preset transformation model from the rotation speed reference coordinate system to a harmonic synchronous shaft reference coordinate system.

4. The control method of a compressor according to claim 2, wherein the filter includes:

a butterworth low pass filter.

5. The method for controlling a compressor according to claim 2, wherein the step of performing feed-forward compensation and feedback compensation on the compressor according to the rotational speed harmonic specifically comprises:

determining a virtual current value through a first regulator according to the rotating speed harmonic;

performing inverse transformation on the virtual current value by using the transformation model to obtain a harmonic compensation current value;

and performing feedforward compensation and feedback compensation on the compressor according to the harmonic compensation current value.

6. The method for controlling a compressor according to claim 5, wherein the step of performing feed-forward compensation and feedback compensation on the compressor according to the harmonic compensation current value specifically comprises:

determining a feedforward compensation voltage value according to the harmonic compensation current value;

and performing feedforward compensation on the compressor according to the feedforward compensation voltage value.

7. The method for controlling a compressor according to claim 5, wherein the step of performing feed-forward compensation and feedback compensation on the compressor according to the harmonic compensation current value specifically comprises:

determining a feedback compensation voltage value by using a second regulator according to the harmonic compensation current value;

and feeding back and compensating the compressor according to the feedback compensation voltage value.

8. The control method of a compressor according to claim 7, wherein the second regulator includes: linear regulators and resonant regulators.

9. The method for controlling a compressor according to any one of claims 1 to 7, wherein the step of obtaining a rotation speed signal of the compressor specifically comprises:

acquiring a rotation speed signal of the compressor through a sensor; or

And acquiring a rotation speed signal of the compressor through an observer.

10. The control method of a compressor according to claim 9,

the sensor includes: a vibration sensor or an acceleration sensor;

the observer includes: high bandwidth sensorless observers.

11. A control apparatus of a compressor, characterized by comprising:

a memory having a program or instructions stored thereon;

a processor configured to implement the control method of the compressor of any one of claims 1 to 10 when executing the program or instructions.

12. The control device of a compressor according to claim 11, further comprising:

the sensor is connected with the processor and used for acquiring a rotation speed signal of the compressor; and/or

The filter is connected with the processor and used for extracting the rotating speed harmonic; and/or

A regulator coupled to the processor for determining a virtual current value.

13. A refrigeration apparatus, comprising:

a compressor; and

a control apparatus of a compressor according to claim 11 or 12.

14. A readable storage medium on which a program or instructions are stored, characterized in that the program or instructions, when executed by a processor, implement a control method of a compressor according to any one of claims 1 to 10.

Technical Field

The invention relates to the field of compressors, in particular to a control method of a compressor, a control device of the compressor, a refrigeration device and a readable storage medium.

Background

In the related art, the basic working principle of the rotary single-rotor compressor is that an eccentric crankshaft drives a rolling piston to rotate, wherein when a cylinder is in compression work, the gas pressure in a compression cavity changes periodically, so that periodically changing torque pulsation is generated between the cylinder and the rotating crankshaft, which is the basic reason for generating torsional vibration of the compressor.

The torsional vibration of the compressor causes the working noise of the compressor to be larger, and influences the hearing.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art.

To this end, a first aspect of the present invention proposes a control method of a compressor.

A second aspect of the present invention provides a control apparatus of a compressor.

A third aspect of the invention provides a refrigeration apparatus.

A fourth aspect of the invention proposes a readable storage medium.

In view of the above, according to a first aspect of the present invention, there is provided a control method of a compressor, including: acquiring a rotation speed signal of a compressor; determining the rotating speed harmonic wave of the compressor according to the rotating speed signal; and performing feedforward compensation and feedback compensation on the compressor according to the rotating speed harmonic waves.

The control method of the compressor provided by the invention obtains the rotation speed signal of the compressor, the continuous rotation speed signal forms a continuous waveform, and then the rotation speed harmonic of the compressor is determined according to the rotation speed signal of the compressor, wherein the rotation speed harmonic is the key of the compressor for generating noise, and further the compressor can be better compensated according to the rotation speed harmonic so as to reduce the generation of the harmonic.

Specifically, the compensation mode of the compressor is carried out for feedforward compensation and feedback compensation together, on one hand, the problem of slow response of a dynamic process of independent feedback compensation is solved, on the other hand, the problems of parameter dependence and poor robustness of only feedforward compensation are also avoided, and the advantages of the two methods can be greatly combined through a reasonable design and fusion strategy, so that the high response speed and the high robustness are realized, the system performance is greatly optimized, the vibration harmonic wave of the compressor is effectively inhibited, and the noise problem of the compressor is improved.

In addition, according to the control method of the compressor in the above technical solution provided by the present invention, the following additional technical features may be further provided:

in the above technical solution, further, the step of determining the rotation speed harmonic of the compressor according to the rotation speed signal specifically includes: and inputting the rotation speed signal into a preset transformation model, and extracting the rotation speed harmonic through a filter.

In the technical scheme, the step of determining the rotating speed harmonic wave of the compressor according to the rotating speed signal specifically comprises the following steps: the rotation speed signal of the compressor is deformed by the aid of the preset transformation model, interference signals are eliminated by the aid of the filter, rotation speed harmonics of the compressor are obtained, and accurate rotation speed harmonics of the compressor can be obtained by the aid of the preset transformation model and the filter.

In any of the above technical solutions, further, before the step of obtaining the rotation speed signal of the compressor, the method further includes: constructing a rotation speed reference coordinate system and a harmonic synchronous shaft reference coordinate system; and establishing a preset transformation model from a rotation speed reference coordinate system to a harmonic synchronous shaft reference coordinate system.

In the technical scheme, before the step of obtaining the rotation speed signal of the compressor, a rotation speed reference coordinate system and a harmonic synchronization shaft reference coordinate system are established, wherein the rotation speed reference coordinate system is a real reference coordinate system corresponding to the rotation speed, parameters in the rotation speed reference coordinate system are real values, the harmonic synchronization shaft reference coordinate system is a virtual parameter coordinate system taking the harmonic as a reference, and parameters in the harmonic synchronization shaft reference coordinate system are virtual values, but the extraction of the rotation speed harmonic is facilitated in the virtual harmonic synchronization shaft reference coordinate system, so that the real parameters are converted into virtual parameters which are easier to calculate through a preset conversion model, and the convenience and the accuracy of the extraction of the rotation speed harmonic are improved.

In any of the above technical solutions, further, the filter includes: a butterworth low pass filter.

In the technical scheme, the low-frequency performance of the Butterworth low-pass filter is better, so that the rotating speed harmonic is extracted by selecting and designing the Butterworth low-pass filter, and more accurate rotating speed harmonic is obtained.

In any of the above technical solutions, further, the step of performing feedforward compensation and feedback compensation on the compressor according to the rotation speed harmonic specifically includes: determining a virtual current value through a first regulator according to the rotation speed harmonic; performing reverse transformation on the virtual current value by using a transformation model to obtain a harmonic compensation current value; and performing feedforward compensation and feedback compensation on the compressor according to the harmonic compensation current value.

In the technical scheme, according to the rotating speed harmonic, a first regulator is used for closed-loop regulation, so that a virtual current value based on a harmonic synchronous shaft reference coordinate system is obtained, a conversion model is used for reverse conversion, namely the virtual current value based on the harmonic synchronous shaft reference coordinate system is converted into a harmonic compensation current value based on a rotating speed reference coordinate system, the harmonic compensation current value is real current data, and feed-forward compensation and feedback compensation are carried out on the compressor based on the harmonic compensation current value, so that a better compensation effect can be achieved.

In any of the above technical solutions, further, the step of performing feedforward compensation and feedback compensation on the compressor according to the harmonic compensation current value specifically includes: determining a feedforward compensation voltage value according to the harmonic compensation current value; and performing feedforward compensation on the compressor according to the feedforward compensation voltage value.

In the technical scheme, the steps of performing feedforward compensation and feedback compensation on the compressor according to the harmonic compensation current value specifically include: and calculating a feedforward compensation voltage value according to the harmonic compensation current value by using a voltage equation of the synchronous motor, and superposing the feedforward compensation voltage value on the input voltage of the compressor, thereby completing the feedforward compensation of the compressor and further realizing the quick response of the compensation of the multiple compressors.

In any of the above technical solutions, further, the step of performing feedforward compensation and feedback compensation on the compressor according to the harmonic compensation current value specifically includes: determining a feedback compensation voltage value by using a second regulator according to the harmonic compensation current value; and feeding back and compensating the compressor according to the feedback compensation voltage value.

In the technical scheme, the steps of performing feedforward compensation and feedback compensation on the compressor according to the harmonic compensation current value specifically include: and calculating a feedback compensation voltage value by utilizing the second regulator through the harmonic compensation current value, feeding back and compensating the compressor according to the feedback compensation voltage value, further depending on the high robustness of a feedback control compensation method, and carrying out online correction and compensation on errors caused by parameter changes, so that the compensation of the compressor is more accurate.

In any of the above solutions, further, the second regulator includes: linear regulators and resonant regulators.

In the technical scheme, the second regulator can be a linear regulator and a resonant regulator, namely the linear regulator and the resonant regulator are connected in parallel, the linear regulator and the resonant regulator are combined, step signal non-static tracking is realized by using the linear regulator, and high-frequency vibration harmonic suppression is realized by using the resonant regulator, so that the feedback compensation voltage value can be accurately and definitely obtained within any harmonic range.

In any of the above technical solutions, further, the step of acquiring a rotation speed signal of the compressor specifically includes: acquiring a rotation speed signal of the compressor through a sensor; or the revolution speed signal of the compressor is acquired through an observer.

In the technical scheme, for the acquisition of the rotation speed signal of the compressor, a sensor of hardware can be used for measuring an acceleration signal or a vibration signal of the compressor and the like, and then the rotation speed signal is determined according to the acceleration signal or the vibration signal.

For the acquisition of the rotation speed signal of the compressor, the rotation speed signal can also be acquired in a software form, namely, an observer is used for acquiring relevant parameters of the compressor, and the rotation speed signal is obtained through calculation.

In any of the above technical solutions, further, the sensor includes: a vibration sensor or an acceleration sensor; the observer includes: high bandwidth sensorless observers.

In this solution, the sensor comprises: the vibration sensor or the acceleration sensor can detect the vibration or the acceleration of the compressor rotor, and further can calculate the rotation speed signal.

And the full-order observer and the improved sliding mode observer of the high-bandwidth sensorless observer can realize high bandwidth and high robustness, and the anti-interference capability of a system can be greatly improved by combining the design of a high-bandwidth phase-locked loop.

According to a second aspect of the present invention, there is provided a control apparatus of a compressor, comprising: a memory having a program or instructions stored thereon; a processor configured to implement the control method of the compressor as set forth in any one of the above technical solutions when executing the program or the instructions.

The control device for the compressor provided by the present invention includes a memory and a processor, and when executed by the processor, the program or the instructions in the memory implement the control method for the compressor provided by any of the above technical solutions.

In the above technical solution, further, the method further includes: the sensor is connected with the processor and used for acquiring a rotation speed signal of the compressor; and/or a filter, connected with the processor, for extracting the rotational speed harmonic; and/or a regulator coupled to the processor for determining the virtual current value.

In this aspect, the control device for a compressor further includes: at least one of the following devices: a sensor, a filter and a regulator, so as to cooperate with the processor to execute the control method of the compressor as set forth in any one of the above technical solutions.

According to a third aspect of the invention, the invention proposes a refrigeration device comprising: a compressor; and a control device for a compressor as set forth in any of the above technical solutions.

The control device for a compressor according to the present invention includes the control device for a compressor according to any one of the above-mentioned embodiments, and therefore, all the advantageous effects of the control device for a compressor according to any one of the above-mentioned embodiments are obtained, and are not described herein.

According to a fourth aspect of the present invention, the present invention proposes a readable storage medium, on which a program or instructions are stored, which when executed by a processor implement the control method of the compressor as proposed in any one of the above-mentioned solutions.

The readable storage medium provided by the present invention stores a program or instructions for implementing the method for controlling a compressor according to any one of the above-mentioned embodiments when the program or instructions are executed by the processor, so that all the advantages of the method for controlling a compressor according to any one of the above-mentioned embodiments are achieved, and thus, the description thereof is omitted.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a flowchart illustrating a control method of a compressor according to a first embodiment of the present invention;

fig. 2 is a flowchart illustrating a control method of a compressor according to a second embodiment of the present invention;

fig. 3 is a flowchart illustrating a control method of a compressor according to a third embodiment of the present invention;

fig. 4 is a flowchart illustrating a control method of a compressor according to a fourth embodiment of the present invention;

fig. 5 is a flowchart illustrating a control method of a compressor according to a fifth embodiment of the present invention;

fig. 6 is a flowchart illustrating a control method of a compressor according to a sixth embodiment of the present invention;

fig. 7 is a flowchart illustrating a control method of a compressor according to a seventh embodiment of the present invention;

fig. 8 is a flowchart illustrating a control method of a compressor according to an eighth embodiment of the present invention;

fig. 9 is a block diagram illustrating a coordinate system transformation in the control method of the compressor according to the present invention;

fig. 10 is a block diagram illustrating the calculation of a harmonic compensation current in the control method of the compressor provided in the present invention;

fig. 11 shows a phase-locked loop system block diagram of an observer in the control method of the compressor provided by the present invention;

FIG. 12 is a waveform diagram illustrating voltage feedforward compensation in a control method of a compressor according to the present invention;

FIG. 13 illustrates a resonant regulator implementing zero error tracking of a harmonic current compensation signal in a control method of a compressor provided by the present invention;

FIG. 14 is a block diagram of a compressor noise harmonic automatic injection and compensation control system in the control method of the compressor according to the present invention;

FIG. 15 is a graph showing a comparison of the compressor provided by the present invention with the fluctuation of the rotational speed of the compressor in the related art;

FIG. 16 is a graph showing a comparison of a frequency spectrum of a fluctuation in a rotational speed of a compressor in a related art in accordance with a control method of a compressor provided by the present invention;

fig. 17 is a graph showing a comparison between a control method of a compressor according to the present invention and a noise OA value of a motor in the related art.

Detailed Description

In order that the above objects, features and advantages of the present invention can be more clearly understood, a more particular description of the invention will be rendered by reference to the appended drawings. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

A control method of a compressor, a control apparatus of a compressor, a refrigeration apparatus, and a readable storage medium according to some embodiments of the present invention are described below with reference to fig. 1 to 17.

Example 1:

fig. 1 is a flowchart illustrating a control method of a compressor according to a first embodiment of the present invention.

As shown in fig. 1, a flow of a method for controlling a compressor according to a first embodiment of the present invention includes the following steps:

step 102: acquiring a rotation speed signal of a compressor;

step 104: determining the rotating speed harmonic wave of the compressor according to the rotating speed signal;

step 106: and performing feedforward compensation and feedback compensation on the compressor according to the rotating speed harmonic waves.

In the embodiment, the control method of the compressor acquires the rotation speed signal of the compressor, the continuous rotation speed signal forms a continuous waveform, and then the rotation speed harmonic of the compressor is determined according to the rotation speed signal of the compressor, wherein the rotation speed harmonic is the key of the compressor for generating noise, and further the compressor can be better compensated according to the rotation speed harmonic so as to reduce the generation of the harmonic.

Specifically, the compensation mode of the compressor is carried out for feedforward compensation and feedback compensation together, on one hand, the problem of slow response of a dynamic process of independent feedback compensation is solved, on the other hand, the problems of parameter dependence and poor robustness of only feedforward compensation are also avoided, and the advantages of the two methods can be greatly combined through a reasonable design and fusion strategy, so that the high response speed and the high robustness are realized, the system performance is greatly optimized, the vibration harmonic wave of the compressor is effectively inhibited, and the noise problem of the compressor is improved.

Step 102 is to obtain a real-time rotation speed signal of the compressor, and the rotation speed signal of the compressor forms a continuous waveform, so that the compressor is continuously compensated during final compensation.

Specifically, a rotation speed signal of the compressor may be acquired by a sensor, such as: a vibration sensor or an acceleration sensor.

Acquiring a real-time acceleration signal of the compressor through a vibration sensor or an acceleration sensor, and further acquiring a real-time rotation speed signal of the compressor;

preprocessing data acquired by a vibration sensor or an acceleration sensor, and then obtaining a real-time rotation speed signal of the compressor through integral operation, wherein the obtained real-time rotation speed signal of the compressor is represented as follows:

where, ω denotes a revolution speed signal,represents the dc component of the slew rate signal,representing the magnitude of the nth harmonic cosine component in the fluctuating component of the slew velocity signal,representing the amplitude of the nth harmonic sinusoidal component of the fluctuating component of the slew velocity signal.

Specifically, the rotation speed signal of the compressor may be acquired by an observer, for example: high bandwidth sensorless observers.

The high-bandwidth sensorless observer is designed to acquire a real-time rotation speed signal of the compressor, wherein the full-order observer and the improved sliding-mode observer can realize high bandwidth and high robustness, and the anti-interference capability of the system can be greatly improved by combining the design of a high-bandwidth phase-locked loop.

As shown in fig. 11, a system block diagram is designed using a full-order phase-locked loop in combination with a high bandwidth,

the obtained real-time rotation speed signal of the compressor is represented as follows:

where, ω denotes a revolution speed signal,represents the dc component of the slew rate signal,representing the magnitude of the nth harmonic cosine component in the fluctuating component of the slew velocity signal,representing the amplitude of the nth harmonic sinusoidal component of the fluctuating component of the slew velocity signal.

Example 2:

fig. 2 is a flowchart illustrating a control method of a compressor according to a second embodiment of the present invention.

As shown in fig. 2, a flow of a method for controlling a compressor according to a second embodiment of the present invention includes the following steps:

step 202: acquiring a rotation speed signal of a compressor;

step 204: inputting a rotation speed signal into a preset transformation model, and extracting a rotation speed harmonic through a filter;

step 206: and performing feedforward compensation and feedback compensation on the compressor according to the rotating speed harmonic waves.

In particular, the filter is a butterworth low pass filter.

On the basis of embodiment 1, further, the step of determining the rotational speed harmonic of the compressor according to the rotation speed signal specifically includes: the rotation speed signal of the compressor is deformed by the aid of the preset transformation model, interference signals are eliminated by the aid of the filter, rotation speed harmonics of the compressor are obtained, and accurate rotation speed harmonics of the compressor can be obtained by the aid of the preset transformation model and the filter.

Specifically, as shown in fig. 9, the rotational speed harmonic component is taken out by a filter,

wherein, ω is_qnHarmonic component of rotation speed, ω, of q-axis, i.e. quadrature axis_dnIs the d-axis, i.e., the rotational speed harmonic component of the direct axis.

Example 3:

fig. 3 is a flowchart illustrating a control method of a compressor according to a third embodiment of the present invention.

As shown in fig. 3, a flow of a method for controlling a compressor according to a third embodiment of the present invention includes the following steps:

step 302: constructing a rotation speed reference coordinate system and a harmonic synchronous shaft reference coordinate system;

step 304: establishing a preset transformation model from a rotation speed reference coordinate system to a harmonic synchronous shaft reference coordinate system;

step 306: acquiring a rotation speed signal of a compressor;

step 308: inputting a rotation speed signal into a preset transformation model, and extracting a rotation speed harmonic through a filter;

step 310: and performing feedforward compensation and feedback compensation on the compressor according to the rotating speed harmonic waves.

On the basis of embodiment 2, further, before the step of obtaining the rotation speed signal of the compressor, a rotation speed reference coordinate system and a harmonic synchronization axis reference coordinate system are constructed, wherein the rotation speed reference coordinate system is a real reference coordinate system corresponding to the rotation speed, and parameters in the rotation speed reference coordinate system are real values, and the harmonic synchronization axis reference coordinate system is a virtual parameter coordinate system based on the harmonic, and parameters in the harmonic synchronization axis reference coordinate system are virtual values. Specifically, the rotation speed reference coordinate system is also used as a rotation speed virtual reference coordinate system.

Specifically, in a steady state condition of the closed loop system for compressor control,

wherein the content of the first and second substances,representing the speed error signal.

Firstly, a rotation speed reference coordinate system of a speed error signal is constructed,

wherein, ω is_dq1Is a matrix of the speed error signal in a slew speed reference frame.

Transforming the harmonic wave to an n-th harmonic wave synchronous reference coordinate system, designing a transformation matrix, namely a transformation model,

wherein the content of the first and second substances,is a transformation matrix.

And (3) coordinate transformation: the formula 6 is multiplied by the formula 7,

example 4:

fig. 4 is a flowchart illustrating a control method of a compressor according to a fourth embodiment of the present invention.

As shown in fig. 4, a flow of a method for controlling a compressor according to a fourth embodiment of the present invention includes the following steps:

step 402: constructing a rotation speed reference coordinate system and a harmonic synchronous shaft reference coordinate system;

step 404: establishing a preset transformation model from a rotation speed reference coordinate system to a harmonic synchronous shaft reference coordinate system;

step 406: acquiring a rotation speed signal of a compressor;

step 408: inputting a rotation speed signal into a preset transformation model, and extracting a rotation speed harmonic through a filter;

step 410: determining a virtual current value through a first regulator according to the rotation speed harmonic;

step 412: performing reverse transformation on the virtual current value by using a transformation model to obtain a harmonic compensation current value;

step 414: and performing feedforward compensation and feedback compensation on the compressor according to the harmonic compensation current value.

On the basis of the embodiment 3, further, according to the rotation speed harmonic, the first regulator is used for closed-loop regulation, so as to obtain a virtual current value based on the harmonic synchronization axis reference coordinate system, and then the conversion model is used for reverse conversion, that is, the virtual current value based on the harmonic synchronization axis reference coordinate system is converted into a harmonic compensation current value based on the rotation speed reference coordinate system, and then the harmonic compensation current value is real current data, so that feedforward compensation and feedback compensation are performed on the compressor based on the harmonic compensation current value, and a better compensation effect can be achieved.

Specifically, as shown in fig. 4, after the rotational speed harmonic is extracted, the rotational speed harmonic can be adjusted by reasonably designing a direct current signal adjuster; the first regulator is a PI regulator (proportional integral controller), and the PI regulator commonly used in engineering can track zero steady-state error for a step signal, namelyThe influence of integral saturation of the PI regulator on the control performance is avoided, the PI regulator with the function of feedback calculation and integral saturation resistance is designed to regulate the rotating speed harmonic, and the virtual current value i based on the harmonic synchronous shaft reference coordinate system is obtained through closed-loop regulation_qnAnd i_dnWherein i is_qnVirtual current values for q-axis, i.e. quadrature axis_dnThe d-axis is a virtual current value of the straight axis.

And according to the built reference coordinate system of the rotation speed and the reference coordinate system of the harmonic synchronous shaft of the compressor, a reverse transformation matrix is built,

the inverse transformation of the coordinate system is performed,

finally, the harmonic compensation current Iq of the closed loop based on the rotation speed reference coordinate system is obtained_comp＝i_q1And Id_comp＝i_d1。

Wherein, Iq_compHarmonic compensation current values, Id, for q-axis, i.e. quadrature axis_compCompensating current values for harmonics of d-axis, i.e. straight axis_q1Indicates a specific current value, i_d1A specific current value is indicated.

Example 5:

fig. 5 is a flowchart illustrating a control method of a compressor according to a fifth embodiment of the present invention.

As shown in fig. 5, a flow of a method for controlling a compressor according to a fifth embodiment of the present invention includes the following steps:

step 402: constructing a rotation speed reference coordinate system and a harmonic synchronous shaft reference coordinate system;

step 504: establishing a preset transformation model from a rotation speed reference coordinate system to a harmonic synchronous shaft reference coordinate system;

step 506: acquiring a rotation speed signal of a compressor;

step 508: inputting a rotation speed signal into a preset transformation model, and extracting a rotation speed harmonic through a filter;

step 510: determining a virtual current value through a first regulator according to the rotation speed harmonic;

step 512: performing reverse transformation on the virtual current value by using a transformation model to obtain a harmonic compensation current value;

step 514: determining a feedforward compensation voltage value according to the harmonic compensation current value;

step 516: performing feedforward compensation on the compressor according to the feedforward compensation voltage value;

step 518: determining a feedback compensation voltage value by using a second regulator according to the harmonic compensation current value;

step 520: and feeding back and compensating the compressor according to the feedback compensation voltage value.

On the basis of embodiment 4, further, the step of performing feedforward compensation and feedback compensation on the compressor according to the harmonic compensation current value specifically includes: and calculating a feedforward compensation voltage value according to the harmonic compensation current value by using a voltage equation of the synchronous motor, and superposing the feedforward compensation voltage value on the input voltage of the compressor, thereby completing the feedforward compensation of the compressor and further realizing the quick response of the compensation of the multiple compressors.

When the compressor operates in a dynamic working condition, the quick response capability of the feedforward compensation method can be relied more to solve the problems of slow convergence and long response time of the dynamic process of the feedback control compensation method;

in combination with the voltage equation of the synchronous machine, the feedforward compensation voltage value is as follows:

V_d＝(r_s+r_damp)×i_d+(-ω×l_q×i_q) (formula 11) of the reaction mixture,

V_q＝(r_s+r_damp)×i_q+(ω×l_d×i_d+ω_ε×ψ_f) (in the formula 12),

mixing Iq_comp＝i_q1And Id_comp＝i_d1Substituting the equation to calculate the feedforward compensation voltage valueAndthe fast response of the high frequency compensation harmonic signal is realized, and the feedforward compensation voltage waveform result is obtained in practice, as shown in fig. 12.

And, according to the harmonic compensation current value, carry on the feedforward compensation and step of the feedback compensation to the compressor, include specifically: and calculating a feedback compensation voltage value by utilizing the second regulator through the harmonic compensation current value, feeding back and compensating the compressor according to the feedback compensation voltage value, further depending on the high robustness of a feedback control compensation method, and carrying out online correction and compensation on errors caused by parameter changes, so that the compensation of the compressor is more accurate.

The second regulator may be a linear regulator and a resonant regulator. Wherein the linear regulator may be a PI regulator.

Specifically, when the compressor operates in a steady-state working condition, in order to avoid the problems of parameter dependence and poor robustness of using only feedforward compensation, the high robustness of the feedback control compensation method can be relied on more, and online correction compensation is performed on errors caused by parameter changes.

Because of the harmonic compensation current Iq to be realized_comp＝i_q1And Id_comp＝i_d1The traditional PI regulator cannot well realize the static error-free tracking of the alternating current signal, and particularly the control of the high-frequency harmonic compensation current needs to specially design the alternating current signal regulator.

The resonance regulator can be derived from an internal model of a sinusoidal signal, and has the excellent characteristics of infinite gain and zero phase delay at a resonance frequency point, so that the resonance regulator can perform ideal control on specific frequency and realize the non-static tracking of any frequency.

And, apply the resonance regulator to the harmonic suppression of the high-frequency vibration of the compressor, on PI control structure, the parallel proportion resonance regulator.

The PI controller can realize the step signal non-static tracking, and the parallel proportional resonance PR regulator can realize the suppression of high-frequency vibration harmonic waves.

In practical application, in order to ensure the stability of the system, the quasi-proportional resonant regulator is designed to have a transfer function as follows:

wherein k is_pRepresents the proportional gain, k_irRepresenting the resonant gain, ω₀Representing the resonance frequency, ω_cRepresenting the filtering bandwidth. k is a radical of_irThe gain, omega, of the regulator can be increased_cNot only the gain of the regulator is influenced, but also the frequency selection characteristic of the resonance regulator is influenced, and the optimal parameters are comprehensively selected by combining the stability of the system.

The above resonant regulator parameter design method can be specifically analyzed by bode plot of its transfer function, as shown in fig. 13.

According to the designed quasi-proportional resonant regulator, zero-error tracking of harmonic current compensation signals is realized, and feedback compensation voltage is obtainedAnd

specifically, when the compressor operates in a dynamic working condition, the quick response capability of the feedforward compensation method can be relied on more to overcome the problems of slow convergence and long response time of the dynamic process of the feedback control compensation method; when the compressor operates in a steady-state working condition, in order to avoid the problems of parameter dependence and poor robustness of only using feedforward compensation, the high robustness of a feedback control compensation method can be relied on more, and online correction compensation is carried out on errors caused by parameter change.

And then through a reasonable design fusion strategy, feedforward compensation and feedback compensation are combined, the advantages of the two methods can be greatly combined, high response speed and high robustness are realized, and the system performance is greatly optimized.

Specifically, the fusion of the feedforward compensation and the feedback compensation is,

wherein k represents a fusion scale factor, and can be based on the differential value of the compressor acceleration command, i.e. the rotation speed commandTo perform the design.

According to the injection method for compressor noise harmonic automatic compensation designed above, in combination with a compressor variable frequency drive control system, a designed control system block diagram is shown in fig. 14, wherein, besides each basic module of FOC control, the designed control system block mainly comprises a high-frequency vibration harmonic automatic compensation control system module designed by the invention, and stable closed-loop high-frequency vibration noise suppression is realized based on speed harmonic extraction of a vibration sensor or an acceleration sensor and the design and speed extraction technology of a high-bandwidth position-free observer.

For example, as shown in fig. 15, 16 and 17, the actual effect of the injection method for compressor noise harmonic automatic compensation designed by the present invention can be verified that the injection method and the control system for compressor noise harmonic automatic compensation designed by the present invention can effectively suppress the compressor high-frequency vibration harmonic, thereby effectively improving the problem of compressor high-frequency harmonic noise.

As shown in fig. 15, with the compressor controlled by the control method of the compressor provided by the present invention, the fluctuation of the rotation speed is significantly smaller than that of the related art compressor.

As shown in fig. 16, the rotation speed fluctuation spectrum of the compressor controlled by the control method of the compressor provided by the present invention is significantly lower than that of the related art compressor. Wherein, light color is the invention.

As shown in fig. 17, compared with the control method of the compressor in the related art, the control method of the compressor provided by the present invention has a dark color, which is the OA value of the noise generated after the control of the compressor by the control method of the compressor provided by the present invention, and obviously, the corresponding frequency is due to the noise of the compressor in the related art.

Specifically, at 250 hz, the present invention is 33.78 db, the correlation technique is 50.53 db, at 315 hz, the present invention is 34.80 db, the correlation technique is 34.61 db, at 400 hz, the present invention is 36.02 db, the correlation technique is 37.87 db, at 500 hz, the present invention is 39.73 db, the correlation technique is 45.47 db, at 630 hz, the present invention is 37.67 db, the correlation technique is 38.89 db, at 800 hz, the present invention is 36.98 db, the correlation technique is 38.44 db, at 1000 hz, the present invention is 38.49 db, the correlation technique is 37.96 db, at 1250 hz, the present invention is 37.17 db, and the correlation technique is 37.15 db. It can be seen that the noise reduction effect of the present invention is superior to that of the prior art in most frequencies.

Example 6:

fig. 6 is a flowchart illustrating a control method of a compressor according to a sixth embodiment of the present invention.

As shown in fig. 6, a flow of a method for controlling a compressor according to a sixth embodiment of the present invention includes the following steps:

step 602: acquiring a rotation speed signal of a compressor in real time;

step 604: constructing a rotation speed virtual reference coordinate system and a harmonic synchronous shaft reference coordinate system of the compressor, and performing coordinate transformation on a rotating harmonic synchronous shaft of the compressor;

step 606: extracting and controlling the harmonic waves of the rotating speed of the compressor;

step 608: performing left inverse transformation on the harmonic synchronous shaft of the compressor rotation speed according to the constructed synchronous coordinate transformation system;

step 610: and carrying out harmonic injection and automatic compensation control based on a mixed strategy of feedforward compensation and feedback control.

Specifically, step 602: acquiring a rotation speed signal of the compressor in real time:

the harmonic component of the compressor rotation speed signal corresponds to the high-frequency harmonic vibration of the compressor, and the MCU (microcontroller) acquires the rotation speed signal value of the compressor in real time and preprocesses the real-time speed signal to be used as the input variable of subsequent vibration noise suppression and harmonic injection.

Step 604: constructing a rotating speed virtual reference coordinate system and a harmonic synchronous shaft reference coordinate system of the compressor, and performing coordinate transformation of a rotating harmonic synchronous shaft of the compressor:

and constructing a virtual reference coordinate system of the rotation speed of the compressor and a harmonic synchronous axis reference coordinate system according to the obtained current signal value of the rotation speed of the compressor, correspondingly obtaining a harmonic synchronous coordinate axis transformation matrix, and further performing harmonic synchronous coordinate transformation on the rotation speed of the compressor.

Step 606: extracting and controlling the harmonic waves of the rotating speed of the compressor:

after the harmonic synchronous shaft coordinate transformation, the harmonic component of the rotation speed of the compressor is changed from alternating current quantity to direct current quantity, and the extraction and adjustment strategies of direct current signals are correspondingly designed, so that the extraction and control of the rotation speed harmonic of the compressor can be well realized.

Step 608: and performing left inverse transformation of the compressor rotating speed harmonic synchronous shaft according to the constructed synchronous coordinate transformation system:

and performing inverse transformation on the coordinates of the compressor rotating speed harmonic synchronous shaft according to the obtained output value of the compressor rotating speed harmonic regulator and the constructed synchronous coordinate transformation system.

Step 610: carrying out harmonic injection and automatic compensation control based on a mixed strategy of feedforward compensation and feedback control:

and designing a mixed strategy based on feedforward compensation and feedback control to carry out harmonic injection and automatic compensation control according to the output value of the compressor rotating speed harmonic synchronous shaft coordinate inverse transformation.

In the embodiment, the invention aims at injecting the noise harmonic of the compressor for automatic compensation, and innovatively introduces the virtual reference coordinate system of the rotation speed of the compressor and the reference coordinate system of the harmonic synchronous shaft aiming at the problems of high-frequency harmonic vibration and noise of a system caused by the harmonic characteristic of the load torque of the compressor, thereby overcoming the problem that the high-frequency harmonic signal is difficult to adjust and track.

Meanwhile, the method greatly optimizes the operation complexity, and compared with other complex methods, the method can well realize the extraction and control of the harmonic wave of the rotating speed of the compressor by only calling the existing trigonometric transformation function of the variable-frequency driving system and reasonably designing the direct-current signal regulator.

In addition, the invention carries out harmonic injection and automatic compensation control based on a mixed strategy of feedforward compensation and feedback control, on one hand, the problem of slow response of a dynamic process of feedback control compensation is solved, on the other hand, the problems of parameter dependence and poor robustness of only feedforward compensation are also avoided, and through a reasonable design and fusion strategy, the advantages of the two methods can be greatly combined, the high response speed and the high robustness are realized, and the system performance is greatly optimized.

Example 7:

fig. 7 is a flowchart illustrating a control method of a compressor according to a seventh embodiment of the present invention.

As shown in fig. 7, a seventh embodiment of the present invention provides a method for controlling a compressor, which comprises the following steps:

step 702: acquiring a real-time acceleration signal of the compressor through a vibration sensor or an acceleration sensor, and further acquiring a real-time rotation speed signal of the compressor;

step 704: constructing a rotation speed virtual reference coordinate system and a harmonic synchronous shaft reference coordinate system of the compressor, and performing coordinate transformation on a rotating harmonic synchronous shaft of the compressor;

step 706: extracting and controlling the harmonic waves of the rotating speed of the compressor;

step 708: performing left inverse transformation on the harmonic synchronous shaft of the compressor rotation speed according to the constructed synchronous coordinate transformation system;

step 710: and carrying out harmonic injection and automatic compensation control based on a mixed strategy of feedforward compensation and feedback control.

In this embodiment, step 702: the real-time acceleration signal of the compressor is collected through a vibration sensor or an acceleration sensor, and then the real-time rotation speed signal of the compressor is obtained:

preprocessing data acquired by a vibration sensor or an acceleration sensor, and then obtaining a real-time rotation speed signal of the compressor through integral operation, wherein the obtained real-time rotation speed signal of the compressor is represented as follows:

where, ω denotes a revolution speed signal,represents the dc component of the slew rate signal,representing the magnitude of the nth harmonic cosine component in the fluctuating component of the slew velocity signal,representing the amplitude of the nth harmonic sinusoidal component of the fluctuating component of the slew velocity signal.

Step 704: constructing a rotating speed virtual reference coordinate system and a harmonic synchronous shaft reference coordinate system of the compressor, and performing coordinate transformation of a rotating harmonic synchronous shaft of the compressor:

in a steady-state situation of the closed-loop control system,

wherein the content of the first and second substances,representing the speed error signal.

Firstly, a speed error signal virtual reference coordinate system is constructed as follows:

and transforming the harmonic wave to an n-th harmonic wave synchronous reference coordinate system, wherein a designed transformation matrix is as follows:

multiplying the coordinate transformation formula 17 by formula 18:

step 706: extracting and controlling the harmonic waves of the rotating speed of the compressor:

the rotating speed harmonic wave of the compressor is converted into a harmonic synchronous reference coordinate, the rotating speed harmonic wave component is converted into direct current, and the direct current can be extracted by reasonably designing a filter.

Because the low-frequency performance of the butterworth low-pass filter is better, the butterworth low-pass filter is selected and designed to extract the direct-current component, as shown in fig. 9, the extracted rotational speed harmonic component is,

after the rotating speed harmonic is extracted, the rotating speed harmonic can be adjusted by reasonably designing a direct current signal adjuster; the PI regulator commonly used in engineering can realize zero steady-state error tracking on step signals, and a feedback meter is designed at the position to avoid the influence of integral saturation of the PI regulator on the control performanceThe PI regulator for calculating integral saturation resistance regulates the rotating speed harmonic wave, and the virtual current value i is obtained by closed-loop regulation_qnAnd i_dn。

Step 708: and performing left inverse transformation of the compressor rotating speed harmonic synchronous shaft according to the constructed synchronous coordinate transformation system:

according to the virtual reference coordinate system of the rotating speed of the compressor and the reference coordinate system of the harmonic synchronous shaft, the inverse transformation matrix is as follows:

the coordinate is inversely transformed and the coordinate is inversely transformed,

finally, the harmonic compensation current Iq of the closed loop based on the rotation speed reference coordinate system is obtained_comp＝i_q1And Id_comp＝i_d1。

The compressor rotation speed harmonic extraction and adjustment method based on the virtual reference coordinate system of the compressor rotation speed and the harmonic synchronous shaft reference coordinate transformation is designed into a block diagram, as shown in fig. 9 and 10.

Step 710: carrying out harmonic injection and automatic compensation control based on a mixed strategy of feedforward compensation and feedback control:

when the compressor operates in a dynamic working condition, the quick response capability of the feedforward compensation method can be relied more to solve the problems of slow convergence and long response time of the dynamic process of the feedback control compensation method; when the compressor operates in a steady-state working condition, in order to avoid the problems of parameter dependence and poor robustness of only using feedforward compensation, the high robustness of a feedback control compensation method can be relied on more, and online correction compensation is carried out on errors caused by parameter change. By reasonably designing a fusion strategy, the advantages of the two methods can be greatly combined, high response speed and high robustness are realized, and the system performance is greatly optimized.

Example 8:

fig. 8 is a flowchart illustrating a control method of a compressor according to an eighth embodiment of the present invention.

As shown in fig. 8, a flow of a method for controlling a compressor according to an eighth embodiment of the present invention includes the following steps:

step 802: acquiring a real-time rotation speed signal of the compressor through a high-bandwidth sensorless observer;

step 804: constructing a rotation speed virtual reference coordinate system and a harmonic synchronous shaft reference coordinate system of the compressor, and performing coordinate transformation on a rotating harmonic synchronous shaft of the compressor;

step 806: extracting and controlling the harmonic waves of the rotating speed of the compressor;

step 808: performing left inverse transformation on the harmonic synchronous shaft of the compressor rotation speed according to the constructed synchronous coordinate transformation system;

step 810: harmonic injection and automatic compensation control based on feedforward compensation;

step 812: harmonic injection and automatic compensation control based on feedback control;

step 814: harmonic injection and automatic compensation control based on a feedforward and feedback fusion strategy;

step 816: and controlling the variable-frequency driving of the compressor based on harmonic injection and automatic compensation control.

In this embodiment, step 802: acquiring a real-time rotation speed signal of the compressor by a high-bandwidth sensorless observer:

the high-bandwidth sensorless observer is designed to acquire a real-time rotation speed signal of the compressor, wherein the full-order observer and the improved sliding-mode observer can realize high bandwidth and high robustness, and the anti-interference capability of the system can be greatly improved by combining the design of a high-bandwidth phase-locked loop. A system block diagram is designed using a full-order phase-locked loop that incorporates high bandwidth, as shown in fig. 11.

The obtained real-time rotation speed signal of the compressor is expressed as follows,

where, ω denotes a revolution speed signal,represents the dc component of the slew rate signal,representing the magnitude of the nth harmonic cosine component in the fluctuating component of the slew velocity signal,representing the amplitude of the nth harmonic sinusoidal component of the fluctuating component of the slew velocity signal.

Step 804: constructing a rotating speed virtual reference coordinate system and a harmonic synchronous shaft reference coordinate system of the compressor, and performing coordinate transformation of a rotating harmonic synchronous shaft of the compressor:

in a steady-state situation of the closed-loop control system,

wherein the content of the first and second substances,representing the speed error signal.

Firstly, a rotation speed reference coordinate system of a speed error signal is constructed,

wherein, ω is_dq1Is a matrix of the speed error signal in a slew speed reference frame.

Transforming the harmonic wave to an n-th harmonic wave synchronous reference coordinate system, designing a transformation matrix, namely a transformation model,

wherein the content of the first and second substances,is a transformation matrix.

And (3) coordinate transformation: the formula 26 x the formula 27 is,

step 806: extracting and controlling the harmonic waves of the rotating speed of the compressor:

the rotating speed harmonic wave of the compressor is converted into a harmonic synchronous reference coordinate, the rotating speed harmonic wave component is converted into direct current, and the direct current can be extracted by reasonably designing a filter. Because the low-frequency performance of the butterworth low-pass filter is better, the butterworth low-pass filter is selected and designed to extract the direct-current component, referring to fig. 9, the extracted rotating speed harmonic component is,

after the rotating speed harmonic is extracted, the rotating speed harmonic can be adjusted by reasonably designing a direct current signal adjuster; the PI regulator commonly used in engineering can realize zero steady-state error tracking on step signals, in order to avoid the influence of integral saturation of the PI regulator on the control performance, the PI regulator with feedback calculation and integral saturation resistance is designed to regulate rotating speed harmonic waves, and the virtual current value i based on a harmonic synchronous axis reference coordinate system is obtained through closed-loop regulation_qnAnd i_dnWherein i is_qnVirtual current values for q-axis, i.e. quadrature axis_dnThe d-axis is a virtual current value of the straight axis.

Step 808: and performing left inverse transformation of the compressor rotating speed harmonic synchronous shaft according to the constructed synchronous coordinate transformation system:

according to the virtual reference coordinate system of the rotating speed of the compressor and the reference coordinate system of the harmonic synchronous shaft, the inverse transformation matrix is as follows:

the compressor rotation speed harmonic extraction and adjustment method based on the virtual reference coordinate system of the compressor rotation speed and the harmonic synchronous shaft reference coordinate transformation is designed into a block diagram, as shown in fig. 9 and 10.

The coordinate inverse transformation process is calculated as follows:

finally, the harmonic compensation current Iq of the closed loop based on the rotation speed reference coordinate system is obtained_comp＝i_q1And Id_comp＝i_d1。

Step 810: harmonic injection and automatic compensation control based on feedforward compensation:

when the compressor operates in a dynamic working condition, the quick response capability of the feedforward compensation method can be relied more to solve the problems of slow convergence and long response time of the dynamic process of the feedback control compensation method;

in conjunction with the voltage equation for the synchronous machine, the voltage feedforward compensation signal is calculated as follows:

V_d＝(r_s+r_damp)×i_d+(-ω×l_q×i_q) (the formula 33) of the reaction mixture,

V_q＝(r_s+r_damp)×i_q+(ω×l_d×i_d+ω_ε×ψ_f) (the formula 34) of the above-mentioned reaction,

mixing Iq_comp＝i_q1And Id_comp＝i_d1Substituting the equation to calculate the feedforward compensation voltage valueAndrealize the quick response of the high-frequency compensation harmonic signalThe resulting feedforward compensation voltage waveform is shown in FIG. 12.

Step 812: harmonic injection and automatic compensation control based on feedback control:

when the compressor operates in a steady-state working condition, in order to avoid the problems of parameter dependence and poor robustness of only using feedforward compensation, the high robustness of a feedback control compensation method can be relied on more, and online correction compensation is carried out on errors caused by parameter change.

Because of the harmonic compensation current Iq to be realized_comp＝i_q1And Id_comp＝i_d1The traditional PI regulator cannot well realize the static error-free tracking of the alternating current signal, and particularly the control of the high-frequency harmonic compensation current needs to specially design the alternating current signal regulator.

The resonance regulator can be derived from an internal model of a sinusoidal signal, and has the excellent characteristics of infinite gain and zero phase delay at a resonance frequency point, so that the resonance regulator can perform ideal control on specific frequency and realize the non-static tracking of any frequency.

And, apply the resonance regulator to the harmonic suppression of the high-frequency vibration of the compressor, on PI control structure, the parallel proportion resonance regulator.

The PI controller can realize the step signal non-static tracking, and the parallel proportional resonance PR regulator can realize the suppression of high-frequency vibration harmonic waves.

In practical application, in order to ensure the stability of the system, the quasi-proportional resonant regulator is designed to have a transfer function as follows:

wherein k is_pRepresents the proportional gain, k_irRepresenting the resonant gain, ω₀Representing the resonance frequency, ω_cRepresenting the filtering bandwidth. k is a radical of_irThe gain, omega, of the regulator can be increased_cNot only the gain of the regulator but also the frequency-selecting characteristic of the resonance regulator, combined with the stability of the systemAnd (4) optimal parameters.

The above resonant regulator parameter design method can be specifically analyzed by bode diagram of its transfer function, as shown in fig. 13.

According to the designed quasi-proportional resonant regulator, zero-error tracking of harmonic current compensation signals is realized, and feedback compensation voltage is obtainedAnd

step 814: harmonic injection and automatic compensation control based on a feedforward and feedback fusion strategy:

when the compressor operates in a dynamic working condition, the quick response capability of the feedforward compensation method can be relied more to solve the problems of slow convergence and long response time of the dynamic process of the feedback control compensation method; when the compressor operates in a steady-state working condition, in order to avoid the problems of parameter dependence and poor robustness of only using feedforward compensation, the high robustness of a feedback control compensation method can be relied on more, and online correction compensation is carried out on errors caused by parameter change.

And then through a reasonable design fusion strategy, feedforward compensation and feedback compensation are combined, the advantages of the two methods can be greatly combined, high response speed and high robustness are realized, and the system performance is greatly optimized.

Specifically, the fusion of the feedforward compensation and the feedback compensation is,

wherein k represents a fusion scale factor, and can be based on the differential value of the compressor acceleration command, i.e. the rotation speed commandTo perform the design.

Step 816: compressor variable frequency drive control based on harmonic injection and automatic compensation control:

according to the injection method for compressor noise harmonic automatic compensation designed above, in combination with a compressor variable frequency drive control system, a designed control system block diagram is shown in fig. 14, wherein, besides each basic module of FOC control, the designed control system block mainly comprises a high-frequency vibration harmonic automatic compensation control system module designed by the invention, and stable closed-loop high-frequency vibration noise suppression is realized based on speed harmonic extraction of a vibration sensor or an acceleration sensor and the design and speed extraction technology of a high-bandwidth position-free observer.

For example, as shown in fig. 15, 16 and 17, the actual effect of the injection method for compressor noise harmonic automatic compensation designed by the present invention can be verified that the injection method and the control system for compressor noise harmonic automatic compensation designed by the present invention can effectively suppress the compressor high-frequency vibration harmonic, thereby effectively improving the problem of compressor high-frequency harmonic noise.

Example 9:

the present invention provides a control device of a compressor, comprising: a memory having a program or instructions stored thereon; a processor configured to execute a program or instructions to implement a method of controlling a compressor as provided in any of the embodiments above.

The control device for the compressor provided by the present invention includes a memory and a processor, and when the program or the instructions in the memory is executed by the processor, the control method for the compressor according to any of the above embodiments is implemented.

Example 10:

on the basis of embodiment 9, further, the method further comprises: the sensor is connected with the processor and used for acquiring a rotation speed signal of the compressor; and/or a filter, connected with the processor, for extracting the rotational speed harmonic; and/or a regulator coupled to the processor for determining the virtual current value.

In this embodiment, the control device of the compressor further includes: at least one of the following devices: a sensor, a filter and a regulator, so as to cooperate with the processor to execute the control method of the compressor as set forth in any one of the above technical solutions.

Example 11:

the present invention provides a refrigeration apparatus comprising: a compressor; and a control device of the compressor provided in any one of the above embodiments.

The control device for a compressor according to the present invention includes the control device for a compressor according to any of the above embodiments, and therefore, all the advantages of the control device for a compressor according to any of the above embodiments are provided, which is not described herein.

Example 12:

the present invention provides a readable storage medium having stored thereon a program or instructions which, when executed by a processor, implement a control method of a compressor as provided in any of the above embodiments.

The readable storage medium provided by the present invention stores a program or instructions for implementing the method for controlling a compressor according to any of the above embodiments when the readable storage medium is executed by a processor, so that all the advantages of the method for controlling a compressor according to any of the above embodiments are achieved, and thus, the description thereof is omitted here.

In the present invention, the terms "first", "second", and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; the term "plurality" means two or more unless expressly limited otherwise. The terms "mounted," "connected," "fixed," and the like are to be construed broadly, and for example, "connected" may be a fixed connection, a removable connection, or an integral connection; "coupled" may be direct or indirect through an intermediary. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "left", "right", "front", "rear", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or unit must have a specific direction, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

In the description herein, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.