CN114234362A - Control method and device for judging aging of components and air conditioner - Google Patents

Abstract

A control method, a device and an air conditioner for judging component aging calculate the deviation of the current power factor and the normal standard in real time, automatically adjust PI parameter to correct the power factor to reach the state close to the standard, reduce the ratio of useless power, reduce the energy consumption of the air conditioner and provide good use experience for customers. In addition, when the power factor is still deviated after adjustment and enters a self-checking state when the deviation reaches a certain degree, a fault code is returned after judgment (the internal machine and the external machine are not stopped), and the fault code is displayed through the double eight display tubes of the internal machine to inform a client that the device is aged and needs to be maintained. Under the condition that the adjustment cannot be continued, the fault is returned after self-checking confirmation and is displayed through the double eight display tubes of the internal machine, a user is informed of the need of maintenance in time, the phenomenon that the power factor caused by device aging is too low to cause a large amount of waste of electric quantity is avoided, and resources are saved.

Description

Control method and device for judging aging of components and air conditioner

Technical Field

The invention relates to the technical field of air conditioner control, in particular to a control method and device for judging component aging and an air conditioner.

Background

The air conditioner power factor is the ratio of useful work to total work, the air conditioner energy consumption is lower when the ratio is closer to 1, in the air conditioner, a power factor correction circuit is called PFC circuit for short, the power factor correction circuit is used for correcting the power factor to enable the power factor to be close to 1 as much as possible, the useful work ratio is improved, when the air conditioner is used for a long time, the phenomenon of circuit component aging is avoided, and the power factor is reduced,

for a user, the user cannot actively know and detect the data, and cannot judge that the device is aged and needs to be maintained, so that the power consumption is increased when the same refrigeration (heating) effect is achieved in the process of using the air conditioner, the electricity cost of the user is increased, the use feeling of the air conditioner is poor, the energy consumption is caused, and the user is not good in use experience, therefore, the invention provides a control method and device for judging the aging of the component and the air conditioner to solve the problems in the prior art.

Disclosure of Invention

In order to overcome the above-mentioned disadvantages of the prior art, it is an object of the present invention to provide: a control method for judging aging of components is characterized by comprising the following steps:

obtaining the deviation between the current power factor and the normal standard power as a deviation value K₀；

If the deviation value K is₀If the deviation is larger than or equal to the first deviation threshold value, adjusting the PI parameter;

after the PI parameter is adjusted, obtaining the deviation K' of the adjusted power and the normal standard power;

if the deviation value K is₀If the current total power P is larger than the second deviation threshold value, the current total power P is obtained₀Inner tube temperature T₁And outer tube temperature T₂And respectively the standard deviation value P from the total power_{Sign board}Standard deviation value T of inner tube temperature_{Label 1}Standard deviation value T of +/-H and outer tube temperature_{Label 2}H, comparison;

if the total power P₀Inner tube temperature T₁And outer tube temperature T₂If the standard deviation is not within the standard deviation, the controller is judged to be aged, and a fault code is sent to the display device.

As a further improvement of the invention: when the deviation value K is₀Less than a first deviation threshold K₁When 0 is less than or equal to K₀＜K₁If so, the system defaults to normal deviation and does not adjust.

As a further improvement of the invention: if the deviation value is K₀If the PI parameter is greater than or equal to the first deviation threshold, adjusting the PI parameter includes:

contrast deviation value K₀With a first deviation threshold K₁The magnitude relation of (1) is compared with the deviation value K₀With a second deviation threshold K₂The magnitude relationship of (1);

if K₁≤K₀≤K₂And adjusting the PI parameter value.

As a further improvement of the invention: if the deviation value is K₀Greater than the second deviation threshold includes:

contrast deviation value K₀With a first deviation threshold K₁；

When K is₀Greater than K₁Time, contrast deviation value K₀Second deviation threshold K₂The magnitude relationship of (1).

As a further improvement of the invention: the adjusting the PI parameters comprises:

acquiring a deviation value K' of PI parameters to be adjusted;

adjusting and increasing PI parameter to obtain adjusted deviation value K₀₁；

Comparison K₀₁And the value of K';

if K₀₁< K', recording the adjustment parameters, comparing the deviation value K₀₁With a first deviation threshold K₁The magnitude relation of (1) is compared with the deviation value K₀₁With a second deviation threshold K₂Size relationship of；

If K₀₁Not less than K', recording adjustment parameters, adjusting again according to the adjustment reduced PI parameter, and obtaining the deviation K of the current power factor and the normal standard frequency₀₂Comparison of the deviation value K₀₂With a first deviation threshold K₁The magnitude relation of (1) is compared with the deviation value K₀₂With a second deviation threshold K₂The magnitude relationship of (1).

As a further improvement of the invention: if K₀₁< K', recording the adjustment parameters, comparing the deviation value K₀₁With a first deviation threshold K₁The magnitude relation of (1) is compared with the deviation value K₀₁With a second deviation threshold K₂The size relationship of (2) includes:

if K₁≤K₀₁≤K₂Continuing to adjust according to the PI parameter until K₀₁＜K₁。

As a further improvement of the invention: deviation value K of the current power factor from the normal standard₀The method comprises the following calculation steps:

calculating a standard power factor value N_Datum；

Calculating the actual power factor N_{Practice of}；

K₀The calculation formula of (a) is as follows:

deviation value K₀And calculating according to the actual power factor and the reference power factor.

As a further improvement of the invention: wherein the standard power factor value N_DatumThe calculation formula of (a) is as follows:

wherein

Is calculated as follows：

In the formula

The phase difference between the voltage and current waveforms is obtained for the trigonometric transformation.

As a further improvement of the invention: wherein N is_DatumAs system parameter storage, different reference power factors exist for different models and different energy efficiencies of only one model.

As a further improvement of the invention: wherein the actual power factor N_{Practice of}The calculation formula of (a) is as follows:

wherein

The calculation formula of (a) is as follows:

in the formula

Is the phase difference of the current and voltage in current use.

The invention also provides a control device for judging the aging of the components, which comprises an acquisition module, a detection module, a comparison module, a control module and a self-checking module;

the acquisition module is used for acquiring a reference power factor N of the air conditioner_Datum；

The detection module is used for detecting the current actual power factor N of the air conditioner_{Practice of}；

The comparison module is used for comparing N_DatumAnd N_{Practice of}Obtaining a deviation K₀And comparing the deviation K₀With a first deviation threshold K₁And a second deviation threshold K₂；

The control module adaptively adjusts the PI parameter according to the comparison result of the comparison module to correct the actual power factor N_{Practice of}；

And the self-checking module is used for comparing the current operating parameters with the standard parameters according to the comparison result of the comparison module and judging whether the controller component is aged or not.

The invention also provides an air conditioner for judging aging of components, which comprises a computer readable storage medium and a processor, wherein the computer readable storage medium stores a computer program, and the computer program is read by the processor and runs to realize the control method for judging aging of the components.

The invention has the beneficial effects that:

1. the invention can calculate the deviation between the current actual power factor and the reference power factor in real time, automatically adjust the PI parameter to correct the power factor to reach the state close to the standard, reduce the ratio of useless power, reduce the power consumption influence caused by the aging of air conditioner components, improve the reliability of the mainboard and provide good use experience for customers.

2. The invention still deviates after the power factor is adjusted, and enters a self-checking state when the deviation reaches a certain degree, returns a fault code after judgment (the internal machine and the external machine are not stopped), and displays the fault code through the internal machine double eight display tube to inform a client that the device is aged and needs to be maintained, thereby avoiding the large waste of electric quantity caused by the over-low power factor caused by the aging of the device and saving resources.

Drawings

Fig. 1 is a schematic step diagram of a control method for judging aging of a component according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the specific embodiments of the present invention and the accompanying drawings. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The invention will now be further described with reference to the accompanying description and examples:

the invention provides a control method for judging aging of components, which comprises the following steps:

obtaining the deviation value K of the current power factor and the normal standard₀；

If the current power factor is deviated from the normal standard by a deviation value K₀If the deviation threshold is greater than or equal to the first deviation threshold, adjusting the PI parameter;

judging the adjusted K₀Deviation from a deviation threshold;

if K₀Obtaining the current total power P when the deviation threshold is larger than the second deviation threshold₀Inner tube temperature T₁And outer tube temperature T₂And comparing with standard deviation values of total power, inner pipe temperature and outer pipe observation temperature;

if the total power P₀Inner tube temperature T₁And outer tube temperature T₂If the standard deviation is not within the standard deviation, the controller is judged to be aged, and a fault code is sent to the display device.

In a specific embodimentIn one embodiment, the deviation K of the current power factor from the normal standard₀If the sum deviation threshold is greater than or equal to the first deviation threshold, adjusting the PI parameter includes:

judging the deviation value K₀Greater than or equal to a first deviation threshold K₁And is less than or equal to a second deviation threshold K₂；

If K₁≤K₀≤K₂And adjusting the PI parameter value.

In one embodiment, the alkyl group is K₀The comparing the deviation threshold value to the second deviation threshold value includes:

comparing the deviation K of the current power factor with the normal standard₀With a first deviation threshold K₁；

When K is₀Greater than K₁Then, the deviation K of the current power factor from the normal standard is judged₀Second deviation threshold K₂。

In a specific embodiment, the adjusting the PI parameter includes:

acquiring a deviation value K' of PI parameters to be adjusted;

adjusting PI parameters, and obtaining the deviation value K of the current power factor and the normal standard after adjustment₀₁；

Comparison K₀₁And the value of K';

if K₀₁< K', recording adjustment parameters, comparing the current power factor with the normal standard deviation K₀With a first deviation threshold K₁And a second deviation threshold K₂；

If K₀Not less than K', recording adjustment parameters, adjusting PI parameters again according to the opposite scheme of adjusting PI parameters, and obtaining the deviation K of the current power factor and the normal standard frequency₀₂Comparison of the deviation value K₀₂With a first deviation threshold K₁The magnitude relation of (1) is compared with the deviation value K₀₂With a second deviation threshold K₂The magnitude relationship of (1).

In one embodiment, the alkyl group is K₀₁< K', recording the adjustment parameters, comparing the deviation value K₀₁With a first deviation threshold K₁The relationship between the size of the first and the second,contrast deviation value K₀₁With a second deviation threshold K₂The size relationship of (2) includes:

if K₁≤K₀≤K₂Continuing to adjust according to the PI parameter until K₀＜K₁。

In one embodiment, the deviation K of the current power factor from the normal standard₀The method comprises the following calculation steps:

calculating a standard power factor value N_Datum；

Calculating the actual power factor N_{Practice of}；

K₀The calculation formula of (a) is as follows:

deviation value K₀And calculating according to the actual power factor and the reference power factor.

In one embodiment, the standard power factor value N is_DatumThe calculation formula of (a) is as follows:

wherein

The calculation formula of (a) is as follows:

in the formula

The phase difference between the voltage and current waveforms is obtained for the trigonometric transformation.

In one embodiment, U, I is a time-varying trigonometric function calculated as follows:

U_datum＝U_{Is provided with}*Sin(ωt+θ_U)

I_Datum＝I_{Is provided with}*Sin(ωt+θ_I)

In the formula of U_{Is provided with}And I_{Is provided with}Collecting the current and the voltage once every 1ms, and obtaining the change of the current and the voltage along with time through MATLAB simulation fitting; the power factor is defined as the variation of current with voltage, and theta can be set_UIs 0.

In one embodiment, where the actual power factor N is_{Practice of}The calculation formula of (a) is as follows:

wherein

The calculation formula of (a) is as follows:

in the formula

Is the phase difference of the current and voltage in current use.

In one embodiment, a standard power factor value N is calculated_DatumThe method comprises the following steps:

obtaining a reference power factor N of an air conditioner_DatumCalculating the current actual power factor N of the air conditioner_{Practice of}Comparison of N_DatumAnd N_{Practice of}Obtaining a deviation K₀；

Setting a first deviation threshold K₁And a second deviation threshold K₂Comparison K₀And K₁、K₂Adaptively adjusting PI parameter to make actual power factor N_{Practice of}And a reference power factor N_DatumMost closely, the parameters at this moment are recorded and stored in the system to replace the original parametersStoring and using the data;

when the adaptive adjustment PI parameter can not correct the actual power factor N_{Practice of}And the system enters a self-checking state in the current mode, acquires the parameter comparison standard parameter in the self-checking state, judges and sends the fault code to display.

The invention can calculate the deviation between the current actual power factor and the reference power factor in real time, automatically adjust the PI parameter to correct the power factor to reach the state close to the standard, reduce the ratio of idle work and provide good use experience for customers. And the device still deviates after the power factor is adjusted, enters a self-checking state when the power factor cannot be corrected, returns a fault code after being judged, displays the fault code to inform a client that the device is aged and needs to be maintained, avoids a large amount of waste of electric quantity caused by too low power factor caused by aging of the device, and saves resources.

As shown in fig. 1, the present invention provides a control method for determining aging of a component, including the following steps:

measuring a standard power factor value N according to the model and the exit area (different area voltages and frequencies)_DatumSetting the inner ring at 20 deg.c, the inner wind shield of the inner fan, the wind shield of the outer fan, the compressor frequency V and the electronic expansion valve step S as the standard state of self-checking mode, and maintaining the total power P in stable operation state in the said environment_{Sign board}Inner pipe temperature T_{Label 1}Temperature T of outer tube_{Label 2}Collecting sampling voltage and current data under commercial power, if the power frequency is 50HZ, the voltage is 220V, each period is 20ms, 20 data, U, are collected simultaneously by the voltage and the current₁+U₂+U₃…+U₂₀，I₁+I₂+I₃…+I₂₀The current and voltage changes along with time are obtained by MATLAB simulation fitting after the acquisition is carried out once every 1ms, and the power factor definition is the change of the current along with the voltage, so that the power factor can be set

θ_UIs 0:

U_datum＝U_{Is provided with}*Sin(ωt+θ_U)

I_Datum＝I_{Is provided with}*Sin(ωt+θ_I)

Eliminating respective existence of U and existence of I to obtain U, I time-varying trigonometric functions, and obtaining phase difference between voltage and current waveforms by trigonometric transformation

And finally, calculating a reference power factor Nreference according to the deviation value between the current and the voltage:

N_datumAs system parameter storage, different reference power factors exist for different models and different energy efficiencies of only one model.

Keeping the same experimental environment, adjusting the inner ring temperature T outer ring (40 ℃ -0 ℃) by keeping the inner fan middle fan, the outer fan middle wind gear, the compressor frequency V and the electronic expansion valve step number S, then obtaining the total power P ' of the stable state under different outer rings, and the inner pipe temperature T ' under different outer rings '₁Outer tube temperature T'₂And finally, obtaining the compensation value of each ring temperature and the standard temperature:

P_{supplement device}=P′-P_{Sign board}

T_{Supplement 1}＝T′₁T_{Label 1}

T_{Supplement 2}=T′₂-T_{Label 2}

In the actual use process of the air conditioner, the phase difference of the current and the voltage in the current use can be obtained in the same test mode

Obtaining an actual power factor Nactual according to actual phase difference conversion:

finally, calculating the actual power factor deviation value K according to the actual power factor and the reference power factor₀：

When the system detects the deviation value K₀Less than a first deviation threshold K₁When 0 is not more than K₀＜K₁The system defaults to normal deviation and does not need to adjust. When the system detects the deviation value K₀Greater than or equal to a first deviation threshold K₁And is less than or equal to a second deviation threshold K₂，K₁≤K₀≤K₂The system considers that the power factor is biased and needs to be adjusted, and then the system records the current bias value K₀₁Adjusting PI parameter value according to set rule, testing adjusted deviation value K again₀。

Comparison K₀₁And K';

if K₀₁If K 'is less than K', it proves that the PI parameter is effectively adjusted according to the current rule, the parameter is stored, and K is compared again₀₁，K₁. If K₁≤K₀₁≤K₂The system continues to adjust according to the current scheme until K₀₁＜K₁。

If K₀₁If not less than K', the adjustment of PI parameter according to current rule has no effect, and the current deviation value K is recorded₀₂Then, the PI parameter test K is adjusted according to a rule reverse scheme₀₂Continue to compare K₀₂And K'.

The invention can calculate the deviation between the current actual power factor and the reference power factor in real time, automatically adjust the PI parameter to correct the power factor to reach the state close to the standard, reduce the ratio of useless power, reduce the power consumption influence caused by the aging of air conditioner components, improve the reliability of the mainboard and provide good use experience for customers.

When detecting the current power factor deviation value K₀₁≥K₂And then judging that the PI parameter is not changed, enabling the system to enter a self-checking mode, namely a middle wind shield of an inner fan, a middle wind shield of an outer fan, the frequency V of a compressor, the step number S of an electronic expansion valve, wherein V and S are consistent with V and S, and testing the current total power P_{Practice of}Temperature T of inner and outer tubes_{Practice 1}，T_{Practice 2}：

Adding compensation values of data at the current temperature, comparing the total power with the standard power, the temperature of the inner pipe and the outer pipe and the temperature of the standard inner pipe and the standard outer pipe, and judging according to the following fault rules:

if the data simultaneously satisfy the following conditions:

(T_{label 1}-H)≤(T_{Practice 1}+T_{Supplement 1})≤(T_{Label 1}+H)

(T_{Label 2}-M)≤(T_{Practice 2}+T_{Supplement 2})≤(T_{Label 2}+M)

P_{Sign board}＜(P_{Practice of}+P_{Supplement device}))

M and H are interval constants.

And judging that the refrigerant is sufficient in the current state, the main load is normal, the idle work is increased, the power factor is reduced, judging that the components of the controller are aged, and sending an aging fault code of the components to the double eight display tubes of the internal machine for displaying.

If the condition is not met, judging that the problem is other problem, and sending fault codes of other problems to the double eight display tubes of the internal machine for display.

The invention still deviates after the power factor is adjusted, and enters a self-checking state when the deviation reaches a certain degree, returns a fault code after judgment (the internal machine and the external machine are not stopped), and displays the fault code through the internal machine double eight display tube to inform a client that the device is aged and needs to be maintained, thereby avoiding the large waste of electric quantity caused by the over-low power factor caused by the aging of the device and saving resources.

The invention also provides a control device for judging the aging of the components, which comprises an acquisition module, a detection module, a comparison module, a control module and a self-checking module;

the collecting mouldThe block is used for collecting the reference power factor N of the air conditioner_Datum；

The detection module is used for detecting the current actual power factor N of the air conditioner_{Practice of}；

The comparison module is used for comparing N_DatumAnd N_{Practice of}Obtaining a deviation K₀And comparing the deviation K₀With a first deviation threshold K₁And a second deviation threshold K₂；

The control module adaptively adjusts the PI parameter according to the comparison result of the comparison module to correct the actual power factor N_{Practice of}；

And the self-checking module compares the current operating parameters with the standard parameters according to the comparison result of the comparison module and judges whether the controller component is aged or not.

The invention also provides an air conditioner for judging aging of components, which comprises a computer readable storage medium and a processor, wherein the computer readable storage medium stores a computer program, and the computer program is read by the processor and runs to realize the control method for judging aging of the components.

The main functions of the invention are as follows: the invention can adaptively correct the power factor deviation, improve the reliability of the mainboard, reduce the power consumption influence caused by the aging of air conditioner components and bring good experience to customers. Under the condition that the adjustment cannot be continued, the fault is returned after self-checking confirmation and is displayed through the double eight display tubes of the internal machine, a user is informed of the need of maintenance in time, the phenomenon that the power factor caused by device aging is too low to cause a large amount of waste of electric quantity is avoided, and resources are saved.

The functions described herein may be implemented in hardware, software executed by a processor, firmware, or any combination thereof. If implemented in software executed by a processor, the functions may be stored on or transmitted over as one or more instructions or code on a computer-readable medium. Other examples and implementations are within the scope and spirit of the invention and the following claims. For example, due to the nature of software, the functions described above may be implemented using software executed by a processor, hardware, firmware, hardwired, or a combination of any of these. In addition, each functional unit may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit.

In the embodiments provided in the present application, it should be understood that the disclosed technology can be implemented in other ways. The above-described embodiments of the apparatus are merely illustrative, and for example, the division of the units may be a logical division, and in actual implementation, there may be another division, for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection through some interfaces, units or modules, and may be in an electrical or other form.

The units described as separate parts may or may not be physically separate, and the parts serving as the control device may or may not be physical units, may be located in one place, or may be distributed on a plurality of units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

The integrated unit, if implemented in the form of a software functional unit and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a removable hard disk, a magnetic or optical disk, and other various media capable of storing program codes.

The above description is only an example of the present invention, and is not intended to limit the present invention, and it is obvious to those skilled in the art that various modifications and variations can be made in the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (10)

1. A control method for judging aging of components is characterized by comprising the following steps:

obtaining the deviation between the current power factor and the normal standard power as a deviation value K₀；

If the deviation value K is₀If the deviation is larger than or equal to the first deviation threshold value, adjusting the PI parameter;

after the PI parameter is adjusted, obtaining the deviation K' of the adjusted power and the normal standard power;

if the deviation value K is₀If the current total power P is larger than the second deviation threshold value, the current total power P is obtained₀Inner tube temperature T₁And outer tube temperature T₂And respectively the standard deviation value P from the total power_{Sign board}Standard deviation value T of inner tube temperature_{Label 1}Standard deviation value T of +/-H and outer tube temperature_{Label 2}H, comparison;

if the total power P₀Inner tube temperature T₁And outer tube temperature T₂If the standard deviation is not within the standard deviation, the controller is judged to be aged, and a fault code is sent to the display device.

2. The control method for judging aging of components according to claim 1, wherein if the deviation value K is smaller than the predetermined value₀If the PI parameter is greater than or equal to the first deviation threshold, adjusting the PI parameter includes:

contrast deviation value K₀With a first deviation threshold K₁The magnitude relation of (1) is compared with the deviation value K₀With a second deviation threshold K₂The magnitude relationship of (1);

if K₁≤K₀≤K₂And adjusting the PI parameter value.

3. The control method for judging aging of components according to claim 2, wherein if the deviation value K is smaller than the predetermined value₀Greater than the second deviation threshold includes:

contrast deviation value K₀With a first deviation threshold K₁；

When K is₀Greater than K₁Time, contrast deviation value K₀Second deviation threshold K₂The magnitude relationship of (1).

4. The control method for judging aging of components and parts according to claim 2, wherein the adjusting of the PI parameters comprises:

acquiring a deviation value K' of PI parameters to be adjusted;

adjusting and increasing PI parameter to obtain adjusted deviation value K₀₁；

Comparison K₀₁And the value of K';

if K₀₁< K', recording the adjustment parameters, comparing the deviation value K₀₁With a first deviation threshold K₁The magnitude relation of (1) is compared with the deviation value K₀₁With a second deviation threshold K₂The magnitude relationship of (1);

if K₀₁Not less than K', recording adjustment parameters, adjusting again according to the adjustment reduced PI parameter, and obtaining the deviation K of the current power factor and the normal standard frequency₀₂Comparison of the deviation value K₀₂With a first deviation threshold K₁The magnitude relation of (1) is compared with the deviation value K₀₂With a second deviation threshold K₂The magnitude relationship of (1).

5. The control method for judging component aging according to claim 4, wherein the number K is₀₁< K', recording the adjustment parameters, comparing the deviation value K₀₁With a first deviation threshold K₁The magnitude relation of (1) is compared with the deviation value K₀₁With a second deviation threshold K₂The size relationship of (2) includes:

if K₁≤K₀₁≤K₂Continuing to adjust according to the PI parameter until K₀₁＜K₁。

6. The control method for judging aging of components and parts as claimed in claim 1, wherein the deviation K of the current power factor from the normal standard is₀The method comprises the following calculation steps:

calculating a standard power factor value N_Datum；

Calculating the actual power factor N_{Practice of}；

K₀The calculation formula of (a) is as follows:

deviation value K₀And calculating according to the actual power factor and the reference power factor.

7. The control method for judging aging of components according to claim 6, wherein the standard power factor value N_DatumThe calculation formula of (a) is as follows:

wherein

The calculation formula of (a) is as follows:

in the formula

The phase difference between the voltage and current waveforms is obtained for the trigonometric transformation.

8. A arbiter as defined in claim 6Method for controlling the ageing of a device, wherein the actual power factor N_{Practice of}The calculation formula of (a) is as follows:

wherein

The calculation formula of (a) is as follows:

in the formula

Is the phase difference of the current and voltage in current use.

9. The utility model provides a judge controlling means that components and parts are ageing which characterized in that: the device comprises an acquisition module, a detection module, a comparison module, a control module and a self-checking module;

the acquisition module is used for acquiring a reference power factor N of the air conditioner_Datum；

The detection module is used for detecting the current actual power factor N of the air conditioner_{Practice of}；

The comparison module is used for comparing N_DatumAnd N_{Practice of}Obtaining a deviation K₀And comparing the deviation K₀With a first deviation threshold K₁And a second deviation threshold K₂；

The control module adaptively adjusts the PI parameter according to the comparison result of the comparison module to correct the actual power factor N_{Practice of}；

And the self-checking module is used for comparing the current operating parameters with the standard parameters according to the comparison result of the comparison module and judging whether the controller component is aged or not.

10. The utility model provides a judge ageing air conditioner of components and parts which characterized in that: comprising a computer-readable storage medium and a processor, in which a computer program is stored, which, when read and executed by the processor, implements a method of controlling a component degradation determination according to any one of claims 1 to 8.

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