CN110873394A - Air conditioner and self-cleaning control method thereof - Google Patents

Abstract

The invention discloses an air conditioner and a self-cleaning control method thereof, and belongs to the technical field of air conditioners. The control method comprises the following steps: in response to the trigger condition meeting the self-cleaning mode, estimating the frost quantity of the air conditioner in the frost process of the self-cleaning mode; and if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing the self-cleaning mode. According to the control method for self-cleaning of the air conditioner, provided by the invention, the frost quantity of the air conditioner in the frost process of the self-cleaning mode is estimated, and the condensation mode capable of increasing the condensation quantity of water vapor is executed in advance under the condition that the frost quantity does not meet the preset frost quantity requirement, so that sufficient condensed water can be condensed into frost in the subsequent frost condensation stage of the self-cleaning mode, and the self-cleaning efficiency of the air conditioner is ensured.

Description

Air conditioner and self-cleaning control method thereof

Technical Field

The invention relates to the technical field of air conditioners, in particular to an air conditioner and a self-cleaning control method thereof.

Background

When the air conditioner operates in a cooling or heating mode, air in an external environment enters the inside of the machine body along the air inlet, and is blown into the external environment again through the air outlet after heat exchange of the heat exchange plate, in the process, impurities such as dust, large particles and the like mixed in the air can enter the indoor machine along with air inlet flow, although a dustproof filter screen arranged at the air inlet of the air conditioner can filter most of the dust and the particles, a small amount of tiny dust can not be completely blocked and filtered, and the dust can be gradually deposited and attached to the surface of the heat exchange plate along with long-term use of the air conditioner.

Generally, a cleaning method of an air conditioner in the prior art mainly includes two modes of manual cleaning and self cleaning of the air conditioner, wherein the self cleaning mode of the air conditioner is mainly divided into a frost condensation stage and a defrosting stage, wherein, taking an indoor unit of a split air conditioner as an example, in the frost condensation stage, the air conditioner firstly operates in a refrigeration mode, and increases refrigerant output quantity to an indoor heat exchanger, so that moisture in indoor air can be gradually condensed into a frost or ice layer on the outer surface of the heat exchanger, and in the process, the condensed frost layer can be combined with dust, so that the dust is peeled off from the outer surface of the heat exchanger; then, in the defrosting stage, the air conditioner operates in a heating mode to melt the frost layer condensed on the outer surface of the heat exchanger, and dust can be collected into the water receiving tray along with the melted water flow, so that the aim of self-cleaning the indoor unit of the air conditioner can be fulfilled; similarly, when the outdoor unit of the split air conditioner is cleaned, the self-cleaning operation is performed according to a reverse flow to that of the indoor unit, that is, the air conditioner operates the heating mode (the temperature of the outdoor unit is reduced, and the frost is condensed) and then operates the cooling mode (the temperature of the outdoor unit is increased, and the frost is melted).

In the above-mentioned self-cleaning method of the air conditioner, the source of the water vapor required for condensing the frost in the frost condensing stage is the water vapor in the air of the external environment where the air conditioner is located, and under some working conditions (e.g. in winter) or under the condition of low water vapor content in the external environment, the condensation amount of the frost in the frost condensing stage of the self-cleaning mode executed by the air conditioner according to the set program is insufficient, which affects the actual cleaning effect of the air conditioner.

Disclosure of Invention

The invention provides an air conditioner and a self-cleaning control method thereof, aiming at solving the problem of insufficient frost quantity in a self-cleaning frost-condensation stage of the air conditioner caused by the fact that humidity does not meet the requirement. The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview and is intended to neither identify key/critical elements nor delineate the scope of such embodiments. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is presented later.

According to a first aspect of the present invention, there is provided a control method of self-cleaning of an air conditioner, comprising:

in response to the trigger condition meeting the self-cleaning mode, estimating the frost quantity of the air conditioner in the frost process of the self-cleaning mode;

and if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing the self-cleaning mode.

In an alternative embodiment, estimating the amount of frost in the condensation process of the air conditioner in the self-cleaning mode includes:

acquiring environmental parameters of an environment where an air conditioner is located and setting parameters of a self-cleaning mode;

and determining the frost quantity of the air conditioner in the self-cleaning mode in the frost condensation flow based on the environmental parameters and the set parameters of the self-cleaning mode.

In an alternative embodiment, the environmental parameters include: indoor temperature and indoor humidity;

the setting of the parameters comprises: the target frost-forming temperature and the target frost-forming time of the frost-forming process.

In an alternative embodiment, the condensation mode comprises:

the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are improved, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

In an optional embodiment, the control method further comprises:

and if the frost condensation amount meets the preset frost condensation amount requirement, controlling the air conditioner to execute a self-cleaning mode.

According to the second aspect of the present invention, there is also provided an air conditioner comprising a machine body and a controller, wherein the controller is configured to:

in response to the trigger condition meeting the self-cleaning mode, estimating the frost quantity of the air conditioner in the frost process of the self-cleaning mode;

and if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing the self-cleaning mode.

In an alternative embodiment, the controller is specifically configured to:

acquiring environmental parameters of an environment where an air conditioner is located and setting parameters of a self-cleaning mode;

and determining the frost quantity of the air conditioner in the self-cleaning mode in the frost condensation flow based on the environmental parameters and the set parameters of the self-cleaning mode.

In an alternative embodiment, the environmental parameters include: indoor temperature and indoor humidity;

the setting of the parameters comprises: the target frost-forming temperature and the target frost-forming time of the frost-forming process.

In an alternative embodiment, the condensation mode comprises:

the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are improved, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

In an alternative embodiment, the controller is further configured to:

and if the frost condensation amount meets the preset frost condensation amount requirement, controlling the air conditioner to execute a self-cleaning mode.

The invention adopts the technical scheme and has the beneficial effects that:

according to the control method for self-cleaning of the air conditioner, provided by the invention, the frost quantity of the air conditioner in the frost process of the self-cleaning mode is estimated, and the condensation mode capable of increasing the condensation quantity of water vapor is executed in advance under the condition that the frost quantity does not meet the preset frost quantity requirement, so that sufficient condensed water can be condensed into frost in the subsequent frost condensation stage of the self-cleaning mode, and the self-cleaning efficiency of the air conditioner is ensured.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

Drawings

Fig. 1 is a first flowchart illustrating a self-cleaning control method of an air conditioner according to an exemplary embodiment of the present invention;

FIG. 2 is a second flowchart illustrating a self-cleaning control method of an air conditioner according to another exemplary embodiment of the present invention;

fig. 3 is a third flowchart illustrating a control method of self-cleaning of an air conditioner according to another exemplary embodiment of the present invention;

fig. 4 is a fourth flowchart illustrating a control method of self-cleaning of an air conditioner according to another exemplary embodiment of the present invention.

Detailed Description

The following description and the drawings sufficiently illustrate specific embodiments of the invention to enable those skilled in the art to practice them. Other embodiments may incorporate structural, logical, electrical, process, and other changes. The examples merely typify possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others. The scope of embodiments of the invention encompasses the full ambit of the claims, as well as all available equivalents of the claims. Embodiments may be referred to herein, individually or collectively, by the term "invention" merely for convenience and without intending to voluntarily limit the scope of this application to any single invention or inventive concept if more than one is in fact disclosed. Herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method or apparatus that comprises the element. The embodiments are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. As for the methods, products and the like disclosed by the embodiments, the description is simple because the methods correspond to the method parts disclosed by the embodiments, and the related parts can be referred to the method parts for description.

The air conditioner comprises an indoor heat exchanger, an outdoor heat exchanger, a throttling device and a compressor, wherein the indoor heat exchanger, the outdoor heat exchanger, the throttling device and the compressor are connected through refrigerant pipelines to form a refrigerant circulation loop, and refrigerant flows along the set flow directions of different operation modes through the refrigerant circulation loop, so that the functions of heating, refrigerating, self-cleaning and the like are realized.

In an embodiment, the operation modes of the air conditioner comprise a refrigeration mode, a heating mode and a self-cleaning mode, wherein the refrigeration mode is generally applied to a high-temperature working condition in summer and used for reducing the indoor environment temperature; the heating mode is generally applied to the low-temperature working condition in winter and is used for increasing the indoor environment temperature; the self-cleaning mode is generally a user's self-selection function mode or self-starting function, and can automatically clean the heat exchanger under the condition that dust and dirt are accumulated on the heat exchanger.

When the air conditioner operates in a refrigeration mode, the set refrigerant flow direction is that high-temperature refrigerant discharged by the compressor firstly flows through the outdoor heat exchanger to exchange heat with the outdoor environment, then flows into the indoor heat exchanger to exchange heat with the indoor environment, and finally the refrigerant flows back to the compressor to be compressed again; in the process, the refrigerant flowing through the outdoor heat exchanger emits heat to the outdoor environment, the refrigerant flowing through the indoor heat exchanger absorbs heat from the indoor environment, and the indoor heat can be continuously discharged to the outdoor environment through the circulating flow of the refrigerant in the refrigerant circulating loop, so that the refrigeration purpose of reducing the temperature of the indoor environment can be achieved.

The set refrigerant flow direction during the heating mode refers to that the high-temperature refrigerant discharged by the compressor firstly flows through the indoor heat exchanger to exchange heat with the outdoor environment, then flows into the outdoor heat exchanger to exchange heat with the indoor environment, and finally flows back to the compressor to be compressed again; in the process, the refrigerant flowing through the indoor heat exchanger emits heat to the indoor environment, the refrigerant flowing through the outdoor heat exchanger absorbs heat from the outdoor environment, and the outdoor heat can be continuously released to the indoor environment through the circulating flow of the refrigerant in the refrigerant circulating loop, so that the heating purpose of improving the temperature of the indoor environment can be achieved.

Generally, since the indoor heat exchanger is a heat exchanger directly used for changing an indoor temperature environment, the degree of cleanliness of the indoor heat exchanger may directly affect the use experience of a user. Therefore, the main application of the self-cleaning mode of the air conditioner of the present invention is an indoor heat exchanger. Of course, the self-cleaning mode of the air conditioner of the present invention may also be used to clean the outdoor heat exchanger, so in a specific embodiment, when the air conditioner of the present invention performs a cleaning process, only one of the indoor heat exchanger and the outdoor heat exchanger may be cleaned, or both of the indoor heat exchanger and the outdoor heat exchanger may be cleaned. It should be understood that if the existing air conditioner uses the same or similar control method as the present invention to perform the self-cleaning operation of the indoor and outdoor heat exchangers, it should be also included in the protection scope of the present invention.

Taking the self-cleaning process of the indoor heat exchanger as an example, the working process of the air conditioner in the self-cleaning operation mode mainly comprises two stages which are sequentially carried out: the defrosting stage of the indoor heat exchanger and the defrosting stage of the indoor heat exchanger. In the defrosting stage of the indoor heat exchanger, ice can be condensed and frosted on the indoor heat exchanger of the indoor unit; in the defrosting stage of the indoor heat exchanger, the condensed frost of the indoor heat exchanger in the previous defrosting stage is melted, impurities such as dust and the like can be separated from the indoor heat exchanger along with the melted condensed water, and the cleaning treatment of the indoor heat exchanger is completed.

Specifically, in the operation process of the air conditioner in the refrigeration mode, if the power of the compressor is improved and the output quantity of the refrigerant is increased, the low-temperature refrigerant quantity input into the indoor unit can be increased, the redundant refrigerant cold quantity can reduce the internal temperature of the indoor unit, and when the internal temperature of the indoor unit is lower than the frost condensation critical temperature value (such as 0 ℃), water vapor in air flowing through the indoor unit can be gradually condensed into frost in the indoor unit.

In the heating mode operation process of the air conditioner, the high-temperature refrigerant firstly flows through the indoor heat exchanger, so that the cold energy of the high-temperature refrigerant can increase the internal temperature of the indoor unit, and when the internal temperature of the indoor unit is higher than the frost condensation critical temperature value (such as 0 ℃), the frost condensed in the indoor unit can be gradually melted and dripped, so that the frost can be separated from the indoor heat exchanger. The control method of the invention is that under the condition that the flow direction of the refrigerant limited by the heating mode of the air conditioner is controlled at the defrosting stage of the indoor heat exchanger, the defrosting operation of the indoor heat exchanger is realized by adjusting the operation parameters of components such as a compressor, a fan, a throttling device and the like.

Similarly, when the outdoor heat exchanger is self-cleaned, when the air conditioner flows in the refrigerant flow direction defined by the heating mode, the refrigerant flowing out of the indoor heat exchanger is a medium-temperature refrigerant and the refrigerant flowing into the outdoor heat exchanger after being throttled by the throttling device is a low-temperature refrigerant, so that the low-temperature refrigerant can reduce the temperature of the outdoor heat exchanger, and when the temperature inside the outdoor unit is lower than the frost condensation critical temperature value (such as 0 ℃), water vapor in the air flowing through the outdoor unit can be gradually condensed into frost inside the outdoor unit. Therefore, the ice and the frost of the outdoor heat exchanger are realized while the ice and the frost of the indoor heat exchanger are melted.

And then, the indoor heat exchanger finishes melting ice and defrosting in the defrosting stage of the indoor heat exchanger, self-cleaning of the indoor heat exchanger is finished, the air conditioner enters the defrosting stage of the outdoor heat exchanger, at the moment, the air conditioner is controlled to flow in the direction of the refrigerant flow defined by the refrigeration mode again, the flow direction of the high-temperature refrigerant discharged by the compressor is changed, and the high-temperature refrigerant flows through the outdoor heat exchanger, so that the ice and defrosting of the outdoor heat exchanger can be realized by utilizing the heat of the high-temperature refrigerant, and the self-cleaning process of the outdoor heat exchanger.

In the self-cleaning process, each stage may be performed according to a preset duration, for example, the indoor heat exchanger frost condensation stage may be preset to 10 min, and the indoor heat exchanger defrosting stage may be preset to 12 min, so that after the air conditioner enters the indoor heat exchanger frost condensation stage of the self-cleaning mode, the air conditioner may start timing, when 10 min is reached, the air conditioner enters the indoor heat exchanger defrosting stage, and continues to 12 min in the indoor heat exchanger defrosting stage, it may be determined that the self-cleaning of the indoor unit is completed, and the air conditioner exits the self-cleaning mode.

In the process that the air conditioner is switched to the flow direction limited by the cooling mode or the heating mode, the opening/closing and the rotating speed of the fans of the indoor unit and the outdoor unit also need to be correspondingly controlled, for example, the indoor fan in the frost condensation stage of the indoor heat exchanger is generally closed or operated at a low speed, and the outdoor fan is opened for operation; and in the defrosting stage of the indoor heat exchanger, the indoor fan is started to operate, and outdoor air is closed or operated at a low speed. Therefore, the indoor unit and the outdoor unit are respectively timed in the self-cleaning process, and when the preset time is reached, the components such as a fan of the air conditioner and the like are controlled to carry out corresponding state switching.

In the above-mentioned self-cleaning process of the air conditioner, the source of the water vapor required for condensing the frost in the frost condensing stage is the water vapor in the air of the external environment where the air conditioner is located, and under some working conditions (e.g. in winter) or under the condition of low water vapor content in the external environment, the amount of the frost condensed in the frost condensing stage of the self-cleaning mode executed by the air conditioner according to the set program is insufficient, which affects the actual cleaning effect of the air conditioner.

Therefore, in view of the above possible problems, the present invention provides an air conditioner and a self-cleaning control method thereof, and aims to solve the problem of insufficient frost formation amount in a self-cleaning frost formation stage of the air conditioner caused by humidity not meeting requirements.

Fig. 1 is a first flowchart illustrating a control method for self-cleaning of an air conditioner according to an exemplary embodiment of the present invention.

As shown in fig. 1, the present invention provides a control method for self-cleaning of an air conditioner, which mainly comprises the following steps:

s101, responding to a trigger condition meeting a self-cleaning mode, and estimating the frost quantity of the air conditioner in a frost process of the self-cleaning mode;

optionally, the triggering condition of the self-cleaning mode is that the accumulated running time of the air conditioner reaches a set accumulated time threshold; or, the self-cleaning triggering condition is that a control instruction for starting self-cleaning input by a user is received; the present invention is not limited thereto.

In step S101, estimating a frost amount of the air conditioner in a condensation flow of the self-cleaning mode includes: acquiring environmental parameters of an environment where an air conditioner is located and setting parameters of a self-cleaning mode; and determining the frost quantity of the air conditioner in the self-cleaning mode in the frost condensation flow based on the environmental parameters and the set parameters of the self-cleaning mode.

Optionally, the environmental parameters include, but are not limited to, indoor temperature and indoor humidity; the setting parameters include, but are not limited to, a target frost temperature and a frost forming time of the frost forming process.

Before the air conditioner leaves a factory, the final frost quantity of the frost process of the air conditioner can be measured in an experiment mode and other modes when the air conditioner is in different environmental conditions (differences exist among environmental parameters) and the self-cleaning mode is operated according to different set parameters; for example, the target frost formation temperature is a1, the frost formation time is B1, and the final frost formation amount of the frost formation process under the humidity conditions of an indoor temperature of 28 ℃ and relative humidities of 40%, 60%, 80%, respectively, can be measured, wherein in the set of experimental data, the indoor temperature, the target frost formation temperature, and the frost formation time are fixed values, the relative humidity is an independent variable, and the final frost formation amount is a dependent variable corresponding to the relative humidity, because the frost formation amounts corresponding to a plurality of different relative humidities can be obtained in a set of combinations of the indoor temperature, the target frost formation temperature, and the frost formation time; similarly, through further experiments, the corresponding frost condensation amount is respectively measured under the condition that the indoor temperature is taken as an independent variable, or the target condensation temperature is taken as an independent variable, or the frost condensation time is taken as an independent variable; and finally, summarizing the experimental data to obtain a frost condensation amount set of a frost condensation flow associated with the acquired environmental parameters of the environment where the air conditioner is located and the set parameters of the self-cleaning mode.

The combination of the environmental parameters of the environment where the air conditioner is located and the setting parameters of the self-cleaning mode and the related frost amount set component form a corresponding relation and are prestored in the controller of the air conditioner; in this way, after the trigger condition of the self-cleaning mode is met, the frost quantity of the air conditioner in the self-cleaning mode in the frost process can be determined through the environmental parameters and the setting parameters of the self-cleaning mode.

And S102, if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing the self-cleaning mode.

In this embodiment, if the amount of frost does not meet the preset requirement of the amount of frost, the problem of poor self-cleaning effect caused by too little condensed frost may occur in the flow of frost in the self-cleaning mode, therefore, the present application controls the air conditioner to execute the condensation mode before executing the self-cleaning mode to increase the amount of condensed water condensed on the heat exchanger to be cleaned, so that the condensed water condensed in advance can be converted into solid frost in the condensation stage of the self-cleaning mode, and thus, the amount of water vapor required for condensing part of frost lacking in the flow of frost in a low humidity condition can be compensated by executing the condensation mode.

Specifically, the condensation mode executed by the application can be a dehumidification mode of the existing air conditioner; alternatively, the condensation mode comprises: the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are improved, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

Here, the air conditioner also presets an association relationship between the condensation temperature and the indoor humidity of the indoor environment, such as a dew point temperature curve relation chart, where in the association relationship, different indoor humidities correspond to a determined condensation temperature, and when the temperature is at the condensation temperature associated with the current indoor humidity, the vapor in the air is converted into a liquid state from a gaseous state; therefore, the obtained indoor humidity can be further used for determining the current condensation temperature according to the correlation, and the current condensation temperature is used as the target condensation temperature of the air conditioner for executing the condensation mode.

Or the target condensation temperature is a fixed temperature value preset by the air conditioner.

Optionally, the control flow of the present invention further includes: and determining the operation time of the condensation mode based on the frost quantity determined in the step S101 and a preset frost quantity requirement. Here, the difference in the amount of frost may be calculated based on the preset frost amount requirement and the amount of frost, and thus the operation time period of the condensation mode is determined based on the difference in the amount of frost. Here, the difference of the amount of frost is in positive correlation with the operation time period of the condensation mode, that is, the larger the difference of the amount of frost is, the longer the operation time period of the condensation mode is, so as to increase the amount of condensed water condensed in the condensation mode state; the smaller the difference in the amount of frost, the shorter the operation time period of the condensation mode.

Optionally, the target condensation temperature may be adjusted according to the amount of frost determined in step S101 and a preset amount of frost requirement. Here, the adjustment of the target dew temperature is a further downward adjustment, i.e. the dew temperature continues to be decreased; for example, a correlation relationship between the difference of the frost quantity and the positive correlation of the temperature adjustment quantity of the condensation mode is preset, and when the difference of the frost quantity is large, the temperature quantity of the target condensation temperature which is adjusted downwards is larger, so that the condensation of water vapor on the heat exchanger is accelerated; when the difference in the amount of frost is small, the smaller the amount of temperature at which the target condensation temperature is adjusted downward.

Here, the lower limit of the down-regulation of the target condensation temperature is a preset condensation temperature.

Here, when the air conditioner operates in the condensation mode for the aforementioned operation length, controlling the air conditioner to start to perform the self-cleaning mode; and the air conditioner re-executes the step of estimating the frost amount in the step S101, and if the frost amount meets the preset frost amount requirement, the air conditioner is controlled to execute the self-cleaning mode.

Here, the specific execution flow of the air conditioner executing the self-cleaning mode may refer to the foregoing description, and is not described herein again.

Fig. 2 is a second flowchart illustrating a self-cleaning control method of an air conditioner according to another exemplary embodiment of the present invention.

As shown in fig. 2, the present invention provides another control method for self-cleaning of an air conditioner, which mainly comprises the following steps:

s201, responding to a trigger condition meeting a self-cleaning mode, and estimating the frost condensation amount of the air conditioner in a frost condensation process of the self-cleaning mode;

in this embodiment, the specific implementation manner of step S201 can refer to step S101, which is not described herein again.

S202, if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing a self-cleaning mode; the condensation mode includes controlling and adjusting operation of at least one component of the air conditioner to reduce the temperature of a heat exchanger to be cleaned of the air conditioner from a current temperature to a target condensation temperature, the target condensation temperature being determined according to an environmental parameter of an environment in which the air conditioner is located.

In this embodiment, if the amount of frost does not meet the preset requirement of the amount of frost, the problem of poor self-cleaning effect caused by too little condensed frost may occur in the flow of frost in the self-cleaning mode, therefore, the present application controls the air conditioner to execute the condensation mode before executing the self-cleaning mode to increase the amount of condensed water condensed on the heat exchanger to be cleaned, so that the condensed water condensed in advance can be converted into solid frost in the condensation stage of the self-cleaning mode, and thus, the amount of water vapor required for condensing part of frost lacking in the flow of frost in a low humidity condition can be compensated by executing the condensation mode.

Specifically, the condensation mode executed by the application can be a dehumidification mode of the existing air conditioner; alternatively, the condensation mode comprises: the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are improved, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

Here, the target condensation temperature is determined according to an environmental parameter of an environment in which the air conditioner is located. The air conditioner is also preset with an incidence relation between the condensation temperature and the indoor humidity of the indoor environment, such as a dew point temperature curve relation graph and the like, wherein in the incidence relation, different indoor humidities correspond to a determined condensation temperature, and when the temperature is at the condensation temperature associated with the current indoor humidity, the vapor in the air is converted into liquid from gas; therefore, the obtained indoor humidity can be further used for determining the current condensation temperature according to the correlation, and the current condensation temperature is used as the target condensation temperature of the air conditioner for executing the condensation mode.

Or the target condensation temperature is a fixed temperature value preset by the air conditioner.

Optionally, the control flow of the present invention further includes: and determining the operation time of the condensation mode based on the frost quantity determined in the step S201 and a preset frost quantity requirement. Here, the difference in the amount of frost may be calculated based on the preset frost amount requirement and the amount of frost, and thus the operation time period of the condensation mode is determined based on the difference in the amount of frost. Here, the difference of the amount of frost is in positive correlation with the operation time period of the condensation mode, that is, the larger the difference of the amount of frost is, the longer the operation time period of the condensation mode is, so as to increase the amount of condensed water condensed in the condensation mode state; the smaller the difference in the amount of frost, the shorter the operation time period of the condensation mode.

Optionally, the target condensation temperature may be adjusted according to the determined condensation amount in step S201 and a preset condensation amount requirement. Here, the adjustment of the target dew temperature is a further downward adjustment, i.e. the dew temperature continues to be decreased; for example, a correlation relationship between the difference of the frost quantity and the positive correlation of the temperature adjustment quantity of the condensation mode is preset, and when the difference of the frost quantity is large, the temperature quantity of the target condensation temperature which is adjusted downwards is larger, so that the condensation of water vapor on the heat exchanger is accelerated; when the difference in the amount of frost is small, the smaller the amount of temperature at which the target condensation temperature is adjusted downward.

Here, the lower limit of the down-regulation of the target condensation temperature is a preset condensation temperature.

Here, when the air conditioner operates in the condensation mode for the aforementioned operation length, controlling the air conditioner to start to perform the self-cleaning mode; the air conditioner re-executes the step of estimating the amount of frost in step S201, and if the amount of frost meets the preset amount of frost requirement, the air conditioner is controlled to execute the self-cleaning mode.

Here, the specific execution flow of the air conditioner executing the self-cleaning mode may refer to the foregoing description, and is not described herein again.

Fig. 3 is a third flowchart illustrating a control method for self-cleaning of an air conditioner according to another exemplary embodiment of the present invention.

As shown in fig. 3, the present invention provides another control method for self-cleaning of an air conditioner, which mainly comprises the following steps:

s301, in response to the trigger condition meeting the self-cleaning mode, estimating the frost quantity of the air conditioner in the frost process of the self-cleaning mode;

in this embodiment, the specific execution flow of step S301 may refer to step S101 in the foregoing, which is not described herein again.

S302, if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing a self-cleaning mode; wherein the condensation mode includes activating the humidifying device.

In this embodiment, if the amount of frost does not meet the preset requirement of the amount of frost, the problem of poor self-cleaning effect caused by too little condensed frost may occur in the flow of frost in the self-cleaning mode, therefore, the present application controls the air conditioner to execute the condensation mode before executing the self-cleaning mode to increase the amount of condensed water condensed on the heat exchanger to be cleaned, so that the condensed water condensed in advance can be converted into solid frost in the condensation stage of the self-cleaning mode, and thus, the amount of water vapor required for condensing part of frost lacking in the flow of frost in a low humidity condition can be compensated by executing the condensation mode.

Specifically, in this embodiment, a humidifying device is further disposed inside the air conditioner, and water vapor generated by the humidifying device can be dissipated to the inside of the indoor unit, so that the water vapor content inside the indoor unit is increased, and the amount of frost condensed in the frost condensation stage of the self-cleaning mode can be increased.

The condensation mode executed by the application can control the air conditioner to execute the existing dehumidification mode while starting the humidifying device; or, the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are increased, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

Here, the air conditioner also presets an association relationship between the condensation temperature and the indoor humidity of the indoor environment, such as a dew point temperature curve relation chart, where in the association relationship, different indoor humidities correspond to a determined condensation temperature, and when the temperature is at the condensation temperature associated with the current indoor humidity, the vapor in the air is converted into a liquid state from a gaseous state; therefore, the obtained indoor humidity can be further used for determining the current condensation temperature according to the correlation, and the current condensation temperature is used as the target condensation temperature of the air conditioner for executing the condensation mode.

Or the target condensation temperature is a fixed temperature value preset by the air conditioner.

Optionally, the control flow of the present invention further includes: and determining the operation time of the condensation mode based on the frost quantity determined in the step S301 and a preset frost quantity requirement. Here, the difference in the amount of frost may be calculated based on the preset frost amount requirement and the amount of frost, and thus the operation time period of the condensation mode is determined based on the difference in the amount of frost. Here, the difference of the amount of frost is in positive correlation with the operation time period of the condensation mode, that is, the larger the difference of the amount of frost is, the longer the operation time period of the condensation mode is, so as to increase the amount of vapor generated by the humidifying device in the condensation mode and the amount of condensed water condensed on the heat exchanger to be cleaned; the smaller the difference in the amount of frost, the shorter the operation time period of the condensation mode.

Optionally, the target condensation temperature may be adjusted according to the determined condensation amount in step S301 and a preset condensation amount requirement. Here, the adjustment of the target dew temperature is a further downward adjustment, i.e. the dew temperature continues to be decreased; for example, a correlation relationship between the difference of the frost quantity and the positive correlation of the temperature adjustment quantity of the condensation mode is preset, and when the difference of the frost quantity is large, the temperature quantity of the target condensation temperature which is adjusted downwards is larger, so that the condensation of water vapor on the heat exchanger is accelerated; when the difference in the amount of frost is small, the smaller the amount of temperature at which the target condensation temperature is adjusted downward.

Here, the lower limit of the down-regulation of the target condensation temperature is a preset condensation temperature.

Here, when the air conditioner operates in the condensation mode for the aforementioned operation length, controlling the air conditioner to start to perform the self-cleaning mode; and the air conditioner re-executes the step of estimating the frost amount in the step S301, and if the frost amount meets the preset frost amount requirement, the air conditioner is controlled to execute the self-cleaning mode.

Here, the specific execution flow of the air conditioner executing the self-cleaning mode may refer to the foregoing description, and is not described herein again.

Fig. 4 is a fourth flowchart illustrating a control method of self-cleaning of an air conditioner according to another exemplary embodiment of the present invention.

As shown in fig. 4, the present invention provides another control method for self-cleaning of an air conditioner, which mainly comprises the following steps:

s401, responding to a trigger condition meeting a self-cleaning mode, and estimating the frost quantity of the air conditioner in a frost process of the self-cleaning mode;

in this embodiment, the specific execution flow of step S401 may refer to step S101 in the foregoing, which is not described herein again.

S402, if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing a self-cleaning mode; the self-cleaning mode comprises the step of controlling the fan to be started and stopped intermittently in the condensation process.

In this embodiment, if the amount of frost does not meet the preset requirement of the amount of frost, the problem of poor self-cleaning effect caused by too little condensed frost may occur in the flow of frost in the self-cleaning mode, therefore, the present application controls the air conditioner to execute the condensation mode before executing the self-cleaning mode to increase the amount of condensed water condensed on the heat exchanger to be cleaned, so that the condensed water condensed in advance can be converted into solid frost in the condensation stage of the self-cleaning mode, and thus, the amount of water vapor required for condensing part of frost lacking in the flow of frost in a low humidity condition can be compensated by executing the condensation mode.

Specifically, the condensation mode executed by the application can be a dehumidification mode of the existing air conditioner; alternatively, the condensation mode comprises: the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are improved, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

Here, the air conditioner also presets an association relationship between the condensation temperature and the indoor humidity of the indoor environment, such as a dew point temperature curve relation chart, where in the association relationship, different indoor humidities correspond to a determined condensation temperature, and when the temperature is at the condensation temperature associated with the current indoor humidity, the vapor in the air is converted into a liquid state from a gaseous state; therefore, the obtained indoor humidity can be further used for determining the current condensation temperature according to the correlation, and the current condensation temperature is used as the target condensation temperature of the air conditioner for executing the condensation mode.

Or the target condensation temperature is a fixed temperature value preset by the air conditioner.

Optionally, the control flow of the present invention further includes: and determining the operation time of the condensation mode based on the frost quantity determined in the step S401 and a preset frost quantity requirement. Here, the difference in the amount of frost may be calculated based on the preset frost amount requirement and the amount of frost, and thus the operation time period of the condensation mode is determined based on the difference in the amount of frost. Here, the difference of the amount of frost is in positive correlation with the operation time period of the condensation mode, that is, the larger the difference of the amount of frost is, the longer the operation time period of the condensation mode is, so as to increase the amount of condensed water condensed in the condensation mode state; the smaller the difference in the amount of frost, the shorter the operation time period of the condensation mode.

Optionally, the target condensation temperature may be adjusted according to the determined condensation amount in step S401 and a preset condensation amount requirement. Here, the adjustment of the target dew temperature is a further downward adjustment, i.e. the dew temperature continues to be decreased; for example, a correlation relationship between the difference of the frost quantity and the positive correlation of the temperature adjustment quantity of the condensation mode is preset, and when the difference of the frost quantity is large, the temperature quantity of the target condensation temperature which is adjusted downwards is larger, so that the condensation of water vapor on the heat exchanger is accelerated; when the difference in the amount of frost is small, the smaller the amount of temperature at which the target condensation temperature is adjusted downward.

Here, the lower limit of the down-regulation of the target condensation temperature is a preset condensation temperature.

Here, when the air conditioner operates in the condensation mode for the aforementioned operation length, controlling the air conditioner to start to perform the self-cleaning mode; and the air conditioner re-executes the step of estimating the frost amount in the step S401, and if the frost amount meets the preset frost amount requirement, the air conditioner is controlled to execute the self-cleaning mode.

Here, in a flow of the air conditioner performing the self-cleaning mode, the blower corresponding to the heat exchanger to be cleaned is intermittently turned on and off.

Specifically, the fan is started and stopped at set frequency, for example, in a period with the duration of 10 min, the air conditioner starts the fan once every 1 min, and the running duration after the fan is started every time is 5 s; optionally, the time interval between two adjacent startups of the fan may be a fixed time interval or an unfixed time interval, and the operation time of a single start of the fan may be equal or unequal. Meanwhile, the rotating speeds of the fans after being started each time can be the same or different. The specific time and the specific rotating speed can be set before the air conditioner leaves a factory, so that the fan can realize dynamic running state switching.

The fan is intermittently started and stopped, so that the flow rate of water vapor in the air conditioner in the frost condensation process can be increased, the condensed frost on the heat exchanger can be more uniform, and the integral cleaning effect can be ensured.

Here, the other execution flows of the air conditioner executing the self-cleaning mode may refer to the foregoing description, and are not described herein again.

In an alternative embodiment, the air conditioning garment generally includes a body and a controller that may be used to control the control flow disclosed in the embodiment of fig. 1 above.

Specifically, the controller is configured to:

in response to the trigger condition meeting the self-cleaning mode, estimating the frost quantity of the air conditioner in the frost process of the self-cleaning mode;

and if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing the self-cleaning mode.

In an alternative embodiment, the controller is specifically configured to:

acquiring environmental parameters of an environment where an air conditioner is located and setting parameters of a self-cleaning mode;

and determining the frost quantity of the air conditioner in the self-cleaning mode in the frost condensation flow based on the environmental parameters and the set parameters of the self-cleaning mode.

In an alternative embodiment, the environmental parameters include: indoor temperature and indoor humidity;

the setting of the parameters comprises: the target frost-forming temperature and the target frost-forming time of the frost-forming process.

In an alternative embodiment, the condensation mode comprises:

the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are improved, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

In an alternative embodiment, the controller is further configured to:

and if the frost condensation amount meets the preset frost condensation amount requirement, controlling the air conditioner to execute a self-cleaning mode.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

In yet another alternative embodiment, the controller of the air conditioning garment may be used to control the control flow disclosed in the embodiment of fig. 2 above.

Specifically, the controller is configured to:

in response to the trigger condition meeting the self-cleaning mode, estimating the frost quantity of the air conditioner in the frost process of the self-cleaning mode;

if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing a self-cleaning mode; the condensation mode includes controlling and adjusting operation of at least one component of the air conditioner to reduce the temperature of a heat exchanger to be cleaned of the air conditioner from a current temperature to a target condensation temperature, the target condensation temperature being determined according to an environmental parameter of an environment in which the air conditioner is located.

In an alternative embodiment, the controller is specifically configured to:

acquiring environmental parameters of an environment where an air conditioner is located and setting parameters of a self-cleaning mode;

and determining the frost quantity of the air conditioner in the self-cleaning mode in the frost condensation flow based on the environmental parameters and the set parameters of the self-cleaning mode.

In an alternative embodiment, the environmental parameters include: indoor temperature and indoor humidity;

the setting of the parameters comprises: the target frost-forming temperature and the target frost-forming time of the frost-forming process.

In an alternative embodiment, the controller is specifically configured to:

the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are improved, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

In an alternative embodiment, the controller is further configured to:

and if the frost condensation amount meets the preset frost condensation amount requirement, controlling the air conditioner to execute a self-cleaning mode.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

In yet another alternative embodiment, the controller of the air conditioning garment may be used to control the control flow disclosed in the embodiment of fig. 3 above.

Specifically, the controller is configured to:

in response to the trigger condition meeting the self-cleaning mode, estimating the frost quantity of the air conditioner in the frost process of the self-cleaning mode;

if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing a self-cleaning mode; wherein the condensation mode includes activating the humidifying device.

In an alternative embodiment, the controller is specifically configured to:

acquiring environmental parameters of an environment where an air conditioner is located and setting parameters of a self-cleaning mode;

and determining the frost quantity of the air conditioner in the self-cleaning mode in the frost condensation flow based on the environmental parameters and the set parameters of the self-cleaning mode.

In an alternative embodiment, the environmental parameters include: indoor temperature and indoor humidity;

the setting of the parameters comprises: the target frost-forming temperature and the target frost-forming time of the frost-forming process.

In an alternative embodiment, the condensation mode further comprises:

the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are improved, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

In an alternative embodiment, the controller is further configured to:

and if the frost condensation amount meets the preset frost condensation amount requirement, controlling the air conditioner to execute a self-cleaning mode.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

In yet another alternative embodiment, the controller of the air conditioning garment may be used to control the control flow disclosed in the embodiment of fig. 4 above.

Specifically, the controller is configured to:

in response to the trigger condition meeting the self-cleaning mode, estimating the frost quantity of the air conditioner in the frost process of the self-cleaning mode;

if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing a self-cleaning mode; the self-cleaning mode comprises the step of controlling the fan to be started and stopped intermittently in the condensation process.

In an alternative embodiment, the controller is specifically configured to:

acquiring environmental parameters of an environment where an air conditioner is located and setting parameters of a self-cleaning mode;

and determining the frost quantity of the air conditioner in the self-cleaning mode in the frost condensation flow based on the environmental parameters and the set parameters of the self-cleaning mode.

In an alternative embodiment, the environmental parameters include: indoor temperature and indoor humidity;

the setting of the parameters comprises: the target frost-forming temperature and the target frost-forming time of the frost-forming process.

In an alternative embodiment, the condensation mode comprises:

the working frequency of a compressor of the air conditioner and the flow opening degree of a throttling device are improved, so that the temperature of a heat exchanger to be cleaned of the air conditioner is reduced from the current temperature to the target condensation temperature.

In an alternative embodiment, the controller is further configured to:

and if the frost condensation amount meets the preset frost condensation amount requirement, controlling the air conditioner to execute a self-cleaning mode.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

It is to be understood that the present invention is not limited to the procedures and structures described above and shown in the drawings, and that various modifications and changes may be made without departing from the scope thereof. The scope of the invention is limited only by the appended claims.

Claims (10)

1. A control method for self-cleaning of an air conditioner is characterized by comprising the following steps:

in response to the fact that a triggering condition of a self-cleaning mode is met, pre-estimating the frost quantity of the air conditioner in a frost condensation process of the self-cleaning mode;

and if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing the self-cleaning mode.

2. The control method according to claim 1, wherein the estimating of the amount of frost of the condensation process of the air conditioner in the self-cleaning mode comprises:

acquiring environmental parameters of the environment where the air conditioner is located and setting parameters of the self-cleaning mode;

and determining the frost quantity of the air conditioner in the self-cleaning mode in the frost process based on the environmental parameter and the set parameter of the self-cleaning mode.

3. The control method according to claim 2, wherein the environmental parameter includes: indoor temperature and indoor humidity;

the setting parameters comprise: and the target frost temperature and the target frost time of the frost process are set.

4. The control method according to claim 1, wherein the condensation mode includes:

and increasing the working frequency of a compressor of the air conditioner and the flow opening of a throttling device so as to reduce the temperature of a heat exchanger to be cleaned of the air conditioner from the current temperature to a target condensation temperature.

5. The control method according to claim 1, characterized by further comprising:

and if the frost quantity meets the preset frost quantity requirement, controlling the air conditioner to execute the self-cleaning mode.

6. An air conditioner, characterized in that, the air conditioner includes an organism and a controller, wherein, the controller is used for:

in response to the fact that a triggering condition of a self-cleaning mode is met, pre-estimating the frost quantity of the air conditioner in a frost condensation process of the self-cleaning mode;

and if the frost quantity does not meet the preset frost quantity requirement, controlling the air conditioner to execute a condensation mode before executing the self-cleaning mode.

7. The air conditioner of claim 6, wherein the controller is specifically configured to:

acquiring environmental parameters of the environment where the air conditioner is located and setting parameters of the self-cleaning mode;

and determining the frost quantity of the air conditioner in the self-cleaning mode in the frost process based on the environmental parameter and the set parameter of the self-cleaning mode.

8. The air conditioner according to claim 7, wherein the environmental parameters include: indoor temperature and indoor humidity;

the setting parameters comprise: and the target frost temperature and the target frost time of the frost process are set.

9. The air conditioner according to claim 6, wherein the condensation mode includes:

and increasing the working frequency of a compressor of the air conditioner and the flow opening of a throttling device so as to reduce the temperature of a heat exchanger to be cleaned of the air conditioner from the current temperature to a target condensation temperature.

10. The air conditioner of claim 6, wherein the controller is further configured to:

and if the frost quantity meets the preset frost quantity requirement, controlling the air conditioner to execute the self-cleaning mode.

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