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CN111102713B - Air conditioner and condensation preventing method thereof - Google Patents

Air conditioner and condensation preventing method thereof Download PDF

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Publication number
CN111102713B
CN111102713B CN201811255039.2A CN201811255039A CN111102713B CN 111102713 B CN111102713 B CN 111102713B CN 201811255039 A CN201811255039 A CN 201811255039A CN 111102713 B CN111102713 B CN 111102713B
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China
Prior art keywords
air conditioner
temperature
indoor
humidity
condensation
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CN201811255039.2A
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CN111102713A (en
Inventor
许文明
罗荣邦
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Qingdao Haier Air Conditioner Gen Corp Ltd
Haier Smart Home Co Ltd
Chongqing Haier Air Conditioner Co Ltd
Original Assignee
Qingdao Haier Air Conditioner Gen Corp Ltd
Haier Smart Home Co Ltd
Chongqing Haier Air Conditioner Co Ltd
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Priority to CN201811255039.2A priority Critical patent/CN111102713B/en
Publication of CN111102713A publication Critical patent/CN111102713A/en
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F13/00Details common to, or for air-conditioning, air-humidification, ventilation or use of air currents for screening
    • F24F13/22Means for preventing condensation or evacuating condensate
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/30Control or safety arrangements for purposes related to the operation of the system, e.g. for safety or monitoring
    • F24F11/32Responding to malfunctions or emergencies
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/50Control or safety arrangements characterised by user interfaces or communication
    • F24F11/61Control or safety arrangements characterised by user interfaces or communication using timers
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/62Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
    • F24F11/63Electronic processing
    • F24F11/64Electronic processing using pre-stored data
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/62Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
    • F24F11/63Electronic processing
    • F24F11/65Electronic processing for selecting an operating mode
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/70Control systems characterised by their outputs; Constructional details thereof
    • F24F11/72Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure
    • F24F11/74Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure for controlling air flow rate or air velocity
    • F24F11/77Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure for controlling air flow rate or air velocity by controlling the speed of ventilators
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/70Control systems characterised by their outputs; Constructional details thereof
    • F24F11/72Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure
    • F24F11/79Control systems characterised by their outputs; Constructional details thereof for controlling the supply of treated air, e.g. its pressure for controlling the direction of the supplied air
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/70Control systems characterised by their outputs; Constructional details thereof
    • F24F11/80Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air
    • F24F11/83Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air by controlling the supply of heat-exchange fluids to heat-exchangers
    • F24F11/84Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air by controlling the supply of heat-exchange fluids to heat-exchangers using valves
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/70Control systems characterised by their outputs; Constructional details thereof
    • F24F11/80Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air
    • F24F11/86Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air by controlling compressors within refrigeration or heat pump circuits
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F13/00Details common to, or for air-conditioning, air-humidification, ventilation or use of air currents for screening
    • F24F13/22Means for preventing condensation or evacuating condensate
    • F24F2013/221Means for preventing condensation or evacuating condensate to avoid the formation of condensate, e.g. dew
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F2110/00Control inputs relating to air properties
    • F24F2110/10Temperature
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F2110/00Control inputs relating to air properties
    • F24F2110/20Humidity
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]
    • Y02B30/70Efficient control or regulation technologies, e.g. for control of refrigerant flow, motor or heating

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Signal Processing (AREA)
  • Physics & Mathematics (AREA)
  • Fuzzy Systems (AREA)
  • Mathematical Physics (AREA)
  • Human Computer Interaction (AREA)
  • Thermal Sciences (AREA)
  • Fluid Mechanics (AREA)
  • Air Conditioning Control Device (AREA)

Abstract

The invention discloses an air conditioner and a condensation preventing method thereof, and belongs to the technical field of air conditioners. The method comprises the steps of obtaining a first indoor humidity and a first indoor temperature of the environment where the air conditioner is located; if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the auxiliary dehumidification mode comprises the steps of controlling an air deflector of the air conditioner to be maintained at a set air outlet angle and continuously operating for a third time; acquiring the humidity of the third chamber; and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode. According to the invention, through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the condensation prevention mode, the occurrence of air conditioner condensation problem can be reduced, and the use experience of a user is improved.

Description

Air conditioner and condensation preventing method thereof
Technical Field
The invention relates to the technical field of air conditioners, in particular to an air conditioner and a condensation preventing method thereof.
Background
Along with the improvement of the living standard of people, air conditioning equipment has also gone into thousands of households, the use of household air conditioners and central air conditioners is more and more common, the requirement of users on the comfort level of the air conditioner is higher and higher, the problems existing in the use process of the air conditioner are also gradually exposed, and one of the problems is the condensation problem of an air conditioner evaporator and an air duct.
The reasons for the condensation of the air conditioner are as follows: (1) the air humidity in the air-conditioning area direction is high; (2) in the range of the air-conditioning area, because the new air exhaust system is unreasonably arranged, overlarge negative pressure is generated, and outdoor air enters the room, so that the humidity and the condensation dew point of the air conditioner are improved; (3) the air conditioner adopts large temperature difference air supply, and air supply quantity and cold quantity of the machine are not allocated, so that cold quantity is too large, and air quantity is too small; (4) the air supply outlet is made of aluminum materials, and due to the good heat conduction performance, the surface temperature of the air outlet materials is too low, and dew is condensed.
Especially, the air conditioner that moves in the high temperature and high humidity environment can appear condensation drop on baffle and panel after the operating duration overlength, also can appear a large amount of condensate on the evaporimeter, will appear blowing and the condition of dripping when the air conditioner is to indoor air supply, has influenced user's use and has experienced, therefore the air conditioner condensation problem is waited for a long time to solve.
Disclosure of Invention
The invention provides an air conditioner and a method for preventing condensation thereof, and aims to solve the problem that condensation is easy to generate in the conventional air conditioner. 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 method of preventing condensation of an air conditioner, the method comprising:
acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an inner fan, switching an air deflector to a set air outlet angle and continuously operating for a second time;
acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling an air deflector of the air conditioner to be maintained at a set air outlet angle and continuously operating for a third time;
acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of an air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
According to a second aspect of the present invention, there is also provided an air conditioner including an air conditioner body provided with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an inner fan, switching an air deflector to a set air outlet angle and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling an air deflector of the air conditioner to be maintained at a set air outlet angle and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The invention adopts the technical scheme and has the beneficial effects that:
the air conditioner condensation preventing method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the condensation preventing mode.
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
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.
FIG. 1 is a schematic flow diagram illustrating a method of preventing condensation in an air conditioner according to an exemplary embodiment of the present invention;
FIG. 2 is a schematic flow diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 3 is a schematic flow diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 4 is a schematic flow chart diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 5 is a schematic flow chart diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 6 is a schematic flow chart illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 7 is a schematic flow chart diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 8 is a schematic flow chart diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 9 is a schematic flow chart diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 10 is a schematic flow chart diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 11 is a schematic flow chart diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
FIG. 12 is a schematic flow chart diagram illustrating a method of preventing condensation in an air conditioner according to the present invention, in accordance with yet another exemplary embodiment;
fig. 13 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
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.
Fig. 1 is a schematic flow chart illustrating a method for preventing condensation of an air conditioner according to an exemplary embodiment of the present invention.
As shown in fig. 1, the invention provides a method for preventing condensation of an air conditioner, which can be used for solving the problem that the air conditioner is easy to condense in environments of high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s101, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
optionally, the air conditioner of the present invention is provided with one or more sensors, wherein the sensors include a humidity sensor, and the humidity sensor can be used for detecting the current humidity of the environment where the air conditioner is located; therefore, in step S101, a first indoor humidity of the environment where the air conditioner is located can be obtained by the humidity sensor;
similarly, the sensor of the air conditioner arrangement further comprises a temperature sensor operable to detect a first indoor temperature of an environment in which the air conditioner is located; thus, the first indoor temperature is obtained by the temperature sensor in step S101.
Here, the first indoor humidity and the first indoor temperature are respectively the current humidity and temperature of the indoor environment before the method for preventing condensation is started, and the humidity and temperature of the indoor environment directly affect whether condensation is generated in the air conditioner during operation and the amount of the condensation.
Before executing the anti-condensation control process of the present invention, the air conditioner generally operates according to a mode originally set by a user, for example, in a high-temperature and high-humidity condition in summer, the air conditioner generally is set by the user to operate a cooling mode, and therefore, in an optional application scenario of the present invention, step S101 is to detect the humidity and temperature conditions of the indoor environment through a humidity sensor during the operation of the air conditioner in the cooling mode.
S102, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling an air conditioner to operate in a dehumidification mode;
optionally, the preset first condensation condition includes that a duration of the first indoor humidity being greater than a first humidity threshold (first humidity condition) and the first indoor temperature being greater than a temperature threshold (first temperature condition) is greater than or equal to a first duration;
the first humidity threshold is a preset threshold parameter, such as 70% or 75% of relative humidity. In this way, in step S102, in the case where the first indoor humidity is greater than the preset first humidity threshold, it may be determined that the first indoor humidity satisfies the first humidity condition among the preset condensation conditions, for example, the preset first humidity threshold is 70% of the relative humidity, and if the first indoor humidity detected at the time of performing step S101 once is 60% of the relative humidity, it may be determined that the first indoor humidity does not satisfy the first humidity condition among the preset condensation conditions; if the first indoor humidity detected when the step S101 is performed again is 80% of the relative humidity, it may be determined that the first indoor humidity satisfies a first humidity condition of a preset condensation condition.
Similarly, the first temperature threshold is also a preset threshold parameter, such as 22 ℃, 23 ℃, and the like. In this way, in step S102, in the case where the first indoor temperature is greater than the preset first temperature threshold, it may be determined that the first indoor temperature satisfies the first temperature condition among the preset condensation conditions, for example, the preset first temperature threshold is 22 ℃, and if the first indoor temperature detected at the time of performing step S101 once is 20 ℃, it may be determined that the first indoor temperature does not satisfy the first temperature condition among the preset condensation conditions; if the first indoor temperature detected when the step S101 is performed again is 25 ℃, it may be determined that the first indoor temperature satisfies a first temperature condition of a preset condensation condition.
Optionally, the first time period is 10 min.
Here, if the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air-conditioning operation dehumidification mode is controlled.
In the present embodiment, the dehumidification mode includes: controlling a compressor of the air conditioner to be switched to a first set frequency, performing first rotation speed compensation on an inner fan, switching an air deflector to a set air outlet angle, and continuously operating for a second time;
specifically, the first set frequency is a frequency value preset for the compressor, and optionally, the frequency value is a frequency value with a higher value so as to increase the exhaust temperature of the compressor, so that the temperature of a refrigerant flowing into the indoor unit heat exchanger after throttling can reach a lower temperature so as to improve the condensation and dehumidification effects; here, when the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air conditioner switches from a frequency corresponding to the previous operation mode to a first set frequency;
the first rotation speed compensation of the inner fan is a positive value or a negative value, when the first rotation speed compensation is the positive value, the rotation speed of the inner fan is increased, and when the first rotation speed compensation is the negative value, the rotation speed of the inner fan is reduced;
here, before the air conditioner leaves the factory, in the process of operating the air conditioner in the dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S102, the rate of moisture condensation on the outer surface of the heat exchanger of the indoor unit during the operation of the internal fan of the air conditioner at different rotation speeds is measured and calculated, and the rotation speed of the internal fan corresponding to the fastest rate of moisture condensation is associated with the coil temperature of the dehumidification mode, so that the association relationship between the coil temperature and the rotation speed of the internal fan during the operation of the dehumidification mode of one or more air conditioners can be obtained, and the association relationship is prestored in the air conditioner.
In this way, in the process of executing the dehumidification mode in step S102, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and find and obtain the corresponding rotation speed of the inner fan according to the detected coil temperature and the preset association relationship. Therefore, the first rotation speed compensation is the difference value between the searched rotation speed and the rotation speed of the fan in the previous working mode of the air conditioner operation.
The air outlet angle of the air deflector can determine the air outlet volume of the air outlet of the air conditioner, the dehumidification capacity is different under different air volumes, and the purpose of improving the dehumidification capacity can be achieved by adjusting the air outlet angle of the air deflector.
Here, before the air conditioner leaves the factory, in the process of operating the air conditioner in the dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S102, the air deflector of the air conditioner operates at different air outlet angles and the rate of water vapor condensation on the outer surface of the indoor unit heat exchanger is measured, and the air outlet angle of the air deflector corresponding to the fastest rate of water vapor condensation is associated with the coil temperature in the dehumidification mode, so that the association relationship between the coil temperatures and the air outlet angles of the air deflectors when the one or more air conditioners operate in the dehumidification mode can be obtained, and the association relationship is prestored in the air conditioner.
In this way, in the process of executing the dehumidification mode in step S102, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and find and obtain the corresponding air outlet angle of the air deflector according to the detected coil temperature and the preset association relationship.
Optionally, the second time period is 1 hour.
The air conditioner can increase condensed dew on the indoor unit of the air conditioner through the operation dehumidification mode, so that the phase state transformation and precipitation of water vapor in the indoor environment are accelerated, the water vapor content and the relative humidity in the air of the indoor environment can be reduced, the humidity condition of the indoor environment in the conventional mode (such as the refrigeration mode) of the air conditioner operation is changed, and then the condensation amount of the air conditioner is effectively reduced or even no condensation is generated in the conventional mode of the air conditioner operation.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S103, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity and the second indoor temperature in step S103 may refer to embodiment S101 in the foregoing, and is not described herein again.
S104, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
optionally, the preset second condensation condition includes that the second indoor humidity is greater than a second humidity threshold (second humidity condition), and a difference between the second indoor temperature and the target temperature is less than a set temperature difference threshold (second temperature condition);
the second humidity threshold is also a preset threshold parameter; here, the humidity threshold in the second condensation condition preset in step S104 is smaller than the humidity threshold in the condensation condition in step S102, and if the humidity threshold in the condensation condition in step S102 is 70% relative humidity, the humidity threshold in the condensation condition in step S104 is 60%, 50%, or the like relative humidity. In this way, in step S104, in the case where the second indoor humidity is greater than or equal to the preset humidity threshold, it may be determined that the second indoor humidity satisfies the preset second condensation condition, for example, the preset humidity threshold is 60% of the relative humidity, and if the detected second indoor humidity is 55% of the relative humidity when step S103 is performed once, it may be determined that the second indoor humidity does not satisfy the preset second condensation condition; if the detected second indoor humidity is 77% relative humidity when the step S103 is performed again, it may be determined that the second indoor humidity satisfies the preset second condensation condition.
Here, the humidity threshold in the second condensation condition preset in step S104 is set to be lower than the humidity threshold in the first condensation condition preset in step S102, so that the humidity range which can satisfy the second condensation condition in step S104 can be expanded, the auxiliary dehumidification mode can be triggered to be started, and the indoor humidity which causes the condensation problem when the air conditioner operates in the normal operation mode can be further reduced.
The target temperature is a temperature value or a temperature range to which the user desires to reach the indoor environment set by a device such as a remote controller or an input panel.
Optionally, the value of the temperature difference threshold is set to be 3 ℃.
Optionally, the auxiliary dehumidification mode includes: and controlling a compressor of the air conditioner to maintain the first set frequency, performing second rotation speed compensation on the internal fan and continuously operating for a third time.
The second rotation speed compensation of the inner fan is a positive value or a negative value, when the second rotation speed compensation is the positive value, the rotation speed of the inner fan is increased, and when the second rotation speed compensation is the negative value, the rotation speed of the inner fan is reduced;
here, before the air conditioner leaves the factory, in a manner of one or more sets of experimental measurements, etc., the humidity change rate and the temperature change rate in the test environment where the air conditioner is located in the process of operating the internal fan of the air conditioner at different rotation speeds are measured and calculated after the air conditioner operates in the dehumidification mode of step S102 in step S104, and the rotation speed of the internal fan corresponding to the maximum humidity drop and the minimum temperature change rate is used as the rotation speed of the internal fan in the auxiliary dehumidification mode, and the rotation speed of the internal fan is prestored in the air conditioner.
In this way, the air conditioner may switch the rotation speed of the inner fan to the previously stored rotation speed of the inner fan during the execution of the auxiliary dehumidification mode in step S104. Therefore, the dehumidification efficiency in the auxiliary dehumidification stage can be ensured, and the problems of fluctuation of indoor temperature and influence on the comfort level of users caused by the operation of the auxiliary dehumidification mode can be reduced.
Optionally, the third time period is 1 hour.
S105, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S105 may be detected by the humidity sensor in the foregoing.
And S106, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
Optionally, the third condensation condition preset in step S106 is the same as the first humidity condition in the first condensation condition in step S102, or the second humidity condition in the second condensation condition in step S104;
the anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode specifically comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew; here, the target coil temperature is greater than the dew condensation temperature for the current operating conditions.
In this embodiment, the anti-condensation mode is to raise the temperature of the inner coil of the air conditioner to a temperature higher than the condensation temperature of the current working condition, so that the residual condensed water on the heat exchanger of the indoor unit is converted into a gaseous state, and the amount of the condensed water on the outer surface of the heat exchanger of the indoor unit is reduced. Here, since a large amount of moisture in the indoor ambient air has been condensed when the air conditioner operates the dehumidification mode in step S102, the moisture content of the indoor environment has been effectively reduced in step S102; after the air conditioner executes the integrated process, the air conditioner is switched to the previous working mode to operate (such as a refrigeration mode), and the temperature environment of water vapor condensation can be caused due to the lower temperature of the surface of the heat exchanger of the indoor unit during the operation of the refrigeration mode, so that the amount of condensed water on the surface of the heat exchanger of the indoor unit is increased. Aiming at the problem, when the condensation condition of the step S104 is met, the temperature of the inner coil is controlled to be increased, so that the residual water vapor of the air conditioner after the air conditioner operates in the dehumidification mode and the auxiliary dehumidification mode is evaporated, the residual condensed water on the outer surface of the heat exchanger of the indoor unit is reduced, and the water quantity on the outer surface of the heat exchanger of the indoor unit after the air conditioner is switched back to the refrigeration mode can be reduced.
Generally, in the air-conditioning operation dehumidification mode and the auxiliary dehumidification mode, the temperature of a coil of an indoor unit of an air conditioner is much lower than that in the air-conditioning operation refrigeration mode, and therefore, the temperature of an indoor environment is further reduced in the process of the air-conditioning operation dehumidification mode. In an alternative embodiment, in order to reduce the influence of the secondary temperature fluctuation on the indoor environment when the air conditioner operates in the anti-condensation mode, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
Optionally, a is a predetermined fixed value, such as 5 ℃, i.e. the temperature difference between the room temperature and the target coil temperature after the increase is less than or equal to 5 ℃. Generally, the temperature of the target coil is lower than the indoor temperature, the temperature difference between the indoor temperature and the raised target coil temperature is maintained within 5 ℃, and the problems that the indoor temperature is further reduced and the body feeling comfort of a user is influenced under the condition that the temperature of the target coil is lower (the temperature difference between the indoor temperature and the raised target coil temperature is greater than 5 ℃) can be solved.
Alternatively, in yet another alternative embodiment, the calculated threshold A is a parameter determined based on the current operating conditions. Specifically, the control method further includes: and determining a calculation threshold A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation.
Here, before the air conditioner leaves the factory, after the air conditioner operates in the auxiliary dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S104 is measured and calculated in a manner of one or more sets of experimental measurements, and if the third condensation condition in step S106 is satisfied, after the air conditioner operates in the anti-condensation mode at different target coil temperatures, the amount of condensation water remaining on the outer surface of the heat exchanger of the indoor unit is calculated, and the target coil temperature corresponding to the minimum amount of condensation water remaining is associated with the coil temperature, so that the association relationship between the coil temperature in the auxiliary dehumidification mode and the target coil temperature in the anti-condensation mode of one or more air conditioners can be obtained, and the association relationship is prestored in the air conditioner.
In this way, during the auxiliary dehumidification mode in step S104, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and in step S104, the calculation threshold a is found according to the detected coil temperature and the preset association relationship.
In an optional embodiment, in the preset correlation, the coil temperature in the auxiliary dehumidification mode of the air conditioner and the calculation threshold a are in a positive correlation, that is, the higher the coil temperature in the auxiliary dehumidification mode is, the smaller the reduction of the indoor environment temperature in the dehumidification process is, the larger the calculation threshold a may be set, at this time, because the auxiliary dehumidification mode has a lower influence on the indoor environment temperature, the target coil temperature setting value in the condensation prevention mode of the air conditioner may also be lower, so that the present invention may control the overall influence of the control flow combining the dehumidification mode, the auxiliary dehumidification mode, and the condensation prevention mode on the indoor environment temperature within a limited range.
On the contrary, the lower the coil temperature in the auxiliary dehumidification mode is, the smaller the calculation threshold a is set to, so that the target coil temperature setting value in the air conditioner performing the anti-condensation mode may also be higher and close to the indoor temperature to compensate for the reduced temperature of the indoor environment caused in the dehumidification mode, and prevent the indoor temperature from being reduced and deviating from the comfortable temperature range desired by the user.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency; optionally, a plurality of working frequency values or frequency ranges may be preset in the compressor of the air conditioner from low to high, where the air conditioner is adjusted to a lower working frequency value or frequency range when the compressor of the air conditioner operates in the anti-condensation mode;
an inner fan of the air conditioner runs at a high wind gear; the air conditioner is characterized in that a plurality of wind speed gears are preset on an inner fan of the air conditioner, such as a low wind gear, a medium wind gear and a high wind gear, the rotating speeds of the fans at the three gears are sequentially increased, and the air output of an indoor unit of the air conditioner is sequentially increased;
an outer fan of the air conditioner runs at a low wind gear; the method is characterized in that a gear setting mode similar to that of an inner fan of the air conditioner is adopted, a plurality of wind speed gears are preset on an outer fan of the air conditioner, such as a low wind gear, a medium wind gear and a high wind gear, the rotating speeds of the fans at the three gears are sequentially increased, and the air output of an outdoor unit of the air conditioner is sequentially increased;
the throttling device of the air conditioner operates at a large opening flow rate; optionally, a plurality of opening values or opening ranges can be preset in the throttling device of the air conditioner from small to large, and here, when the air conditioner operates in the anti-condensation mode, the throttling device of the air conditioner is adjusted to be a larger opening value or opening range;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle; optionally, the air guide assembly of the air conditioner comprises an air deflector provided with an air outlet of the air conditioner, wherein an air outlet angle is set as an angle at which the air conditioner can perform air outlet at the maximum air outlet amount, and at this time, the wind blocking influence of the air guide assembly on the air outlet airflow flowing through the air outlet is the lowest, so that the air outlet airflow with evaporated steam can be discharged out of the indoor unit as soon as possible.
Fig. 2 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 2, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s201, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution process of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S201 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S202, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode;
optionally, the preset first condensation condition in this embodiment is the same as the preset first condensation condition in step S102;
here, if the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air-conditioning operation dehumidification mode is controlled.
In the present embodiment, the dehumidification mode includes: controlling a compressor of the air conditioner to be switched to a first set frequency, performing first rotation speed compensation on an inner fan, and continuously operating for a second time;
specifically, the first set frequency is a frequency value preset for the compressor, and optionally, the frequency value is a frequency value with a higher value so as to increase the exhaust temperature of the compressor, so that the temperature of a refrigerant flowing into the indoor unit heat exchanger after throttling can reach a lower temperature so as to improve the condensation and dehumidification effects; here, when the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air conditioner switches from a frequency corresponding to the previous operation mode to a first set frequency;
the first rotation speed compensation of the inner fan is a positive value or a negative value, when the first rotation speed compensation is the positive value, the rotation speed of the inner fan is increased, and when the first rotation speed compensation is the negative value, the rotation speed of the inner fan is reduced;
here, before the air conditioner leaves the factory, in the process of operating the air conditioner in the dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S202, the rate of moisture condensation on the outer surface of the heat exchanger of the indoor unit during the operation of the internal fan of the air conditioner at different rotation speeds is measured and calculated, and the rotation speed of the internal fan corresponding to the fastest rate of moisture condensation is associated with the coil temperature of the dehumidification mode, so that the association relationship between the coil temperature and the rotation speed of the internal fan during the operation of the dehumidification mode of one or more air conditioners can be obtained, and the association relationship is prestored in the air conditioner.
In this way, in the process of executing the dehumidification mode in step S202, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and find and obtain the corresponding rotation speed of the inner fan according to the detected coil temperature and the preset association relationship. Therefore, the first rotation speed compensation is the difference value between the searched rotation speed and the rotation speed of the fan in the previous working mode of the air conditioner operation.
Optionally, the second time period is 1 hour.
The air conditioner can increase condensed dew on the indoor unit of the air conditioner through the operation dehumidification mode, so that the phase state transformation and precipitation of water vapor in the indoor environment are accelerated, the water vapor content and the relative humidity in the air of the indoor environment can be reduced, the humidity condition of the indoor environment in the conventional mode (such as the refrigeration mode) of the air conditioner operation is changed, and then the condensation amount of the air conditioner is effectively reduced or even no condensation is generated in the conventional mode of the air conditioner operation.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S203, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity and the second indoor temperature in step S203 may refer to embodiment S201 in the foregoing, and is not described herein again.
S204, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
in this embodiment, the specific execution process of step S204 may refer to embodiment S104 in the foregoing, which is not described herein again.
S205, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S205 may also be detected by the humidity sensor in the foregoing.
And S206, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S206 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 3 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 3, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s301, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution process of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S301 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S302, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling an air conditioner to operate in a dehumidification mode;
optionally, the preset first condensation condition in this embodiment is the same as the preset first condensation condition in step S102;
here, if the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air-conditioning operation dehumidification mode is controlled.
In the present embodiment, the dehumidification mode includes: controlling a compressor of the air conditioner to be switched to a first set frequency, performing first rotation speed compensation on an inner fan, switching an air deflector to a set air outlet angle, and continuously operating for a second time;
specifically, the first set frequency is a frequency value preset for the compressor, and optionally, the frequency value is a frequency value with a higher value so as to increase the exhaust temperature of the compressor, so that the temperature of a refrigerant flowing into the indoor unit heat exchanger after throttling can reach a lower temperature so as to improve the condensation and dehumidification effects; here, when the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air conditioner switches from a frequency corresponding to the previous operation mode to a first set frequency;
the first rotation speed compensation of the inner fan is a positive value or a negative value, when the first rotation speed compensation is the positive value, the rotation speed of the inner fan is increased, and when the first rotation speed compensation is the negative value, the rotation speed of the inner fan is reduced;
here, before the air conditioner leaves the factory, in the process of the air conditioner running in the dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S302, the rate of moisture condensation on the outer surface of the heat exchanger of the indoor unit during the running of the internal fan of the air conditioner at different rotation speeds is measured and calculated, and the rotation speed of the internal fan corresponding to the fastest rate of moisture condensation is associated with the coil temperature of the dehumidification mode, so that the association relationship between the coil temperature and the rotation speed of the internal fan during the dehumidification mode of one or more air conditioners can be obtained, and the association relationship is prestored in the air conditioner.
In this way, in the process of executing the dehumidification mode in step S302, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and find and obtain the corresponding rotation speed of the inner fan according to the detected coil temperature and the preset association relationship. Therefore, the first rotation speed compensation is the difference value between the searched rotation speed and the rotation speed of the fan in the previous working mode of the air conditioner operation.
The air outlet angle of the air deflector can determine the air outlet volume of the air outlet of the air conditioner, the dehumidification capacity is different under different air volumes, and the purpose of improving the dehumidification capacity can be achieved by adjusting the air outlet angle of the air deflector.
Here, before the air conditioner leaves the factory, in the process of operating the air conditioner in the dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S302, the air deflector of the air conditioner operates at different air outlet angles and the rate of water vapor condensation on the outer surface of the indoor unit heat exchanger is measured, and the air outlet angle of the air deflector corresponding to the fastest rate of water vapor condensation is associated with the coil temperature in the dehumidification mode, so that the association relationship between the coil temperatures and the air outlet angles of the air deflectors when the one or more air conditioners operate in the dehumidification mode can be obtained, and the association relationship is prestored in the air conditioner.
In this way, in the process of executing the dehumidification mode in step S302, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and find and obtain the corresponding air outlet angle of the air deflector according to the detected coil temperature and the preset association relationship.
Optionally, the second time period is 1 hour.
The air conditioner can increase condensed dew on the indoor unit of the air conditioner through the operation dehumidification mode, so that the phase state transformation and precipitation of water vapor in the indoor environment are accelerated, the water vapor content and the relative humidity in the air of the indoor environment can be reduced, the humidity condition of the indoor environment in the conventional mode (such as the refrigeration mode) of the air conditioner operation is changed, and then the condensation amount of the air conditioner is effectively reduced or even no condensation is generated in the conventional mode of the air conditioner operation.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S303, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity and the second indoor temperature in step S303 may refer to embodiment S301 in the foregoing, and is not described herein again.
S304, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
in this embodiment, the specific execution process of step S304 may refer to embodiment S104 in the foregoing, which is not described herein again.
S305, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S305 may be detected by the humidity sensor in the foregoing.
And S306, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S306 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 4 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 4, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s401, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution process of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S401 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S402, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling an air conditioner to operate in a dehumidification mode;
optionally, the preset first condensation condition in this embodiment is the same as the preset first condensation condition in step S102;
here, if the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air-conditioning operation dehumidification mode is controlled.
In the present embodiment, the dehumidification mode includes: performing first rotation speed compensation on the inner fan, switching the air deflector to a set air outlet angle and continuously operating for a second time;
specifically, the first rotation speed compensation of the inner fan is a positive value or a negative value, when the first rotation speed compensation is the positive value, the rotation speed of the inner fan is increased, and when the first rotation speed compensation is the negative value, the rotation speed of the inner fan is reduced;
here, before the air conditioner leaves the factory, in the process of operating the air conditioner in the dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S402, the rate of moisture condensation on the outer surface of the heat exchanger of the indoor unit during the operation of the internal fan of the air conditioner at different rotation speeds is measured and calculated, and the rotation speed of the internal fan corresponding to the fastest rate of moisture condensation is associated with the coil temperature of the dehumidification mode, so that the association relationship between the coil temperature and the rotation speed of the internal fan during the operation of the dehumidification mode of one or more air conditioners can be obtained, and the association relationship is prestored in the air conditioner.
In this way, in the process of executing the dehumidification mode in step S402, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and find and obtain the corresponding rotation speed of the inner fan according to the detected coil temperature and the preset association relationship. Therefore, the first rotation speed compensation is the difference value between the searched rotation speed and the rotation speed of the fan in the previous working mode of the air conditioner operation.
The air outlet angle of the air deflector can determine the air outlet volume of the air outlet of the air conditioner, the dehumidification capacity is different under different air volumes, and the purpose of improving the dehumidification capacity can be achieved by adjusting the air outlet angle of the air deflector.
Here, before the air conditioner leaves the factory, in the process of operating the air conditioner in the dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S402, the air deflector of the air conditioner operates at different air outlet angles and the rate of water vapor condensation on the outer surface of the indoor unit heat exchanger is measured, and the air outlet angle of the air deflector corresponding to the fastest rate of water vapor condensation is associated with the coil temperature in the dehumidification mode, so that the association relationship between the coil temperatures and the air outlet angles of the air deflectors when the one or more air conditioners operate in the dehumidification mode can be obtained, and the association relationship is prestored in the air conditioner.
In this way, in the process of executing the dehumidification mode in step S402, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and find and obtain the corresponding air outlet angle of the air deflector according to the detected coil temperature and the preset association relationship.
Optionally, the second time period is 1 hour.
The air conditioner can increase condensed dew on the indoor unit of the air conditioner through the operation dehumidification mode, so that the phase state transformation and precipitation of water vapor in the indoor environment are accelerated, the water vapor content and the relative humidity in the air of the indoor environment can be reduced, the humidity condition of the indoor environment in the conventional mode (such as the refrigeration mode) of the air conditioner operation is changed, and then the condensation amount of the air conditioner is effectively reduced or even no condensation is generated in the conventional mode of the air conditioner operation.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S403, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity and the second indoor temperature in step S403 may refer to embodiment S401 in the foregoing, which is not described herein again.
S404, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling an air conditioner to operate in an auxiliary dehumidification mode;
in this embodiment, the specific execution process of step S404 may refer to embodiment S104 in the foregoing, which is not described herein again.
S405, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S405 may be detected by the humidity sensor in the foregoing.
And S406, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S406 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 5 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 5, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s501, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution process of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S501 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S502, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode;
optionally, the preset first condensation condition in this embodiment is the same as the preset first condensation condition in step S102;
here, if the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air-conditioning operation dehumidification mode is controlled.
In the present embodiment, the dehumidification mode includes: controlling a compressor of the air conditioner to be switched to a first set frequency and continuously run for a second time;
specifically, the first set frequency is a frequency value preset for the compressor, and optionally, the frequency value is a frequency value with a higher value so as to increase the exhaust temperature of the compressor, so that the temperature of a refrigerant flowing into the indoor unit heat exchanger after throttling can reach a lower temperature so as to improve the condensation and dehumidification effects; here, when the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air conditioner switches from a frequency corresponding to the previous operation mode to a first set frequency;
optionally, the second time period is 1 hour.
The air conditioner can increase condensed dew on the indoor unit of the air conditioner through the operation dehumidification mode, so that the phase state transformation and precipitation of water vapor in the indoor environment are accelerated, the water vapor content and the relative humidity in the air of the indoor environment can be reduced, the humidity condition of the indoor environment in the conventional mode (such as the refrigeration mode) of the air conditioner operation is changed, and then the condensation amount of the air conditioner is effectively reduced or even no condensation is generated in the conventional mode of the air conditioner operation.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S503, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity and the second indoor temperature in step S503 may refer to embodiment S501 in the foregoing, and is not described herein again.
S504, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
in this embodiment, the specific execution process of step S504 may refer to embodiment S104 in the foregoing, which is not described herein again.
S505, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S505 may be detected by the humidity sensor in the foregoing.
And S506, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S506 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 6 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 6, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s601, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution process of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S601 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S602, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling an air conditioner to operate in a dehumidification mode;
optionally, the preset first condensation condition in this embodiment is the same as the preset first condensation condition in step S102;
here, if the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air-conditioning operation dehumidification mode is controlled.
In the present embodiment, the dehumidification mode includes: performing first rotation speed compensation on the inner fan and continuously operating for a second time;
specifically, the first rotation speed compensation of the inner fan is a positive value or a negative value, when the first rotation speed compensation is the positive value, the rotation speed of the inner fan is increased, and when the first rotation speed compensation is the negative value, the rotation speed of the inner fan is reduced;
here, before the air conditioner leaves the factory, in the process of operating the air conditioner in the dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S602, the rate of moisture condensation on the outer surface of the heat exchanger of the indoor unit during the operation of the internal fan of the air conditioner at different rotation speeds is measured and calculated, and the rotation speed of the internal fan corresponding to the fastest rate of moisture condensation is associated with the coil temperature of the dehumidification mode, so that the association relationship between the coil temperature and the rotation speed of the internal fan during the operation of the dehumidification mode of one or more air conditioners can be obtained, and the association relationship is prestored in the air conditioner.
In this way, in the process of executing the dehumidification mode in step S602, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and find and obtain the corresponding rotation speed of the inner fan according to the detected coil temperature and the preset association relationship. Therefore, the first rotation speed compensation is the difference value between the searched rotation speed and the rotation speed of the fan in the previous working mode of the air conditioner operation.
Optionally, the second time period is 1 hour.
The air conditioner can increase condensed dew on the indoor unit of the air conditioner through the operation dehumidification mode, so that the phase state transformation and precipitation of water vapor in the indoor environment are accelerated, the water vapor content and the relative humidity in the air of the indoor environment can be reduced, the humidity condition of the indoor environment in the conventional mode (such as the refrigeration mode) of the air conditioner operation is changed, and then the condensation amount of the air conditioner is effectively reduced or even no condensation is generated in the conventional mode of the air conditioner operation.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S603, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity and the second indoor temperature in step S603 may refer to embodiment S601 in the foregoing, and is not described herein again.
S604, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
in this embodiment, the specific execution process of step S604 may refer to embodiment S104 in the foregoing, which is not described herein again.
S605, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S605 may be detected by the humidity sensor in the foregoing.
And S606, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S606 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 7 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 7, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s701, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution process of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S701 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S702, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode;
optionally, the preset first condensation condition in this embodiment is the same as the preset first condensation condition in step S102;
here, if the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air-conditioning operation dehumidification mode is controlled.
In the present embodiment, the dehumidification mode includes: the air deflector is switched to a set air outlet angle and continuously operates for a second time;
specifically, the air outlet angle of the air deflector can determine the air outlet volume of the air outlet of the air conditioner, the dehumidification capacity is different under different air volumes, and the purpose of improving the dehumidification capacity can be achieved by adjusting the air outlet angle of the air deflector.
Here, before the air conditioner leaves the factory, in the process of operating the air conditioner in the dehumidification mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S702, the air deflector of the air conditioner operates at different air outlet angles and the rate of water vapor condensation on the outer surface of the indoor unit heat exchanger is measured, and the air outlet angle of the air deflector corresponding to the fastest rate of water vapor condensation is associated with the coil temperature in the dehumidification mode, so that the association relationship between the coil temperatures and the air outlet angles of the air deflectors when the one or more air conditioners operate in the dehumidification mode can be obtained, and the association relationship is prestored in the air conditioner.
In this way, in the process of executing the dehumidification mode in step S702, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and find and obtain the corresponding air outlet angle of the air deflector according to the detected coil temperature and the preset association relationship.
Optionally, the second time period is 1 hour.
The air conditioner can increase condensed dew on the indoor unit of the air conditioner through the operation dehumidification mode, so that the phase state transformation and precipitation of water vapor in the indoor environment are accelerated, the water vapor content and the relative humidity in the air of the indoor environment can be reduced, the humidity condition of the indoor environment in the conventional mode (such as the refrigeration mode) of the air conditioner operation is changed, and then the condensation amount of the air conditioner is effectively reduced or even no condensation is generated in the conventional mode of the air conditioner operation.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S703, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity and the second indoor temperature in step S703 may refer to embodiment S701 in the foregoing, which is not described herein again.
S704, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
in this embodiment, the specific execution process of step S704 may refer to embodiment S104 in the foregoing, which is not described herein again.
S705, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S705 may be detected by the humidity sensor in the foregoing.
And S706, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S706 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 8 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 8, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s801, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution process of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S801 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S802, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode;
optionally, in the present embodiment, the specific execution process of step S802 may refer to step S102 in the foregoing embodiment, which is not described herein again.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S803, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity and the second indoor temperature in step S803 may refer to embodiment S801 in the foregoing, which is not described herein again.
S804, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
optionally, the preset second condensation condition in this embodiment is the same as the second condensation condition preset in step S102;
optionally, the auxiliary dehumidification mode includes: and controlling the air deflector to be maintained at the set air outlet angle and continuously operating for a third time.
Optionally, the third time period is 1 hour.
S805, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S805 may be detected by the humidity sensor in the foregoing.
And S806, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S806 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 9 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 9, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s901, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution process of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S901 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S902, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode;
optionally, in the present embodiment, the specific execution process of step S902 may refer to step S102 in the foregoing embodiment, which is not described herein again.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S903, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity and the second indoor temperature in step S903 may refer to embodiment S901 in the foregoing, which is not described herein again.
S904, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
optionally, the preset second condensation condition in this embodiment is the same as the second condensation condition preset in step S102;
optionally, the auxiliary dehumidification mode includes performing a second speed compensation on the inner fan and continuously operating for a third time period.
The second rotation speed compensation of the inner fan is a positive value or a negative value, when the second rotation speed compensation is the positive value, the rotation speed of the inner fan is increased, and when the second rotation speed compensation is the negative value, the rotation speed of the inner fan is reduced;
here, before the air conditioner leaves the factory, in a manner of one or more sets of experimental measurements, etc., the humidity change rate and the temperature change rate in the test environment where the air conditioner is located in the process of operating the internal fan of the air conditioner at different rotation speeds are measured and calculated after the air conditioner operates in the dehumidification mode of step S102 in step S104, and the rotation speed of the internal fan corresponding to the maximum humidity drop and the minimum temperature change rate is used as the rotation speed of the internal fan in the auxiliary dehumidification mode, and the rotation speed of the internal fan is prestored in the air conditioner.
In this way, the air conditioner may switch the rotation speed of the inner fan to the previously stored rotation speed of the inner fan during the execution of the auxiliary dehumidification mode in step S104. Therefore, the dehumidification efficiency in the auxiliary dehumidification stage can be ensured, and the problems of fluctuation of indoor temperature and influence on the comfort level of users caused by the operation of the auxiliary dehumidification mode can be reduced.
Optionally, the third time period is 1 hour.
S905, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S905 can be detected by the humidity sensor in the foregoing.
And S906, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S906 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 10 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 10, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s1001, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution process of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S1001 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S1002, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling an air conditioner to operate in a dehumidification mode;
optionally, in the present embodiment, the specific execution process of step S1002 may refer to step S102 in the foregoing embodiment, which is not described herein again.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S1003, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific execution process of acquiring the second indoor humidity and the second indoor temperature in step S1003 may refer to embodiment S1001 in the foregoing, and is not described herein again.
S1004, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
optionally, the preset second condensation condition in this embodiment is the same as the second condensation condition preset in step S102;
optionally, the auxiliary dehumidification mode includes: and controlling a compressor of the air conditioner to maintain the first set frequency and continuously run for a third time period.
Optionally, the third time period is 1 hour.
S1005, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
here, the third indoor humidity in step S1005 may be detected by the humidity sensor in the foregoing.
And S1006, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S1006 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 11 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 11, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s1101, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
s1102, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode;
s1103, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
s1104, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
s1105, acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
in this embodiment, the specific execution flow of steps S1101 to S1105 can refer to steps S101 to S105 in the foregoing, which is not described herein again.
And S1106, controlling the air conditioner to operate in a temperature and humidity double-control mode if the humidity in the third chamber meets a preset third condensation condition.
The air conditioner condensation preventing method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by judging through the parameters of indoor temperature and humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user through the control flow combining the dehumidification mode, the auxiliary dehumidification mode and the temperature and humidity double control mode.
In an optional embodiment, the air conditioner operation temperature and humidity double control mode is controlled, and the air conditioner operation temperature and humidity double control mode comprises the steps of determining a target operation frequency of an air conditioner compressor based on a third indoor temperature and a third indoor humidity after the air conditioner operation auxiliary dehumidification mode, so that the temperature of an inner coil of the air conditioner is increased to a preset target coil temperature for reducing condensation of water vapor into dew; the target coil temperature is greater than the condensation temperature of the current operating condition.
Specifically, determining the target operating frequency of the air conditioner compressor based on the third indoor temperature and the third indoor humidity after the air conditioner operation dehumidification mode includes: determining a temperature difference value between the third indoor temperature and the target temperature and a humidity difference value between the third indoor humidity and the target humidity; determining a first operating frequency of the compressor according to the temperature difference, and determining a second operating frequency of the compressor according to the humidity difference; a target operating frequency of the compressor is determined based on the first operating frequency and the second operating frequency.
Here, the target temperature and the target humidity are environmental parameter ranges that can be achieved by a desired indoor environment input by a user through a remote controller, an input panel, or the like, or environmental parameter ranges that satisfy a user comfort requirement automatically set by an air conditioner.
Optionally, the first operating frequency of the air-conditioning compressor is obtained by performing PID calculation according to the following formula:
Hz1=Out_gain*[Kp*Dn+Ki*Pn+Kd*(Dn-Dn-1)];
wherein D isn=Pn–Pn-1,Dn-1=Pn-1–Pn-2
Hz1 is the first operating frequency, Out _ gain is the output coefficient, Kp is the proportional control quantity, Ki is the integral control quantity, Kd is the derivative control quantity, DnA first temperature deviation value between the temperature difference value of the current process and the first temperature difference value determined in the previous process, Dn-1A second temperature deviation value, P, of the first temperature difference value and a second temperature difference value determined last timenIs the temperature difference, P, of the current processn-1Is a first temperature difference, Pn-2Is a second temperature difference;
and performing PID calculation according to the following formula to obtain a second operating frequency of the air-conditioning compressor:
Hz2=Out_gain*[Kp*dn+Ki*pn+Kd*(dn-dn-1)];
wherein d isn=pn–pn-1,dn-1=pn-1–pn-2
Hz2 is the second operating frequency, Out _ gain is the output coefficient, Kp is the proportional control quantity, Ki is the integral control quantity, Kd is the derivative control quantity, dnA first humidity deviation value, d, of the humidity difference value of the current process and the first humidity difference value determined last timen-1A second humidity deviation value, p, for the first humidity difference value and a second humidity difference value determined last timenIs the humidity difference of the current process, pn-1Is a first humidity difference, pn-2Is a second humidity difference;
determining a target operating frequency of the compressor according to the first operating frequency and the second operating frequency may specifically include: and comparing the first operating frequency with the second operating frequency, and determining the operating frequency with a larger value as the target operating frequency of the compressor, so that the refrigerant quantity output to the air conditioner refrigerant circulating system by the compressor meets the refrigerant quantity requirement of the air conditioner operation, and can be matched with the current working condition, thereby achieving the effects of saving energy, reducing consumption and improving the overall performance of the air conditioner. .
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises: determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
Fig. 12 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 12, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s1201, acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located;
in this embodiment, the specific execution flow of acquiring the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S1201 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S1202, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a temperature and humidity double-control mode;
optionally, the first condensation condition preset in step S1202 is the same as the first condensation condition preset in step S102.
Here, if the first indoor humidity and the first indoor temperature satisfy a preset first condensation condition, the air conditioner operation temperature and humidity dual control mode is controlled.
In this embodiment, the specific process of the air-conditioning operation temperature and humidity dual control mode may refer to the technical content disclosed in the embodiment corresponding to fig. 11, which is not described herein again.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S1203, acquiring a second indoor humidity after the air conditioner runs in the dehumidification mode;
in this embodiment, the specific implementation process of acquiring the second indoor humidity in step S1203 may refer to embodiment S1201 in the foregoing, which is not described herein again.
And S1204, if the second indoor humidity meets a preset second condensation condition, controlling the air conditioner to operate in an anti-condensation mode.
In this embodiment, the specific execution process of step S1204 may refer to embodiment S106 in the foregoing, which is not described herein again.
The air conditioner condensation preventing method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by combining the parameters of indoor temperature, humidity and the like acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user by combining a temperature-humidity double control mode and a condensation preventing mode.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode specifically comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew; here, the target coil temperature is greater than the dew condensation temperature for the current operating conditions.
In this embodiment, the anti-condensation mode is to raise the temperature of the inner coil of the air conditioner to a temperature higher than the condensation temperature of the current working condition, so that the residual condensed water on the heat exchanger of the indoor unit is converted into a gaseous state, and the amount of the condensed water on the outer surface of the heat exchanger of the indoor unit is reduced. Here, since part of the moisture in the indoor ambient air has been condensed out when the air-conditioning operation is in the temperature-humidity dual control mode in step S102, the moisture content in the indoor environment has been effectively reduced in step S102; after the air conditioner executes the integrated process, the air conditioner is switched to the previous working mode to operate (such as a refrigeration mode), and the temperature environment of water vapor condensation can be caused due to the lower temperature of the surface of the heat exchanger of the indoor unit during the operation of the refrigeration mode, so that the amount of condensed water on the surface of the heat exchanger of the indoor unit is increased. Aiming at the problem, when the second condensation condition of the step S104 is met, the temperature of the inner coil is controlled to be increased, so that the residual water vapor of the air conditioner after the air conditioner operates in the temperature and humidity double-control mode is evaporated, the residual condensed water on the outer surface of the heat exchanger of the indoor unit is reduced, and the water quantity on the outer surface of the heat exchanger of the indoor unit after the air conditioner is switched back to the cooling mode can be reduced.
Generally, when the air conditioner operates in the temperature and humidity dual control mode, the temperature of a coil pipe of an indoor unit of the air conditioner is low, and therefore, the temperature of the indoor environment is further reduced in the process of operating the temperature and humidity dual control mode of the air conditioner. In an alternative embodiment, in order to reduce the influence of the secondary temperature fluctuation on the indoor environment when the air conditioner operates in the anti-condensation mode, the target coil temperature should also satisfy the following relationship:
indoor temperature-target coil temperature is less than or equal to A;
and A is a calculation threshold, and the indoor temperature is the indoor temperature obtained after the air conditioner runs in the temperature and humidity double-control mode.
Optionally, a is a predetermined fixed value, such as 5 ℃, i.e. the temperature difference between the room temperature and the target coil temperature after the increase is less than or equal to 5 ℃. Generally, the temperature of the target coil is lower than the indoor temperature, the temperature difference between the indoor temperature and the raised target coil temperature is maintained within 5 ℃, and the problems that the indoor temperature is further reduced and the body feeling comfort of a user is influenced under the condition that the temperature of the target coil is lower (the temperature difference between the indoor temperature and the raised target coil temperature is greater than 5 ℃) can be solved.
Alternatively, in yet another alternative embodiment, the calculated threshold A is a parameter determined based on the current operating conditions. Specifically, the control method further includes: and determining a calculation threshold value A based on the coil temperature in the temperature and humidity double-control mode of air conditioner operation and a preset incidence relation.
Here, before the air conditioner leaves the factory, after the air conditioner operates the temperature and humidity double control mode at different coil temperatures (e.g., 1 ℃, 2 ℃, etc.) in step S102 is measured and calculated in a manner of one or more sets of experimental measurements, and if the second condensation condition in step S104 is satisfied, after the air conditioner operates the anti-condensation mode at different target coil temperatures, the amount of condensation water remaining on the outer surface of the heat exchanger of the indoor unit is calculated, and the target coil temperature corresponding to the minimum amount of condensation water remaining is associated with the coil temperature, so that the association relationship between the coil temperature in the temperature and humidity double control mode of operation of one or more air conditioners and the target coil temperature in the anti-condensation mode can be obtained, and the association relationship is prestored in the air conditioner.
In this way, during the execution of the temperature and humidity dual control mode in step S102, the air conditioner may detect the coil temperature of the indoor unit through another sensor, and in step S104, the calculation threshold a is found according to the detected coil temperature and the preset association relationship.
In an optional embodiment, in the preset association relationship, the corresponding relationship of positive correlation between the coil temperature when the air conditioner operates in the temperature and humidity dual control mode and the calculation threshold a is set, that is, the higher the coil temperature when the temperature and humidity dual control mode is, the smaller the reduction amount of the indoor environment temperature in the dehumidification process is, the larger the calculation threshold a may be set, at this time, because the temperature influence of the temperature and humidity dual control mode on the indoor environment is lower, the target coil temperature setting value when the air conditioner executes the condensation prevention mode may also be lower, so that the overall influence of the control flow combining the temperature and humidity dual control mode and the condensation prevention mode on the indoor environment temperature may also be controlled within a limited range.
On the contrary, the lower the coil temperature in the temperature and humidity dual control mode is, the smaller the calculation threshold a is set to, so that the target coil temperature setting value in the air conditioner performing the anti-condensation mode may also be higher and close to the indoor temperature, so as to compensate for the reduced temperature of the indoor environment caused in the temperature and humidity dual control mode, and avoid the indoor temperature from being reduced and deviating from the comfortable temperature range desired by the user.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency; optionally, a plurality of working frequency values or frequency ranges may be preset in the compressor of the air conditioner from low to high, where the air conditioner is adjusted to a lower working frequency value or frequency range when the compressor of the air conditioner operates in the anti-condensation mode;
an inner fan of the air conditioner runs at a high wind gear; the air conditioner is characterized in that a plurality of wind speed gears are preset on an inner fan of the air conditioner, such as a low wind gear, a medium wind gear and a high wind gear, the rotating speeds of the fans at the three gears are sequentially increased, and the air output of an indoor unit of the air conditioner is sequentially increased;
an outer fan of the air conditioner runs at a low wind gear; the method is characterized in that a gear setting mode similar to that of an inner fan of the air conditioner is adopted, a plurality of wind speed gears are preset on an outer fan of the air conditioner, such as a low wind gear, a medium wind gear and a high wind gear, the rotating speeds of the fans at the three gears are sequentially increased, and the air output of an outdoor unit of the air conditioner is sequentially increased;
the throttling device of the air conditioner operates at a large opening flow rate; optionally, a plurality of opening values or opening ranges can be preset in the throttling device of the air conditioner from small to large, and here, when the air conditioner operates in the anti-condensation mode, the throttling device of the air conditioner is adjusted to be a larger opening value or opening range;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle; optionally, the air guide assembly of the air conditioner comprises an air deflector provided with an air outlet of the air conditioner, wherein an air outlet angle is set as an angle at which the air conditioner can perform air outlet at the maximum air outlet amount, and at this time, the wind blocking influence of the air guide assembly on the air outlet airflow flowing through the air outlet is the lowest, so that the air outlet airflow with evaporated steam can be discharged out of the indoor unit as soon as possible.
Fig. 13 is a flowchart illustrating a method of preventing condensation of an air conditioner according to the present invention, according to still another exemplary embodiment.
As shown in fig. 13, the present invention provides another method for preventing condensation of an air conditioner, which can be used to solve the problem that the air conditioner is prone to condensation in environments such as high temperature and high humidity in summer; specifically, the method mainly comprises the following steps:
s1301, acquiring first indoor humidity and first indoor temperature of the environment where the air conditioner is located;
in this embodiment, the specific execution process of obtaining the first indoor humidity and the first indoor temperature of the environment where the air conditioner is located in step S1301 may refer to step S101 in the foregoing embodiment, which is not described herein again.
S1302, if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a temperature and humidity double-control mode;
optionally, the preset first condensation condition in this embodiment is the same as the preset first condensation condition in step S102;
in this embodiment, the specific process of the air-conditioning operation temperature and humidity dual control mode may refer to the technical content disclosed in the embodiment corresponding to fig. 11, which is not described herein again.
And if the first indoor humidity and the first indoor temperature do not meet the preset first condensation condition, ending the control process.
S1303, acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
in this embodiment, the specific implementation process of obtaining the second indoor humidity and the second indoor temperature in step S1303 may refer to embodiment S1301 in the foregoing, and details are not described herein.
S1304, if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode;
in this embodiment, the specific execution process of step S1304 may refer to embodiment S104 in the foregoing, which is not described herein again.
S1305, acquiring third indoor humidity after the air conditioner runs in the auxiliary dehumidification mode;
here, the third indoor humidity in step S1305 may also be detected by the humidity sensor in the foregoing.
And S1306, if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In this embodiment, the specific execution process of step S1306 may refer to embodiment S106 in the foregoing, which is not described herein again.
The anti-condensation air conditioner control method provided by the invention can accurately judge whether the current running state and the environmental condition of the air conditioner possibly cause the condensation problem of the air conditioner by combining the indoor temperature and humidity and other parameters acquired for many times and combining the preset condensation condition, and can reduce the condensation problem of the air conditioner and improve the use experience of a user by combining the temperature and humidity double control mode, the auxiliary dehumidification mode and the anti-condensation mode.
In an alternative embodiment, the method for controlling the temperature and humidity dual control mode of the air conditioner comprises the steps of determining a target operation frequency of an air conditioner compressor based on a first indoor temperature and a first indoor humidity so as to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the first indoor temperature-target coil temperature is less than or equal to A;
wherein A is a calculation threshold.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature of the air conditioner and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the temperature of the coil of the air conditioner and the calculation threshold A.
In an alternative embodiment, determining the target operating frequency of the air conditioner compressor based on the first indoor temperature and the first indoor humidity includes:
determining a temperature difference value between the first indoor temperature and the target temperature and a humidity difference value between the first indoor humidity and the target humidity;
determining a first operating frequency of the compressor according to the temperature difference, and determining a second operating frequency of the compressor according to the humidity difference;
a target operating frequency of the compressor is determined based on the first operating frequency and the second operating frequency.
In an optional embodiment, the control of the air conditioner operation condensation prevention mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an optional embodiment, the control method further comprises:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, controlling and adjusting one or more operating parameters of the air conditioner includes:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
Here, for the specific implementation processes of the multiple optional embodiments, reference may be made to the technical contents disclosed in the corresponding parts in the embodiment of fig. 1, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of performing the control flow disclosed in the embodiment of fig. 1 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with: a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an inner fan, switching an air deflector to a set air outlet angle and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency, performing second rotation speed compensation on an internal fan and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
The controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of performing the control flow disclosed in the embodiment of fig. 2 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an inner fan and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency, performing second rotation speed compensation on an internal fan and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of performing the control flow disclosed in the embodiment of fig. 3 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with: a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, controlling the air deflector to be switched to a set air outlet angle and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency, performing second rotation speed compensation on an internal fan and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of executing the control flow disclosed in the embodiment of fig. 4 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of carrying out first rotating speed compensation on the inner fan, switching the air deflector to a set air outlet angle and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency, performing second rotation speed compensation on an internal fan and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of executing the control flow disclosed in the embodiment of fig. 5 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency and continuously run for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency, performing second rotation speed compensation on an internal fan and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of performing the control flow disclosed in the embodiment of fig. 6 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of carrying out first rotating speed compensation on the inner fan and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency, performing second rotation speed compensation on an internal fan and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of performing the control flow disclosed in the embodiment of fig. 7 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling the air deflector to be switched to a set air outlet angle and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency, performing second rotation speed compensation on an internal fan and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of executing the control flow disclosed in the embodiment of fig. 8 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an inner fan, switching an air deflector to a set air outlet angle and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling an air deflector of the air conditioner to be maintained at a set air outlet angle and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of executing the control flow disclosed in the embodiment of fig. 9 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an inner fan, switching an air deflector to a set air outlet angle and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency and continuously run for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of executing the control flow disclosed in the embodiment of fig. 10 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an inner fan, switching an air deflector to a set air outlet angle and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency and continuously run for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of executing the control flow disclosed in the embodiment of fig. 11.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an inner fan, switching an air deflector to a set air outlet angle and continuously operating for a second time; and the number of the first and second groups,
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to maintain a first set frequency, performing second rotation speed compensation on an internal fan and continuously operating for a third time; and the number of the first and second groups,
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a temperature and humidity double-control mode.
In an alternative embodiment, the controller is specifically configured to determine a target operating frequency of the air conditioner compressor based on a third indoor temperature and a third indoor humidity after the air conditioner operates in the auxiliary dehumidification mode, so as to raise an inner coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner runs in the auxiliary dehumidification mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the auxiliary dehumidification mode of the air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the auxiliary dehumidification mode.
In an alternative embodiment, the air conditioner is specifically configured to:
determining a temperature difference value between the third indoor temperature and the target temperature and a humidity difference value between the third indoor humidity and the target humidity;
determining a first operating frequency of the compressor according to the temperature difference, and determining a second operating frequency of the compressor according to the humidity difference;
a target operating frequency of the compressor is determined based on the first operating frequency and the second operating frequency.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of executing the control flow disclosed in the embodiment of fig. 12 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity after the temperature and humidity double-control mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a temperature and humidity double-control mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; and
and if the second indoor humidity meets the preset second condensation condition, controlling the air conditioner to operate in the condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to controllably adjust one or more operating parameters of the air conditioner to raise an internal coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the second indoor temperature-the target coil temperature is less than or equal to A;
and A is a calculation threshold, and the second indoor temperature is the second indoor temperature obtained after the air conditioner operates in the temperature and humidity double-control mode.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature in the temperature and humidity double-control mode of air conditioner operation and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature and the calculation threshold A when the air conditioner operates in the temperature and humidity double-control mode.
In an alternative embodiment, the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
an inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
the air guide component of the indoor unit of the air conditioner is switched to a set air outlet angle.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are not described herein again.
In an alternative embodiment, the present invention further provides an air conditioner capable of executing the control flow disclosed in the embodiment of fig. 13 above.
The air conditioner includes the air conditioner organism, and the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where an air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the temperature and humidity double-control mode of air conditioner operation; acquiring a third indoor humidity after the auxiliary dehumidification mode of air conditioner operation;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a temperature and humidity double-control mode; the preset first condensation condition comprises that the first indoor humidity is greater than a first humidity threshold value, and the duration of the first indoor temperature which is greater than a temperature threshold value is greater than or equal to a first duration; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold, and the second humidity threshold is smaller than the first humidity threshold; the auxiliary dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out second rotation speed compensation on an inner fan and continuously operating for a third time; and
and if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode.
In an alternative embodiment, the controller is specifically configured to determine a target operating frequency of the air conditioning compressor based on the first indoor temperature and the first indoor humidity to raise an inner coil temperature of the air conditioner to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current operating condition.
In an alternative embodiment, the target coil temperature should also satisfy the following relationship:
the first indoor temperature-target coil temperature is less than or equal to A;
wherein A is a calculation threshold.
In an alternative embodiment, the controller is further configured to:
determining a calculation threshold value A based on the coil temperature of the air conditioner and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the temperature of the coil of the air conditioner and the calculation threshold A.
In an alternative embodiment, the controller is specifically configured to:
determining a temperature difference value between the first indoor temperature and the target temperature and a humidity difference value between the first indoor humidity and the target humidity;
determining a first operating frequency of the compressor according to the temperature difference, and determining a second operating frequency of the compressor according to the humidity difference;
a target operating frequency of the compressor is determined based on the first operating frequency and the second operating frequency.
The specific manner of executing the above process by the air conditioner control may refer to the foregoing embodiments, which are 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 (4)

1. A method of preventing condensation in an air conditioner, the method comprising:
acquiring a first indoor humidity and a first indoor temperature of an environment where the air conditioner is located;
if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an internal fan, switching an air deflector to a set air outlet angle and continuously operating for a second time;
acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold value, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold value, and the second humidity threshold value is smaller than the first humidity threshold value; the auxiliary dehumidification mode comprises the step of controlling the air deflector of the air conditioner to be maintained at a set air outlet angle and continuously run for a third time;
acquiring a third indoor humidity after the air conditioner operates in the auxiliary dehumidification mode;
if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode;
the control of the air conditioner operation anti-condensation mode comprises the steps of controlling and adjusting one or more operation parameters of the air conditioner so as to enable the temperature of an inner coil of the air conditioner to be increased to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current working condition;
the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
wherein A is a calculation threshold, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates the auxiliary dehumidification mode;
determining the calculation threshold A based on the coil temperature of the air conditioner in the auxiliary dehumidification mode and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature when the air conditioner operates in the auxiliary dehumidification mode and the calculation threshold A.
2. The method of claim 1, wherein the controlling adjusts one or more operating parameters of the air conditioner, comprising:
a compressor of the air conditioner operates at a low frequency;
the inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
and the air guide assembly of the indoor unit of the air conditioner is switched to a set air outlet angle.
3. The utility model provides an air conditioner, its characterized in that, the air conditioner includes the air conditioner organism, the air conditioner organism is equipped with:
a sensor for: acquiring a first indoor humidity and a first indoor temperature of an environment where the air conditioner is located; acquiring a second indoor humidity and a second indoor temperature after the air conditioner operates in the dehumidification mode;
a controller to: if the first indoor humidity and the first indoor temperature meet a preset first condensation condition, controlling the air conditioner to operate in a dehumidification mode; the dehumidification mode comprises the steps of controlling a compressor of the air conditioner to be switched to a first set frequency, carrying out first rotation speed compensation on an internal fan, switching an air deflector to a set air outlet angle and continuously operating for a second time; and
if the second indoor humidity and the second indoor temperature meet a preset second condensation condition, controlling the air conditioner to operate in an auxiliary dehumidification mode; the second condensation condition comprises that the second indoor humidity is greater than a second humidity threshold value, the difference value between the second indoor temperature and the target temperature is smaller than a set temperature difference threshold value, and the second humidity threshold value is smaller than the first humidity threshold value; the auxiliary dehumidification mode comprises the step of controlling the air deflector of the air conditioner to be maintained at a set air outlet angle and continuously run for a third time; and
if the humidity in the third chamber meets a preset third condensation condition, controlling the air conditioner to operate in a condensation prevention mode;
the controller is specifically used for controlling and adjusting one or more operating parameters of the air conditioner so as to enable the temperature of an inner coil of the air conditioner to be raised to a preset target coil temperature for reducing condensation of water vapor into dew;
the target coil temperature is greater than the condensation temperature of the current working condition;
the target coil temperature should also satisfy the following relationship:
the third indoor temperature-the target coil temperature is less than or equal to A;
wherein A is a calculation threshold value, and the third indoor temperature is the third indoor temperature obtained after the air conditioner operates in the dehumidification mode;
the controller is further configured to:
determining the calculation threshold A based on the coil temperature of the air conditioner in the auxiliary dehumidification mode and a preset incidence relation; the preset incidence relation is used for representing the positive correlation corresponding relation between the coil temperature when the air conditioner operates in the auxiliary dehumidification mode and the calculation threshold A.
4. The air conditioner of claim 3, wherein the controller is specifically configured to:
a compressor of the air conditioner operates at a low frequency;
the inner fan of the air conditioner runs at a high wind gear;
an outer fan of the air conditioner runs at a low wind gear;
the throttling device of the air conditioner operates at a large opening flow rate;
and the air guide assembly of the indoor unit of the air conditioner is switched to a set air outlet angle.
CN201811255039.2A 2018-10-26 2018-10-26 Air conditioner and condensation preventing method thereof Active CN111102713B (en)

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