CN118089183A - Moistureproof control method and device for air conditioner, air conditioner and storage medium - Google Patents

Abstract

The application provides a moistureproof control method and device for an air conditioner, the air conditioner and a storage medium, wherein the moistureproof control method comprises the following steps: s1: acquiring the current indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} ; s2: controlling the running states of a compressor and a fan according to the indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} so as to realize dehumidification; the moisture-proof control method of the air conditioner can adjust the running states of the fan and the compressor by detecting the relation between the indoor dew point temperature and the wall temperature in real time so as to achieve better dehumidification effect, avoid condensation of walls and glass in a room and improve user experience.

Description

Moistureproof control method and device for air conditioner, air conditioner and storage medium

Technical Field

The invention relates to the technical field of air conditioners, in particular to a moistureproof control method and device for an air conditioner, the air conditioner and a storage medium.

Background

In southern China, a phenomenon of moisture regain occurs in spring every year, room walls and glass are easy to condense, and if a person is not in the room in daytime and a window is opened, conditions of wall body, bedding getting wet and water drops all occur may occur, so that a special air conditioning mode is required to prevent the occurrence of the phenomenon in the period.

Disclosure of Invention

In view of the above, the present invention is directed to a method and an apparatus for controlling moisture resistance of an air conditioner, an air conditioner and a storage medium thereof, so as to solve the problem that the wall and glass in the room are easy to be condensed in the spring of the south in the prior art.

In order to achieve the above purpose, the technical scheme of the invention is realized as follows:

a moisture-proof control method of an air conditioner, the moisture-proof control method comprising:

s1: acquiring the current indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} ;

S2: controlling the running states of a compressor and a fan according to the indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} so as to realize dehumidification;

Wherein, T _{Room temperature} is indoor environment temperature, Z is environment humidity, T _{Dew point} is indoor dew point temperature, T _{Wall body} is indoor wall temperature.

According to the moistureproof control method of the air conditioner, the running states of the fan and the compressor can be regulated by detecting the relation between the indoor dew point temperature and the wall temperature in real time, so that a better dehumidification effect is achieved, condensation of the wall and glass in a room is avoided, and user experience is improved.

Further, according to the indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} , the operation states of the compressor and the fan are controlled to realize dehumidification, the method comprises the following steps:

A1: judging whether to enter a dampproof mode, if so, entering A2, and if not, entering A1;

A2: judging whether T _{Dew point temperature} +1℃≤T _{Wall temperature} is present, if yes, entering A3;

a3: and (3) stopping the compressor, stopping the fan, and entering A2.

When the air conditioner enters a dampproof mode, the running state of the air conditioner can be flexibly adjusted to dehumidify according to the real-time wall temperature and the dew point temperature so as to adapt to different humidity environments.

Further, B1: in step A2, if T _{Dew point temperature} +1℃≤T _{Wall temperature} is not satisfied, then go to B2;

B2: judging whether T _{Dew point temperature} ≤T _{Wall temperature} ＜T _{Dew point temperature} +1 ℃, if so, entering B3;

B3: the compressor is stopped, the fan is started at the lowest wind speed of 20s, stopped for 40s, and enters A2.

The device can control the compressor and the fan to intermittently operate according to different dehumidification conditions, so that air convection can be promoted, the real-time performance of temperature detection is ensured, the conditions of excessive dehumidification or insufficient dehumidification are avoided, the dehumidification effect is improved, and the energy consumption can be reduced.

In the step B2, if T _{Dew point temperature} ≤T _{Wall temperature} ＜T _{Dew point temperature} +1deg.C is not satisfied, then C2 is entered;

C2: judging whether T _{Wall temperature} ＜T _{Dew point temperature} is present, if so, entering C3;

and C3: starting a compressor, continuously running a fan at the lowest wind speed, and entering C4;

and C4: judging whether T _{Dew point temperature} +2℃≤T _{Wall temperature} is available, if yes, entering C5, and if no, entering C4;

c5: and (3) stopping the compressor, stopping the fan, and entering A2.

The device can dehumidify in time, avoid condensation, save energy and reduce cost.

Further, D1: judging whether the compressor is started, if so, entering D2, and if not, entering D1;

d2: the compressor runs at an initial frequency, the fan runs at the lowest wind speed, and D3 is entered;

d3: the compressor and the fan run for a period of time T1 in a state, and enter D4;

D4: judging whether T _{Evaporator temperature} ≤T _{Dew point temperature} -3 ℃ or not, if so, entering D5;

d5: the fan runs at the lowest wind speed, the running frequency of the compressor is-2 Hz, and D6 is entered;

d6: judging whether the fan and the compressor are operated in a state for a period of time T2, if so, entering D4, and if not, entering D6;

wherein T _Evaporator is the evaporator temperature.

The arrangement can reduce the influence on the indoor environment and can also achieve the effect of energy conservation.

Further, E1: in the step D4, if T _{Evaporator temperature} ≤T _{Dew point temperature} -3 ℃ is not satisfied, E2 is entered;

e2: judging whether T _{Dew point temperature} -3℃＜T _{Evaporator temperature} ≤T _{Dew point temperature} -1 ℃, if so, entering E3, and if not, entering E4;

e3: the fan runs at the lowest wind speed, the compressor maintains frequency running, and D6 is entered;

E4: compressor operating frequency +2hz, fan operating at minimum wind speed, enter D6.

When T _{Dew point temperature} -3℃＜T _{Evaporator temperature} ≤T _{Dew point temperature} -1 ℃, the evaporator can be used for stably dehumidifying, the fan runs at the lowest wind speed, the compressor maintains the running at the existing frequency, the air conditioner can be enabled to provide a stable dehumidifying effect, when T _{Evaporator temperature} ≤T _{Dew point temperature} -3 ℃ is met, the evaporator can be used for effectively dehumidifying, the frequency of the compressor can be reduced to ensure the lowest influence on the energy saving and the environment temperature, and when T _{Evaporator temperature} ＞T _{Dew point temperature} -1 ℃, the running frequency of the compressor is increased, the dehumidifying efficiency is improved, and condensation is prevented.

Further, F1: detecting and judging whether the compressor is started, if so, entering F2, and if not, entering F1;

F2: recording indoor environment temperature T _{Opening the ring temperature} at the starting time of the compressor, and entering F3;

F3: judging whether the compressor runs for a period of time T3 at the frequency, if so, entering F4, and if not, entering F3;

f4: judging whether T _{Room temperature} +2℃≤T _{Opening the ring temperature} is available, if yes, entering F5, and if no, entering F4;

And F5: starting an electric heating belt and entering F6;

F6: judging whether the compressor runs for a period of time T3 at the frequency, if so, entering F7, and if not, entering F6;

F7: judging whether T _{Room temperature} ≥T _{Opening the ring temperature} is present, if yes, entering F8, if no, entering F7;

F8: closing the electric heating belt and entering F2;

Wherein T _{Opening the ring temperature} is the indoor ambient temperature at the time of the compressor start.

In order to avoid great influence on the environment temperature during the operation of the moistureproof mode, people feel uncomfortable, when the compressor is operated, the working state of the electric heating belt is controlled according to the relation between the current indoor environment temperature and the indoor environment temperature at the starting moment of the compressor, the indoor environment temperature can be maintained in a set temperature interval while the dehumidification effect is ensured, and the influence on the body feeling of a user due to the fact that the temperature is too low is avoided.

A moistureproof control device of an air conditioner operates according to the moistureproof control method described above.

An air conditioner comprising a computer readable storage medium storing a computer program and a processor, the computer program implementing the moisture-proof control method described above when read and run by the processor.

A computer readable storage medium storing a computer program which, when read and run by a processor, implements the moisture control method described above.

Compared with the prior art, the moistureproof control method and device for the air conditioner, the air conditioner and the storage medium have the following advantages:

1) The running states of the fan and the compressor can be regulated by detecting the relation between the indoor dew point temperature and the wall temperature in real time, so that a better dehumidification effect is achieved, the wall and glass in a room are prevented from being condensed, and the user experience is improved;

2) The working state of the electric heating belt is controlled according to the relation between the current indoor environment temperature and the indoor environment temperature at the starting moment of the compressor, so that the indoor environment temperature can be maintained in a set temperature interval while the dehumidification effect is ensured, and the influence of the excessively low temperature on the body feeling of a user is avoided.

Drawings

FIG. 1 is a flow chart of a method for controlling moisture resistance of an air conditioner according to an embodiment of the present invention;

FIG. 2 is a flow chart of an operating strategy for a compressor according to an embodiment of the present invention;

fig. 3 is a flowchart of an operation strategy of the electric heating belt according to an embodiment of the present invention.

Detailed Description

In order that the above objects, features and advantages of the invention will be readily understood, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

Example 1

As shown in fig. 1 to 3, a moisture-proof control method of an air conditioner, the moisture-proof control method comprising:

s1: acquiring the current indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} ;

S2: controlling the running states of a compressor and a fan according to the indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} so as to realize dehumidification;

Wherein, T _{Room temperature} is indoor environment temperature, Z is environment humidity, T _{Dew point} is indoor dew point temperature, T _{Wall body} is indoor wall temperature.

According to the moistureproof control method of the air conditioner, the running states of the fan and the compressor can be regulated by detecting the relation between the indoor dew point temperature and the wall temperature in real time, so that a better dehumidification effect is achieved, condensation of the wall and glass in a room is avoided, and user experience is improved.

As a preferred example of the present application, the steps of controlling the operation states of the compressor and the blower to achieve dehumidification according to the indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} include:

A1: judging whether to enter a dampproof mode, if so, entering A2, and if not, entering A1;

A2: judging whether T _{Dew point temperature} +1℃≤T _{Wall temperature} is present, if yes, entering A3;

a3: and (3) stopping the compressor, stopping the fan, and entering A2.

Specifically, when the air conditioner enters a dampproof mode, the running state of the air conditioner can be flexibly adjusted to dehumidify according to the real-time wall temperature and the dew point temperature so as to adapt to different humidity environments.

As a preferred example of the present application, B1: in step A2, if T _{Dew point temperature} +1℃≤T _{Wall temperature} is not satisfied, then go to B2;

B2: judging whether T _{Dew point temperature} ≤T _{Wall temperature} ＜T _{Dew point temperature} +1 ℃, if so, entering B3;

B3: the compressor is stopped, the fan is started at the lowest wind speed of 20s, stopped for 40s, and enters A2.

Specifically, the device can control the compressor and the fan to intermittently operate according to different dehumidification conditions, so that air convection can be promoted, the real-time performance of temperature detection is ensured, the conditions of excessive dehumidification or insufficient dehumidification are avoided, the dehumidification effect is improved, and the energy consumption is reduced.

In step B2, if T _{Dew point temperature} ≤T _{Wall temperature} ＜T _{Dew point temperature} +1deg.C is not satisfied, then enter C2;

C2: judging whether T _{Wall temperature} ＜T _{Dew point temperature} is present, if so, entering C3;

and C3: starting a compressor, continuously running a fan at the lowest wind speed, and entering C4;

and C4: judging whether T _{Dew point temperature} +2℃≤T _{Wall temperature} is available, if yes, entering C5, and if no, entering C4;

c5: and (3) stopping the compressor, stopping the fan, and entering A2.

Specifically, when T _{Wall temperature} ＜T _{Dew point temperature} , wall temperature is less than dew point temperature, has the risk of condensation, starts compressor and fan this moment, can in time reduce indoor humidity, avoids the wall body dewing, and when T _{Dew point temperature} +2℃≤T _{Wall temperature} , dew point temperature is lower, does not have the risk of condensation, closes compressor and fan this moment, can the energy saving, and this kind of setting both can in time dehumidify, avoids the condensation, can also the energy saving, reduce cost.

As a preferred example of the present application, D1: judging whether the compressor is started, if so, entering D2, and if not, entering D1;

d2: the compressor runs at an initial frequency, the fan runs at the lowest wind speed, and D3 is entered;

d3: the compressor and the fan run for a period of time T1 in a state, and enter D4;

D4: judging whether T _{Evaporator temperature} ≤T _{Dew point temperature} -3 ℃ or not, if so, entering D5;

d5: the fan runs at the lowest wind speed, the running frequency of the compressor is-2 Hz, and D6 is entered;

d6: judging whether the fan and the compressor are operated in a state for a period of time T2, if so, entering D4, and if not, entering D6;

wherein T _Evaporator is the evaporator temperature.

Specifically, when T _{Evaporator temperature} ≤T _{Dew point temperature} -3 ℃, the evaporator can effectively dehumidify, so that the temperature of the evaporator is lower than the dew point temperature, the dehumidification purpose can be achieved, and at the moment, the frequency of the compressor is reduced, so that the influence on the indoor environment can be reduced, and the energy-saving effect can be achieved.

As a preferred example of the present application, E1: in the step D4, if T _{Evaporator temperature} ≤T _{Dew point temperature} -3 ℃ is not satisfied, E2 is entered;

e2: judging whether T _{Dew point temperature} -3℃＜T _{Evaporator temperature} ≤T _{Dew point temperature} -1 ℃, if so, entering E3, and if not, entering E4;

e3: the fan runs at the lowest wind speed, the compressor maintains frequency running, and D6 is entered;

E4: compressor operating frequency +2hz, fan operating at minimum wind speed, enter D6.

Specifically, when T _{Dew point temperature} -3℃＜T _{Evaporator temperature} ≤T _{Dew point temperature} -1 ℃, the evaporator can be shown to be capable of stably dehumidifying, at the moment, the fan runs at the lowest wind speed, the compressor maintains the running at the existing frequency, so that the air conditioner can provide a stable dehumidifying effect, and when T _{Evaporator temperature} ≤T _{Dew point temperature} -3 ℃ is met, the evaporator is shown to be effectively dehumidified, and in order to ensure the energy saving and the lowest influence on the environment temperature, the frequency of the compressor can be reduced; when the temperature is between T _{Evaporator temperature} ＞T _{Dew point temperature} and 1 ℃, the running frequency of the compressor is increased, and the dehumidification efficiency is improved so as to prevent condensation.

As a preferred example of the present application, F1: detecting and judging whether the compressor is started, if so, entering F2, and if not, entering F1;

F2: recording indoor environment temperature T _{Opening the ring temperature} at the starting time of the compressor, and entering F3;

F3: judging whether the compressor runs for a period of time T3 at the frequency, if so, entering F4, and if not, entering F3;

f4: judging whether T _{Room temperature} +2℃≤T _{Opening the ring temperature} is available, if yes, entering F5, and if no, entering F4;

And F5: starting an electric heating belt and entering F6;

F6: judging whether the compressor runs for a period of time T3 at the frequency, if so, entering F7, and if not, entering F6;

F7: judging whether T _{Room temperature} ≥T _{Opening the ring temperature} is present, if yes, entering F8, if no, entering F7;

F8: closing the electric heating belt and entering F2;

Wherein T _{Opening the ring temperature} is the indoor ambient temperature at the time of the compressor start.

Specifically, in order to avoid causing great influence to the ambient temperature when the dampproof mode is operated, the human body feels uncomfortable, and when the compressor is operated, the working state of the electric heating belt is controlled according to the relation between the current indoor ambient temperature and the indoor ambient temperature at the moment when the compressor is started, so that the indoor ambient temperature can be maintained in a set temperature interval while the dehumidification effect is ensured, and the influence of the temperature to the body feeling of a user due to the fact that the temperature is too low is avoided.

In addition, the present application also provides a moisture-proof control device of an air conditioner, which operates according to the moisture-proof control method described above, the moisture-proof control device comprising:

The indoor temperature sensor is used for detecting indoor environment temperature in real time, the indoor humidity sensor is used for detecting indoor environment humidity in real time, the indoor wall temperature sensor is arranged on the surface of an indoor wall or embedded into the wall and used for detecting indoor wall temperature in real time, and the evaporator temperature sensor is arranged on the surface of the evaporator and used for detecting evaporator temperature in real time;

The dew point temperature acquisition unit is used for acquiring the dew point temperature according to the indoor environment temperature and the indoor environment humidity; the dew point temperature is obtained through the indoor environment temperature and the environment humidity in the prior art, and is not described herein.

The storage unit is used for storing the indoor temperature, the indoor humidity, the wall temperature, the evaporator temperature information, the compressor frequency adjustment amplitude information and the like detected by the detection unit;

The judging unit can execute corresponding judging actions according to the moistureproof control method, such as judging the magnitude relation between the wall temperature and the dew point temperature, the magnitude relation between the evaporator temperature and the dew point temperature, judging whether the frequency of the compressor accords with the setting or not according to the magnitude relation between the current indoor environment temperature and the indoor environment temperature at the starting moment of the compressor, judging whether the rotating speed of the fan accords with the setting or not, and the like;

the control unit can control the air conditioner to operate according to the moistureproof control method according to the information transmitted by the detection unit, the dew point temperature acquisition unit, the storage unit and the judgment unit;

Preferably, the indoor wall temperature sensor transmits the temperature data to the control unit through wireless transmission.

Furthermore, the application also provides an air conditioner, which comprises an indoor unit and an outdoor unit, wherein the indoor unit comprises an indoor heat exchanger, an inner motor and the like, the outdoor unit comprises a compressor, an outer motor, an outdoor heat exchanger and the like, the air conditioner also comprises a computer readable storage medium and a processor, wherein a computer program is stored in the computer readable storage medium, and the processor reads and runs the computer program to realize the moisture-proof control method.

The application also provides a computer readable storage medium storing a computer program which, when read and run by a processor, implements the moisture protection control method described above.

In summary, the moisture-proof control method and device for the air conditioner, the air conditioner and the storage medium have the following advantages: 1) The running states of the fan and the compressor can be regulated by detecting the relation between the indoor dew point temperature and the wall temperature in real time, so that a better dehumidification effect is achieved, the wall and glass in a room are prevented from being condensed, and the user experience is improved; 2) The working state of the electric heating belt is controlled according to the relation between the current indoor environment temperature and the indoor environment temperature at the starting moment of the compressor, so that the indoor environment temperature can be maintained in a set temperature interval while the dehumidification effect is ensured, and the influence of the excessively low temperature on the body feeling of a user is avoided.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the invention, and the scope of the invention should be assessed accordingly to that of the appended claims.

Claims (10)

1. A moisture-proof control method of an air conditioner, the control method comprising:

s1: acquiring the current indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} ;

S2: controlling the running states of a compressor and a fan according to the indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body} so as to realize dehumidification;

Wherein, T _{Room temperature} is indoor environment temperature, Z is environment humidity, T _{Dew point} is indoor dew point temperature, T _{Wall body} is indoor wall temperature.

2. The method of claim 1, wherein the step of controlling the operation states of the compressor and the blower according to the indoor environment temperature T _{Room temperature} , the indoor environment humidity Z, the indoor dew point temperature T _{Dew point} and the indoor wall temperature T _{Wall body ,} to achieve dehumidification comprises:

A1: judging whether to enter a dampproof mode, if so, entering A2, and if not, entering A1;

A2: judging whether T _{Dew point temperature} +1℃≤T _{Wall temperature} is present, if yes, entering A3;

a3: and (3) stopping the compressor, stopping the fan, and entering A2.

3. A moisture control method as claimed in claim 2, wherein,

B1: in step A2, if T _{Dew point temperature} +1℃≤T _{Wall temperature} is not satisfied, then go to B2;

B2: judging whether T _{Dew point temperature} ≤T _{Wall temperature} ＜T _{Dew point temperature} +1 ℃, if so, entering B3;

B3: the compressor is stopped, the fan is started at the lowest wind speed of 20s, stopped for 40s, and enters A2.

4. A moisture control method as claimed in claim 3, wherein,

C1, in the step B2, if T _{Dew point temperature} ≤T _{Wall temperature} ＜T _{Dew point temperature} +1deg.C is not satisfied, entering C2;

C2: judging whether T _{Wall temperature} ＜T _{Dew point temperature} is present, if so, entering C3;

and C3: starting a compressor, continuously running a fan at the lowest wind speed, and entering C4;

and C4: judging whether T _{Dew point temperature} +2℃≤T _{Wall temperature} is available, if yes, entering C5, and if no, entering C4;

c5: and (3) stopping the compressor, stopping the fan, and entering A2.

5. The moisture control method of claim 4, wherein,

D1: judging whether the compressor is started, if so, entering D2, and if not, entering D1;

d2: the compressor runs at an initial frequency, the fan runs at the lowest wind speed, and D3 is entered;

d3: the compressor and the fan run for a period of time T1 in a state, and enter D4;

D4: judging whether T _{Evaporator temperature} ≤T _{Dew point temperature} -3 ℃ or not, if so, entering D5;

d5: the fan runs at the lowest wind speed, the running frequency of the compressor is-2 Hz, and D6 is entered;

d6: judging whether the fan and the compressor are operated in a state for a period of time T2, if so, entering D4, and if not, entering D6;

wherein T _Evaporator is the evaporator temperature.

6. The moisture control method of claim 5, wherein,

E1: in the step D4, if T _{Evaporator temperature} ≤T _{Dew point temperature} -3 ℃ is not satisfied, E2 is entered;

e2: judging whether T _{Dew point temperature} -3℃＜T _{Evaporator temperature} ≤T _{Dew point temperature} -1 ℃, if so, entering E3, and if not, entering E4;

e3: the fan runs at the lowest wind speed, the compressor maintains frequency running, and D6 is entered;

E4: compressor operating frequency +2hz, fan operating at minimum wind speed, enter D6.

7. The moisture control method of claim 1, wherein,

F1: detecting and judging whether the compressor is started, if so, entering F2, and if not, entering F1;

F2: recording indoor environment temperature T _{Opening the ring temperature} at the starting time of the compressor, and entering F3;

F3: judging whether the compressor runs for a period of time T3 at the frequency, if so, entering F4, and if not, entering F3;

f4: judging whether T _{Room temperature} +2℃≤T _{Opening the ring temperature} is available, if yes, entering F5, and if no, entering F4;

And F5: starting an electric heating belt and entering F6;

F6: judging whether the compressor runs for a period of time T3 at the frequency, if so, entering F7, and if not, entering F6;

F7: judging whether T _{Room temperature} ≥T _{Opening the ring temperature} is present, if yes, entering F8, if no, entering F7;

F8: closing the electric heating belt and entering F2;

Wherein T _{Opening the ring temperature} is the indoor ambient temperature at the time of the compressor start.

8. A moisture-proof control apparatus of an air conditioner, characterized in that the moisture-proof control apparatus operates according to the moisture-proof control method as claimed in any one of the preceding claims 1 to 7.

9. An air conditioner comprising a computer readable storage medium storing a computer program and a processor, the computer program implementing the moisture-proof control method according to any one of claims 1 to 7 when read and executed by the processor.

10. A computer readable storage medium, characterized in that the computer readable storage medium stores a computer program which, when read and run by a processor, implements the moisture protection control method according to any one of claims 1 to 7.