CN114576834A - Control method, device and equipment for no-wind-sense function and storage medium - Google Patents

Abstract

The invention discloses a control method, a control device, control equipment and a storage medium for a no-wind-sense function, wherein if a no-wind-sense function starting signal is received, a no-wind-sense default angle mode is entered, and environmental parameters are obtained; comparing the environmental parameter with a preset parameter threshold value, and determining a non-wind-sensation target angle mode according to a comparison result; and controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode, and entering the non-wind-sensation target angle mode. According to the invention, after the no-wind-sense function starting signal is received, the no-wind-sense target angle mode is rapidly determined according to the environmental parameters, and the air conditioner rapidly enters the no-wind-sense target mode by controlling the sliding-out length of the rotational flow air deflector, so that the cooling requirement of a user based on no wind sense is met, the use efficiency of the no-wind-sense function is improved, and the use experience of the no-wind-sense function of the user is improved.

Description

Control method, device and equipment for no-wind-sense function and storage medium

Technical Field

The invention relates to the technical field of air conditioning equipment, in particular to a control method, a control device, control equipment and a storage medium for a no-wind-sense function.

Background

With the continuous improvement of the living standard of people, the air conditioner is more and more widely used in thousands of households, and the demand of people on the air conditioner is not simply kept on the common refrigerating and heating functions, so that how to provide a comfortable use environment for users becomes a more concerned topic and becomes a popular research of air conditioner manufacturers.

In order to enable a user to obtain experience of no wind feeling and cool feeling, the user is generally advised to start the no wind feeling under the condition that the room temperature is not very high, so that the requirements of the user on refrigeration and no wind feeling can be met. However, the existing control conditions are harsh, and the user can only get into the no-wind feeling function when the air conditioner is operated for a long time, so that the use efficiency of the no-wind feeling function is low, and the experience of the no-wind feeling function of the user is seriously influenced.

Disclosure of Invention

The invention mainly aims to provide a control method, a control device, control equipment and a storage medium for a no-wind-sensation function, and aims to solve the technical problems that the use efficiency of the current no-wind-sensation function is low, and the experience of the no-wind-sensation function of a user is seriously influenced.

In order to achieve the above object, an embodiment of the present invention provides a method for controlling a non-wind-sensing function, where the method for controlling a non-wind-sensing function includes:

if a no-wind-sense function starting signal is received, entering a no-wind-sense default angle mode, and acquiring environmental parameters;

comparing the environmental parameter with a preset parameter threshold value, and determining a non-wind-sensation target angle mode according to a comparison result; and

and controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode, and entering the non-wind-sensation target angle mode.

Preferably, the step of controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode includes:

searching in a preset slide-out length table according to the non-wind-sensation target angle mode;

determining the sliding-out length of the non-wind-sensation target angle mode from the preset sliding-out length table; and

and controlling the rotational flow air deflector to slide out by the sliding-out length to enter the non-wind-sensation target angle mode.

Preferably, the environmental parameter includes an environmental temperature, the preset parameter threshold includes a preset temperature threshold, the comparing the environmental parameter with the preset parameter threshold, and the determining the non-wind-sensation target angle mode according to the comparison result includes:

carrying out ratio operation on the environment temperature and a preset temperature threshold value to obtain the ratio of the environment temperature to the preset temperature threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the ratio of the ambient temperature to the preset temperature threshold.

Preferably, the environmental parameter includes an environmental humidity, the preset parameter threshold includes a preset humidity threshold, the step of comparing the environmental parameter with the preset parameter threshold and determining the non-wind-feeling target angle mode according to the comparison result further includes:

carrying out ratio operation on the environment humidity and a preset humidity threshold value to obtain the ratio of the environment humidity and the preset humidity threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the ratio of the environment humidity to the preset humidity threshold value.

Preferably, the step of comparing the environmental parameter with a preset parameter threshold value and determining the non-wind-sensation target angle mode according to the comparison result further includes:

performing difference operation on the environment temperature and a preset temperature threshold to obtain a difference value of the environment temperature and the preset temperature threshold; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the difference value between the environment temperature and the preset temperature threshold value.

Preferably, the step of comparing the environmental parameter with a preset parameter threshold value and determining the non-wind-sensation target angle mode according to the comparison result further includes:

performing difference operation on the environment humidity and a preset humidity threshold value to obtain a difference value of the environment humidity and the preset humidity threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the difference value between the environment humidity and the preset humidity threshold value.

Preferably, the step of entering the no-wind-sense default angle mode if the no-wind-sense function start signal is received includes:

if a non-wind-sensing function starting signal is received, determining whether the microporous air deflector is positioned at a refrigerating angle; and

and if the microporous air deflector is positioned at the refrigerating angle, controlling the rotational flow air deflector to slide out, forming a non-wind-sense default angle with the microporous air deflector, and entering a non-wind-sense default angle mode.

In order to achieve the above object, the present invention also provides a control device without a wind-sensing function, comprising:

the receiving module is used for entering a no-wind-sense default angle mode and acquiring environmental parameters if a no-wind-sense function starting signal is received;

the determining module is used for comparing the environmental parameters with preset parameter thresholds and determining a non-wind-sensation target angle mode according to a comparison result; and

and the control module is used for controlling the rotational flow air deflector to slide out by the sliding-out length corresponding to the non-wind-sensation target angle mode and enter the non-wind-sensation target angle mode.

Further, in order to achieve the above object, the present invention also provides a control device without a wind-sensing function, which includes a memory, a processor, and a control program without a wind-sensing function stored in the memory and executable on the processor, wherein the control program without a wind-sensing function implements the steps of the control method without a wind-sensing function when executed by the processor.

Further, in order to achieve the above object, the present invention provides a storage medium having a control program of the non-wind-sensing function stored thereon, wherein the control program of the non-wind-sensing function implements the steps of the control method of the non-wind-sensing function when executed by a processor.

The embodiment of the invention provides a control method, a control device, control equipment and a storage medium for a no-wind-sense function, wherein if a no-wind-sense function starting signal is received, a no-wind-sense default angle mode is entered, and environmental parameters are obtained; comparing the environmental parameter with a preset parameter threshold value, and determining a non-wind-sensation target angle mode according to a comparison result; and controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode, and entering the non-wind-sensation target angle mode. According to the invention, after the no-wind-sense function starting signal is received, the no-wind-sense target angle mode is quickly determined according to the environmental parameters, and the air conditioner quickly enters the no-wind-sense target mode by controlling the sliding-out length of the cyclone air deflector, so that the no-wind-sense cooling requirement of a user is met, the use efficiency of the no-wind-sense function is improved, and the use experience of the no-wind-sense function of the user is improved.

Drawings

FIG. 1 is a schematic structural diagram of a hardware operating environment according to an embodiment of a control method for a non-wind-sensing function of the present invention;

FIG. 2 is a flowchart illustrating a control method without a wind-sensing function according to a first embodiment of the present invention;

FIG. 3 is a schematic view of the air conditioner at the shutdown angle;

FIG. 4 is a schematic view of the air conditioner of the present invention in a cooling position;

FIG. 5 is a schematic structural view of the air conditioner at a default angle without wind sensation according to the present invention;

FIG. 6 is a schematic view of the present invention showing the swirl vanes in a staggered configuration;

FIG. 7 is a flowchart illustrating a control method without a wind-sensing function according to a second embodiment of the present invention;

FIG. 8 is a flowchart illustrating a control method without a wind-sensing function according to a third embodiment of the present invention;

FIG. 9 is a functional block diagram of a control device without a wind sensing function according to a preferred embodiment of the present invention.

The implementation, functional features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The embodiment of the invention provides a control method, a control device, control equipment and a storage medium for a no-wind-sense function, wherein if a no-wind-sense function starting signal is received, a no-wind-sense default angle mode is entered, and environmental parameters are obtained; comparing the environmental parameter with a preset parameter threshold value, and determining a non-wind-sensation target angle mode according to a comparison result; and controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode, and entering the non-wind-sensation target angle mode. According to the invention, after the no-wind-sense function starting signal is received, the no-wind-sense target angle mode is rapidly determined according to the environmental parameters, and the air conditioner rapidly enters the no-wind-sense target mode by controlling the sliding-out length of the rotational flow air deflector, so that the cooling requirement of a user based on no wind sense is met, the use efficiency of the no-wind-sense function is improved, and the use experience of the no-wind-sense function of the user is improved.

As shown in fig. 1, fig. 1 is a schematic structural diagram of a control device without a wind sensing function in a hardware operating environment according to an embodiment of the present invention.

In the following description, suffixes such as "module", "component", or "unit" used to denote elements are used only for facilitating the explanation of the present invention, and have no specific meaning in itself. Thus, "module", "component" or "unit" may be used mixedly.

The control device without the wind sensing function in the embodiment of the invention can be a PC, and can also be a mobile terminal device such as a tablet computer and a portable computer.

As shown in fig. 1, the control apparatus of the no-wind-sensing function may include: a processor 1001, such as a CPU, a network interface 1004, a user interface 1003, a memory 1005, a communication bus 1002. The communication bus 1002 is used to implement connection communication among these components. The user interface 1003 may include a Display screen (Display), an input unit such as a Keyboard (Keyboard), and the optional user interface 1003 may also include a standard wired interface, a wireless interface. The network interface 1004 may optionally include a standard wired interface, a wireless interface (e.g., WI-FI interface). The memory 1005 may be a high-speed RAM memory or a non-volatile memory (e.g., a magnetic disk memory). The memory 1005 may alternatively be a storage device separate from the processor 1001.

It will be appreciated by those skilled in the art that the configuration of the non-wind-activated control device shown in fig. 1 does not constitute a limitation of the non-wind-activated control device and may include more or fewer components than those shown, or some components may be combined, or a different arrangement of components.

As shown in fig. 1, a memory 1005, which is a storage medium, may include therein an operating system, a network communication module, a user interface module, and a control program of a non-sensory function.

In the device shown in fig. 1, the network interface 1004 is mainly used for connecting to a backend server and performing data communication with the backend server; the user interface 1003 is mainly used for connecting a client (user side) and performing data communication with the client; and the processor 1001 may be configured to call a control program of the non-wind-sensing function stored in the memory 1005, and perform the following operations:

if a no-wind-sense function starting signal is received, entering a no-wind-sense default angle mode, and acquiring environmental parameters;

comparing the environmental parameter with a preset parameter threshold value, and determining a non-wind-sensation target angle mode according to a comparison result; and

and controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode, and entering the non-wind-sensation target angle mode.

Further, the step of controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode and entering the non-wind-sensation target angle mode comprises the following steps:

searching in a preset slide-out length table according to the non-wind-sensation target angle mode;

determining the sliding-out length of the non-wind-sensation target angle mode from the preset sliding-out length table; and

and controlling the rotational flow air deflector to slide out by the sliding-out length to enter the non-wind-sensation target angle mode.

Further, the step of comparing the environmental parameter with a preset parameter threshold value and determining the non-wind-sensation target angle mode according to the comparison result includes:

carrying out ratio operation on the environment temperature and a preset temperature threshold value to obtain the ratio of the environment temperature to the preset temperature threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the ratio of the ambient temperature to the preset temperature threshold.

Further, the step of comparing the environmental parameter with a preset parameter threshold value and determining the non-wind-sensation target angle mode according to the comparison result further includes:

carrying out ratio operation on the environment humidity and a preset humidity threshold value to obtain the ratio of the environment humidity and the preset humidity threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the ratio of the environment humidity to the preset humidity threshold value.

Further, the step of comparing the environmental parameter with a preset parameter threshold value and determining the non-wind-sensation target angle mode according to the comparison result further includes:

performing difference operation on the environment temperature and a preset temperature threshold value to obtain a difference value of the environment temperature and the preset temperature threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the difference value between the environment temperature and the preset temperature threshold value.

Further, the step of comparing the environmental parameter with a preset parameter threshold value and determining the non-wind-sensation target angle mode according to the comparison result further includes:

performing difference operation on the environment humidity and a preset humidity threshold value to obtain a difference value of the environment humidity and the preset humidity threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the difference value between the environment humidity and the preset humidity threshold value.

Further, the step of entering the no-wind-sense default angle mode if the no-wind-sense function start signal is received includes:

if a no-wind-sense function starting signal is received, determining whether the microporous air deflector is at a refrigerating angle; and

and if the microporous air deflector is positioned at the refrigerating angle, controlling the rotational flow air deflector to slide out, forming a non-wind-sense default angle with the microporous air deflector, and entering a non-wind-sense default angle mode.

For a better understanding of the above technical solutions, exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

In order to better understand the technical solution, the technical solution will be described in detail with reference to the drawings and the specific embodiments.

Referring to fig. 2, a first embodiment of the invention provides a flow chart of a control method for a non-wind-sensing function. In this embodiment, the control method of the no-wind-sense function includes the following steps:

step S10, if a no-wind-sense function starting signal is received, entering a no-wind-sense default angle mode and acquiring environmental parameters;

in this embodiment, the control method of the no-wind-sensation function is applied to an air conditioner, and the air conditioner at least includes: the wind wheel is used for forming wind by utilizing electric energy, the wind outlet channel is used for transmitting the wind formed by the wind wheel, the micropore air deflector is provided with micropores for ventilation, the cyclone air deflector can be used for performing cyclone dispersion on the wind transmitted by the wind outlet channel, so that direct current wind is dispersed around, cold wind direct blowing is avoided, the direct current wind can be cooled more quickly by dispersing the direct current wind, the cyclone wind blade is arranged on the cyclone air deflector and at least has two staggered and overlapped forms, the direct current wind can pass through and perform cyclone dispersion when staggered, and the direct current wind is blocked when overlapped. Referring to fig. 3, fig. 3 is a schematic structural view of the air conditioner at a shutdown angle, at the shutdown angle, the microporous air deflector is closed, the rotational flow air deflector does not slide out and is in a contracted state, the rotational flow air vanes are in an overlapped state, and the wind wheel stops running; referring to fig. 4, fig. 4 is a schematic structural view of the air conditioner at a refrigerating angle, at the refrigerating angle, the microporous air deflectors are opened, so that the wind wheel rotates to form and wind transmitted through the wind outlet duct is supplied from the opening to the outside, at the moment, the rotational flow air deflectors do not slide out and are in a contraction state, and the rotational flow wind leaves are in an overlapping state; referring to fig. 5 and 6, fig. 5 is a schematic structural view of the air conditioner at a non-wind-sensation default angle, fig. 6 is a schematic view of the rotational flow air vanes in a staggered form, at the non-wind-sensation default angle, the microporous air guide plates are opened, so that wind formed by rotation of the wind wheel is supplied from the openings to the outside, at the moment, the rotational flow air guide plates all slide out, the rotational flow air vanes are in the staggered form, the wind transmitted by the wind outlet channel can be subjected to rotational flow dispersion through the rotational flow air vanes on the rotational flow air guide plates, wherein the rotational flow air guide plates can slide out different sliding-out lengths according to different angle modes, and non-wind-sensation refrigeration functions of different degrees are realized.

Further, when needing to perform non-wind cooling, a user can start the air conditioner through the remote controller and select a refrigeration mode to operate, or start the air conditioner through touching or clicking a start button on the air conditioner and touch or click a refrigeration key on the air conditioner to trigger the air conditioner to operate in the refrigeration mode, and when operating in the refrigeration mode, the microporous air deflector in the air conditioner operates at a refrigeration angle. Further, when the air conditioner receives a no-wind-sense function starting signal sent by a user based on a no-wind-sense key, the air deflector component consisting of the microporous air deflector and the rotational flow air deflector is controlled to be switched to a no-wind-sense default angle from an original angle, and the air conditioner enters a no-wind-sense default angle mode. Further, still be provided with detection module in the air conditioner, wherein detection module can be used to detect the environmental parameter such as the temperature of current environment and humidity data, and after getting into the default angle mode of no wind sense, the air conditioner still need adjust the mode of locating according to current environment, therefore the air conditioner calls detection module, carries out the environmental parameter detection to current environment through detection module, wherein the environmental parameter can include ambient temperature and ambient humidity in this embodiment.

Further, if the no-wind-sense function start signal is received, the step of entering the no-wind-sense default angle mode includes:

step S11, if the no-wind-sensing function starting signal is received, determining whether the micropore air deflector is at the refrigerating angle; and

and step S12, if the microporous air deflector is at the refrigerating angle, controlling the rotational flow air deflector to slide out, forming a non-wind-sense default angle with the microporous air deflector, and entering a non-wind-sense default angle mode.

Furthermore, when the air conditioner receives a no-wind-sense function starting signal sent by a user based on a no-wind-sense key, whether a microporous air deflector is controlled in the air conditioner is at a refrigerating angle needs to be determined, and only when the microporous air deflector is currently at the refrigerating angle, the rotational flow air deflector can be slid out and forms a no-wind-sense default angle together with the microporous air deflector, so that no-wind-sense refrigeration is realized; specifically, the current position of the micro-hole air deflector can be detected, and the current angle of the micro-hole air deflector can be determined. Further, if the microporous air deflector is detected to be in the refrigerating angle currently, the rotational flow air deflector is completely slid out from the original contraction state and is in lap joint with the microporous air deflector to form a closed triangular area serving as a non-wind-sensation default angle, so that the air conditioner smoothly enters the non-wind-sensation default angle mode.

Step S20, comparing the environmental parameter with a preset parameter threshold value, and determining a non-wind-sensation target angle mode according to the comparison result;

furthermore, the air conditioner is also provided with a calculation module which can be used for calculating, after entering the no-wind-sense default angle mode and acquiring the environmental parameters, the air conditioner can call the calculation module, comparing the environmental parameter with a preset parameter threshold value through a calculation module, determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to a comparison result, the preset parameter threshold comprises a preset temperature threshold and a preset humidity threshold in the embodiment, the preset temperature threshold can be a comfortable temperature value set by a user according to actual requirements, the preset humidity threshold is a comfortable humidity value set by the user according to actual requirements, and the plurality of non-wind-sensation angle modes can comprise a non-wind-sensation first angle mode, a non-wind-sensation second angle mode, a non-wind-sensation third angle mode and a non-wind-sensation default angle mode in the embodiment.

And step S30, controlling the rotational flow air deflector to slide out by a sliding-out length corresponding to the non-wind-sensation target angle mode, and entering the non-wind-sensation target angle mode.

Further, after the no-wind-sensation target angle mode is determined, the air conditioner searches the sliding-out length corresponding to the no-wind-sensation target angle mode from the preset sliding-out length table, then controls the cyclone air deflector to slide out according to the searched sliding-out length and lap-joint with the microporous air deflector to form a closed triangular area as the no-wind-sensation target angle, so that the air conditioner enters the no-wind-sensation target angle mode, the no-wind-sensation cooling requirement of a user is met, the no-wind-sensation function use experience of the user is improved, wherein the preset sliding-out length table is provided with a plurality of no-wind-sensation angle modes, and each no-wind-sensation angle mode has a corresponding sliding-out length. It can be understood that the preset slide-out length table may not be set in this embodiment, specifically, the slide-out may be performed according to a complete slide-out of 1 and a non-slide-out of 0, and the other angle modes are between 0 and 1; it can be further understood that if the sliding-out length of the swirling air deflector in the non-wind-sensation target angle mode is the same as that of the swirling air deflector in the non-wind-sensation default angle mode, the non-wind-sensation default angle mode is maintained.

The embodiment provides a control method, a control device, equipment and a storage medium for a no-wind-sense function, wherein if a no-wind-sense function starting signal is received, a no-wind-sense default angle mode is entered, and an ambient temperature and/or an ambient humidity are/is acquired; determining a non-wind-sensation target angle mode according to the difference value between the environment temperature and a preset temperature threshold value and/or the difference value between the environment humidity and a preset humidity threshold value; and controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode, and entering the non-wind-sensation target angle mode. According to the invention, after the no-wind-sense function starting signal is received, the no-wind-sense target angle mode is rapidly determined according to the ambient temperature or the ambient humidity, and the air conditioner rapidly enters the no-wind-sense target mode by controlling the sliding-out length of the rotational flow air deflector, so that the cooling requirement of a user based on no wind sense is met, the use efficiency of the no-wind-sense function is improved, and the use experience of the no-wind-sense function of the user is improved.

Further, referring to fig. 7, a second embodiment of the control method without a wind-sensing function according to the present invention is provided based on the first embodiment of the control method without a wind-sensing function according to the present invention, in the second embodiment, the step of controlling the cyclone air deflector to slide out of the slide-out length corresponding to the target angular mode without a wind-sensing function includes:

step S31, searching in a preset slide-out length table according to the non-wind-feeling target angle mode;

step S32, determining the sliding-out length of the non-wind-sensation target angle mode from the preset sliding-out length table; and

and step S33, controlling the cyclone air deflector to slide out by the sliding-out length, and entering the non-wind-sensation target angle mode.

Further, after the non-wind-sensation target angle mode is determined, the air conditioner uses the non-wind-sensation target angle mode as a retrieval formula, searches in the preset slide-out length table, and determines whether the slide-out length corresponding to the non-wind-sensation target angle mode exists in the preset slide-out length table. Further, if the sliding-out length corresponding to the non-wind-sensation target angle mode is found, determining the sliding-out length as the sliding-out length of the cyclone air deflector. Further, the air conditioner controls the cyclone air deflector to slide out according to the determined sliding-out length, and the cyclone air deflector is overlapped with the micropore air deflector to form a closed triangular area, so that the air conditioner enters a non-wind-sensing target angle mode. For example, the determined non-wind-sensing target angle mode is a non-wind-sensing second angle mode, the air conditioner uses the non-wind-sensing second angle mode as an index mode, the index mode is searched in a preset slide-out length table, whether a slide-out length corresponding to the non-wind-sensing second angle mode exists in the preset slide-out length table is determined, if the searched slide-out length is half of the slide-out length, half of the slide-out length is determined as the slide-out length corresponding to the non-wind-sensing second angle mode, then the vortex air deflector is controlled to slide out by half of the slide-out length, and the vortex air deflector is overlapped with the micropore air deflector after sliding out by half, so that a closed triangular area is formed, and the air conditioner enters the non-wind-sensing second angle mode.

According to the embodiment, the corresponding sliding-out length is quickly searched in the preset sliding-out length meter according to the non-wind-sensation target angle mode, the cyclone air deflector is controlled to slide out according to the determined sliding-out length, the non-wind-sensation target angle mode is entered, the sliding-out length is quickly determined, and the cyclone air deflector is controlled to slide out, so that the air conditioner can quickly enter the non-wind-sensation target angle mode, the purposes of quickly entering the non-wind-sensation and quickly cooling are achieved, the cooling requirement of a user based on the non-wind-sensation is met, the use efficiency of the non-wind-sensation function is improved, and the use experience of the non-wind-sensation function of the user is improved.

Further, referring to fig. 8, a third embodiment of the control method of a non-wind-sensing function of the present invention is proposed based on the first embodiment of the control method of a non-wind-sensing function of the present invention, in the third embodiment, the environment parameter includes an environment temperature, the preset parameter threshold includes a preset temperature threshold, the step of comparing the environment parameter with the preset parameter threshold and determining the non-wind-sensing target angle mode according to the comparison result includes:

step A1, performing ratio operation on the environment temperature and a preset temperature threshold value to obtain the ratio of the environment temperature and the preset temperature threshold value; and

step A2, determining a non-wind-feeling target angle mode from a plurality of non-wind-feeling angle modes according to the ratio of the environment temperature to the preset temperature threshold.

The air conditioner can call the calculation module, input the data of the ambient temperature and the data of the preset temperature threshold into the calculation module, and perform the ratio operation on the ambient temperature and the preset temperature threshold through the calculation module, specifically, the ambient temperature can be input into the calculation module first, the preset temperature threshold is input into the calculation module after the ratio operator is selected, and the ratio of the ambient temperature and the preset temperature threshold is obtained after the operation is completed; further, the air conditioner uses ratio data between the ambient temperature and a preset temperature threshold value as a search formula, searches from a plurality of non-wind-sensation angle modes, determines whether the non-wind-sensation angle mode corresponding to the ratio between the ambient temperature and the preset temperature threshold value exists, and determines the non-wind-sensation angle mode as a non-wind-sensation target angle mode if the non-wind-sensation angle mode corresponding to the ratio between the ambient temperature and the preset temperature threshold value exists.

Further, the step of comparing the environmental parameter with a preset parameter threshold and determining the non-wind-feeling target angle mode according to the comparison result further comprises:

step B1, carrying out ratio operation on the environment humidity and a preset humidity threshold value to obtain the ratio of the environment humidity and the preset humidity threshold value; and

and step B2, determining a non-wind-feeling target angle mode from a plurality of non-wind-feeling angle modes according to the ratio of the environmental humidity to the preset humidity threshold value.

The air conditioner can also call the calculation module, input the data of the ambient humidity and the data of the preset humidity threshold into the calculation module, and perform the ratio operation on the ambient humidity and the preset humidity threshold through the calculation module, specifically, the ambient humidity can be input into the calculation module, the preset humidity threshold is input into the calculation module after the ratio operator is selected, and the ratio of the ambient humidity and the preset humidity threshold is obtained after the operation is completed; further, the air conditioner uses ratio data between the ambient humidity and the preset humidity threshold value as a search formula, searches from a plurality of non-wind-sensation angle modes, determines whether a non-wind-sensation angle mode corresponding to the ratio between the ambient humidity and the preset humidity threshold value exists, and determines the non-wind-sensation angle mode as a non-wind-sensation target angle mode if the non-wind-sensation angle mode corresponding to the ratio between the ambient humidity and the preset humidity threshold value exists.

Further, the step of comparing the environmental parameter with a preset parameter threshold value and determining the non-wind-sensation target angle mode according to the comparison result further includes:

step C1, performing difference operation on the environment temperature and a preset temperature threshold value to obtain a difference value between the environment temperature and the preset temperature threshold value; and

and step C2, determining a non-wind-feeling target angle mode from a plurality of non-wind-feeling angle modes according to the difference value between the environment temperature and the preset temperature threshold value.

Furthermore, the air conditioner can also call a calculation module, the data of the ambient temperature and the data of the preset temperature threshold are input into the calculation module, and the difference value between the ambient temperature and the preset temperature threshold is obtained through the difference value calculation of the ambient temperature and the preset temperature threshold by the calculation module. Further, the air conditioner searches for a difference between the ambient temperature and the preset temperature threshold as a search formula from a plurality of non-wind-sensation angle modes, determines whether the non-wind-sensation angle mode corresponding to the difference between the ambient temperature and the preset temperature threshold exists, and determines the non-wind-sensation angle mode as the non-wind-sensation target angle mode if the non-wind-sensation angle mode corresponding to the difference between the ambient temperature and the preset temperature threshold exists. It can be understood that each of the plurality of non-wind-sensing angle modes corresponds to a temperature difference range, and the non-wind-sensing cooling capacities of the different non-wind-sensing angle modes are different. For example, the air conditioner includes 3 non-wind-sensing angle modes (a non-wind-sensing first angle mode, a non-wind-sensing second angle mode, and a non-wind-sensing third angle mode), where T is greater than or equal to 0 and less than or equal to 1.5, T is greater than or equal to 1.5 and less than or equal to 3.5, T is a temperature unit, and if the difference between the ambient temperature and the preset temperature threshold is 2, the non-wind-sensing second angle mode is determined as the non-wind-sensing target angle mode.

Further, the step of comparing the environmental parameter with a preset parameter threshold value and determining the non-wind-sensation target angle mode according to the comparison result further includes:

step D1, performing difference operation on the environment humidity and a preset humidity threshold value to obtain a difference value between the environment humidity and the preset humidity threshold value; and

and D2, determining a non-wind-feeling target angle mode from a plurality of non-wind-feeling angle modes according to the difference value between the environment humidity and the preset humidity threshold value.

Furthermore, the air conditioner can also call a calculation module, the data of the environment humidity and the data of the preset humidity threshold value are input into the calculation module, and the difference value between the environment humidity and the preset humidity threshold value is obtained through the difference value calculation of the environment humidity and the preset humidity threshold value by the calculation module. Further, the air conditioner searches for a difference between the ambient humidity and the preset humidity threshold value from the plurality of non-wind-sensation angle modes as a search formula, determines whether a non-wind-sensation angle mode corresponding to the difference between the ambient humidity and the preset humidity threshold value exists, and determines the non-wind-sensation angle mode as a non-wind-sensation target angle mode if the non-wind-sensation angle mode corresponding to the difference between the ambient humidity and the preset humidity threshold value exists. It can be understood that each of the non-wind-sensing angle modes corresponds to a humidity difference range, for example, the air conditioner includes 3 non-wind-sensing angle modes (a non-wind-sensing first angle mode, a non-wind-sensing second angle mode, and a non-wind-sensing third angle mode), the first humidity difference range is greater than or equal to 50 and less than or equal to hucr and less than or equal to 65, and the second humidity difference range is: and hucr is more than 65 and less than or equal to 80, the third humidity difference range is hucr >80, hucr is a humidity unit, and if the difference between the ambient humidity and the preset humidity threshold is 50, the non-wind-sensation first angle mode is determined as the non-wind-sensation target angle mode.

The difference value comparison or ratio comparison is carried out on the acquired environmental parameters and the preset parameter threshold value, the non-wind-sensation target angle mode is rapidly determined from the plurality of non-wind-sensation angle modes according to the comparison result, the air conditioner is rapidly enabled to enter the non-wind-sensation target mode by controlling the sliding-out length of the cyclone air deflector, the cooling requirement of a user based on non-wind sensation is met, the use efficiency of the non-wind-sensation function is improved, and the use experience of the non-wind-sensation function of the user is improved.

Furthermore, the invention also provides a control device with no wind sensing function.

Referring to fig. 9, fig. 9 is a functional block diagram of a control device without a wind sensing function according to a first embodiment of the present invention.

The control device of the no wind-sensing function comprises:

the receiving module 10 is configured to enter a no-wind-sense default angle mode and acquire an environmental parameter if a no-wind-sense function start signal is received;

the determining module 20 is configured to compare the environmental parameter with a preset parameter threshold, and determine a non-wind-sensation target angle mode according to a comparison result; and

and the control module 30 is used for controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode and enter the non-wind-sensation target angle mode.

Further, the receiving module 10 includes:

the receiving unit is used for determining whether the microporous air deflector is positioned at a refrigerating angle or not if the no-wind-sense function starting signal is received; and

and the sliding-out unit is used for controlling the rotational flow air deflector to slide out if the microporous air deflector is positioned at the refrigerating angle, forming a non-wind-sense default angle with the microporous air deflector and entering a non-wind-sense default angle mode.

Further, the determining module 20 includes:

the first operation unit is used for carrying out ratio operation on the environment temperature and a preset temperature threshold value to obtain the ratio of the environment temperature to the preset temperature threshold value; and

and the first determining unit is used for determining the non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the ratio of the ambient temperature to the preset temperature threshold.

Further, the determining module 20 further includes:

the second operation unit is used for carrying out ratio operation on the environment humidity and a preset humidity threshold value to obtain the ratio of the environment humidity to the preset humidity threshold value; and

and the second determining unit is used for determining the non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the ratio of the environmental humidity to the preset humidity threshold value.

Further, the determining module 20 further includes:

the third operation unit is used for performing difference operation on the environment temperature and a preset temperature threshold value to obtain a difference value of the environment temperature and the preset temperature threshold value; and

and the third determining unit is used for determining the non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the difference value between the environment temperature and the preset temperature threshold value.

Further, the determining module 20 further includes:

the fourth operation unit is used for performing difference operation on the environment humidity and a preset humidity threshold value to obtain a difference value between the environment humidity and the preset humidity threshold value; and

and the fourth determining unit is used for determining the non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the difference value between the environment humidity and the preset humidity threshold value.

Further, the control module 30 includes:

the searching unit is used for searching in a preset slide-out length table according to the non-wind-sensation target angle mode;

a fifth determining unit, configured to determine a slide-out length of the non-wind-sensation target angle pattern from the preset slide-out length table; and

and the control unit is used for controlling the rotational flow air deflector to slide out by the sliding-out length and enter the non-wind-sensation target angle mode.

Furthermore, the present invention also provides a storage medium, preferably a computer-readable storage medium, on which a control program of a no-wind-sensation function is stored, which when executed by a processor implements the steps of the embodiments of the control method of a no-wind-sensation function described above.

In the embodiments of the control device and the computer-readable medium without a wind-sensing function of the present invention, all technical features of the embodiments of the control method without a wind-sensing function are included, and the descriptions and explanations of the embodiments are substantially the same as those of the embodiments of the control method without a wind-sensing function, and are not repeated herein.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, 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, article, 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, article, or apparatus that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solution of the present invention or a part contributing to the prior art may be embodied in the form of a software product, where the computer software product is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk), and includes a plurality of instructions for enabling a terminal device (which may be a fixed terminal, such as an internet of things smart device including smart homes, such as a smart air conditioner, a smart lamp, a smart power supply, a smart router, etc., or a mobile terminal, including a smart phone, a wearable networked AR/VR device, a smart sound box, an autonomous driving automobile, etc.) to execute the method according to each embodiment of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A control method of a no-wind-sensation function is characterized by comprising the following steps:

if a no-wind-sense function starting signal is received, entering a no-wind-sense default angle mode, and acquiring environmental parameters;

comparing the environmental parameter with a preset parameter threshold value, and determining a non-wind-sensation target angle mode according to a comparison result; and

and controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode, and entering the non-wind-sensation target angle mode.

2. The method for controlling the non-wind-sensing function according to claim 1, wherein the step of controlling the cyclone air deflector to slide out of the non-wind-sensing target angle mode by a sliding-out length corresponding to the non-wind-sensing target angle mode comprises:

searching in a preset slide-out length table according to the non-wind-sensation target angle mode;

determining the sliding-out length of the non-wind-sensation target angle mode from the preset sliding-out length table; and

and controlling the rotational flow air deflector to slide out by the sliding-out length to enter the non-wind-sensation target angle mode.

3. The method of claim 1, wherein the environmental parameter comprises an environmental temperature, the predetermined parameter threshold comprises a predetermined temperature threshold, the comparing the environmental parameter with the predetermined parameter threshold, and the determining the non-wind-sensitive target angle mode according to the comparing comprises:

carrying out ratio operation on the environment temperature and a preset temperature threshold value to obtain the ratio of the environment temperature to the preset temperature threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the ratio of the ambient temperature to the preset temperature threshold.

4. The method of claim 1, wherein the environmental parameter comprises an environmental humidity, the predetermined parameter threshold comprises a predetermined humidity threshold, the comparing the environmental parameter to the predetermined parameter threshold, and the determining the non-wind target angle mode according to the comparing further comprises:

carrying out ratio operation on the environment humidity and a preset humidity threshold value to obtain the ratio of the environment humidity and the preset humidity threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the ratio of the environment humidity to the preset humidity threshold value.

5. The method of claim 1, wherein the environmental parameter comprises an environmental temperature, the predetermined parameter threshold comprises a predetermined temperature threshold, the comparing the environmental parameter to the predetermined parameter threshold, and the determining the non-wind-related target angle pattern according to the comparing further comprises:

performing difference operation on the environment temperature and a preset temperature threshold value to obtain a difference value of the environment temperature and the preset temperature threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the difference value between the environment temperature and the preset temperature threshold value.

6. The method of claim 1, wherein the environmental parameter comprises an environmental humidity, the predetermined parameter threshold comprises a predetermined humidity threshold, the comparing the environmental parameter to the predetermined parameter threshold, and the determining the non-wind target angle mode according to the comparing further comprises:

performing difference operation on the environment humidity and a preset humidity threshold value to obtain a difference value of the environment humidity and the preset humidity threshold value; and

and determining a non-wind-sensation target angle mode from a plurality of non-wind-sensation angle modes according to the difference value between the environment humidity and the preset humidity threshold value.

7. The method as claimed in claim 1, wherein the step of entering the no-wind default angle mode if the no-wind function start signal is received comprises:

if a no-wind-sense function starting signal is received, determining whether the microporous air deflector is at a refrigerating angle; and

and if the microporous air deflector is positioned at the refrigerating angle, controlling the rotational flow air deflector to slide out, forming a non-wind-sense default angle with the microporous air deflector, and entering a non-wind-sense default angle mode.

8. A control device with no wind-sensing function, comprising:

the receiving module is used for entering a no-wind-sense default angle mode and acquiring environmental parameters if a no-wind-sense function starting signal is received;

the determining module is used for comparing the environmental parameter with a preset parameter threshold value and determining a non-wind-sensation target angle mode according to a comparison result; and

and the control module is used for controlling the rotational flow air deflector to slide out of the sliding-out length corresponding to the non-wind-sensation target angle mode and enter the non-wind-sensation target angle mode.

9. A non-wind-sensing-function control apparatus, characterized in that the non-wind-sensing-function control apparatus comprises a memory, a processor, and a non-wind-sensing-function control program stored on the memory and executable on the processor, the non-wind-sensing-function control program, when executed by the processor, implementing the steps of the non-wind-sensing-function control method according to any one of claims 1 to 7.

10. A storage medium having stored thereon a control program for a no-wind-sensing function, the control program for a no-wind-sensing function implementing the steps of the control method for a no-wind-sensing function according to any one of claims 1 to 7 when executed by a processor.

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