阅读说明：本技术 一种空调的控制方法、装置、空调、存储介质及处理器 (Control method and device of air conditioner, storage medium and processor ) 是由 翁颖达 邓忠文 黄子睿 金国华 刘安祺 于 2021-07-26 设计创作，主要内容包括：本发明公开了一种空调的控制方法、装置、空调、存储介质及处理器,该方法包括：获取所述空调的使用者的操作参数；所述操作参数,是用于设定所述空调的送风空间或避风空间的参数；所述送风空间,用于表示使用者设定的所述空调的送风位置或送风区域；所述避风空间,用于表示使用者设定的所述空调的避风位置或避风区域；根据所述操作参数,确定所述空调的送风空间或避风空间的空间坐标；根据所述空间坐标,确定所述空调的送风角度,并控制所述空调按所述送风角度运行。该方案,通过对空调的送风角度进行灵活设置,能够提升用户体验。(The invention discloses a control method and a control device of an air conditioner, the air conditioner, a storage medium and a processor, wherein the method comprises the following steps: acquiring operation parameters of a user of the air conditioner; the operation parameters are parameters for setting an air supply space or a wind shielding space of the air conditioner; the air supply space is used for representing an air supply position or an air supply area of the air conditioner set by a user; the wind-sheltering space is used for representing the wind-sheltering position or the wind-sheltering area of the air conditioner set by a user; determining the space coordinates of the air supply space or the wind shielding space of the air conditioner according to the operation parameters; and determining the air supply angle of the air conditioner according to the space coordinate, and controlling the air conditioner to operate according to the air supply angle. This scheme, through carrying out nimble setting to the air supply angle of air conditioner, can promote user experience.)

1. A control method of an air conditioner, comprising:

acquiring operation parameters of a user of the air conditioner; the operation parameters are parameters for setting an air supply space or a wind shielding space of the air conditioner; the air supply space is used for representing an air supply position or an air supply area of the air conditioner set by a user; the wind-sheltering space is used for representing the wind-sheltering position or the wind-sheltering area of the air conditioner set by a user;

determining the space coordinates of the air supply space or the wind shielding space of the air conditioner according to the operation parameters;

and determining the air supply angle of the air conditioner according to the space coordinate, and controlling the air conditioner to operate according to the air supply angle.

2. The control method of an air conditioner according to claim 1, wherein the controller of the air conditioner has a positioning device; the positioning device comprises: an inner machine positioning part and a handheld positioning part;

the operating parameters include: the position parameter and the click parameter generated by clicking the handheld positioning part at the position of the user, or the path parameter and the click parameter generated by clicking the handheld positioning part for a long time on the path passed by the user; the click parameter is used for indicating whether the click operation of the user is an air supply operation or a wind shielding operation; the long press parameter is used for indicating whether the long press operation of the user is an air supply operation or a wind shielding operation; wherein at least one of the position parameter and the path parameter comprises a parameter generated by a user operating the handheld positioning part or a parameter generated by the internal positioning part identifying the user operating the handheld positioning part;

obtaining operating parameters of a user of the air conditioner, including:

the position or the path of the handheld positioning part is positioned through the inner machine positioning part, or the position or the path of the handheld positioning part generated by operating the handheld positioning part by a user is identified by the inner machine positioning part, and the point-press parameter sent by the point-press operation of the handheld positioning part or the long-press parameter sent by the long-press operation is received, so that the operation parameter of the handheld positioning part is obtained.

3. The control method of an air conditioner according to claim 1 or 2, wherein the controller of the air conditioner further has a wind sweeping part; an air supply model of the air conditioner is preset on the air sweeping part; the air supply model comprises the corresponding relation among the air supply angle, the air supply intensity and the air supply range of the air conditioner;

determining the space coordinates of the air supply space or the wind shielding space of the air conditioner according to the operation parameters, comprising the following steps:

and determining the space coordinates of the air supply space or the wind shielding space of the air conditioner through the wind sweeping part according to the operation parameters and the air supply model.

4. The control method of the air conditioner according to claim 3, wherein the air supply model determines a correspondence relationship between an air supply angle, an air supply intensity, and an air supply range of the air conditioner, which is obtained according to an equipment parameter and an air outlet parameter of the air conditioner;

the air supply model can be preset in the air sweeping part of the air conditioner; when the air supply model is changed, the air supply model can be changed through a set communication mode and a set change protocol.

5. The method of claim 3, wherein determining an air supply angle of the air conditioner according to the spatial coordinates, and controlling the air conditioner to operate at the air supply angle comprises:

and determining the corresponding relation between the space coordinate and the air supply angle of the air conditioner based on the corresponding relation among the air supply angle, the air supply intensity and the air supply range in the air supply model according to the space coordinate so as to obtain the air supply angle of the air conditioner, and controlling the air conditioner to operate according to the air supply angle.

6. The control method of an air conditioner according to claim 5, wherein the spatial coordinates include: one coordinate or more than two coordinates;

and under the condition that the space coordinates comprise more than two coordinates, the air supply angle is a set of more than two angles corresponding to the more than two coordinates, and the more than two angles in the set are sequenced according to a set sequence to form a running path of the air sweeping plate of the air conditioner.

7. A control device of an air conditioner, characterized by comprising:

an acquisition unit configured to acquire an operation parameter of a user of the air conditioner; the operation parameters are parameters for setting an air supply space or a wind shielding space of the air conditioner; the air supply space is used for representing an air supply position or an air supply area of the air conditioner set by a user; the wind-sheltering space is used for representing the wind-sheltering position or the wind-sheltering area of the air conditioner set by a user;

a control unit configured to determine spatial coordinates of an air supply space or a wind shielding space of the air conditioner according to the operation parameters;

the control unit is further configured to determine an air supply angle of the air conditioner according to the spatial coordinates, and control the air conditioner to operate according to the air supply angle.

8. The control device of the air conditioner according to claim 7, wherein the controller of the air conditioner has a positioning device; the positioning device comprises: an inner machine positioning part and a handheld positioning part;

the operating parameters include: the position parameter and the click parameter generated by clicking the handheld positioning part at the position of the user, or the path parameter and the click parameter generated by clicking the handheld positioning part for a long time on the path passed by the user; the click parameter is used for indicating whether the click operation of the user is an air supply operation or a wind shielding operation; the long press parameter is used for indicating whether the long press operation of the user is an air supply operation or a wind shielding operation; wherein at least one of the position parameter and the path parameter comprises a parameter generated by a user operating the handheld positioning part or a parameter generated by the internal positioning part identifying the user operating the handheld positioning part;

the acquiring unit acquires an operating parameter of a user of the air conditioner, and includes:

the position or the path of the handheld positioning part is positioned through the inner machine positioning part, or the position or the path of the handheld positioning part generated by operating the handheld positioning part by a user is identified by the inner machine positioning part, and the point-press parameter sent by the point-press operation of the handheld positioning part or the long-press parameter sent by the long-press operation is received, so that the operation parameter of the handheld positioning part is obtained.

9. The control device of an air conditioner according to claim 7 or 8, wherein the controller of the air conditioner further has a wind sweeping part; an air supply model of the air conditioner is preset on the air sweeping part; the air supply model comprises the corresponding relation among the air supply angle, the air supply intensity and the air supply range of the air conditioner;

the control unit determines the space coordinates of the air supply space or the wind shielding space of the air conditioner according to the operation parameters, and comprises:

and determining the space coordinates of the air supply space or the wind shielding space of the air conditioner through the wind sweeping part according to the operation parameters and the air supply model.

10. The control device of the air conditioner according to claim 9, wherein the air supply model determines a correspondence relationship between an air supply angle, an air supply intensity, and an air supply range of the air conditioner, based on an equipment parameter and an air outlet parameter of the air conditioner;

the air supply model can be preset in the air sweeping part of the air conditioner; when the air supply model is changed, the air supply model can be changed through a set communication mode and a set change protocol.

11. The control device of claim 9, wherein the control unit determines an air supply angle of the air conditioner according to the spatial coordinates, and controls the air conditioner to operate at the air supply angle, and the control unit includes:

and determining the corresponding relation between the space coordinate and the air supply angle of the air conditioner based on the corresponding relation among the air supply angle, the air supply intensity and the air supply range in the air supply model according to the space coordinate so as to obtain the air supply angle of the air conditioner, and controlling the air conditioner to operate according to the air supply angle.

12. The control device of an air conditioner according to claim 11, wherein the spatial coordinates include: one coordinate or more than two coordinates;

and under the condition that the space coordinates comprise more than two coordinates, the air supply angle is a set of more than two angles corresponding to the more than two coordinates, and the more than two angles in the set are sequenced according to a set sequence to form a running path of the air sweeping plate of the air conditioner.

13. An air conditioner, comprising: the control device of the air conditioner according to any one of claims 7 to 12.

14. A storage medium characterized by comprising a stored program, wherein an apparatus in which the storage medium is located is controlled to execute the control method of the air conditioner according to any one of claims 1 to 6 when the program is executed.

15. A processor, characterized in that the processor is configured to execute a program, wherein the program executes a control method of an air conditioner according to any one of claims 1 to 6.

Technical Field

The invention belongs to the technical field of air conditioners, and particularly relates to a control method and device of an air conditioner, the air conditioner, a storage medium and a processor, in particular to a method and device for realizing the accurate blowing and wind shielding function of an indoor unit with a wind sweeping plate, the air conditioner, the storage medium and the processor.

Background

In recent years, the concept of no wind sensation of the air conditioner has been rising. However, based on the principle of air conditioning refrigeration and heating in the related schemes, the air conditioner needs air to exchange heat and cold through the evaporator, so that the air needs to flow, namely, wind is needed to carry out cooling capacity or heat; therefore, the air volume is indispensable. Therefore, the air conditioning wind is not the part that should be eliminated, but the part that requires a more intelligent and comfortable control manner. In the related scheme, the air supply angle of the air conditioner is fixed and is inconvenient to set, so that the experience of the user in using the air conditioner is influenced.

The above is only for the purpose of assisting understanding of the technical aspects of the present invention, and does not represent an admission that the above is prior art.

Disclosure of Invention

The invention aims to provide a control method and device of an air conditioner, the air conditioner, a storage medium and a processor, so as to solve the problems that the air supply angle of the air conditioner is fixed and inconvenient to set, and user experience is influenced, and achieve the effect of improving the user experience by flexibly setting the air supply angle of the air conditioner.

The invention provides a control method of an air conditioner, which comprises the following steps: acquiring operation parameters of a user of the air conditioner; the operation parameters are parameters for setting an air supply space or a wind shielding space of the air conditioner; the air supply space is used for representing an air supply position or an air supply area of the air conditioner set by a user; the wind-sheltering space is used for representing the wind-sheltering position or the wind-sheltering area of the air conditioner set by a user; determining the space coordinates of the air supply space or the wind shielding space of the air conditioner according to the operation parameters; and determining the air supply angle of the air conditioner according to the space coordinate, and controlling the air conditioner to operate according to the air supply angle.

In some embodiments, a controller of the air conditioner has a positioning device; the positioning device comprises: an inner machine positioning part and a handheld positioning part; the operating parameters include: the position parameter and the click parameter generated by clicking the handheld positioning part at the position of the user, or the path parameter and the click parameter generated by clicking the handheld positioning part for a long time on the path passed by the user; the click parameter is used for indicating whether the click operation of the user is an air supply operation or a wind shielding operation; the long press parameter is used for indicating whether the long press operation of the user is an air supply operation or a wind shielding operation; wherein at least one of the position parameter and the path parameter comprises a parameter generated by a user operating the handheld positioning part or a parameter generated by the internal positioning part identifying the user operating the handheld positioning part; obtaining operating parameters of a user of the air conditioner, including: the position or the path of the handheld positioning part is positioned through the inner machine positioning part, or the position or the path of the handheld positioning part generated by operating the handheld positioning part by a user is identified by the inner machine positioning part, and the point-press parameter sent by the point-press operation of the handheld positioning part or the long-press parameter sent by the long-press operation is received, so that the operation parameter of the handheld positioning part is obtained.

In some embodiments, the controller of the air conditioner further has a wind sweeping part; an air supply model of the air conditioner is preset on the air sweeping part; the air supply model comprises the corresponding relation among the air supply angle, the air supply intensity and the air supply range of the air conditioner; determining the space coordinates of the air supply space or the wind shielding space of the air conditioner according to the operation parameters, comprising the following steps: and determining the space coordinates of the air supply space or the wind shielding space of the air conditioner through the wind sweeping part according to the operation parameters and the air supply model.

In some embodiments, the air supply model determines a correspondence relationship between an air supply angle, an air supply intensity and an air supply range of the air conditioner according to an equipment parameter and an air outlet parameter of the air conditioner; the air supply model can be preset in the air sweeping part of the air conditioner; when the air supply model is changed, the air supply model can be changed through a set communication mode and a set change protocol.

In some embodiments, determining an air supply angle of the air conditioner according to the spatial coordinates, and controlling the air conditioner to operate at the air supply angle includes: and determining the corresponding relation between the space coordinate and the air supply angle of the air conditioner based on the corresponding relation among the air supply angle, the air supply intensity and the air supply range in the air supply model according to the space coordinate so as to obtain the air supply angle of the air conditioner, and controlling the air conditioner to operate according to the air supply angle.

In some embodiments, the spatial coordinates comprise: one coordinate or more than two coordinates; and under the condition that the space coordinates comprise more than two coordinates, the air supply angle is a set of more than two angles corresponding to the more than two coordinates, and the more than two angles in the set are sequenced according to a set sequence to form a running path of the air sweeping plate of the air conditioner.

In accordance with the above method, another aspect of the present invention provides a control apparatus for an air conditioner, comprising: an acquisition unit configured to acquire an operation parameter of a user of the air conditioner; the operation parameters are parameters for setting an air supply space or a wind shielding space of the air conditioner; the air supply space is used for representing an air supply position or an air supply area of the air conditioner set by a user; the wind-sheltering space is used for representing the wind-sheltering position or the wind-sheltering area of the air conditioner set by a user; a control unit configured to determine spatial coordinates of an air supply space or a wind shielding space of the air conditioner according to the operation parameters; the control unit is further configured to determine an air supply angle of the air conditioner according to the spatial coordinates, and control the air conditioner to operate according to the air supply angle.

In some embodiments, a controller of the air conditioner has a positioning device; the positioning device comprises: an inner machine positioning part and a handheld positioning part; the operating parameters include: the position parameter and the click parameter generated by clicking the handheld positioning part at the position of the user, or the path parameter and the click parameter generated by clicking the handheld positioning part for a long time on the path passed by the user; the click parameter is used for indicating whether the click operation of the user is an air supply operation or a wind shielding operation; the long press parameter is used for indicating whether the long press operation of the user is an air supply operation or a wind shielding operation; wherein at least one of the position parameter and the path parameter comprises a parameter generated by a user operating the handheld positioning part or a parameter generated by the internal positioning part identifying the user operating the handheld positioning part; the acquiring unit acquires an operating parameter of a user of the air conditioner, and includes: the position or the path of the handheld positioning part is positioned through the inner machine positioning part, or the position or the path of the handheld positioning part generated by operating the handheld positioning part by a user is identified by the inner machine positioning part, and the point-press parameter sent by the point-press operation of the handheld positioning part or the long-press parameter sent by the long-press operation is received, so that the operation parameter of the handheld positioning part is obtained.

In some embodiments, the controller of the air conditioner further has a wind sweeping part; an air supply model of the air conditioner is preset on the air sweeping part; the air supply model comprises the corresponding relation among the air supply angle, the air supply intensity and the air supply range of the air conditioner; the control unit determines the space coordinates of the air supply space or the wind shielding space of the air conditioner according to the operation parameters, and comprises: and determining the space coordinates of the air supply space or the wind shielding space of the air conditioner through the wind sweeping part according to the operation parameters and the air supply model.

In some embodiments, the air supply model determines a correspondence relationship between an air supply angle, an air supply intensity and an air supply range of the air conditioner according to an equipment parameter and an air outlet parameter of the air conditioner; the air supply model can be preset in the air sweeping part of the air conditioner; when the air supply model is changed, the air supply model can be changed through a set communication mode and a set change protocol.

In some embodiments, the control unit, determining an air supply angle of the air conditioner according to the spatial coordinates, and controlling the air conditioner to operate at the air supply angle, includes: and determining the corresponding relation between the space coordinate and the air supply angle of the air conditioner based on the corresponding relation among the air supply angle, the air supply intensity and the air supply range in the air supply model according to the space coordinate so as to obtain the air supply angle of the air conditioner, and controlling the air conditioner to operate according to the air supply angle.

In some embodiments, the spatial coordinates comprise: one coordinate or more than two coordinates; and under the condition that the space coordinates comprise more than two coordinates, the air supply angle is a set of more than two angles corresponding to the more than two coordinates, and the more than two angles in the set are sequenced according to a set sequence to form a running path of the air sweeping plate of the air conditioner.

In accordance with another aspect of the present invention, there is provided an air conditioner including: the control device of the air conditioner described above.

In accordance with the above method, a further aspect of the present invention provides a storage medium, which includes a stored program, wherein when the program runs, an apparatus in which the storage medium is located is controlled to execute the above control method of the air conditioner.

In accordance with the above method, a further aspect of the present invention provides a processor for executing a program, wherein the program executes the control method of the air conditioner.

Therefore, according to the scheme of the invention, the space coordinates are selected as the air supply points and the wind shielding points, and then the space coordinates are corresponding to the air supply angle of the air conditioner, so that the air supply angle of the air conditioner can be flexibly set; therefore, the air supply angle of the air conditioner is flexibly set, and the user experience can be improved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

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

FIG. 2 is a schematic structural diagram of a control device of an air conditioner according to an embodiment of the present invention;

fig. 3 is a hardware topology diagram of an embodiment of a controller in an apparatus for implementing a precise blowing and wind-shielding function of an indoor unit with a wind-sweeping plate;

fig. 4 is a control flow diagram illustrating an implementation method of an accurate blowing and wind-shielding function of an indoor unit with a wind-sweeping plate according to an embodiment;

fig. 5 is a schematic single-point coordinate diagram of an implementation scheme of a precise blowing and wind-sheltering function of an indoor unit with a wind sweeping plate;

fig. 6 is a schematic diagram of a path and coordinates of an embodiment of an implementation scheme of a precise blowing and wind shielding function of an indoor unit with a wind sweeping plate;

fig. 7 is a schematic diagram of a moving path and an air supply angle of a positioning device according to an embodiment of an implementation scheme of an accurate air blowing and wind shielding function of an indoor unit with a sweep plate.

The reference numbers in the embodiments of the present invention are as follows, in combination with the accompanying drawings:

102-an obtaining unit; 104-control unit.

Detailed Description

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

According to an embodiment of the present invention, a method for controlling an air conditioner is provided, as shown in fig. 1, which is a schematic flow chart of an embodiment of the method of the present invention. The control method of the air conditioner may include: step S110 to step S130.

At step S110, operating parameters of a user of the air conditioner are acquired. The operation parameter is a parameter for setting an air supply space or a wind shielding space of the air conditioner. The air supply space is used for representing the air supply position or the air supply area of the air conditioner set by a user, namely the position or the area to which the user wants the air conditioner to supply air. The wind-sheltered space is used for representing the wind-sheltered position or wind-sheltered area of the air conditioner set by a user, namely the position or area to which the user does not want the air conditioner to blow.

In some embodiments, the controller of the air conditioner has a positioning device. The positioning device comprises: the positioning device comprises an inner machine positioning part and a handheld positioning part. The indoor unit positioning portion, such as a positioning device indoor portion, is provided on an indoor unit of the air conditioner. The handheld positioning part, such as a positioning device handheld part, is arranged on a remote controller of the air conditioner.

The operating parameters include: the position parameter and the point-to-point parameter are generated by clicking the handheld positioning part at the position of the user, or the path parameter and the long-press parameter are generated by pressing the handheld positioning part for a long time on the path passed by the user. The click parameter is used for indicating whether the click operation of the user is an air supply operation or a wind shielding operation. The long press parameter is used for indicating whether the long press operation of the user is an air supply operation or a wind shielding operation. Wherein at least one of the position parameter and the path parameter comprises a parameter generated by a user operating the handheld positioning part or a parameter generated by the internal positioning part recognizing the user operating the handheld positioning part.

The step S110 of obtaining the operating parameters of the user of the air conditioner includes: the position or the path of the handheld positioning part is positioned through the inner machine positioning part, or the position or the path of the handheld positioning part generated by operating the handheld positioning part by a user is identified by the inner machine positioning part, and the point-press parameter sent by the point-press operation of the handheld positioning part or the long-press parameter sent by the long-press operation is received, so that the operation parameter of the handheld positioning part is obtained.

Fig. 3 is a hardware topology diagram of an embodiment of a controller in an apparatus for implementing a precise blowing and wind-shielding function of an indoor unit with a wind-sweeping plate. As shown in fig. 3, the controller of the device for implementing the precise wind blowing and shielding function of the indoor unit with the wind sweeping plate comprises a positioning device. In the example shown in FIG. 3, the positioning device includes two parts, a positioning device hand-held part and a positioning device built-in part.

Wherein, positioner handheld portion includes: physical keys capable of human-computer interaction. The handheld part of the positioning device can be integrated into an air conditioner remote controller. The physical keys capable of performing man-machine interaction can use a combined key or a special key to enter the functions of 'presetting an air supply point' and 'setting an air supply point'. Presetting an air supply point: and storing the current coordinate or path, and directly selecting the stored preset air supply point when the left side or path needs to be blown/sheltered from wind subsequently. Setting an air supply point: the left side or the path of the current wind needing to be blown/sheltered can be set, a preset air supply point can be selected, and the left side or the path can also be directly set by a positioning device.

The handheld portion of positioner still includes: and the signal unit can send signals which can be received by the air conditioner indoor unit.

Positioning a device inboard portion, comprising: and the sensing unit is used for receiving signals sent by the handheld part of the positioning device.

The internal portion of positioner still includes: and a calculation unit for performing position recognition. The position identification comprises the following steps: and translating the coordinates of the air supply model of the air conditioner and the positioning device, and converting a coordinate system when the original point of the air supply model is inconsistent with that of the positioning device.

At step S120, spatial coordinates of the air supply space or the wind shielding space of the air conditioner are determined according to the operation parameters.

In some embodiments, the controller of the air conditioner further has a wind sweeping part. An air supply model of the air conditioner is preset on the air sweeping part. And the air supply model comprises the corresponding relation among the air supply angle, the air supply intensity and the air supply range of the air conditioner.

In step S120, determining a spatial coordinate of the air supply space or the wind shielding space of the air conditioner according to the operation parameter includes: and determining the space coordinates of the air supply space or the wind shielding space of the air conditioner through the wind sweeping part according to the operation parameters and the air supply model.

As shown in fig. 3, the controller of the device for implementing the accurate wind blowing and sheltering function of the indoor unit with the wind sweeping plate further comprises a wind sweeping unit. That is to say, the controller in the device for realizing the accurate blowing and wind-shielding function of the indoor unit with the wind-sweeping plate comprises a positioning device and a wind-sweeping unit (namely a wind-sweeping part), and the positioning device and the wind-sweeping unit can finish the accurate blowing and wind-shielding of the wind-sweeping plate. The air supply point and the wind shielding point (namely, the space coordinate) are selected through the positioning device, and then the space coordinate corresponds to the air supply angle of the air conditioner, so that the effect of accurate air blowing and wind shielding is achieved.

In the example shown in fig. 3, the wind sweeping part includes: and a calculation unit for controlling the action of the wind sweeping plate. And the computing unit is used for controlling the action of the air sweeping plate and is responsible for determining the action of the air sweeping plate according to the air supply model and the air supply point. Sweep the wind part, still include: and an operation unit for performing a wind sweeping operation.

In some embodiments, the air supply model is a corresponding relationship between an air supply angle, an air supply intensity and an air supply range of the air conditioner, which is determined according to an equipment parameter and an air outlet parameter of the air conditioner.

The air supply model can be preset in the air sweeping part of the air conditioner. When the air supply model is changed, the air supply model can be changed through a set communication mode and a set change protocol.

Fig. 4 is a control flow diagram illustrating an implementation method of an accurate blowing and wind shielding function of an indoor unit with a wind sweeping plate according to an embodiment. As shown in fig. 4, the control flow of the method for implementing the accurate blowing and wind-shielding function of the indoor unit with the wind-sweeping plate includes:

step 1, pre-installing an air supply model, namely pre-installing an air supply model of a controller.

And step 11, determining an air supply model of the controller. According to the structure (such as fan type, fan blade shape and air deflector area) of the equipment, air quantity, air pressure, rotating speed, outlet air speed and the like, the air sweeping unit is internally provided with a plurality of air supply angles, air supply strengths and air supply ranges based on the equipment.

Specifically, only a first-order relation needs to be considered, firstly, linear relation among the air supply range, the area of the air deflector, the air supply intensity and the air supply angle is assumed, then a quaternary linear function of the air supply range, the equipment structure and the air speed is derived according to test data, and after the linear fitting degree (such as a complex correlation coefficient and a partial correlation coefficient) of the quaternary linear function is evaluated, the quaternary linear function is written into an air supply model.

For example: the air supply angle has a maximum air supply angle and a minimum air supply angle, and can be adjusted according to a unit angle in the range. The air supply intensity has zero rotating speed and maximum rotating speed, and can be adjusted according to the unit rotating speed in the range. The air supply range is determined according to the installation height of the equipment, the air supply angle and the air supply intensity.

In general, macroscopic gas motion is a statistical average of the microscopic motion of a large number of gas molecules and is not well suited for model calculations in a controller. And blowing comfort is a mental activity that varies from person to person that is difficult to quantify accurately. Therefore, the air supply range can be determined by manufacturers in the development stage according to the structure, air volume, air pressure, rotating speed, outlet air speed and the like of equipment, user data, experimental data and the like, and the air supply range is preloaded in the internal storage of the controller, so that the corresponding relation among the air supply angle, the air supply intensity and the air supply range is finally formed.

And 12, changing an air supply model. The unit can provide communication mode and change agreement, and the producer personnel change the air supply model, namely the corresponding relation of air supply angle, air supply intensity and air supply scope.

The air supply model is stored in the air conditioner indoor unit, so that the air supply model needs to be changed by communicating with the indoor unit, for example, by communication modes such as 485 communication, CAN (controller area network) communication, wireless WIFI communication and the like, and the air supply model is changed.

The modified protocol can be used for appointing a handshaking mode, for example, when the air conditioner internal unit identifies a special function code, the received data is stored as an air supply model parameter, and then the air supply model parameter is sent back to the upper computer for confirmation. And finally, after receiving the specific function code (namely the specific function code), the air conditioner internal unit confirms to change the model, and replaces the air supply model parameter with the latest received parameter data.

In a communication protocol, there is often a part of data for indicating the meaning and purpose of the frame data, which can be arbitrarily set by human based on communication. For example, the 10 th data of a frame communication is defined as a function code to indicate the function that the device receiving the frame data needs to perform. Also, for example, the number "0 xA 5" is often used as a filler of frame data in wire communication because its binary value is 10100101, which causes the bus level to be continuously inverted, thereby generating a special waveform.

And step 2, presetting an air supply point.

When the function of 'presetting air supply points' is entered, the internal part of the device is positioned, and the current coordinates of the handheld part of the positioning device are identified so as to determine the air supply points.

Step 21 and fig. 5 are schematic single-point coordinates of an embodiment of an implementation scheme of an indoor unit with a sweep plate for precise blowing and wind shielding functions. Clicking a key on the handheld part of the positioning device sets the current position as a preset blowing point, which can be seen as the "a2" point, "C1" point, and "D2" point in the example shown in fig. 5.

And step 22, moving when the key of the handheld part of the positioning device is pressed for a long time, and setting the moving path as the preset air supply range of the key. Fig. 6 is a schematic diagram of a path and coordinates of an embodiment of an implementation scheme of a precise blowing and wind shielding function of an indoor unit with a wind sweeping plate. Assuming that the moving path takes the "a2" point, the "B1" point, the "C1" point, the "D2" point, and the "E2" point, a COORDINATE point set D1(COORDINATE) can be obtained, as shown in fig. 6.

And 3, setting an air supply point by a user.

When the function of 'setting air supply points' is entered, the preset air supply points can be selected by pressing the corresponding keys of the handheld part of the positioning device, or the current coordinates of the handheld part can be identified by the inside of the positioning device, so that the air supply points are determined.

And step 31, when the preset air supply point is set by pressing the key, setting according to the air supply point or the air supply range represented by the single key.

And step 32, when the air supply points are set through the identification coordinates, the operation logic is consistent with the function of the preset air supply points, namely, a single air supply angle can be set, and a continuous air supply range can be set.

There is a particular application here: the air conditioner internal unit can be arranged to supply air along with the handheld part or avoid the handheld part to supply air, so that the aim of avoiding people along with the wind of people is indirectly fulfilled.

And at step S130, determining an air supply angle of the air conditioner according to the spatial coordinates, and controlling the air conditioner to operate according to the air supply angle.

The scheme of the invention provides a novel application mode combining wind sweeping, space positioning and user interaction, which is a popular and easily understood wind sweeping setting mode which accords with the use habits of users and is simple and convenient to operate, and the users can reasonably blow wind by setting the wind sweeping range to realize various wind sweeping effects. Such as: the user can instruct the air conditioner to blow to the wet land board which has just dragged the ground, instruct the air conditioner to blow to the wet clothes which are not easy to dry in plum rain weather, instruct the air conditioner to blow to corners to avoid crowds and the like. In addition, due to the simple operation and flexible arrangement, the operation is as simple and easy as the remote channel change of the television.

In the scheme of the invention, the air supply point and the wind shielding point are selected by adopting the positioning device, so that the wind can be swept to perform stepless motion, and the air can be discharged accurately. The air supply angle of the air conditioner is fixed and the air supply angle of the air conditioner is inconvenient to set by adopting a mode that the air supply point or the wind shielding point is selected by the positioning device, so that the convenience and the comfort of a user using the air conditioner are improved. The wind sweeping in the related scheme is in a sub-angle mode, for example, the primary wind sweeping is performed by the wind sweeping plate between an opening angle of 15-30 degrees. That is, the setting is performed only according to the keys, which is a method that can not exhaust all angles, and only can divide a plurality of fixed ranges.

In the scheme of the invention, the air supply angle is corresponding to the space coordinate, so that the intelligent control can be realized, and the intelligent air supply device is simple, convenient and comfortable. The air supply angle of the air sweeping plate corresponds to the coordinates in the space, so that the problems that the user is not clear in space cognition and needs to think about an indoor three-dimensional space view when setting the air supply angle are solved, and the intelligent degree of air conditioner control is improved.

In some embodiments, the determining an air supply angle of the air conditioner according to the spatial coordinates and controlling the air conditioner to operate at the air supply angle in step S130 includes: and determining the corresponding relation between the space coordinate and the air supply angle of the air conditioner based on the corresponding relation among the air supply angle, the air supply intensity and the air supply range in the air supply model according to the space coordinate so as to obtain the air supply angle of the air conditioner, and controlling the air conditioner to operate according to the air supply angle.

In some embodiments, the spatial coordinates comprise: one coordinate or more than two coordinates; and under the condition that the space coordinates comprise more than two coordinates, the air supply angle is a set of more than two angles corresponding to the more than two coordinates, and the more than two angles in the set are sequenced according to a set sequence to form a running path of the air sweeping plate of the air conditioner.

As shown in fig. 4, the control flow of the method for implementing the accurate blowing and wind-shielding function of the indoor unit with the wind-sweeping plate further includes:

and 4, determining the wind sweeping action by the controller.

And step 41, the controller acquires the relation between the corresponding coordinates and the air supply angle according to the corresponding relation among the air supply angle, the air supply intensity and the air supply range according to the air supply point or the air supply range set by the positioning device. The air supply angle is the opening angle (corresponding to the coordinate) of the air sweeping plate, namely the continuous air sweeping angle.

For convenience, one of two approaches is generally used: and in the table method, the air supply model is stored in a table mode, and when the air supply intensity and the air supply range are determined, the corresponding air supply angle can be searched according to each coordinate, so that the air supply angle or the air supply angle interval is determined. And in the formula method, the air supply model is stored in a formula mode, and when the air supply intensity and the air supply range are determined, the formula is substituted to calculate the air supply angle.

Step 42, assuming that there is a mapping d (coordinate) → r (angle) between the blowing angle and the blowing range when the indoor unit is operated at the blowing intensity F at the installation height H, a corresponding angle can be obtained for each coordinate set by the positioning device. If only one coordinate exists, the angle corresponding to the coordinate is the hovering angle value of the wind sweeping board. Fig. 7 is a schematic diagram of a moving path and an air supply angle of a positioning device according to an embodiment of an implementation scheme of an accurate air blowing and wind shielding function of an indoor unit with a sweep plate. If there are multiple coordinates, then the set of multiple angles R1(Angle) is obtained, and the angles are sorted in increments to obtain the travel path of the wind deflector, as shown in the example of fig. 7.

Therefore, the scheme of the invention can determine the wind sweeping model according to the real-time operation result of the user, realize the wind sweeping action control under the simple operation of the user and solve the mismatch contradiction between the air quantity of the indoor unit and the comfortable feeling of the human body.

Through a large number of tests, the technical scheme of the embodiment is adopted, the space coordinates are selected as the air supply points and the wind shielding points, and then the space coordinates correspond to the air supply angle of the air conditioner, so that the air supply angle of the air conditioner can be flexibly set. Therefore, the air supply angle of the air conditioner is flexibly set, and the user experience can be improved.

According to an embodiment of the present invention, there is also provided a control apparatus of an air conditioner corresponding to the control method of the air conditioner. Referring to fig. 2, a schematic diagram of an embodiment of the apparatus of the present invention is shown. The control device of the air conditioner may include: an acquisition unit 102 and a control unit 104.

Wherein the obtaining unit 102 is configured to obtain an operation parameter of a user of the air conditioner. The operation parameter is a parameter for setting an air supply space or a wind shielding space of the air conditioner. The air supply space is used for representing the air supply position or the air supply area of the air conditioner set by a user, namely the position or the area to which the user wants the air conditioner to supply air. The wind-sheltered space is used for representing the wind-sheltered position or wind-sheltered area of the air conditioner set by a user, namely the position or area to which the user does not want the air conditioner to blow. The specific functions and processes of the acquiring unit 102 are referred to in step S110.

In some embodiments, the controller of the air conditioner has a positioning device. The positioning device comprises: the positioning device comprises an inner machine positioning part and a handheld positioning part. The indoor unit positioning portion, such as a positioning device indoor portion, is provided on an indoor unit of the air conditioner. The handheld positioning part, such as a positioning device handheld part, is arranged on a remote controller of the air conditioner.

The operating parameters include: the position parameter and the point-to-point parameter are generated by clicking the handheld positioning part at the position of the user, or the path parameter and the long-press parameter are generated by pressing the handheld positioning part for a long time on the path passed by the user. The click parameter is used for indicating whether the click operation of the user is an air supply operation or a wind shielding operation. The long press parameter is used for indicating whether the long press operation of the user is an air supply operation or a wind shielding operation. Wherein at least one of the position parameter and the path parameter comprises a parameter generated by a user operating the handheld positioning part or a parameter generated by the internal positioning part recognizing the user operating the handheld positioning part.

The obtaining unit 102 obtains an operation parameter of a user of the air conditioner, and includes: the obtaining unit 102 is specifically configured to locate, by the internal positioning unit, a located position or a path of the handheld positioning unit, or receive, by the internal positioning unit, the located position or the path of the handheld positioning unit generated by a user operating the handheld positioning unit, and receive, by the handheld positioning unit, a click parameter sent by a click operation of the handheld positioning unit or a long press parameter sent by a long press operation of the handheld positioning unit, so as to obtain the operation parameter of the handheld positioning unit.

Fig. 3 is a hardware topology diagram of an embodiment of a controller in an apparatus for implementing a precise blowing and wind-shielding function of an indoor unit with a wind-sweeping plate. As shown in fig. 3, the controller of the device for implementing the precise wind blowing and shielding function of the indoor unit with the wind sweeping plate comprises a positioning device. In the example shown in FIG. 3, the positioning device includes two parts, a positioning device hand-held part and a positioning device built-in part.

Wherein, positioner handheld portion includes: physical keys capable of human-computer interaction. The handheld part of the positioning device can be integrated into an air conditioner remote controller. The physical keys capable of performing man-machine interaction can use a combined key or a special key to enter the functions of 'presetting an air supply point' and 'setting an air supply point'.

The handheld portion of positioner still includes: and the signal unit can send signals which can be received by the air conditioner indoor unit.

Positioning a device inboard portion, comprising: and the sensing unit is used for receiving signals sent by the handheld part of the positioning device.

The internal portion of positioner still includes: and a calculation unit for performing position recognition. The position identification comprises the following steps: and translating the coordinates of the air supply model of the air conditioner and the positioning device, and converting a coordinate system when the original point of the air supply model is inconsistent with that of the positioning device.

A control unit 104 configured to determine spatial coordinates of an air supply space or a wind shielding space of the air conditioner according to the operation parameter. The specific function and processing of the control unit 104 are referred to in step S120.

In some embodiments, the controller of the air conditioner further has a wind sweeping part. An air supply model of the air conditioner is preset on the air sweeping part. And the air supply model comprises the corresponding relation among the air supply angle, the air supply intensity and the air supply range of the air conditioner.

The control unit 104, determining the spatial coordinates of the air supply space or the wind shielding space of the air conditioner according to the operation parameters, includes: the control unit 104 is further specifically configured to determine, by the wind sweeping part, a spatial coordinate of the air supply space or the wind shielding space of the air conditioner according to the operation parameter and the air supply model.

As shown in fig. 3, the controller of the device for implementing the accurate wind blowing and sheltering function of the indoor unit with the wind sweeping plate further comprises a wind sweeping unit. That is to say, the controller in the device for realizing the accurate blowing and wind-shielding function of the indoor unit with the wind-sweeping plate comprises a positioning device and a wind-sweeping unit (namely a wind-sweeping part), and the positioning device and the wind-sweeping unit can finish the accurate blowing and wind-shielding of the wind-sweeping plate. The air supply point and the wind shielding point (namely, the space coordinate) are selected through the positioning device, and then the space coordinate corresponds to the air supply angle of the air conditioner, so that the effect of accurate air blowing and wind shielding is achieved.

In the example shown in fig. 3, the wind sweeping part includes: and a calculation unit for controlling the action of the wind sweeping plate. And the computing unit is used for controlling the action of the air sweeping plate and is responsible for determining the action of the air sweeping plate according to the air supply model and the air supply point. Sweep the wind part, still include: and an operation unit for performing a wind sweeping operation.

In some embodiments, the air supply model is a corresponding relationship between an air supply angle, an air supply intensity and an air supply range of the air conditioner, which is determined according to an equipment parameter and an air outlet parameter of the air conditioner.

The air supply model can be preset in the air sweeping part of the air conditioner. When the air supply model is changed, the air supply model can be changed through a set communication mode and a set change protocol.

Fig. 4 is a control flow diagram of an implementation apparatus for implementing a precise blowing and wind-shielding function of an indoor unit with a wind-sweeping plate. As shown in fig. 4, the control process of the device for implementing the accurate wind blowing and sheltering function of the indoor unit with the wind sweeping plate includes:

step 1, pre-installing an air supply model, namely pre-installing an air supply model of a controller.

And step 11, determining an air supply model of the controller. According to the structure (such as fan type, fan blade shape and air deflector area) of the equipment, air quantity, air pressure, rotating speed, outlet air speed and the like, the air sweeping unit is internally provided with a plurality of air supply angles, air supply strengths and air supply ranges based on the equipment.

Specifically, only a first-order relation needs to be considered, firstly, linear relation among the air supply range, the area of the air deflector, the air supply intensity and the air supply angle is assumed, then a quaternary linear function of the air supply range, the equipment structure and the air speed is derived according to test data, and after the linear fitting degree (such as a complex correlation coefficient and a partial correlation coefficient) of the quaternary linear function is evaluated, the quaternary linear function is written into an air supply model.

For example: the air supply angle has a maximum air supply angle and a minimum air supply angle, and can be adjusted according to a unit angle in the range. The air supply intensity has zero rotating speed and maximum rotating speed, and can be adjusted according to the unit rotating speed in the range. The air supply range is determined according to the installation height of the equipment, the air supply angle and the air supply intensity.

In general, macroscopic gas motion is a statistical average of the microscopic motion of a large number of gas molecules and is not well suited for model calculations in a controller. And blowing comfort is a mental activity that varies from person to person that is difficult to quantify accurately. Therefore, the air supply range can be determined by manufacturers in the development stage according to the structure, air volume, air pressure, rotating speed, outlet air speed and the like of equipment, user data, experimental data and the like, and the air supply range is preloaded in the internal storage of the controller, so that the corresponding relation among the air supply angle, the air supply intensity and the air supply range is finally formed.

And 12, changing an air supply model. The unit can provide communication mode and change agreement, and the producer personnel change the air supply model, namely the corresponding relation of air supply angle, air supply intensity and air supply scope.

The air supply model is stored in the air conditioner indoor unit, so that the air supply model needs to be changed by communicating with the indoor unit, for example, by communication modes such as 485 communication, CAN (controller area network) communication, wireless WIFI communication and the like, and the air supply model is changed.

The modified protocol can be used for appointing a handshaking mode, for example, when the air conditioner internal unit identifies a special function code, the received data is stored as an air supply model parameter, and then the air supply model parameter is sent back to the upper computer for confirmation. And finally, after receiving the specific function code (namely the specific function code), the air conditioner internal unit confirms to change the model, and replaces the air supply model parameter with the latest received parameter data.

And step 2, presetting an air supply point.

When the function of 'presetting air supply points' is entered, the internal part of the device is positioned, and the current coordinates of the handheld part of the positioning device are identified so as to determine the air supply points.

Step 21 and fig. 5 are schematic single-point coordinates of an embodiment of an implementation scheme of an indoor unit with a sweep plate for precise blowing and wind shielding functions. Clicking a key on the handheld part of the positioning device sets the current position as a preset blowing point, which can be seen as the "a2" point, "C1" point, and "D2" point in the example shown in fig. 5.

And step 22, moving when the key of the handheld part of the positioning device is pressed for a long time, and setting the moving path as the preset air supply range of the key. Fig. 6 is a schematic diagram of a path and coordinates of an embodiment of an implementation scheme of a precise blowing and wind shielding function of an indoor unit with a wind sweeping plate. Assuming that the moving path takes the "a2" point, the "B1" point, the "C1" point, the "D2" point, and the "E2" point, a COORDINATE point set D1(COORDINATE) can be obtained, as shown in fig. 6.

And 3, setting an air supply point by a user.

When the function of 'setting air supply points' is entered, the preset air supply points can be selected by pressing the corresponding keys of the handheld part of the positioning device, or the current coordinates of the handheld part can be identified by the inside of the positioning device, so that the air supply points are determined.

And step 31, when the preset air supply point is set by pressing the key, setting according to the air supply point or the air supply range represented by the single key.

And step 32, when the air supply points are set through the identification coordinates, the operation logic is consistent with the function of the preset air supply points, namely, a single air supply angle can be set, and a continuous air supply range can be set.

There is a particular application here: the air conditioner internal unit can be arranged to supply air along with the handheld part or avoid the handheld part to supply air, so that the aim of avoiding people along with the wind of people is indirectly fulfilled.

The control unit 104 is further configured to determine an air supply angle of the air conditioner according to the spatial coordinates, and control the air conditioner to operate at the air supply angle. The specific function and processing of the control unit 104 are also referred to in step S130.

The scheme of the invention provides a novel application mode combining wind sweeping, space positioning and user interaction, which is a popular and easily understood wind sweeping setting mode which accords with the use habits of users and is simple and convenient to operate, and the users can reasonably blow wind by setting the wind sweeping range to realize various wind sweeping effects. Such as: the user can instruct the air conditioner to blow to the wet land board which has just dragged the ground, instruct the air conditioner to blow to the wet clothes which are not easy to dry in plum rain weather, instruct the air conditioner to blow to corners to avoid crowds and the like. In addition, due to the simple operation and flexible arrangement, the operation is as simple and easy as the remote channel change of the television.

In the scheme of the invention, the air supply point and the wind shielding point are selected by adopting the positioning device, so that the wind can be swept to perform stepless motion, and the air can be discharged accurately. The air supply angle of the air conditioner is fixed and the air supply angle of the air conditioner is inconvenient to set by adopting a mode that the air supply point or the wind shielding point is selected by the positioning device, so that the convenience and the comfort of a user using the air conditioner are improved.

In the scheme of the invention, the air supply angle is corresponding to the space coordinate, so that the intelligent control can be realized, and the intelligent air supply device is simple, convenient and comfortable. The air supply angle of the air sweeping plate corresponds to the coordinates in the space, so that the problems that the user is not clear in space cognition and needs to think about an indoor three-dimensional space view when setting the air supply angle are solved, and the intelligent degree of air conditioner control is improved.

In some embodiments, the control unit 104, determining an air supply angle of the air conditioner according to the spatial coordinates, and controlling the air conditioner to operate at the air supply angle, includes:

the control unit 104 is further specifically configured to determine, according to the spatial coordinates, a corresponding relationship between the spatial coordinates and an air supply angle of the air conditioner based on a corresponding relationship between an air supply angle, an air supply intensity, and an air supply range in the air supply model, so as to obtain an air supply angle of the air conditioner, and control the air conditioner to operate according to the air supply angle.

In some embodiments, the spatial coordinates comprise: one coordinate or more than two coordinates; and under the condition that the space coordinates comprise more than two coordinates, the air supply angle is a set of more than two angles corresponding to the more than two coordinates, and the more than two angles in the set are sequenced according to a set sequence to form a running path of the air sweeping plate of the air conditioner.

As shown in fig. 4, the control process of the device for implementing the accurate wind blowing and sheltering function of the indoor unit with the wind sweeping plate further includes:

and 4, determining the wind sweeping action by the controller.

And step 41, the controller acquires the relation between the corresponding coordinates and the air supply angle according to the corresponding relation among the air supply angle, the air supply intensity and the air supply range according to the air supply point or the air supply range set by the positioning device.

Step 42, assuming that there is a mapping d (coordinate) → r (angle) between the blowing angle and the blowing range when the indoor unit is operated at the blowing intensity F at the installation height H, a corresponding angle can be obtained for each coordinate set by the positioning device. If only one coordinate exists, the angle corresponding to the coordinate is the hovering angle value of the wind sweeping board. Fig. 7 is a schematic diagram of a moving path and an air supply angle of a positioning device according to an embodiment of an implementation scheme of an accurate air blowing and wind shielding function of an indoor unit with a sweep plate. If there are multiple coordinates, then the set of multiple angles R1(Angle) is obtained, and the angles are sorted in increments to obtain the travel path of the wind deflector, as shown in the example of fig. 7.

Therefore, the scheme of the invention can determine the wind sweeping model according to the real-time operation result of the user, realize the wind sweeping action control under the simple operation of the user and solve the mismatch contradiction between the air quantity of the indoor unit and the comfortable feeling of the human body.

Since the processes and functions implemented by the apparatus of this embodiment substantially correspond to the embodiments, principles and examples of the method, reference may be made to the related descriptions in the embodiments without being detailed in the description of this embodiment, which is not described herein again.

Through a large number of tests, the technical scheme of the invention is adopted, the space coordinates are selected as the air supply point and the wind shielding point, and then the space coordinates are corresponding to the air supply angle of the air conditioner, so that the flexible setting of the air supply angle of the air conditioner is realized, the air can be swept to perform stepless motion, the air can be discharged accurately, and the user experience is improved.

According to an embodiment of the present invention, there is also provided an air conditioner corresponding to a control device of the air conditioner. The air conditioner may include: the control device of the air conditioner described above.

Since the processing and functions of the air conditioner of this embodiment are basically corresponding to the embodiments, principles and examples of the foregoing devices, reference may be made to the related descriptions in the foregoing embodiments without being detailed in the description of this embodiment.

Through a large number of tests, the technical scheme of the invention is adopted, and the spatial coordinates are selected as the air supply point and the wind shielding point and then correspond to the air supply angle of the air conditioner, so that the flexible setting of the air supply angle of the air conditioner is realized, and the convenience and the comfort of a user in using the air conditioner are improved.

According to an embodiment of the present invention, there is also provided a storage medium corresponding to a control method of an air conditioner, the storage medium including a stored program, wherein an apparatus where the storage medium is located is controlled to execute the control method of the air conditioner described above when the program is run.

Since the processing and functions implemented by the storage medium of this embodiment substantially correspond to the embodiments, principles, and examples of the foregoing method, reference may be made to the related descriptions in the foregoing embodiments without being detailed in the description of this embodiment.

Through a large number of tests, the technical scheme of the invention is adopted, and the spatial coordinates are selected as the air supply point and the wind shielding point and then correspond to the air supply angle of the air conditioner, so that the flexible setting of the air supply angle of the air conditioner is realized, and the intelligent degree of air conditioner control is improved.

According to an embodiment of the present invention, there is also provided a processor corresponding to a control method of an air conditioner, the processor being configured to execute a program, wherein the program executes the control method of the air conditioner described above.

Since the processing and functions implemented by the processor of this embodiment substantially correspond to the embodiments, principles, and examples of the foregoing method, reference may be made to the related descriptions in the foregoing embodiments without being detailed in the description of this embodiment.

Through a large number of tests, the technical scheme of the invention is adopted, and the spatial coordinates are selected as the air supply point and the wind shielding point, and then are corresponding to the air supply angle of the air conditioner, so that the flexible setting of the air supply angle of the air conditioner is realized, and the effect of accurate air blowing and wind shielding can be achieved.

In summary, it is readily understood by those skilled in the art that the advantageous modes described above can be freely combined and superimposed without conflict.

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