CN111306736B

CN111306736B - Control method and device of air conditioner, air conditioner and electronic equipment

Info

Publication number: CN111306736B
Application number: CN202010120964.5A
Authority: CN
Inventors: 姬安生; 蔡国健; 杜顺开
Original assignee: GD Midea Air Conditioning Equipment Co Ltd
Current assignee: GD Midea Air Conditioning Equipment Co Ltd
Priority date: 2020-02-26
Filing date: 2020-02-26
Publication date: 2021-08-20
Anticipated expiration: 2040-02-26
Also published as: CN111306736A

Abstract

The application discloses a control method and device of an air conditioner, the air conditioner and electronic equipment. The air conditioner comprises a shell and a non-wind-sensing structure, wherein the shell is provided with a front air outlet, the non-wind-sensing structure is movably arranged on the shell and can avoid or at least partially shield the front air outlet, the non-wind-sensing structure comprises a mounting plate and a wind guide assembly, an air outlet is formed in the mounting plate, the wind guide assembly comprises a static blade and a rotatable movable blade, and the static blade and the movable blade are arranged along the axial direction of the air outlet. The method comprises the following steps: responding to an instruction of the no-wind-sensation operation mode, and controlling the no-wind-sensation structure to operate according to a default first operation parameter; acquiring the indoor temperature of the room where the air conditioner is located; determining a target rotating speed of an indoor fan and a target operation parameter of a non-wind-sensing structure according to the indoor temperature and the set temperature of the air conditioner; the indoor fan is controlled to be adjusted to the target rotating speed from the current rotating speed, and the non-wind-sensation structure is controlled to be adjusted to the target operating parameter from the current operating parameter, so that the refrigerating speed of the air conditioner is accelerated.

Description

Control method and device of air conditioner, air conditioner and electronic equipment

Technical Field

The present disclosure relates to the field of air conditioners, and in particular, to a method and an apparatus for controlling an air conditioner, an electronic device, and a computer-readable storage medium.

Background

Along with the improvement of the living standard of people, the requirement on the comfort of the air conditioner is higher and higher. The air outlet of the indoor unit of the existing air conditioner is generally provided with a non-wind-sensing structure, so that the air outlet of the air conditioner is more uniform, and the wind sense is more comfortable. However, the cooling speed of the no-wind-sense mode of the existing air conditioner is slow, the control method is single, and the user requirements cannot be met.

Disclosure of Invention

The present application is directed to solving, at least to some extent, one of the technical problems in the related art.

To this end, a first object of the present application is to provide a control method of an air conditioner.

A second object of the present application is to provide a control apparatus of an air conditioner.

A third object of the present application is to provide an air conditioner.

A fourth object of the present application is to provide an electronic device.

A fifth object of the present application is to propose a computer-readable storage medium.

In order to achieve the above object, an embodiment of a first aspect of the present application provides a control method for an air conditioner, the air conditioner includes a housing and an air-out structure, the housing has a front air outlet, the air-out structure is movably disposed on the housing and can avoid or at least partially block the front air outlet, the air-out structure includes a mounting plate and a wind guide assembly, an air outlet is disposed on the mounting plate, the wind guide assembly includes a stationary blade and a rotatable movable blade, the stationary blade and the movable blade are arranged along an axial direction of the air outlet, and the control method includes the following steps: responding to an instruction of a no-wind-sensation operation mode, and controlling the no-wind-sensation structure to operate according to a default first operation parameter; the operation parameters of the non-wind-sensation structure comprise the amount of the mounting plate moving out of the accommodating cavity and the rotating angle of the movable blades in the air guide assembly; acquiring the indoor temperature of the room where the air conditioner is located; determining a target rotating speed of an indoor fan and a target operation parameter of the non-wind-sensing structure according to the indoor temperature and the set temperature of the air conditioner; and controlling the indoor fan to be adjusted to the target rotating speed from the current rotating speed, and controlling the non-wind-sensation structure to be adjusted to the target operating parameter from the current operating parameter.

In addition, the control method of the air conditioner proposed according to the above-mentioned embodiment of the present application may further have the following additional technical features:

in an embodiment of the present application, the determining a target rotation speed of an indoor fan and a target operation parameter of the non-air-sensing structure according to the indoor temperature and the set temperature of the air conditioner includes: acquiring the offset of the indoor environment and the set temperature; and determining the target rotating speed and the target operation parameter according to the target range in which the offset is positioned.

In an embodiment of the present application, before determining the target rotation speed and the target operating parameter according to the target range in which the offset is located, the method further includes: and identifying the set rotating speed of the indoor fan.

In an embodiment of the application, the determining the target rotation speed and the target operating parameter according to the target range in which the offset is located includes: if the indoor fan does not have the set rotating speed and the target range is a first range, maintaining the target rotating speed as a default first rotating speed, and the target operating parameter is the first operating parameter;

if the indoor fan does not have the set rotating speed and the target range is a second range, determining that the target rotating speed is the highest rotating speed and the target operating parameter is the second operating parameter; wherein the amount of removal of the mounting plate in the second operating parameter is less than or equal to the amount of removal of the mounting plate in the first operating parameter, and the angle of rotation of the movable blade in the second operating parameter is less than or equal to the angle of rotation of the movable blade in the first operating parameter;

if the indoor fan does not have the set rotating speed and the target range is a third range, performing coefficient correction on the highest rotating speed to obtain the target rotating speed, wherein the target operating parameter is the third operating parameter; the target rotating speed obtained after the coefficient correction is greater than or equal to the highest rotating speed, the moving-out amount of the mounting plate in the third operating parameter is less than or equal to the moving-out amount of the mounting plate in the second operating parameter, and the rotating angle of the movable blade in the third operating parameter is less than or equal to the rotating angle of the movable blade in the second operating parameter;

wherein an upper endpoint of the first range is less than or equal to a lower endpoint of the second range, and an upper endpoint of the second range is less than or equal to a lower endpoint of the third range.

In an embodiment of the application, the determining the target rotation speed and the target operating parameter according to the target range in which the offset is located includes: if the indoor fan has the set rotating speed and the target range is a first range, maintaining the target rotating speed as the set rotating speed and the target operating parameter as the first operating parameter;

the indoor fan has the set rotating speed, and the target range is a second range, the set rotating speed is corrected to obtain the target rotating speed, and the target operating parameter is the second operating parameter;

if the indoor fan has the set rotating speed and the target range is a third range, performing coefficient correction on the default rotating speed of the air conditioner to obtain the target rotating speed, wherein the target operating parameter is the third operating parameter; the target rotating speed obtained after the coefficient correction is greater than or equal to the default rotating speed, and the target rotating speed is less than or equal to the highest rotating speed;

in one embodiment of the present application, the air conditioner further includes an outer air deflector, and the outer air deflector can open or close the front air outlet; after determining that the target operating parameter is the third operating parameter, further comprising: and maintaining the current wind guiding angle of an external wind guiding plate of the air conditioner.

In an embodiment of the present application, before controlling the air conditioner to enter the no-wind mode, the method further includes: receiving a starting instruction of the air conditioner; and controlling an outer air deflector in the air conditioner to open the front air outlet and controlling the non-wind-sensing structure to keep avoiding the state of the front air outlet.

In one embodiment of the present application, the control method of the air conditioner further includes: receiving a closing instruction of the no-wind-sensation mode; and controlling the non-wind-sensing structure to be adjusted from a state of at least partially shielding the front air outlet to a state of avoiding the front air outlet.

In order to achieve the above object, an embodiment of a second aspect of the present application provides a control device of an air conditioner, the air conditioner includes a housing and an air-out structure, the housing has a front air outlet, the air-out structure is movably established on the housing, and can dodge or at least partially shelter from the front air outlet, the air-out structure includes a mounting panel and a wind guide assembly, be provided with the exhaust vent on the mounting panel, the wind guide assembly includes stationary blade and rotatable movable blade, the stationary blade with the movable blade is followed the axial of exhaust vent is arranged, the control device includes: the instruction response module is used for responding to an instruction of the no-wind-sensation operation mode and controlling the no-wind-sensation structure to operate according to a default first operation parameter; the operation parameters of the non-wind-sensation structure comprise the amount of the mounting plate moving out of the accommodating cavity and the rotating angle of the movable blades in the air guide assembly; the temperature acquisition module is used for acquiring the indoor temperature of the room where the air conditioner is located; the determining module is used for determining target operation parameters of the non-wind-sensing structure according to the indoor temperature and the set temperature of the air conditioner; and the adjusting module is used for controlling the indoor fan to be adjusted from the current rotating speed to the target rotating speed and controlling the non-wind-sensing structure to be adjusted from the current operating parameter to the target operating parameter.

In addition, the control device of the air conditioner according to the above embodiment of the present application may further have the following additional technical features:

in an embodiment of the application, the determining module is specifically configured to: acquiring the offset of the indoor environment and the set temperature; and determining the target rotating speed and the target operation parameter according to the target range in which the offset is positioned.

In an embodiment of the application, the determining module is specifically configured to: and identifying the set rotating speed of the indoor fan before determining the target rotating speed and the target operating parameters according to the target range of the offset.

In an embodiment of the application, the determining module is further configured to: if the indoor fan does not have the set rotating speed and the target range is a first range, maintaining the target rotating speed as a default first rotating speed, and the target operating parameter is the first operating parameter;

if the indoor fan does not have the set rotating speed and the target range is a third range, performing coefficient correction on the highest rotating speed to obtain the target rotating speed, wherein the target operating parameter is the third operating parameter; the target rotating speed obtained after the coefficient correction is greater than or equal to the highest rotating speed, the moving-out amount of the mounting plate in the third operating parameter is less than or equal to the moving-out amount of the mounting plate in the second operating parameter, and the rotating angle of the movable blade in the third operating parameter is less than or equal to the rotating angle of the movable blade in the second operating parameter.

In an embodiment of the application, the determining module is further configured to: if the indoor fan has the set rotating speed and the target range is a first range, maintaining the target rotating speed as the set rotating speed and the target operating parameter as the first operating parameter;

in one embodiment of the present application, the air conditioner further includes an outer air deflector, and the outer air deflector can open or close the front air outlet; the adjusting module is further configured to: and after the target operation parameter is determined to be the third operation parameter, maintaining the current wind guide angle of an outer wind deflector of the air conditioner.

In an embodiment of the application, the instruction response module is further configured to: before the air conditioner is controlled to enter the no-wind-sense mode to operate, a starting instruction of the air conditioner is received; and controlling an outer air deflector in the air conditioner to open the front air outlet and controlling the non-wind-sensing structure to keep avoiding the state of the front air outlet.

In an embodiment of the application, the instruction response module is further configured to: receiving a closing instruction of the no-wind-sensation mode; and controlling the non-wind-sensing structure to be adjusted from a state of at least partially shielding the front air outlet to a state of avoiding the front air outlet.

To achieve the above object, an embodiment of a third aspect of the present application provides an air conditioner, including: casing and no wind-sensing structure, the casing has preceding air outlet, the movably establishment of no wind-sensing structure on the casing, and can dodge or at least partially shelter from preceding air outlet, no wind-sensing structure includes mounting panel and wind guide component, be provided with the exhaust vent on the mounting panel, wind guide component includes quiet leaf and rotatable movable vane, quiet leaf with the movable vane is followed the axial of exhaust vent is arranged to and the controlling means of foretell air conditioner.

In one embodiment of the application, a first driving assembly is further arranged on the non-wind-sensing structure, the first driving assembly is connected with a movable blade in at least one wind guide assembly through a first transmission part, and is connected with an adjacent movable blade in the wind guide assembly through a second transmission part; the first driving assembly is connected with a control device of the air conditioner, and drives the movable blades in the air guide assembly to rotate under the control of the control device of the air conditioner.

In one embodiment of the present application, the number of the first driving assemblies is at least two, and each first driving assembly is connected to a moving blade in at least one of the wind guide assemblies.

In one embodiment of the present application, the air conditioner further includes: the second driving assembly is connected with the mounting plate in the non-wind-sensing structure and is connected with the control device of the air conditioner, and the mounting plate is driven to move in the accommodating cavity in a telescopic mode under the control of the control device of the air conditioner; the second drive assembly includes: the motor is arranged on the shell; the gear is connected with an output shaft of the motor; the rack is arranged on the mounting plate and extends along the up-down direction, and the rack is suitable for being meshed with the gear.

In one embodiment of the present application, the mounting plate further includes thereon: a limiting plate; the limiting plate is arranged on the mounting plate and is suitable for contacting with the shell when the mounting plate moves so as to limit the moving amount of the mounting plate out of the accommodating cavity.

To achieve the above object, a fourth aspect of the present application provides an electronic device, including a memory, a processor; the processor reads the executable program codes stored in the memory to run programs corresponding to the executable program codes, so as to realize the control method of the air conditioner.

To achieve the above object, a fifth aspect of the present application provides a computer-readable storage medium storing a computer program, which when executed by a processor, implements the control method of the air conditioner.

One or more technical solutions provided in the embodiments of the present application have at least the following technical effects or advantages:

1. in the application, the target rotating speed of the indoor fan and the target operating parameter of the non-wind-sensing structure can be determined according to the indoor temperature and the set temperature in the process of the air conditioner operating in the non-wind-sensing mode, so that the rotating speed of the indoor fan and the operating parameter of the non-wind-sensing structure are matched with the current indoor temperature and the set temperature, the air conditioner refrigerating speed is accelerated, and the comfort level of a user is improved.

2. Can confirm the target rotational speed of indoor fan and the target operating parameter of no wind sense structure according to the offset of indoor temperature and settlement temperature in this application for the rotational speed of indoor fan, the operating parameter of no wind sense structure and current indoor temperature and the offset phase-match of settlement temperature are favorable to accelerating the refrigeration speed of air conditioner, have improved user's comfort level.

3. Can confirm the target rotational speed of indoor fan according to the settlement rotational speed or the default rotational speed of indoor fan in this application to and the scope that the offset of indoor temperature and settlement temperature is located, the flexibility is higher.

4. In this application, if the air conditioner further comprises an outer air deflector, the front air outlet can be opened or closed by the outer air deflector. And identifying that the target range in which the offset is positioned is a third range, and maintaining the current air guide angle of an outer air deflector of the air conditioner after determining that the target operation parameter of the non-wind-sensation structure is the third operation parameter so as to keep the opening angle of the front air outlet.

5. In this application, if the air conditioner further comprises an outer air deflector, the front air outlet can be opened or closed by the outer air deflector. Before the air conditioner is controlled to run in the no-wind-sensation mode, the starting-up instruction of the air conditioner can be received, the outer air deflector is controlled to open the front air outlet, the no-wind-sensation structure is controlled to keep the state of avoiding the front air outlet, and the air conditioner can run in the normal working mode. And the control device can also receive a closing instruction of the no-wind-sensation mode and then control the no-wind-sensation structure to adjust from a state of at least partially shielding the front air outlet to a state of avoiding the front air outlet so as to close the no-wind-sensation mode of the air conditioner.

Drawings

The foregoing and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a schematic view of an air conditioner in a no-wind mode according to an embodiment of the present application;

FIG. 2 is a schematic cross-sectional view illustrating an air conditioner in an off state according to an embodiment of the present application;

FIG. 3 is a schematic cross-sectional view illustrating an embodiment of an air conditioner in a normal operation mode;

FIG. 4 is a schematic cross-sectional view illustrating an air conditioner in a no-wind mode according to an embodiment of the present application;

FIG. 5 is a schematic view of a non-wind-sensing structure on a housing of an air conditioner according to an embodiment of the present application;

FIG. 6 is an exploded view of a non-wind sensitive structure according to one embodiment of the present application;

FIG. 7 is a schematic view of a portion of the non-wind-sensing structure of FIG. 5;

FIG. 8 is a schematic view of the relative positions of the vane and the blade of the wind guide assembly in the non-wind-induced structure according to an embodiment of the present application;

FIG. 9 is a schematic view of the relative positions of the vane and the blade of the wind guide assembly in the non-wind-induced structure according to another embodiment of the present application;

fig. 10 is a flowchart of a control method of an air conditioner according to an embodiment of the present application;

FIG. 11 is a schematic cross-sectional view of an air conditioner with a non-wind-sensing structure according to an embodiment of the present application, wherein the operating parameters of the non-wind-sensing structure are default first operating parameters, and the relative positions of a stationary blade and a movable blade on an air guide assembly in the non-wind-sensing structure are schematic diagrams;

fig. 12 is a flowchart of a control method of an air conditioner according to another embodiment of the present application;

fig. 13 is a flowchart of a control method of an air conditioner according to another embodiment of the present application;

FIG. 14 is a schematic cross-sectional view of an air conditioner with a non-wind-sensing structure according to an embodiment of the present application, wherein the operation parameter of the non-wind-sensing structure is a first operation parameter, and the relative positions of a stationary blade and a movable blade on the wind guide assembly in the non-wind-sensing structure are shown;

FIG. 15 is a schematic cross-sectional view of an air conditioner according to an embodiment of the present application, wherein the operating parameter of the non-wind-sensing structure is a second operating parameter, and the relative positions of the stationary blade and the movable blade of the wind guide assembly in the non-wind-sensing structure are shown;

FIG. 16 is a schematic cross-sectional view of an air conditioner according to an embodiment of the present application, wherein the operation parameter of the non-wind-sensing structure is a third operation parameter, and the relative positions of the stationary blade and the movable blade of the wind guide assembly in the non-wind-sensing structure are shown;

fig. 17 is a block diagram schematically illustrating a control apparatus of an air conditioner according to an embodiment of the present application;

FIG. 18 is a block schematic diagram of an air conditioner according to one embodiment of the present application; and

FIG. 19 is a block diagram of an electronic device according to one embodiment of the present application.

Reference numerals:

10-a housing; 101-front air outlet;

11-no wind-sensing structure; 111-a mounting plate; 112-a wind guide component; 113-a first drive assembly; 114-a first transmission; 115-a second transmission part; 1111-air outlet; 1112-a rack; a second drive assembly 116; a 1113 motor; 1114-gear; 1115-a limiting plate; 1121-stationary vanes; 1122-the bucket;

12-an outer air deflector;

13-inner wind deflector;

14-rotating axis.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present application and should not be construed as limiting the present application.

A control method and apparatus of an air conditioner, an electronic device, and a computer-readable storage medium according to embodiments of the present application are described below with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of an air conditioner in a no-wind mode according to an embodiment of the present disclosure. As shown in fig. 1, the air conditioner includes a casing 10, a non-wind sensing structure 11 and an external air deflector 12; the casing 10 has a front air outlet, which may be located at the lower end of the casing 10, and the air conditioner exhausts air through the front air outlet, as shown in fig. 1, that is, an air outlet area where the non-wind-sensing structure 11 and the outer air guide plate 12 are overlapped. Optionally, at least one vent is disposed on the outer air deflection plate 12.

Fig. 2 is a schematic cross-sectional structure view of an air conditioner in an off state according to an embodiment of the present disclosure, and fig. 3 is a schematic cross-sectional structure view of an air conditioner in an on state in a normal operating mode according to an embodiment of the present disclosure. As shown in fig. 2, when the air conditioner is in a shutdown state, the outer air deflector 12 closes the front air outlet of the air conditioner, a first side of the outer air deflector 12 contacts with a lower edge of a right side (in an orientation in the figure) of the casing 10, a second side of the outer air deflector 12 contacts with a right edge of a lower side (in an orientation in the figure) of the casing 10, and meanwhile, the non-wind-sensing structure 11 is located inside the casing 10. As shown in fig. 3, when the air conditioner is turned on and in the normal operation mode (cooling mode), the outer air guiding plate 12 rotates towards the lower region of the casing 10 to open the front air outlet 101 of the air conditioner, and at this time, the non-wind-sensing structure 11 is still located in the accommodating cavity (not shown) inside the casing 10.

Further, a rotatable inner air guide plate 13 is provided in the air conditioner, and a rotation shaft 14 of the inner air guide plate 13 is arranged in a left-right direction (left-right direction in fig. 1) of the casing 10, i.e., extends from the left side to the right side of the casing 10.

Fig. 4 is a schematic cross-sectional view illustrating an air conditioner in a no-wind mode according to an embodiment of the present disclosure. Referring to fig. 3 and 4, after the air conditioner is switched from the normal operation mode to the no-wind-sensation mode, the no-wind-sensation structure 11 is removed from the casing 10 and at least partially covers the front wind outlet 101; meanwhile, the states of the outer air deflector 12 and the inner air deflector 13 are kept unchanged.

Fig. 5 is a schematic structural diagram of a no-wind structure on a case of an air conditioner in an embodiment of the present disclosure. As shown in fig. 5, the non-wind-sensing structure 11 includes a mounting plate 111 and a wind guiding assembly 112, the mounting plate 111 is provided with an air outlet 1111, the wind guiding assembly 112 is disposed in the air outlet 112, the wind guiding assembly 112 includes a stationary blade 1121 and a rotatable movable blade 1122, and the stationary blade 1121 and the movable blade 1122 are arranged along an axial direction of the air outlet 1111. Racks 1112 are respectively arranged at two ends of the mounting plate 111, a second driving assembly 116 (not shown in the figure) matched with the racks 1112 is arranged on the casing 10 of the air conditioner, and the racks 1112 are driven to move by the second driving assembly 116 on the casing 10, so that the non-wind-sensing structure 11 is controlled to shield or avoid the front air outlet 101 on the casing 10.

Optionally, as shown in fig. 6, the non-wind-sensing structure 11 further includes a second driving assembly 116 for driving the mounting plate 111 to move telescopically in the accommodating cavity, the second driving assembly 116 is connected to the mounting plate 111 and connected to a control device 200 (not shown) of the air conditioner, and the mounting plate 111 is driven to move telescopically in the accommodating cavity under the control of the control device 200 of the air conditioner. Fig. 17 is a schematic structural diagram of the control device 200 of the air conditioner. The second drive assembly 116 includes: motor 1113, gear 1114 and rack 1112, motor 1113 is set on the shell 10. Gear 1114 is coupled to an output shaft of motor 1113. A rack 1112 is provided on the mounting plate 111 and extends in the up-down direction, and the rack 1112 is adapted to engage with a gear 1114. That is, when the mounting plate 111 needs to be driven to move telescopically in the accommodating cavity, the gear 1114 is meshed with the rack 1112, and the motor 1113 rotates forward or backward, so that the mounting plate 111 can move telescopically in the accommodating cavity, and the telescopic movement of the mounting plate 111 is more reliable.

In addition, as shown in fig. 6, the non-wind sensing structure 11 further includes a limit plate 1115, the limit plate 1115 is disposed on the mounting plate 111, and the limit plate 1115 is adapted to contact the housing 10 when the mounting plate 111 moves so as to limit the amount of the mounting plate 111 moving out of the accommodating cavity. That is, through the limiting plate 1115 installed on the mounting plate 111, after the mounting plate 111 moves to the preset position, the limiting plate 1115 can abut against the housing 10, so as to achieve the purpose of limiting the mounting plate 111 to continue moving, and further make the movement of the mounting plate more reliable.

Alternatively, one end of the stationary blade 1121 of the air guide assembly 112 is fixed to the mounting plate 111, the other end of the stationary blade 1121 is fixed to the mounting shaft, and the movable blade 1122 is mounted to the mounting shaft by the rotating member; wherein, the rotating member is sleeved on the mounting shaft, and the axial direction of the mounting shaft is the same as that of the air outlet 1111. In this embodiment, the rotating member rotates relative to the installation shaft, and can drive the movable blade 1122 to rotate.

Optionally, the stationary vanes 1121 are plural and are fixedly arranged at intervals along the circumferential direction of the mounting shaft; the rotor blades 1122 are provided in plurality and are fixedly arranged at intervals in the circumferential direction of the rotor. Wherein, the number of the vanes 1121 may be, but not limited to, equal to the number of the blades 1122.

Fig. 7 is a partial structure diagram of the non-wind-sensing structure in fig. 5. As shown in fig. 7, the non-wind-sensing structure 11 is further provided with a first driving assembly 113 (such as a motor, etc.), and the first driving assembly 113 is connected to the movable blade 1122 of the at least one wind guide assembly 112 through the first transmission part 114. The blades 1122 of adjacent wind guide assemblies 112 are connected to each other by the second transmission unit 115. One of the moving blades 1122 is driven to rotate by the first driving assembly 113, so that the remaining moving blades 1122 rotate synchronously. Alternatively, the first transmission portion 114 and the second transmission portion 115 are both transmission gears, wherein racks matched with the transmission gears (i.e., the first transmission portion 114 and the second transmission portion 115) are disposed on the outer edges of the movable blades 1122 or other positions of the movable blades 1122. The first driving unit 113 is connected to the control device 200 (not shown) of the air conditioner, and drives the movable blade 1122 of the air guide unit 112 to rotate under the control of the control device 200 of the air conditioner.

Optionally, a first accommodating cavity capable of accommodating a part of the area on the air guide assembly 112 and a second accommodating cavity capable of accommodating the second transmission part 115 are formed in the mounting plate 111, wherein the first accommodating cavity is communicated with the second accommodating cavity.

It should be understood that, when the second transmission portion 115 is a transmission gear, a gear shaft engaged with the transmission gear is provided in the second receiving chamber. Further, the movable blade 1122 of the air guide assembly 112 is also provided with a rack gear engaged with the transmission gear.

Optionally, there are at least two first driving assemblies 113, and each first driving assembly 113 is connected to the movable blade 1122 in at least one air guiding assembly 112, so as to implement independent control on at least one air guiding assembly, improve user flexibility, and further meet different user requirements. It should be understood that there is no connection relationship between the wind guide assemblies 112 connected to different first driving assemblies 113.

Fig. 8 is a schematic diagram illustrating relative positions of a stationary blade and a movable blade on an air guide assembly in a non-wind-sensing structure according to an embodiment of the disclosure. As shown in fig. 8, the vanes 1121 and the blades 1122 are arranged in a staggered manner, and the area of the airflow outlet passing through the non-wind-sensing structure 11 is small, so that the amount of airflow flowing out of the non-wind-sensing structure 11 is small.

Fig. 9 is a schematic diagram illustrating relative positions of a vane and a blade on an air guide assembly in a non-wind-sensing structure according to another embodiment of the present disclosure. As shown in fig. 9, the stationary blade 1121 and the movable blade 1122 are arranged to overlap each other, and at this time, the area of the airflow outlet passing through the non-wind-sensing structure 11 is small, and therefore, the amount of airflow flowing out of the non-wind-sensing structure 11 is large.

It should be noted that, when the air conditioner in this embodiment receives the start instruction of the no-wind-sensation mode, the driving mechanism inside the casing 10 (or at another position) drives the rack 1112 on the no-wind-sensation structure 11, so as to drive the no-wind-sensation structure 11 to move out of the accommodating cavity in the casing 10 and at least partially shield the front wind outlet 101 of the air conditioner. After the non-wind-sensing structure 10 at least partially shields the front air outlet 101, the air outlet flow of the front air outlet 101 is reduced, so that the air supply wind sense of the air conditioner is reduced; that is, under the action of the non-wind-feeling structure 11, the wind blown out by the air conditioner is firstly diffused and then flows to the environment where the air conditioner is located, so that the wind feeling of the air supply is reduced, and the use comfort of the air conditioner is improved. When the air conditioner receives a closing instruction of closing the no-wind-sensation mode, the driving mechanism in the housing 10 (or at another position) drives the rack 1112 on the no-wind-sensation structure 11, so as to drive the no-wind-sensation structure 11 to move into the accommodating cavity in the housing 10, thereby avoiding the front air outlet 101 of the air conditioner.

It should be understood that, in this embodiment, the non-wind-sensing structure 11 is hidden from the front air outlet 101, which is understood in a broad sense, that is, at least most of the front air outlet 101 is not shielded by the non-wind-sensing structure 11 (including complete hiding, that is, the front air outlet 101 is not shielded at all), but a shielding area of the non-wind-sensing structure 11 in the shielding position needs to be larger than a shielding area of the non-wind-sensing structure 11 in the shielding position.

In the embodiment, the no-wind-sensation mode is that the average value of the air flow speed and the blowing sensation index of the target area can meet the comfort requirement in each operation mode of the air conditioner. In general, the no-wind-sense mode needs to satisfy that the wind speed at a preset distance from the air outlet of the air conditioner is lower than a preset wind speed threshold and the blowing sense index is lower than a preset blowing sense index threshold. Optionally, the preset distance from the air outlet of the air conditioner is 2m to 3m, the preset wind speed threshold is 0.15m/s to 0.3m/s, and the blowing sensation index is 4.5% to 5.5%. Wherein, the blowing sensation index can be calculated by the following formula:

DR＝(34-T₁)*(V₁-0.05)0.62*(0.37*V₁*t₁+3.14)

dr (draught rate) is a draught index, which represents the percentage of dissatisfied persons resulting from the airflow carrying away human heat; generally, when the air conditioner is located in a room with different floor heights, the threshold ranges corresponding to the blowing sensations are different.

T₁Is the indoor temperature, V₁Is the average flow velocity of the indoor air, t₁Is the average turbulence intensity of the indoor air.

It should be noted that, in the no-wind mode, the ratio of the actual cooling capacity to the rated cooling capacity of the air conditioner also needs to satisfy the set threshold range. When the rated refrigerating capacity is less than or equal to 4500W, the ratio of the actual refrigerating capacity to the rated refrigerating capacity needs to be within the range of a threshold value of 45% -55%; when the rated refrigerating capacity is larger than 4500W, the ratio of the actual refrigerating capacity to the rated refrigerating capacity needs to be within the range of 25% -35% of the threshold value.

Fig. 10 is a flowchart of a control method of an air conditioner according to an embodiment of the present application.

As shown in fig. 10, the method for controlling an air conditioner according to the embodiment of the present application includes the following steps:

and S101, responding to the instruction of the no-wind-sensation operation mode, and controlling the no-wind-sensation structure to operate according to a default first operation parameter. The operation parameters of the non-wind-sensing structure comprise the removal amount of the mounting plate from the accommodating cavity and the rotation angle of the movable blades in the wind guide assembly.

It should be noted that the air conditioner in the embodiment of the present Application has a no-wind mode, and a user may send an opening instruction of the no-wind mode to the air conditioner through a remote controller, an air conditioner APP (Application program) in the mobile terminal, or an operation panel on a body of the air conditioner in a non-contact manner such as a language, a gesture, and the like. The air conditioner responds to the turn-on command, and normally, a non-air-sensing structure in the air conditioner can operate according to a default first operation parameter.

Referring to fig. 1 to 9, the air conditioner of the embodiment of the present application has a driving mechanism (not shown) capable of driving the mounting plate to be removed from the receiving chamber and driving the removed mounting plate to be returned to the receiving chamber. The blades in the air guide assembly can rotate to change the relative positions of the blades and the static vanes.

Alternatively, the default first operating parameter may be calibrated according to actual conditions, and may be preset in a storage space of the air conditioner, for example, may be stored in a main board of the air conditioner in advance.

For example, as shown in fig. 11, the amount of the mounting plate moving out of the accommodating cavity in the default first operating parameter is a, a is the maximum value of the amount of the mounting plate moving out of the accommodating cavity, the rotation angle of the blade in the air guide assembly is B, and B is the maximum angle of the blade, so that the blade and the vane are arranged in a staggered manner. When the no-wind-sensation structure operates according to the default first operating parameter shown in fig. 11, the amount of wind flowing through the front air outlet in the air conditioner is the smallest, the wind flowing out of the air conditioner flows to the area relatively close to the air conditioner, and the cooling speed of the air conditioner is the slowest.

S102, obtaining the indoor temperature of the room where the air conditioner is located.

Alternatively, the indoor temperature may be acquired by installing a temperature detection device on an indoor unit of the air conditioner, wherein the temperature detection device may be a temperature sensor.

And S103, determining a target rotating speed of the indoor fan and a target operation parameter of the non-wind-sensing structure according to the indoor temperature and the set temperature of the air conditioner.

Therefore, the method can comprehensively consider the influence of the indoor temperature and the set temperature on the rotating speed of the indoor fan and the operating parameter of the non-wind-sensing structure, so that the rotating speed of the indoor fan and the operating parameter of the non-wind-sensing structure are matched with the current indoor temperature and the set temperature, the refrigeration speed of the air conditioner is increased, and the comfort level of a user is improved.

Optionally, the user may set the temperature of the air conditioner through a remote controller, an air conditioner APP in the mobile terminal, or an operation panel on the body of the air conditioner in a non-contact manner such as a language, a gesture, or the like.

Optionally, a mapping relation and a mapping table between the indoor temperature, the set temperature, the target rotating speed of the indoor fan and the target operating parameter of the non-wind-sensing structure may be pre-established, and after the indoor temperature and the set temperature are obtained, the mapping relation or the mapping table is queried, so that the target rotating speed of the indoor fan of the air conditioner and the target operating parameter of the non-wind-sensing structure at the time can be determined, and the target rotating speed of the indoor fan and the target operating parameter of the non-wind-sensing structure are respectively adjusted. It should be noted that different mapping relationships or mapping tables may be respectively constructed according to different operation modes of the air conditioner, for example, different mapping relationships or mapping tables may be respectively constructed according to cooling and heating modes of the air conditioner.

As another possible embodiment, determining the target rotation speed of the indoor fan and the target operation parameter of the non-wind sensing structure according to the indoor temperature and the set temperature of the air conditioner may include determining the target rotation speed of the indoor fan and the target operation parameter of the non-wind sensing structure according to a magnitude relation between the indoor temperature and the set temperature.

Use the air conditioner to be in the refrigeration mode as an example, if discernment indoor temperature is greater than the settlement temperature, it is slower to explain the refrigeration speed of air conditioner this moment, can increase the target rotational speed of indoor fan, reduce the volume that the mounting panel shifted out from holding the chamber, and reduce the rotation angle of movable vane among the air guide component, make the amount of wind of the preceding air outlet in the air conditioner of flowing through increase, in order to accelerate the refrigeration speed of air conditioner, and can flow the wind that flows out in the air conditioner to the region relatively far away from the air conditioner, make the refrigeration effect of air conditioner more even, user's comfort level has been improved.

If the indoor temperature is equal to the set temperature, the indoor temperature reaches the set temperature of the user, the target rotating speed of the indoor fan can be reduced, the moving amount of the mounting plate out of the accommodating cavity is increased, the rotating angle of the movable blade in the air guide assembly is increased, the air quantity flowing through the front air outlet in the air conditioner is reduced, the refrigerating speed of the air conditioner is reduced, and the indoor temperature is continuously maintained at the set temperature.

And S104, controlling the indoor fan to adjust from the current rotating speed to the target rotating speed, and controlling the non-wind-sensation structure to adjust from the current operating parameter to the target operating parameter.

In summary, according to the control method of the air conditioner in the embodiment of the application, in the process that the air conditioner operates in the no-wind-sensation mode, the target rotating speed of the indoor fan and the target operating parameters of the no-wind-sensation structure can be determined according to the indoor temperature and the set temperature, so that the rotating speed of the indoor fan and the operating parameters of the no-wind-sensation structure are matched with the current indoor temperature and the set temperature, the refrigeration speed of the air conditioner is increased, and the comfort level of a user is improved.

A control method of an air conditioner according to another embodiment of the present application will be described with reference to fig. 12.

As shown in fig. 12, the method for controlling an air conditioner according to the embodiment of the present application includes the following steps:

and S201, responding to the instruction of the no-wind-sensation operation mode, and controlling the no-wind-sensation structure to operate according to the default first operation parameter. The operation parameters of the non-wind-sensing structure comprise the removal amount of the mounting plate from the accommodating cavity and the rotation angle of the movable blades in the wind guide assembly.

In one embodiment of the present application, as shown in fig. 2, the air conditioner further includes an outer air deflector 12, and the outer air deflector 12 can open or close the front outlet. As shown in fig. 2, when the air conditioner is in a shutdown state, the front outlet of the air conditioner is closed by the external air deflector 12. As shown in fig. 3, before the air conditioner is controlled to enter the no-wind-sensation mode, the air conditioner may further receive a start-up instruction of the air conditioner, then control the outer air deflector 12 to open the front air outlet 101, and control the no-wind-sensation structure 11 to keep avoiding the front air outlet 101, so that the air conditioner can operate in a normal operation mode.

Optionally, the user may send the start instruction to the air conditioner through a remote controller, an air conditioner APP in the mobile terminal, or an operation panel on the body of the air conditioner in a non-contact manner such as a language, a gesture, or the like.

S202, acquiring the indoor temperature of the room where the air conditioner is located.

S203, acquiring the offset of the indoor temperature and the set temperature of the air conditioner.

The offset may include a difference, a ratio, and the like between the indoor temperature and the set temperature.

And S204, determining the target rotating speed of the indoor fan and the target operating parameters of the non-wind-sensing structure according to the target range of the offset.

Therefore, the method can determine the target rotating speed of the indoor fan and the target operating parameter of the non-wind-sensing structure according to the offset of the indoor temperature and the set temperature, so that the rotating speed of the indoor fan and the operating parameter of the non-wind-sensing structure are matched with the offset of the current indoor temperature and the set temperature, the refrigeration speed of the air conditioner is increased, and the comfort level of a user is improved.

It should be noted that, a range in which the offset between the indoor temperature and the set temperature is located may be calibrated in advance, and it is understood that the range may be multiple, and different ranges may correspond to different target rotating speeds of the indoor fan and target operating parameters of the non-wind-sensing structure.

Optionally, a mapping relation and a mapping table between the range of the offset and the target rotation speed of the indoor fan and the target operation parameter of the non-wind-sensing structure may be pre-established, and after the target range of the offset is obtained, the mapping relation or the mapping table is queried, so that the target rotation speed of the indoor fan of the air conditioner and the target operation parameter of the non-wind-sensing structure at the time can be determined, and the target rotation speed of the indoor fan and the target operation parameter of the non-wind-sensing structure are respectively adjusted.

Taking the offset as the ratio of the indoor temperature to the set temperature as an example, the mapping relation and the mapping table between the range of the offset and the target rotating speed of the indoor fan and the target operating parameters of the non-wind-sensing structure can be calibrated by referring to the table 1.

TABLE 1 Range of offset and corresponding target speed of indoor fan, target operation parameter of non-wind-sensing structure

Wherein n is₁<n₂<n₃，L₁>L₂>L₃，θ₁>θ₂>θ₃. That is to say, the target rotational speed of indoor fan is positively correlated with the offset, and the volume that the mounting panel shifts out from holding the chamber, the rotation angle of movable vane in the air guide component and offset are negatively correlated with.

The air conditioner is in a refrigeration mode, the larger the offset is, the larger the difference between the indoor temperature and the set temperature is, the higher the refrigeration speed of the air conditioner is, therefore, the higher the rotating speed of the indoor fan is, the smaller the amount of the mounting plate moving out of the accommodating cavity is, the smaller the rotating angle of the movable blade in the air guide assembly is, the larger the overlapping area of the movable blade and the fixed blade is, the larger the air volume flowing through the front air outlet in the air conditioner is, the refrigeration speed of the air conditioner is accelerated, the air flowing out of the air conditioner can flow to an area relatively far away from the air conditioner, the refrigeration effect of the air conditioner is more uniform, and the comfort level of a user is improved.

S205, controlling the indoor fan to adjust from the current rotating speed to the target rotating speed, and controlling the non-wind-sensation structure to adjust from the current operating parameter to the target operating parameter.

In one embodiment of the present application, as shown in fig. 4, the air conditioner further includes an outer air deflector 12, and the outer air deflector 12 can open or close the front air outlet 101. As shown in fig. 4, when the air conditioner is in the no-wind mode, the no-wind structure 11 at least partially covers the front wind outlet 101.

Further, after the non-wind-sensing structure is adjusted from the current operation parameter to the target operation parameter for a period of time, the closing instruction of the non-wind-sensing mode may be further received, so as to control the non-wind-sensing structure 11 to be adjusted from a state of at least partially shielding the front air outlet 101 to a state of avoiding the front air outlet 101, so as to close the non-wind-sensing mode of the air conditioner, as shown in fig. 3.

Optionally, the user may send a closing instruction of the no-wind mode to the air conditioner through a remote controller, an air conditioner APP in the mobile terminal, or an operation panel on a body of the air conditioner in a non-contact manner such as a language, a gesture, and the like.

It should be noted that details that are not disclosed in the control method of the air conditioner in the embodiment of the present application refer to details disclosed in the above embodiments of the present application, and are not described herein again.

In summary, according to the control method of the air conditioner in the embodiment of the application, in the process that the air conditioner operates in the non-wind-sensation mode, the target rotating speed of the indoor fan and the target operating parameters of the non-wind-sensation structure can be determined according to the offset between the indoor temperature and the set temperature, so that the rotating speed of the indoor fan and the operating parameters of the non-wind-sensation structure are matched with the offset between the current indoor temperature and the set temperature, the refrigeration speed of the air conditioner is increased, and the comfort level of a user is improved.

A control method of an air conditioner according to another embodiment of the present application will be described with reference to fig. 13.

As shown in fig. 13, the method for controlling an air conditioner according to the embodiment of the present application includes the following steps:

and S301, responding to the instruction of the no-wind-sensation operation mode, and controlling the no-wind-sensation structure to operate according to the default first operation parameter. The operation parameters of the non-wind-sensing structure comprise the removal amount of the mounting plate from the accommodating cavity and the rotation angle of the movable blades in the wind guide assembly.

S302, the indoor temperature of the room where the air conditioner is located is obtained.

And S303, acquiring the offset of the indoor temperature and the set temperature of the air conditioner.

For specific descriptions of S301 to S303, reference may be made to the descriptions of relevant contents in the above embodiments, and details are not described herein again.

And S304, identifying the set rotating speed of the indoor fan.

Optionally, the user may set the rotation speed of the indoor fan of the air conditioner in a non-contact manner such as a language or a gesture through a remote controller, an air conditioner APP in the mobile terminal, or an operation panel on the body of the air conditioner.

S305, the indoor fan has no set rotating speed.

In one embodiment of the present application, if the indoor fan has no set rotation speed, the indoor fan is controlled to operate at a default rotation speed.

The default rotation speed may be calibrated according to actual conditions, for example, may be calibrated to 1000 rpm, and the default rotation speed may be preset in a storage space of the air conditioner, for example, may be stored in a main board of the air conditioner in advance.

And S306, determining the target rotating speed of the indoor fan and the target operating parameters of the non-wind-sensing structure according to the target range of the offset.

In one embodiment of the application, after the indoor fan is identified as having no set rotating speed, a target range where the offset of the indoor temperature and the set temperature is located can be identified, and the target rotating speed of the indoor fan and the target operating parameters of the non-wind-sensing structure are determined according to the target range where the offset is located.

And if the target range in which the offset is identified is the first range, continuously maintaining the target rotating speed of the indoor fan as the default rotating speed, and determining the target operating parameter of the non-wind-sensing structure as the first operating parameter.

It should be noted that both the first range and the corresponding first operating parameter can be calibrated according to actual conditions. Alternatively, taking the offset as the ratio of the indoor temperature and the set temperature as an example, the first range may be calibrated to be (1.0-1.05), the first operating parameter may be calibrated with reference to fig. 14, as shown in fig. 14, the amount of the mounting plate moving out of the accommodating cavity in the first operating parameter is a, a is the maximum value of the amount of the mounting plate moving out of the accommodating cavity, the rotation angle of the movable blade in the air guide assembly is B, and B is the maximum angle of the movable blade, so that the movable blade and the stationary blade are arranged in a staggered manner.

And if the target range in which the offset is identified is the second range, determining that the target rotating speed of the indoor fan is the highest rotating speed, and determining that the target operating parameter of the non-wind-sensing structure is the second operating parameter.

The maximum rotation speed can be calibrated according to actual conditions, for example, the maximum rotation speed can be calibrated to 1400 rpm. It is understood that the default rotational speed is less than or equal to the maximum rotational speed.

It should be noted that both the second range and the corresponding second operating parameter can be calibrated according to actual conditions. Alternatively, taking the offset as the ratio of the indoor temperature and the set temperature as an example, the second range may be calibrated to be (1.05-1.15), the second operating parameter may be calibrated with reference to fig. 15, as shown in fig. 15, the amount of the mounting plate moving out of the accommodating cavity in the second operating parameter is a, a is the maximum value of the amount of the mounting plate that can move out of the accommodating cavity, and the rotation angle of the movable blade in the air guide assembly is 0, so that the movable blade and the stationary blade are completely overlapped.

And if the target range in which the offset is identified is the third range, performing coefficient correction on the highest rotating speed to obtain the target rotating speed of the indoor fan, and determining the target operating parameter of the non-wind-sensing structure as the third operating parameter.

Optionally, the maximum rotation speed is less than or equal to the target rotation speed after coefficient correction is performed on the maximum rotation speed.

The coefficient correction of the highest rotation speed may include obtaining a correction coefficient according to the offset, and taking the product of the highest rotation speed and the correction coefficient as the target rotation speed of the indoor fan. Taking the offset as the ratio of the indoor temperature to the set temperature as an example, the correction coefficient may be the offset, that is, the correction coefficient may be the ratio of the indoor temperature to the set temperature.

It should be noted that both the third range and the corresponding third operating parameter can be calibrated according to actual conditions, optionally, the offset is taken as a ratio of the indoor temperature to the set temperature as an example, the third range can be calibrated to (1.15-1.25), the third operating parameter can be calibrated with reference to fig. 16, as shown in fig. 16, an amount of the mounting plate in the third operating parameter moving out of the accommodating cavity is a/2, a is a maximum value of an amount of the mounting plate being able to move out of the accommodating cavity, and a rotation angle of the movable blade in the air guide assembly is 0, so that the movable blade and the stationary blade are completely overlapped.

It should be noted that the upper endpoint of the first range is less than or equal to the lower endpoint of the second range, and the upper endpoint of the second range is less than or equal to the lower endpoint of the third range.

In one embodiment of the present application, as shown in fig. 3, the air conditioner further includes an outer air deflector 12, and the outer air deflector 12 can open or close the front air outlet 101. And identifying that the target range in which the offset is positioned is a third range, and after determining that the target operation parameter of the non-wind-sensation structure is the third operation parameter, maintaining the current wind guide angle of an outer wind deflector of the air conditioner so as to keep the opening angle of the front air outlet.

Further, taking the air conditioner as an example in a cooling mode, the larger the offset is, the larger the difference between the indoor temperature and the set temperature is, the higher the cooling speed of the air conditioner should be, so that the target rotating speed of the indoor fan should be higher, and the smaller the amount of the mounting plate moving out of the accommodating cavity should be, the smaller the rotating angle of the movable blade in the air guide assembly should be, so that the larger the overlapping area between the movable blade and the stationary blade is, the larger the air volume flowing through the front air outlet in the air conditioner is, the cooling speed of the air conditioner is increased, the air flowing out of the air conditioner can flow to an area relatively far away from the air conditioner, so that the cooling effect of the air conditioner is more uniform, and the comfort level of a user is improved.

That is to say, the target rotational speed of indoor fan is positively correlated with the offset, and the volume that the mounting panel shifts out from holding the chamber, the rotation angle of movable vane in the air guide component and offset are negatively correlated with.

Because the upper endpoint of the first range is less than or equal to the lower endpoint of the second range and the upper endpoint of the second range is less than or equal to the lower endpoint of the third range, the target rotating speed corresponding to the first range is less than or equal to the target rotating speed corresponding to the second range, and the target rotating speed corresponding to the second range is less than or equal to the target rotating speed corresponding to the third range; the amount of shift out in the first operating parameter is greater than or equal to the amount of shift out in the second operating parameter, which is greater than or equal to the amount of shift out in the third operating parameter; the rotation angle in the first operation parameter is greater than or equal to the rotation angle in the second operation parameter, and the rotation angle in the second operation parameter is greater than or equal to the rotation angle in the third operation parameter.

Continuing with the example of fig. 14-16, the amount of removal of the mounting plate from the receiving cavity in the first operating parameter is equal to the amount of removal in the second operating parameter, which is greater than the amount of removal in the third operating parameter. The rotation angle of the movable blade 1122 in the air guide assembly in the first operation parameter is greater than that in the second operation parameter, and the rotation angle of the movable blade 1122 in the air guide assembly in the second operation parameter is equal to that in the third operation parameter.

It can be understood that, in different temperature difference ranges, the rotating angles of the movable blades in the air guide assembly often have differences under the condition that the mounting plate is moved out of the accommodating cavity in the same amount, and similarly, in different temperature difference ranges, the rotating angles of the movable blades in the air guide assembly are often different under the condition that the rotating angles of the movable blades in the air guide assembly are the same, and the amount of the mounting plate moved out of the accommodating cavity often has differences.

And S307, the indoor fan has a set rotating speed.

In one embodiment of the present application, if the indoor fan has a set rotation speed, the indoor fan is controlled to operate at the set rotation speed.

And S308, determining the target rotating speed of the indoor fan and the target operating parameters of the non-wind-sensing structure according to the target range of the offset.

It can be understood that, similar to the case of identifying that the indoor fan has no set rotating speed, after identifying that the indoor fan has the set rotating speed, the target range where the offset of the indoor temperature and the set temperature is located can be identified, and the target rotating speed of the indoor fan and the target operating parameter of the non-wind-sensing structure are determined according to the target range where the offset is located.

And if the target range in which the offset is identified is the first range, continuously maintaining the target rotating speed of the indoor fan to be the set rotating speed, and determining the target operating parameter of the non-wind-sensing structure to be the first operating parameter.

And if the target range in which the offset is identified is the second range, performing coefficient correction on the set rotating speed to obtain the target rotating speed of the indoor fan, and determining the target operating parameter of the non-wind-sensing structure as the second operating parameter.

Alternatively, the set rotation speed is less than or equal to the target rotation speed after coefficient correction of the set rotation speed.

The coefficient correction of the set rotating speed can include obtaining a correction coefficient according to the offset, and taking the product of the set rotating speed and the correction coefficient as the target rotating speed of the indoor fan. Taking the offset as the ratio of the indoor temperature to the set temperature as an example, the correction coefficient may be the offset, that is, the correction coefficient may be the ratio of the indoor temperature to the set temperature.

And if the target range in which the offset is identified is the third range, performing coefficient correction on the default rotating speed to obtain the target rotating speed of the indoor fan, and determining the target operating parameter of the non-wind-sensing structure as the third operating parameter.

Optionally, the default rotation speed is less than or equal to the target rotation speed after coefficient correction is performed on the default rotation speed.

And performing coefficient correction on the default rotating speed, wherein the coefficient correction can comprise obtaining a correction coefficient according to the offset, and taking the product of the default rotating speed and the correction coefficient as the target rotating speed of the indoor fan. Taking the offset as the ratio of the indoor temperature to the set temperature as an example, the correction coefficient may be twice the offset, that is, the correction coefficient may be twice the ratio of the indoor temperature to the set temperature.

It should be noted that the calibration of the first range and the corresponding first operating parameter, the second range and the corresponding second operating parameter, and the third range and the corresponding third operating parameter can be performed with reference to the case when the indoor fan has no set rotating speed, and details are not repeated here.

S309, controlling the indoor fan to adjust to the target rotating speed from the current rotating speed, and controlling the non-wind feeling structure to adjust to the target operating parameter from the current operating parameter.

In summary, according to the control method of the air conditioner in the embodiment of the present application, in the process that the air conditioner operates in the no-wind-sensation mode, the target rotation speed of the indoor fan can be determined according to the set rotation speed or the default rotation speed of the indoor fan and the range where the offset between the indoor temperature and the set temperature is located, and the flexibility is higher.

A control device of an air conditioner according to an embodiment of the present application will be described with reference to fig. 17.

As shown in fig. 17, the control device 200 of the air conditioner according to the embodiment of the present invention includes a command response module 21, a temperature obtaining module 22, a determination module 23, and an adjustment module 24.

The instruction response module 21 is configured to respond to an instruction of the no-wind-sensation operation mode, and control the no-wind-sensation structure to operate according to a default first operation parameter; the operation parameters of the non-wind-sensation structure comprise the moving amount of the mounting plate out of the accommodating cavity and the rotating angle of the movable blades in the air guide assembly.

The temperature obtaining module 22 is used for obtaining the indoor temperature of the room where the air conditioner is located.

The determining module 23 is configured to determine a target operating parameter of the non-wind-sensing structure according to the indoor temperature and the set temperature of the air conditioner.

The adjusting module 24 is configured to control the indoor fan to adjust from a current rotating speed to the target rotating speed, and control the non-wind-sensing structure to adjust from a current operating parameter to the target operating parameter.

In an embodiment of the present application, the determining module 23 is specifically configured to obtain an offset between the indoor environment and the set temperature; and determining the target rotating speed and the target operation parameter according to the target range in which the offset is positioned.

In an embodiment of the application, the determining module 23 is specifically configured to identify the set rotation speed of the indoor fan before determining the target rotation speed and the target operating parameter according to the target range in which the offset is located.

In an embodiment of the application, the determining module 23 is further configured to maintain the target rotation speed as a default first rotation speed if the indoor fan has no set rotation speed and the target range is a first range, and the target operating parameter is the first operating parameter;

In an embodiment of the present application, the determining module 23 is further configured to maintain the target rotation speed as the set rotation speed if the indoor fan has the set rotation speed and the target range is a first range, and the target operating parameter is the first operating parameter;

if the indoor fan has the set rotating speed and the target range is a third range, performing coefficient correction on the default rotating speed of the air conditioner to obtain the target rotating speed, wherein the target operating parameter is the third operating parameter; and the target rotating speed obtained after the coefficient correction is greater than or equal to the default rotating speed, and the target rotating speed is less than or equal to the highest rotating speed.

In one embodiment of the present application, the air conditioner further includes an outer air deflector, and the outer air deflector can open or close the front air outlet; the adjusting module 24 is further configured to maintain a current wind guiding angle of an external wind guiding plate of the air conditioner after determining that the target operation parameter is the third operation parameter.

In an embodiment of the present application, the instruction response module 21 is further configured to receive a start instruction of the air conditioner before the air conditioner is controlled to enter the no-wind-sense mode; and controlling an outer air deflector in the air conditioner to open the front air outlet and controlling the non-wind-sensing structure to keep avoiding the state of the front air outlet.

In one embodiment of the present application, the command response module 21 is further configured to receive a closing command of the no-wind mode; and controlling the non-wind-sensing structure to be adjusted from a state of at least partially shielding the front air outlet to a state of avoiding the front air outlet.

It should be noted that, for details not disclosed in the control device of the air conditioner in the embodiment of the present application, please refer to details disclosed in the control method of the air conditioner in the above embodiment of the present application, which are not described herein again.

To sum up, the control device of the air conditioner of the embodiment of the application can determine the target rotating speed of the indoor fan and the target operating parameters of the non-wind-sensing structure according to the indoor temperature and the set temperature in the process that the air conditioner operates in the non-wind-sensing mode, so that the rotating speed of the indoor fan and the operating parameters of the non-wind-sensing structure are matched with the current indoor temperature and the set temperature, the refrigeration speed of the air conditioner is accelerated, and the comfort level of a user is improved.

In order to implement the above embodiments, the present application also provides an air conditioner 300, as shown in fig. 18, including the control device 200 of the air conditioner. Further, the air conditioner further includes: the air conditioner comprises a shell 10 and a non-wind-sensing structure 11 as shown in fig. 1-9, wherein the shell 10 is provided with a front air outlet 101, the non-wind-sensing structure 11 is movably arranged on the shell 10 and can avoid or at least partially shield the front air outlet 101, the non-wind-sensing structure 11 comprises a mounting plate 111 and an air guide assembly 112, an air outlet 1111 is arranged on the mounting plate 111, the air guide assembly 112 comprises a stationary blade 1121 and a rotatable movable blade 1122, and the stationary blade 1121 and the movable blade 1122 are arranged along the axial direction of the air outlet 1111.

In an embodiment of the present application, a first driving assembly 113 is further disposed on the non-wind-sensing structure 11, the first driving assembly 113 is connected to at least one of the movable blades 1122 in the wind guide assembly 112 through a first transmission portion 114, and the adjacent movable blade 1122 in the wind guide assembly 112 is connected to a second transmission portion 115; the first driving unit 113 is connected to the control device 200 of the air conditioner, and drives the movable blade 1122 of the air guide unit 112 to rotate under the control of the control device 200 of the air conditioner.

In one embodiment of the present application, there are at least two first driving assemblies 113, and each first driving assembly 113 is connected to a moving blade 1122 in at least one of the wind guide assemblies 112.

In an embodiment of the present application, the air conditioner 300 further includes a second driving assembly 116 connected to the mounting plate 111 in the non-wind sensing structure 11, the second driving assembly 116 is connected to the control device 200 of the air conditioner, and the mounting plate 111 is driven to move telescopically in the accommodating cavity under the control of the control device 200 of the air conditioner;

the second driving assembly 116 includes a motor 1113, a gear 1114, and a rack 1112. Wherein, the motor 1113 is arranged on the shell 10; the gear 1114 is connected with an output shaft of the motor 1113; the rack 1112 is provided on the mounting plate 111 and extends in the up-down direction, and the rack 1112 is adapted to engage with the gear 1114.

In one embodiment of the present application, the mounting plate 111 further comprises a limiting plate 1115; the retainer plate 1115 is disposed on the mounting plate 111, and the retainer plate 1115 is adapted to contact the housing 10 when the mounting plate 111 moves to limit the amount of the mounting plate 111 that moves out of the receiving cavity.

The air conditioner of this application embodiment, at the in-process that the air conditioner moves according to the no wind sense mode, can be according to indoor temperature and settlement temperature, confirm the target rotational speed of indoor fan and the target operating parameter of no wind sense structure for the rotational speed of indoor fan, the operating parameter of no wind sense structure and current indoor temperature, settlement temperature phase-match are favorable to accelerating the refrigeration speed of air conditioner, have improved user's comfort level.

In order to implement the above embodiments, the present application also proposes an electronic device 400, as shown in fig. 19, where the electronic device 400 includes a memory 41 and a processor 42. Wherein, the processor 42 runs a program corresponding to the executable program code by reading the executable program code stored in the memory 41 for implementing the control method of the air conditioner as described above.

The electronic equipment of the embodiment of the application can determine the target rotating speed of the indoor fan and the target operating parameter of the non-wind-sensing structure according to the indoor temperature and the set temperature in the process of the air conditioner operating in the non-wind-sensing mode, so that the rotating speed of the indoor fan and the operating parameter of the non-wind-sensing structure are matched with the current indoor temperature and the set temperature, the refrigeration speed of the air conditioner is accelerated, and the comfort level of a user is improved.

In order to implement the above embodiments, the present application also proposes a computer-readable storage medium storing a computer program that, when executed by a processor, implements the control method of the air conditioner described above.

The computer-readable storage medium of the embodiment of the application can determine the target rotating speed of the indoor fan and the target operating parameters of the non-wind-sensing structure according to the indoor temperature and the set temperature in the process that the air conditioner operates in the non-wind-sensing mode, so that the rotating speed of the indoor fan and the operating parameters of the non-wind-sensing structure are matched with the current indoor temperature and the set temperature, the refrigeration speed of the air conditioner is accelerated, and the comfort level of a user is improved.

In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral parts; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through intervening media. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

In the description herein, reference to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the application. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Although embodiments of the present application have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present application, and that variations, modifications, substitutions and alterations may be made to the above embodiments by those of ordinary skill in the art within the scope of the present application.

Claims

1. The control method of the air conditioner is characterized in that the air conditioner comprises a shell and a non-wind-sensing structure, the shell is provided with a front air outlet, the non-wind-sensing structure is movably arranged on the shell and can avoid or at least partially shield the front air outlet, the non-wind-sensing structure comprises a mounting plate and a wind guide assembly, an air outlet is formed in the mounting plate, the wind guide assembly comprises a static blade and a rotatable movable blade, and the static blade and the movable blade are arranged along the axial direction of the air outlet;

the control method comprises the following steps:

responding to an instruction of a no-wind-sensation operation mode, and controlling the no-wind-sensation structure to operate according to a default first operation parameter; the operation parameters of the non-wind-sensation structure comprise the amount of the mounting plate moving out of the accommodating cavity and the rotating angle of the movable blades in the air guide assembly;

acquiring the indoor temperature of the room where the air conditioner is located;

determining a target rotating speed of an indoor fan and a target operation parameter of the non-wind-sensing structure according to the indoor temperature and the set temperature of the air conditioner;

controlling the indoor fan to adjust from the current rotating speed to the target rotating speed, and controlling the non-wind-sensing structure to adjust from the current operating parameter to the target operating parameter;

wherein, according to the indoor temperature and the set temperature of the air conditioner, determining the target rotating speed of the indoor fan and the target operating parameters of the non-wind-sensing structure comprises:

acquiring the offset of the indoor temperature and the set temperature;

determining the target rotating speed and the target operation parameters according to the target range of the offset;

before determining the target rotating speed and the target operating parameter according to the target range in which the offset is located, the method further includes:

identifying the set rotating speed of the indoor fan;

wherein, the determining the target rotating speed and the target operating parameter according to the target range in which the offset is located includes:

if the indoor fan does not have the set rotating speed and the target range is a first range, maintaining the target rotating speed as a default first rotating speed, and the target operating parameter is the first operating parameter;

if the indoor fan does not have the set rotating speed and the target range is a second range, determining that the target rotating speed is the highest rotating speed and the target operating parameter is a second operating parameter; wherein the amount of removal of the mounting plate in the second operating parameter is less than or equal to the amount of removal of the mounting plate in the first operating parameter, and the angle of rotation of the movable blade in the second operating parameter is less than or equal to the angle of rotation of the movable blade in the first operating parameter;

if the indoor fan does not have the set rotating speed and the target range is a third range, performing coefficient correction on the highest rotating speed to obtain the target rotating speed, wherein the target operating parameter is a third operating parameter; the target rotating speed obtained after the coefficient correction is greater than or equal to the highest rotating speed, the moving-out amount of the mounting plate in the third operating parameter is less than or equal to the moving-out amount of the mounting plate in the second operating parameter, and the rotating angle of the movable blade in the third operating parameter is less than or equal to the rotating angle of the movable blade in the second operating parameter;

2. The method of claim 1, wherein determining the target speed and the target operating parameter based on the target range in which the offset is located comprises:

if the indoor fan has the set rotating speed and the target range is a first range, maintaining the target rotating speed as the set rotating speed and the target operating parameter as the first operating parameter;

3. The method of claim 1 or 2, wherein the air conditioner further comprises an outer air guide plate, and the outer air guide plate can open or close the front air outlet;

after determining that the target operating parameter is the third operating parameter, further comprising:

and maintaining the current wind guiding angle of an external wind guiding plate of the air conditioner.

4. The method according to any one of claims 1-2, wherein before controlling the air conditioner to enter the no-wind operation mode, the method further comprises:

receiving a starting instruction of the air conditioner;

and controlling an outer air deflector in the air conditioner to open the front air outlet and controlling the non-wind-sensing structure to keep avoiding the state of the front air outlet.

5. The method according to any one of claims 1-2, further comprising:

receiving a closing instruction of the no-wind-sense operation mode;

and controlling the non-wind-sensing structure to be adjusted from a state of at least partially shielding the front air outlet to a state of avoiding the front air outlet.

6. The control device of the air conditioner is characterized in that the air conditioner comprises a shell and a non-wind-sensing structure, the shell is provided with a front air outlet, the non-wind-sensing structure is movably arranged on the shell and can avoid or at least partially shield the front air outlet, the non-wind-sensing structure comprises a mounting plate and a wind guide assembly, an air outlet is formed in the mounting plate, the wind guide assembly comprises a fixed blade and a rotatable movable blade, and the fixed blade and the movable blade are arranged along the axial direction of the air outlet;

the control device includes:

the instruction response module is used for responding to an instruction of the no-wind-sensation operation mode and controlling the no-wind-sensation structure to operate according to a default first operation parameter; the operation parameters of the non-wind-sensation structure comprise the amount of the mounting plate moving out of the accommodating cavity and the rotating angle of the movable blades in the air guide assembly;

the temperature acquisition module is used for acquiring the indoor temperature of the room where the air conditioner is located;

the determining module is used for determining target operation parameters of the non-wind-sensing structure according to the indoor temperature and the set temperature of the air conditioner;

the adjusting module is used for controlling the indoor fan to adjust from the current rotating speed to the target rotating speed and controlling the non-wind-sensing structure to adjust from the current operating parameter to the target operating parameter;

the determining module is specifically configured to obtain an offset between the indoor temperature and the set temperature; determining the target rotating speed and the target operation parameters according to the target range of the offset; identifying the set rotating speed of the indoor fan before determining the target rotating speed and the target operating parameter according to the target range of the offset;

the determining module is further configured to maintain the target rotation speed as a default first rotation speed if the indoor fan does not have the set rotation speed and the target range is a first range, and the target operating parameter is the first operating parameter;

7. An air conditioner, comprising:

the wind-proof structure comprises a mounting plate and a wind guide assembly, wherein the mounting plate is provided with a wind outlet, the wind guide assembly comprises a static blade and a rotatable movable blade, and the static blade and the movable blade are arranged along the axial direction of the wind outlet;

and a control device of an air conditioner according to claim 6.

8. The air conditioner as claimed in claim 7, wherein the non-wind-sensing structure is further provided with a first driving assembly, the first driving assembly is connected with the movable blade of at least one of the wind guide assemblies through a first transmission part, and is connected with the adjacent movable blade of the wind guide assembly through a second transmission part;

the first driving assembly is connected with a control device of the air conditioner, and drives the movable blades in the air guide assembly to rotate under the control of the control device of the air conditioner.

9. The air conditioner as claimed in claim 8, wherein the number of the first driving assemblies is at least two, and each first driving assembly is connected to the moving blade of at least one of the air guiding assemblies.

10. The air conditioner according to claim 7, further comprising: the second driving assembly is connected with the mounting plate in the non-wind-sensing structure and is connected with the control device of the air conditioner, and the mounting plate is driven to move in the accommodating cavity in a telescopic mode under the control of the control device of the air conditioner;

the second drive assembly includes:

the motor is arranged on the shell;

the gear is connected with an output shaft of the motor;

the rack is arranged on the mounting plate and extends along the up-down direction, and the rack is suitable for being meshed with the gear.

11. The air conditioner of claim 10, further comprising on the mounting plate: a limiting plate; the limiting plate is arranged on the mounting plate and is suitable for contacting with the shell when the mounting plate moves so as to limit the moving amount of the mounting plate out of the accommodating cavity.

12. An electronic device comprising a memory, a processor;

wherein the processor executes a program corresponding to the executable program code by reading the executable program code stored in the memory, for implementing the control method of the air conditioner as set forth in any one of claims 1 to 5.

13. A computer-readable storage medium storing a computer program, characterized in that the program realizes the control method of the air conditioner according to any one of claims 1 to 5 when being executed by a processor.