Detailed Description
The following description and the drawings sufficiently illustrate specific embodiments of the invention to enable those skilled in the art to practice them. The embodiments are merely representative of possible variations, individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others. The scope of embodiments of the invention encompasses the full ambit of the claims, as well as all available equivalents of the claims. Embodiments may be referred to herein, individually or collectively, by the term "invention" merely for convenience and without intending to voluntarily limit the scope of this application to any single invention or inventive concept if more than one is in fact disclosed. Herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without requiring or implying any actual such relationship or order between such entities or actions.
It should be noted that the description in the present invention as referring to "first", "second", etc. is for descriptive purposes only and is 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 at least one such feature.
In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted" and "connected" are to be interpreted broadly, e.g., as a fixed connection, a detachable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.
The embodiments are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.
Fig. 1 to 4 are schematic structural views illustrating a panel structure of an air conditioner according to an exemplary embodiment.
In this alternative embodiment, there is provided a panel structure of an air conditioner, the panel structure including:
the air deflector 1 is provided with a first microporous structure 11 penetrating through the thickness direction of the air deflector 1 and swings up and down under the driving of a motor of the air deflector 1;
the vertical swing blade assembly 2 comprises a swing rod 21 and one or more vertical swing blades 22 with bionic leaf structures, wherein the vertical swing blades 22 are arranged on the swing rod 21, the swing rod 21 drives the vertical swing blades 22 to swing left and right under the driving of a driving motor of the swing rod 21, and the vertical swing blades 22 are provided with second microporous structures 221 penetrating through the thickness direction of the vertical swing blades.
In this alternative embodiment, since the natural wind is generally more gentle after being decelerated by the shade leaves, the vertical swinging leaves 22 are made to simulate the shape of natural leaves, the swing rod 21 drives the motor to drive the motor to swing left and right, so that the wind coming out of the volute is closer to natural wind under the action of the vertical swing blade 22, the air which is adjusted left and right through the vertical swinging blade 22 is adjusted up and down through the air deflector 1, so that the air blown out by the air conditioner is softer, meanwhile, the first microporous structure 11 is arranged on the air deflector 1, the second microporous structure 221 is arranged on the vertical swing blade 22, and in the process of the wind swinging of the air deflector 1 and the vertical swing blade 22, the air flow penetrates out of the first microporous structure 11 or the second microporous structure 221, the moving direction of the air flow is further disturbed, the air speed in a certain specific direction is reduced, the air flow is cool but not cold or warm but not hot, and the body feeling comfort level of a human body is improved.
In some alternative embodiments, when there are a plurality of the vertical swinging blades 22, the blades of any two adjacent vertical swinging blades 22 have different sizes. When the airflow passing through a certain vertical swing blade 22 blows to the vertical swing blade 22 adjacent to the vertical swing blade 22, the moving direction of the airflow is further changed due to the different sizes of the blades of the two vertical swing blades 22, so that the wind speed in a certain specific direction is reduced, and the airflow is softer.
In some alternative embodiments, the sizes of the vanes of the plurality of vertical swinging vanes 22 are decreased gradually from the middle position of the swinging rod 21 to two sides; or, the sizes of the blades of the plurality of vertical swing blades 22 are gradually increased from the middle position of the swing rod 21 to two sides. Alternatively, a plurality of the vertical swing vanes 22 are provided in a structure having a similar shape. The vertical swing blades 22 are similar in shape, the sizes of the blades change along the swing rods 21 in a stepped mode, the moving direction of airflow changes constantly, the wind speed in a certain specific direction can be reduced, and indoor wind is softer or meets the requirement of no wind sensation.
In some optional embodiments, the maximum swing angle of the vertical swing blade 22 ranges from [40 °, 160 °, optionally, the maximum swing angle of the vertical swing blade 22 ranges from 45 °, 60 °, 80 °, and 120 °. The maximum swing angle of the vertical swing vane 22 is too small, the adjustment range of the moving direction of the wind coming out of the volute is too small, the maximum swing angle of the vertical swing vane 22 is too large, the adjustment frequency of the moving direction of the wind coming out of the volute is too small, the value range of the maximum swing angle of the vertical swing vane 22 is set to be [40 degrees and 160 degrees ], the adjustment range and the adjustment frequency of the moving direction of the wind coming out of the volute can be well balanced, and the non-wind effect is better.
In some optional embodiments, the panel structure further comprises a pad 5 disposed on the upper portion of the vertical swing blade assembly 2, and the width of the pad 5 is not less than the maximum width of the vertical swing blade 22. The liner 5 is arranged at the upper part of the vertical swinging blade assembly 2, so that the air flow can be prevented from losing from the vertical swinging blade assembly 2, and the wind coming out of the volute can be completely used for indoor temperature regulation.
In some optional embodiments, the air deflector 1 includes a plurality of first air deflectors 12 arranged in parallel up and down along the panel body 3 of the panel structure, and the first air deflectors 12 are provided with the first microporous structure 11 penetrating through the thickness direction thereof. The first air deflectors 12 act together, so that the air direction adjusting effect is better. Furthermore, the directions of the vertical swing of the two adjacent first air deflectors 12 are different, so that the wind direction of the airflow passing through the vertical swing blade assembly 2 can be further disturbed, and the air outlet of the air conditioner is closer to natural wind.
Fig. 5-6 are schematic structural views of a wind deflector according to an exemplary embodiment.
In this alternative embodiment, there is provided an air deflector 1 of the panel structure, and the first microporous structure 11 of the air deflector 1 is configured as a structure in which the cross-sectional area of the cross-section increases from the middle to both ends.
Optionally, the second microporous structure 221 of the vertical swing vane 22 is configured as a structure in which the cross-sectional area of the cross-section increases from the middle to both ends.
In this optional embodiment, the first microporous structure 11 of the air deflector 1 and/or the second microporous structure 221 of the vertical swing blade 22 are/is configured as a structure whose cross section increases from the middle to the two ends, and the two ends of the microporous structure diverge outward, which is not only beneficial to mold stripping of the structural process, but also can diverge outward through the wind direction of the microporous structure, so that the wind directions passing through the first microporous structure 11 and/or the second microporous structure 221 are different and are closer to natural wind.
FIG. 7 is a schematic structural diagram of a vertical pendulum blade shown in accordance with an exemplary embodiment.
In this optional embodiment, the width of the vertical swing blade 22 decreases from the middle to the two ends, and the peripheral edge line of the vertical swing blade 22 is streamline.
In this optional embodiment, since the natural wind is generally gentler after being decelerated by the green shade leaves, the vertical swing blade 22 is set to a shape of a bionic natural-world leaf whose width decreases gradually from the middle to both ends, the airflow is gentler after being decelerated by the vertical swing blade 22, and further, the peripheral edge line of the vertical swing blade 22 is set to be streamlined, so that the resistance when the vertical swing blade 22 swings left and right is smaller, and the airflow is gentler.
In some optional embodiments, a retaining member 222 and a rotating member 223 are disposed on the vertical swing blade 22, the vertical swing blade 22 is connected to the swing link 21 by the retaining member 222, the vertical swing blade 22 is rotatably connected to the panel frame 4 of the panel structure by the rotating member 223, and the swing link 21 drives the vertical swing blade 22 to swing left and right relative to the panel frame 4 under the driving of the driving motor of the swing link 21. Specifically, the card is held 222 include with the first recess of pendulum rod 21 complex, first recess with the pendulum rod 21 joint, it includes the second recess to rotate piece 223, be provided with on the panel frame 4 with second recess complex is protruding, it passes through to rotate piece 223 the second recess drives the vertical pendulum leaf 22 winds the arch rotates, pendulum rod 21 is in control under pendulum rod 21 driving motor's the drive and is moved, vertical pendulum leaf 22 is in wind under the drive of pendulum rod 21 protruding horizontal hunting. The vertical swing blade 22 is movably connected with the swing rod 21 and the panel frame 4 through the clamping piece 222 and the rotating piece 223, and is easy to assemble and disassemble.
In some alternative embodiments, the ratio of the total area of the second microporous structure 221 of the louver 22 to the total area of the louver 22 is in a range of [ 45%, 85% ]. Optionally, the total area of the second microporous structure 221 of the vertical swing vane 22 accounts for 60%, 75%, and 78% of the total area of the vertical swing vane 22. The proportion of the total area of the second microporous structures 221 of the vertical swing blades 22 in the total area of the vertical swing blades 22 is too small, the air outlet area of the air flow passing through the second microporous structures 221 is too small, the air outlet amount is insufficient, the proportion of the total area of the second microporous structures 221 of the vertical swing blades 22 in the total area of the vertical swing blades 22 is too large, the breeze adjusting effect is poor, the value range of the proportion of the total area of the second microporous structures 221 of the vertical swing blades 22 in the total area of the vertical swing blades 22 is set to be [ 45% and 85% ], and the air outlet amount and the breeze adjusting effect of the second microporous structures 221 can be well balanced.
In some alternative embodiments, the maximum width of the second microporous structure 221 is in the range of [5mm, 10mm ]. Optionally, the maximum width of the second microporous structure 221 is 6mm, 7mm, 8mm, or 9 mm. The value range of the maximum width of the second microporous structure 221 is set to be [5mm, 10mm ], and the breeze adjusting effect is better.
In some optional embodiments, the thickness of the vertical swing blade 22 decreases from the center to the periphery, and the difference between the maximum thickness and the minimum thickness of the vertical swing blade 22 has a value range of [3mm, 8mm ]. Optionally, the difference between the maximum thickness and the minimum thickness of the vertical swing blade 22 is 5mm, 6mm, or 7 mm. The thickness of the vertical swing blade 22 is set to be gradually decreased from the center to the periphery, so that the firmness of the structure of the vertical swing blade 22 can be improved, meanwhile, an airflow layer is formed on the surface of the vertical swing blade 22, the movement direction of the airflow is further disturbed, and the airflow is softer.
Fig. 8 to 11 are schematic structural views illustrating a panel structure of an air conditioner according to an exemplary embodiment.
In this alternative embodiment, there is provided a panel structure of an air conditioner, the panel structure including:
the air deflector 1 is provided with a first microporous structure 11 penetrating through the thickness direction of the air deflector 1 and swings up and down under the driving of a motor of the air deflector 1;
the vertical swing blade assembly 2 comprises a swing rod 21 and one or more vertical swing blades 22 of bionic leaf structures, wherein the vertical swing blades 22 are arranged on the swing rod 21, the swing rod 21 drives the vertical swing blades 22 to swing left and right under the driving of a driving motor of the swing rod 21, and the vertical swing blades 22 are provided with second microporous structures 221 penetrating through the thickness direction of the vertical swing blades;
the panel body 3 is provided with a reinforcing rib 31.
In this optional embodiment, on the one hand, the reinforcing ribs 31 are arranged on the panel body 3, so that the structural strength of the panel structure is improved, and the panel structure is not easy to deform, on the other hand, the vertical swing blades 22 simulate the shape of natural leaves and swing left and right under the driving of the motor, so that the wind coming out of the volute is closer to the natural wind under the action of the vertical swing blades 22, and the wind adjusted left and right through the vertical swing blades 22 is adjusted up and down through the microporous air guide plate 1, so that the wind blown out by the air conditioner is softer, and the requirement of the comfort level of the human body is met.
In some alternative embodiments, the reinforcing ribs are provided as one or more first transverse reinforcing ribs along the length direction of the panel body 3, and/or one or more first longitudinal reinforcing ribs along the width direction of the panel body 3. Optionally, the first transverse reinforcing rib and/or the first longitudinal reinforcing rib are arranged as a bar-shaped reinforcing rib, and the bar-shaped reinforcing rib and the panel body 3 are integrally formed. First horizontal strengthening rib and/or first vertical strengthening rib has improved the bulk strength of panel body 3, moreover, set up the bar strengthening rib, 3 lines of whole bar panel body are brief, have optimized the structure of panel body 3.
In some alternative embodiments, the length of the first transverse stiffener is equal to the length of the panel body 3, and the length of the first longitudinal stiffener is equal to the width of the panel body 3. First horizontal strengthening rib runs through the length direction setting of panel body 3, first vertical strengthening rib runs through the width direction setting of panel body 3, the structure of panel body 3 is more compact, and processing technology is simpler.
In some alternative embodiments, the air deflector 1 is provided with one or more second transverse reinforcing ribs along the length direction thereof and/or one or more second longitudinal reinforcing ribs along the width direction thereof. The second transverse reinforcing ribs and/or the second longitudinal reinforcing ribs improve the overall strength of the air deflector 1, the whole strip-shaped air deflector 1 is simple in line, and the structure of the air deflector 1 is optimized.
In some optional embodiments, when the air deflector 1 is closed, the first transverse reinforcing rib and the second transverse reinforcing rib are in the same straight line, and/or the first longitudinal reinforcing rib and the second longitudinal reinforcing rib are in the same straight line, so that the structural strength of the panel structure is improved, and the structural consistency of the panel structure is improved.
In some alternative embodiments, said first microporous structure 11 is provided on said second transverse reinforcing bar and/or said second longitudinal reinforcing bar. The first microporous structure 11 penetrates through the second transverse reinforcing rib and/or the second longitudinal reinforcing rib in the thickness direction to play a role in breeze adjustment.
In some optional embodiments, the panel body 3 comprises a first portion located at the periphery of the panel body 3 and a second portion located at the middle of the panel body 3, the density of the plurality of first transverse reinforcing ribs located at the first portion is greater than the density of the plurality of first transverse reinforcing ribs located at the second portion, and/or the density of the plurality of first longitudinal reinforcing ribs located at the first portion is greater than the density of the plurality of first longitudinal reinforcing ribs located at the second portion. In the use process of the panel structure, the periphery of the panel body 3 is more easily damaged than the middle of the panel body 3, the distribution density of the first transverse reinforcing ribs and/or the second transverse reinforcing ribs which are positioned at the first part of the panel body 3 is set to be larger, the structural stability of the panel body 3 which is positioned at the first part can be further improved, the structural strength requirement of the panel body 3 which is positioned at the second part is lower, the distribution density of the first transverse reinforcing ribs and/or the second transverse reinforcing ribs which are positioned at the second part of the panel body 3 is set to be smaller, the quality of the panel body 3 can be reduced, the processing technology of the panel body 3 is simplified, and the production cost is reduced.
Fig. 12 to 15 are schematic structural views illustrating a panel structure of an air conditioner according to an exemplary embodiment.
In this alternative embodiment, there is provided a panel structure of an air conditioner, the panel structure including:
the air deflector 1 comprises a plurality of second air deflectors 13 which are arranged in parallel left and right along the panel body 3 of the panel structure, each second air deflector 13 swings up and down under the driving of a driving motor of the air deflector 1, and a first microporous structure 11 penetrating through the second air deflector 13 in the thickness direction is arranged on the second air deflector 13;
the vertical swing blade assembly 2 comprises a swing rod 21 and one or more vertical swing blades 22 of bionic leaf structures, wherein the vertical swing blades 22 are arranged on the swing rod 21, the swing rod 21 drives the vertical swing blades 22 to swing left and right under the driving of a driving motor of the swing rod 21, and the vertical swing blades 22 are provided with second microporous structures 221 penetrating through the thickness direction of the vertical swing blades;
and the human body sensing device 6 is used for sensing the position of a human body and transmitting the position information of the human body to the controller of the air conditioner, so that the controller controls the operation mode of the second air deflector 1 and the vertical swinging blade 22 according to the position information of the human body.
In this optional embodiment, on one hand, the air deflector 1 includes a plurality of second air deflectors 13 arranged in parallel left and right along the panel body 3 of the panel structure, and can control the operation modes of the second air deflectors 13 and the vertical swing vanes 22 according to the human body position information acquired by the human body sensing device 6, so as to realize different air outlet requirements of different positions of the air conditioner and meet different air outlet requirements of users in different directions in the same room, and on the other hand, the vertical swing vanes 22 simulate the shape of natural leaves and swing left and right under the driving of a motor, so that the air coming out of the volute is closer to natural air under the action of the vertical swing vanes 22, and the air adjusted left and right by the vertical swing vanes 22 is then adjusted up and down by the microporous air deflectors, so that the air blown out by the air conditioner is softer and meets the requirement of human comfort.
In some optional embodiments, the human body sensor 61 of the human body sensing device 6 is embedded on the panel body 3. Optionally, the human body sensor 61 may be an infrared human body sensor 61. The human body inductor 61 is embedded on the panel body 3, and the structure of the panel structure is more compact.
Fig. 16 is a flowchart illustrating a method of air conditioner control according to an exemplary embodiment.
In this alternative embodiment, there is provided a method of controlling an air conditioner, the method comprising the steps of:
s161: and acquiring human body position information by using the human body sensing device.
S162: and controlling the operation mode of the second air deflector and the vertical swinging blade according to the human body position information.
In this optional embodiment, the operation modes of the second air deflector 13 and the vertical swing blade 22 are controlled according to the human body position information obtained by the human body sensing device 6, so that different air outlet requirements of different positions of the air conditioner are met, and different air outlet requirements of users in different directions in the same room are met.
Fig. 17 is a flowchart illustrating a method of air conditioner control according to an exemplary embodiment.
In this alternative embodiment, there is provided a method of controlling an air conditioner, the method comprising the steps of:
s171: and acquiring human body position information by using the human body sensing device.
And determining the human body position information according to the human body position acquired by the human body sensing device 6.
S172: and comparing the human body position information with pre-stored position area information to acquire a pre-stored position area where the human body position is located.
The area which can be sensed by the human body sensing device 6 is partitioned in advance, and the coordinate information in the human body position information is compared with the coordinate information in the pre-stored position area information to obtain the pre-stored position area where the human body position is located.
For example, if the coordinate information in the human body position information is (5, 8, 6), and the coordinate information of the pre-stored first position area is (4 to 7, 7 to 9, 5 to 7), it can be determined that the human body position is in the pre-stored first position area.
S173: and if the position of the human body is in a pre-stored first position area, controlling a second air deflector positioned on the first side of the center of the panel structure to swing up and down, closing the second air deflector positioned on the second side of the center of the panel structure, and controlling the vertical swinging blade to swing left and right.
The human body position is in a pre-stored first position area, the second air deflector 13 located on the first side of the center of the panel structure is controlled to swing up and down, the second air deflector 13 located on the second side of the center of the panel structure is controlled to close, and the vertical swing blade 22 is controlled to swing left and right, so that the space located on the first side of the panel structure is uniform in large air volume, and the space located on the second side of the panel structure is soft in air.
S174: and if the position of the human body is in a pre-stored second position area, controlling the second air deflector positioned on the first side of the center of the panel structure to be closed, and controlling the vertical swing blade to swing left and right by the second air deflector positioned on the second side of the center of the panel structure to swing up and down.
The human body position is in a pre-stored second position area, the second air deflector 13 positioned on the first side of the center of the panel structure is controlled to be closed, the second air deflector 13 positioned on the second side of the center of the panel structure swings up and down, and the vertical swing blade 22 is controlled to swing left and right, so that the space on the first side of the panel structure is soft, and the space on the second side of the panel structure is uniform and large in air volume.
S175: and if the human body position is in a pre-stored first position area and a pre-stored second position area, controlling the second air deflector to be closed, and controlling the vertical swinging blade to swing left and right.
The human body position is in a pre-stored first position area and a pre-stored second position area, the second air deflector 13 is controlled to be closed, and the vertical swing blade 22 is controlled to swing left and right, so that the whole space can be soft.
S176: if the human body position is in a pre-stored first position area, a pre-stored second position area and a pre-stored third position area, controlling the second air deflector to swing up and down, and controlling the vertical swing blade to swing left and right; or the second air deflector is controlled to be transversely erected, and the vertical swinging blade is controlled to be erected.
The human body position is in a pre-stored first position area, a pre-stored second position area and a pre-stored third position area, the second air deflector 13 is controlled to swing up and down, and the vertical swing blade 22 is controlled to swing left and right; or, the second air deflector 13 is controlled to be transversely erected, and the vertical swinging blade 22 is controlled to be erected, so that the whole space has large air volume.
In this alternative embodiment, the pre-stored first location area corresponds to an area located at the second side of the center of the panel structure, the pre-stored second location area corresponds to an area located at the first side of the center of the panel structure, and the pre-stored third location area is a specific area, which indicates that the spatial human body density is greater at this time. When the air conditioner detects that the human body is located in the pre-stored first position area, the area located on the second side of the center of the panel structure can be enabled to be soft; when the air conditioner detects that the human body is located in the pre-stored second position area, the area located on the first side of the center of the panel structure can be enabled to be soft; the air conditioner detects that the human body is located in the pre-stored first position area and the pre-stored second position area, so that the whole space is soft; the air conditioner detects that the human body is located in the pre-stored first position area, the pre-stored second position area and the pre-stored third position area, so that the large air volume of the whole space is achieved, different air outlet requirements of different positions of the air conditioner are met, and the air conditioner is more intelligent and flexible.
Fig. 18 is a schematic structural diagram illustrating an apparatus for controlling an air conditioner according to an exemplary embodiment.
In this alternative embodiment, there is provided an apparatus for controlling an air conditioner, the apparatus comprising:
a first obtaining module 81, configured to obtain human body position information by using the human body sensing device 6;
and the first control module 82 is used for controlling the operation modes of the second air deflector 13 and the vertical swinging blade 22 according to the human body position information.
In some optional embodiments, the first control module 82 is specifically configured to:
comparing the human body position information with pre-stored position area information to obtain a pre-stored position area where the human body position is located;
if the position of the human body is in a pre-stored first position area, controlling the second air deflector 13 positioned on the first side of the center of the panel structure to swing up and down, closing the second air deflector 13 positioned on the second side of the center of the panel structure, and controlling the vertical swing blade 22 to swing left and right;
if the position of the human body is in a pre-stored second position area, controlling the second air deflector 13 positioned on the first side of the center of the panel structure to be closed, and controlling the second air deflector 13 positioned on the second side of the center of the panel structure to swing up and down to control the vertical swing blade 22 to swing left and right;
if the human body position is in a pre-stored first position area and a pre-stored second position area, the second air deflector 13 is controlled to be closed, and the vertical swing blade 22 is controlled to swing left and right;
if the human body position is in a pre-stored first position area, second position area and third position area, controlling the second air deflector 13 to swing up and down, and controlling the vertical swing blade 22 to swing left and right; or, the second air deflector 13 is controlled to be erected horizontally, and the vertical swing blade 22 is controlled to be erected.
In some alternative embodiments, there is provided an air conditioner control apparatus for an air conditioner, the apparatus comprising:
a processor;
a memory for storing processor-executable instructions;
wherein the processor is configured to:
acquiring human body position information by using a human body sensing device 6;
and controlling the operation modes of the second air deflector 13 and the vertical swinging blade 22 according to the human body position information.
Further, the treatment appliance is configured to:
acquiring human body position information by using the human body sensing device 6;
comparing the human body position information with pre-stored position area information to obtain a pre-stored position area where the human body position is located;
if the position of the human body is in a pre-stored first position area, controlling the second air deflector 13 positioned on the first side of the center of the panel structure to swing up and down, closing the second air deflector 13 positioned on the second side of the center of the panel structure, and controlling the vertical swing blade 22 to swing left and right;
if the position of the human body is in a pre-stored second position area, controlling the second air deflector 13 positioned on the first side of the center of the panel structure to be closed, and controlling the second air deflector 13 positioned on the second side of the center of the panel structure to swing up and down to control the vertical swing blade 22 to swing left and right;
if the human body position is in a pre-stored first position area and a pre-stored second position area, the second air deflector 13 is controlled to be closed, and the vertical swing blade 22 is controlled to swing left and right;
if the human body position is in a pre-stored first position area, second position area and third position area, controlling the second air deflector 13 to swing up and down, and controlling the vertical swing blade 22 to swing left and right; or, the second air deflector 13 is controlled to be erected horizontally, and the vertical swing blade 22 is controlled to be erected.
Fig. 19 to 22 are schematic structural views illustrating a panel structure of an air conditioner according to an exemplary embodiment.
In this alternative embodiment, there is provided a panel structure of an air conditioner, the panel structure including:
the air deflector 1 is provided with a first microporous structure 11 penetrating through the thickness direction of the air deflector 1 and swings up and down under the driving of a motor of the air deflector 1;
a plurality of edges perpendicular pendulum leaf subassembly 2 of parallel setting about panel structure's panel body 3, each perpendicular pendulum leaf subassembly 2 includes the perpendicular pendulum leaf 22 of pendulum rod 21 and one or more bionical leaf structure, wherein, perpendicular pendulum leaf 22 set up in on the pendulum rod 21, pendulum rod 21 drives under pendulum rod 21 driving motor's drive perpendicular pendulum leaf 22 left and right sides swing, be provided with the second microporous structure 221 that runs through its thickness direction on the perpendicular pendulum leaf 22.
In this optional implementation mode, erect pendulum leaf 22 bionical nature leaf shape, multirow erect pendulum leaf 22 and pass through motor drive horizontal hunting, the air conditioner air-out is behind the evaporimeter, through the multirow erect the wind that pendulum leaf 22 left and right sides was adjusted then rethread micropore aviation baffle 1 is adjusted from top to bottom, changes wind direction and wind speed many times, makes the air-out more comfortable, more is close to the natural wind, and the noise of wind sound is lower, and user experience is better.
In some alternative embodiments, the vertical swing blades 22 of any two adjacent vertical swing blade assemblies 2 are arranged in a staggered manner. The vertical swing blades 22 of two adjacent vertical swing blade assemblies 2 are arranged in a staggered mode, and the airflow passing through one vertical swing blade 22 further decelerates and changes direction through the vertical swing blade 22 adjacent to the vertical swing blade 22, so that the movement direction of the airflow is more disordered, and the aim of being free of wind sensation is fulfilled.
In some alternative embodiments, the vanes of the vanes 22 of any two adjacent drag vane assemblies 2 are of different sizes. When the airflow passing through a certain vertical swing blade 22 blows to the vertical swing blade 22 adjacent to the vertical swing blade 22, the moving direction of the airflow is further changed due to the different sizes of the blades of the two vertical swing blades 22, so that the wind speed in a certain specific direction is reduced, and the airflow is softer.
In some alternative embodiments, the distance between two adjacent vertical swing blades 22 decreases from the middle position of the swing rod 21 to two sides; or, the distance between two adjacent vertical swing blades 22 increases from the middle position of the swing rod 21 to two sides. The distance between two adjacent vertical swinging blades 22 is gradually changed, and when each vertical swinging blade 22 swings left and right, the wind coming out of the volute uniformly passes through the vertical swinging blade 22, so that the directions and the sizes of the air flows passing through the vertical swinging blades 22 are different, and the air flows are softer.
Optionally, the distance between two adjacent vertical swing vanes 22 satisfies the following relationship:
d=1.7*L(n-1)/[n*(N-1)]
wherein, L is the length of the swing link 21, N is the number of the vertical swing leaves 22 located on the swing link 21, N is the number of the distance between two adjacent vertical swing leaves 22 from the center position of the swing link 21, and d is the distance between two adjacent vertical swing leaves 22 at the nth section.
Specifically, n is an integer number which increases from the integer 2 from the central position of the swing link 21, such as 2, 3, 4, 5 …
When the distance between two adjacent vertical swinging blades 22 satisfies the relationship and increases progressively, and when each vertical swinging blade 22 swings left and right, the direction of the airflow from the volute through the vertical swinging blade 22 is more disordered, the airflow is softer, and the structure of the vertical swinging blade 22 is more reasonable and compact.
Fig. 23 to 26 are schematic structural views illustrating a panel structure of an air conditioner according to an exemplary embodiment.
In this alternative embodiment, there is provided a panel structure of an air conditioner, the panel structure including:
the air deflector 1 is provided with a first microporous structure 11 penetrating through the thickness direction of the air deflector 1 and swings up and down under the driving of a motor of the air deflector 1;
the vertical swing blade assembly 2 comprises a swing rod 21 and one or more vertical swing blades 22, wherein the vertical swing blades 22 are arranged on the swing rod 21, the swing rod 21 drives the vertical swing blades 22 to swing left and right under the driving of a driving motor of the swing rod 21, and the vertical swing blades 22 are provided with second microporous structures 221 penetrating through the thickness direction of the vertical swing blades.
In this optional embodiment, the vertical swing blade 22 is driven by the motor to swing left and right to adjust the air coming out of the volute, the air adjusted left and right by the vertical swing blade 22 is then adjusted up and down by the microporous air deflector 1, and the vertical swing blade 22, the air deflector 1 and the microporous structure are integrated, so that the air blown out by the air conditioner is closer to natural air, and the air conditioner is clean and healthy and improves the comfort level of human bodies.
FIG. 27 is a schematic structural view of a vertical pendulum blade shown in accordance with an exemplary embodiment.
In this alternative embodiment, the vertical swing blade 22 is configured to include a plurality of sub-blades parallel to each other, and the second microporous structures 221 located on any two adjacent sub-blades are arranged in a staggered manner. The air flow passing through the vertical swing blade 22 is in the diversion takes place between the sub-blade of vertical swing blade 22 to, the air flow further breaks up the direction of motion of air flow through the mutual dislocation set second microporous structure 221, makes to pass through the air flow disorder of vertical swing blade 22 is close natural wind, promotes user experience.
In some alternative embodiments, a rotatable blade is disposed within the second microporous structure 221, and the blade rotates under the action of the external air flow. The airflow passing through the second microporous structure 221 is driven by the rotation of the blades, the airflow direction changes obviously, and the airflow direction is disturbed more thoroughly, so that the airflow passing through the vertical swing blade 22 is more disorderly and is close to natural wind, the requirement of no wind sensation is met, and the user experience is good.
In some optional embodiments, the vertical swing blade 22 has a triangular structure, and the peripheral edge of the triangular structure is streamlined, so that the stability is high and the swing resistance is small.
Fig. 28 is a flowchart illustrating a method of air conditioner control according to an exemplary embodiment.
In this alternative embodiment, there is provided a method of controlling an air conditioner, the method comprising the steps of:
s281: and acquiring the running mode of the air conditioner.
S282: and controlling the operation modes of the air deflector and the vertical swinging blade according to the operation modes.
In this optional embodiment, different operation modes of the air deflector 1 and the vertical swing blade 22 can be controlled according to the operation mode of the air conditioner, so that the control of different operation modes of the air conditioner is realized, and the air conditioner is flexible and convenient.
Fig. 29 is a flowchart illustrating a method of air conditioner control according to an exemplary embodiment.
In this alternative embodiment, there is provided a method of controlling an air conditioner, the method comprising the steps of:
s291: and acquiring the running mode of the air conditioner.
S292: and if the operation mode is uniform and large-air-volume operation, controlling the air deflector to swing up and down and controlling the vertical swing blade to swing left and right.
The air which is adjusted left and right by the vertical swing blade 22 is blown out after being adjusted up and down by the air deflector 1, and the uniform large air volume operation of the air conditioner can be realized.
S293: and if the operation mode is soft and small air volume operation, controlling the air deflector to swing up and down, and controlling the vertical swing blade to be closed.
The breeze passing through the second microporous structure 221 of the vertical swing blade 22 is blown out after being vertically adjusted by the air deflector 1, so that the soft and small-air-volume operation of the air conditioner can be realized.
S294: and if the operation mode is soft and high-air-volume operation, controlling the air deflector to be closed and controlling the vertical swinging blade to swing left and right.
The air which is adjusted left and right through the vertical swing blade 22 is blown out through the first microporous structure 11 of the air deflector 1, so that the soft and large-air-volume operation of the air conditioner can be realized.
S295: and if the operation mode is soft breeze operation, controlling the air deflector to be closed and controlling the vertical swinging blade to be closed.
The breeze passing through the second microporous structure 221 of the vertical swing blade 22 is blown out through the first microporous structure 11 of the air deflector 1, so that the soft breeze operation of the air conditioner can be realized.
S296: and if the operation mode is large-air-volume operation, controlling the air deflector to be transversely erected and controlling the vertical swinging blade to be erected.
The vertical swing blade 22 is vertical, the air deflector 1 is horizontal, and the air blown out from the volute of the air conditioner is directly blown out, so that the large-air-volume operation of the air conditioner can be realized.
In this optional embodiment, different operation modes of the air deflector 1 and the vertical swing blade 22 can be controlled according to the operation mode of the air conditioner, so that control of different operation modes of the air conditioner is realized, and requirements of users on different operation modes of the air conditioner are met.
Fig. 30 is a schematic structural diagram illustrating an air conditioner controlling apparatus according to an exemplary embodiment.
In this alternative embodiment, there is provided an apparatus for controlling an air conditioner, the apparatus comprising:
a second obtaining module 83, configured to obtain an operation mode of the air conditioner;
and the second control module 84 controls the operation modes of the air deflector 1 and the vertical swinging blade 22 according to the operation modes.
Further, the second control module 84 is specifically configured to:
if the operation mode is uniform large-air-volume operation, controlling the air deflector 1 to swing up and down, and controlling the vertical swing blade 22 to swing left and right;
if the operation mode is soft and small air volume operation, controlling the air deflector 1 to swing up and down, and controlling the vertical swing blade 22 to be closed;
if the operation mode is soft and high-air-volume operation, the air deflector 1 is controlled to be closed, and the vertical swing blade 22 is controlled to swing left and right;
if the operation mode is soft breeze operation, controlling the air deflector 1 to be closed, and controlling the vertical swinging blade 22 to be closed;
and if the operation mode is large-air-volume operation, controlling the air deflector 1 to be transversely erected and controlling the vertical swinging blade 22 to be erected.
In some alternative embodiments, there is provided an air conditioner control apparatus for an air conditioner, the apparatus comprising:
a processor;
a memory for storing processor-executable instructions;
wherein the processor is configured to:
acquiring an operation mode of the air conditioner;
and controlling the operation modes of the air deflector 1 and the vertical swinging blade 22 according to the operation modes.
Further, the treatment appliance is configured to:
acquiring an operation mode of the air conditioner;
if the operation mode is uniform large-air-volume operation, controlling the air deflector 1 to swing up and down, and controlling the vertical swing blade 22 to swing left and right;
if the operation mode is soft and small air volume operation, controlling the air deflector 1 to swing up and down, and controlling the vertical swing blade 22 to be closed;
if the operation mode is soft and high-air-volume operation, the air deflector 1 is controlled to be closed, and the vertical swing blade 22 is controlled to swing left and right;
if the operation mode is soft breeze operation, controlling the air deflector 1 to be closed, and controlling the vertical swinging blade 22 to be closed;
and if the operation mode is large-air-volume operation, controlling the air deflector 1 to be transversely erected and controlling the vertical swinging blade 22 to be erected.
Fig. 31 to 33 are schematic structural views illustrating a panel structure of an air conditioner according to an exemplary embodiment.
In this alternative embodiment, there is provided a panel structure of an air conditioner, the panel structure including:
a panel body 3 provided with one or more first transverse reinforcing ribs along the length direction thereof and/or one or more first longitudinal reinforcing ribs along the width direction thereof;
the air deflector 1 comprises a plurality of second air deflectors 13 which are arranged in parallel left and right along the panel body 3, each second air deflector 13 swings up and down under the driving of a driving motor of the air deflector 1, and a first microporous structure 11 penetrating through the second air deflector 13 in the thickness direction is arranged on the second air deflector 13;
the vertical swing blade assembly 2 comprises a swing rod 21 and one or more vertical swing blades 22 with bionic leaf structures, wherein the vertical swing blades 22 are arranged on the swing rod 21, the swing rod 21 drives the vertical swing blades 22 to swing left and right under the driving of a driving motor of the swing rod 21, and the vertical swing blades 22 are provided with second microporous structures 221 penetrating through the thickness direction of the vertical swing blades.
In this optional embodiment, the panel body 3 is provided with one or more first transverse reinforcing ribs along the length direction thereof and/or one or more first longitudinal reinforcing ribs along the width direction thereof, so as to improve the structural strength of the panel, the panel is not easy to deform, moreover, the vertical swing blade 22 simulates the shape of a natural leaf, the wind coming out of the volute is driven by the motor to swing left and right, so that the wind is closer to the natural wind under the action of the vertical swing blade 22, the wind adjusted left and right by the vertical swing blade 22 is then adjusted up and down by the microporous wind guide plate 1, so that the wind blown out by the air conditioner is softer, and the requirement of the comfort level of the human body is met, in addition, the wind guide plate 1 comprises a plurality of second wind guide plates 13 arranged in parallel left and right along the panel body 3, and by controlling different operation modes of the second wind guide plates 13 and the vertical swing blade 22, the different air-out of different positions of the air conditioner is realized, and the different air-out requirements of users in different directions in the same room are met.
In some alternative embodiments, the second air guiding plate 13 is provided with one or more second transverse reinforcing ribs along the length direction thereof and/or one or more second longitudinal reinforcing ribs along the width direction thereof. The second transverse reinforcing rib and/or the second longitudinal reinforcing rib improve the overall strength of the second air deflector 13, and optimize the structure of the second air deflector 13.
In some alternative embodiments, the length of the second transverse stiffener is equal to the length of the second air deflection plate 13, and the length of the second longitudinal stiffener is equal to the width of the second air deflection plate 13. The second transverse reinforcing rib penetrates through the length direction of the second air deflector 13, the second longitudinal reinforcing rib penetrates through the width direction of the second air deflector 13, the structure of the second air deflector 13 is more compact, and the processing technology is simpler.
In some optional embodiments, the panel structure further includes a human body sensing device 6 for sensing a position of a human body and transmitting the position information of the human body to the controller of the air conditioner, so that the controller controls an operation mode of the second air deflector 1 and the vertical swing blade 22 according to the position information of the human body. The operation modes of the second air deflector 13 and the vertical swing blade 22 are controlled according to the human body position information acquired by the human body sensing device 6, so that different air outlet requirements of different positions of the air conditioner are realized, and different air outlet requirements of users in different directions in the same room can be met.
Fig. 34-35 are schematic structural views of a trim panel shown according to an exemplary embodiment.
In this alternative embodiment, a trim panel 7 is provided for mounting with the panel body 3, the trim panel 7 being provided with one or more third transverse ribs along its length and/or one or more third longitudinal ribs along its width. The third transverse reinforcing ribs and/or the third longitudinal reinforcing ribs improve the overall strength of the decorative plate 7, and optimize the structure of the decorative plate 7, wherein the decorative plate plays a role in protecting the panel body.
In some optional embodiments, when the decorative plate 7 is mounted on the panel body 3, the first transverse stiffener and the third transverse stiffener are in the same straight line, and/or the first longitudinal stiffener and the third longitudinal stiffener are in the same straight line. The structural consistency of the panel structure is improved while the structural strength of the panel structure is improved.
Furthermore, when the decorative plate 7 and the panel body 3 are installed, the first transverse reinforcing rib is overlapped with the third transverse reinforcing rib, and/or the first longitudinal reinforcing rib is overlapped with the third longitudinal reinforcing rib, so that the structure is more compact.
In some alternative embodiments, there is provided a panel structure of an air conditioner, including:
the air deflector 1 is provided with a first microporous structure 11 penetrating through the thickness direction of the air deflector 1 and swings left and right under the drive of a motor of the air deflector 1;
the horizontal swing blade assembly comprises a swing rod 21 and one or more horizontal swing blades of a bionic leaf structure, wherein the horizontal swing blades are arranged on the swing rod 21, the swing rod 21 is driven by a driving motor of the swing rod 21 to swing up and down, and second microporous structures 221 penetrating through the horizontal swing blades in the thickness direction are arranged on the horizontal swing blades.
In this alternative embodiment, since the natural wind is generally gentler after being decelerated by the shade leaves, the yaw leaves are made to simulate the shape of the leaves in the nature, the swing rod 21 drives the motor to drive the motor to swing up and down, so that the wind coming out of the volute is closer to natural wind under the action of the horizontal swinging blade, the air blown out by the air conditioner is softer through the up-and-down adjustment of the horizontal swinging blades and the left-and-right adjustment of the air deflector 1, meanwhile, the first microporous structure 11 is arranged on the air deflector 1, the second microporous structure 221 is arranged on the horizontal swinging blade, and in the swinging process of the air deflector 1 and the horizontal swinging blade, the air flow penetrates out of the first microporous structure 11 or the second microporous structure 221, the moving direction of the air flow is further disturbed, the air speed in a certain specific direction is reduced, the air flow is cool but not cold or warm but not hot, and the body feeling comfort level of a human body is improved.
Optionally, the width of the traverse vanes decreases from the middle to both ends, and the peripheral edge lines of the traverse vanes are streamline.
Optionally, when a plurality of the traverse blades are provided, the blades of any two adjacent traverse blades have different sizes.
Optionally, the sizes of the blades of the plurality of the traverse oscillating blades are decreased from the middle position of the oscillating bar 21 to two sides; or, the sizes of the blades of the plurality of the traverse oscillating blades are gradually increased from the middle position of the oscillating bar 21 to two sides.
Specifically, the distance between two adjacent yaw blades satisfies the following relationship:
d=1.7*L(n-1)/[n*(N-1)]
wherein, L is the length of the swing link 21, N is the number of the swing leaves located on the swing link 21, N is the number of the distance between two adjacent swing leaves from the center of the swing link 21, and d is the distance between two adjacent swing leaves of the nth segment.
Specifically, n is an integer number which increases from the integer 2 from the central position of the swing link 21, such as 2, 3, 4, 5 …
Optionally, a clamping piece 222 and a rotating piece 223 are arranged on the swinging blade, the swinging blade is connected with the swinging rod 21 in a clamping manner through the clamping piece 222, the swinging blade is rotatably connected with the panel frame 4 of the panel structure through the rotating piece 223, and the swinging rod 21 is driven by the driving motor of the swinging rod 21 to drive the swinging blade to swing up and down relative to the panel frame 4.
Optionally, the maximum swing angle of the traverse blade is in a range of [40 ° and 160 °.
Optionally, the air deflector 1 includes a plurality of first air deflectors 12 arranged in parallel left and right along the panel body 3 of the panel structure, and the first air deflectors 12 are provided with the first microporous structure 11 penetrating through the first air deflector in the thickness direction.
In some alternative embodiments, there is provided a panel structure of an air conditioner, the panel structure including:
the air deflector 1 is provided with a first microporous structure 11 penetrating through the thickness direction of the air deflector 1 and swings left and right under the drive of a motor of the air deflector 1;
the transverse swing blade assembly comprises a swing rod 21 and one or more transverse swing blades of a bionic leaf structure, wherein the transverse swing blades are arranged on the swing rod 21, the swing rod 21 drives the transverse swing blades to swing up and down under the driving of a driving motor of the swing rod 21, and second microporous structures 221 penetrating through the transverse swing blades in the thickness direction are arranged on the transverse swing blades;
the panel body 3 is provided with a reinforcing rib 31.
In some alternative embodiments, there is provided a panel structure of an air conditioner, the panel structure including:
the air deflector 1 comprises a plurality of second air deflectors 13 which are arranged in parallel left and right along the panel body 3 of the panel structure, each second air deflector 13 swings left and right under the driving of a driving motor of the air deflector 1, and a first microporous structure 11 penetrating through the second air deflector 13 in the thickness direction is arranged on the second air deflector 13;
the transverse swing blade assembly comprises a swing rod 21 and one or more transverse swing blades of a bionic leaf structure, wherein the transverse swing blades are arranged on the swing rod 21, the swing rod 21 drives the transverse swing blades to swing up and down under the driving of a driving motor of the swing rod 21, and second microporous structures 221 penetrating through the transverse swing blades in the thickness direction are arranged on the transverse swing blades;
and the human body sensing device 6 is used for sensing the position of a human body and transmitting the position information of the human body to the controller of the air conditioner so that the controller controls the operation mode of the second air deflector 1 and the horizontal swinging blade according to the position information of the human body.
In some alternative embodiments, there is provided a method of controlling an air conditioner, the method including:
acquiring human body position information by using the human body sensing device 6;
and controlling the operation modes of the second air deflector 13 and the transverse swinging blade according to the human body position information.
Optionally, the controlling the operation modes of the second air deflector 13 and the yaw blade according to the human body position information includes:
comparing the human body position information with pre-stored position area information to obtain a pre-stored position area where the human body position is located;
if the position of the human body is in a pre-stored first position area, controlling the second air deflector 13 positioned on the first side of the center of the panel structure to swing left and right, closing the second air deflector 13 positioned on the second side of the center of the panel structure, and controlling the horizontal swinging blade to swing up and down;
if the position of the human body is in a pre-stored second position area, controlling the second air deflector 13 positioned on the first side of the center of the panel structure to be closed, and controlling the second air deflector 13 positioned on the second side of the center of the panel structure to swing left and right to control the horizontal swinging blade to swing up and down;
if the human body position is in a pre-stored first position area and a pre-stored second position area, controlling the second air deflector 13 to be closed, and controlling the horizontal swinging blade to swing up and down;
if the human body position is in a pre-stored first position area, a pre-stored second position area and a pre-stored third position area, controlling the second air deflector 13 to swing left and right, and controlling the horizontal swinging blade to swing up and down; or, the second air deflector 13 is controlled to be erected, and the horizontal swinging blade is controlled to be erected horizontally.
In some alternative embodiments, there is provided an apparatus for controlling an air conditioner, the apparatus including:
the third acquisition module is used for acquiring human body position information by using the human body induction device 6;
and the third control module is used for controlling the operation modes of the second air deflector 13 and the horizontal swinging blade according to the human body position information.
Optionally, the third control module is specifically configured to:
comparing the human body position information with pre-stored position area information to obtain a pre-stored position area where the human body position is located;
if the position of the human body is in a pre-stored first position area, controlling the second air deflector 13 positioned on the first side of the center of the panel structure to swing left and right, closing the second air deflector 13 positioned on the second side of the center of the panel structure, and controlling the horizontal swinging blade to swing up and down;
if the position of the human body is in a pre-stored second position area, controlling the second air deflector 13 positioned on the first side of the center of the panel structure to be closed, and controlling the second air deflector 13 positioned on the second side of the center of the panel structure to swing left and right to control the horizontal swinging blade to swing up and down;
if the human body position is in a pre-stored first position area and a pre-stored second position area, controlling the second air deflector 13 to be closed, and controlling the horizontal swinging blade to swing up and down;
if the human body position is in a pre-stored first position area, a pre-stored second position area and a pre-stored third position area, controlling the second air deflector 13 to swing left and right, and controlling the horizontal swinging blade to swing up and down; or, the second air deflector 13 is controlled to be erected, and the horizontal swinging blade is controlled to be erected horizontally.
In some alternative embodiments, there is provided a panel structure of an air conditioner, the panel structure including:
the air deflector 1 is provided with a first microporous structure 11 penetrating through the thickness direction of the air deflector 1 and swings left and right under the drive of a motor of the air deflector 1;
a plurality of edges yaw leaf subassembly of parallel setting about panel structure's panel body 3, each yaw leaf subassembly includes the yaw leaf of pendulum rod 21 and one or more bionical leaf structure, wherein, yaw leaf set up in on the pendulum rod 21, pendulum rod 21 drives under the drive of pendulum rod 21 driving motor yaw leaf luffing motion, be provided with the second microporous structure 221 that runs through its thickness direction on the yaw leaf.
Optionally, the yaw blades of any two adjacent yaw blade assemblies are arranged in a staggered manner.
Optionally, the blades of the traverse blades of any two adjacent traverse blade assemblies are different in size.
Optionally, the distance between two adjacent horizontal swing blades decreases from the middle position of the swing rod 21 to two sides; or, the distance between two adjacent horizontal swing blades increases from the middle position of the swing rod 21 to two sides.
Optionally, the value range of the proportion of the total area of the second microporous structures 221 of the traverse blade to the total area of the traverse blade is [ 45%, 85% ].
Optionally, the thickness of the yaw blade decreases from the center to the periphery, and the value range of the difference between the maximum thickness and the minimum thickness of the yaw blade is [3mm, 8mm ].
In some alternative embodiments, there is provided a panel structure of an air conditioner, the panel structure including:
the air deflector 1 is provided with a first microporous structure 11 penetrating through the thickness direction of the air deflector 1 and swings left and right under the drive of a motor of the air deflector 1;
the transverse swing blade assembly comprises a swing rod 21 and one or more transverse swing blades, wherein the transverse swing blades are arranged on the swing rod 21, the swing rod 21 drives the transverse swing blades to swing up and down under the driving of a driving motor of the swing rod 21, and the transverse swing blades are provided with second microporous structures 221 penetrating through the thickness direction of the transverse swing blades.
Optionally, the yaw blade is configured to include a plurality of sub-blades parallel to each other, and the second microporous structures 221 located on any two adjacent sub-blades are arranged in a staggered manner.
Optionally, the material of the horizontal swinging blade is a PVC material.
In some alternative embodiments, there is provided a method of controlling an air conditioner, the method including:
acquiring an operation mode of the air conditioner;
and controlling the operation modes of the air deflector 1 and the traverse blades according to the operation modes.
In the optional embodiment, different operation modes of the air deflector 1 and the traverse blade can be controlled according to the operation mode of the air conditioner, so that the control of different operation modes of the air conditioner is realized, and the air conditioner is flexible and convenient.
Optionally, the controlling the operation modes of the air deflector 1 and the yaw blades according to the operation mode includes:
if the operation mode is uniform large-air-volume operation, controlling the air deflector 1 to swing left and right, and controlling the horizontal swinging blade to swing up and down;
the air which is adjusted up and down by the horizontal swinging blades is blown out after being adjusted left and right by the air deflector 1, and the uniform large air volume operation of the air conditioner can be realized.
If the operation mode is soft and small-air-volume operation, controlling the air deflector 1 to swing left and right, and controlling the horizontal swinging blades to be closed;
the breeze passing through the second microporous structure 221 of the horizontal swing blade is blown out after being left and right adjusted by the air deflector 1, so that the soft and small air volume operation of the air conditioner can be realized.
If the operation mode is soft and high-wind-volume operation, the air deflector 1 is controlled to be closed, and the horizontal swinging blade is controlled to swing up and down;
the air adjusted up and down by the horizontal swinging blades is blown out by the first microporous structures 11 of the air deflector 1, so that the soft and large-air-volume operation of the air conditioner can be realized.
If the operation mode is soft breeze operation, controlling the air deflector 1 to be closed and controlling the yaw blades to be closed;
the breeze passing through the second microporous structure 221 of the horizontal swing blade is blown out through the first microporous structure 11 of the air deflector 1, so that the soft breeze operation of the air conditioner can be realized.
And if the operation mode is large-air-volume operation, controlling the air deflector 1 to be vertical and controlling the horizontal swinging blade to be vertical.
The horizontal swinging blades are horizontally vertical, the air deflector 1 is vertical, and the air blown out from the volute of the air conditioner is directly blown out, so that the large-air-volume operation of the air conditioner can be realized.
In this optional embodiment, different operation modes of the air deflector 1 and the traverse blade may be controlled according to the operation mode of the air conditioner, so as to control different operation modes of the air conditioner, and meet the requirements of users for different operation modes of the air conditioner.
In some alternative embodiments, there is provided an apparatus for controlling an air conditioner, the apparatus including:
the fourth acquisition module is used for acquiring the operation mode of the air conditioner;
and the fourth control module is used for controlling the operation modes of the air deflector 1 and the traverse blades according to the operation modes.
Optionally, the fourth control module is specifically configured to:
if the operation mode is uniform large-air-volume operation, controlling the air deflector 1 to swing left and right, and controlling the horizontal swinging blade to swing up and down;
if the operation mode is soft and small-air-volume operation, controlling the air deflector 1 to swing left and right, and controlling the horizontal swinging blades to be closed;
if the operation mode is soft and high-wind-volume operation, the air deflector 1 is controlled to be closed, and the horizontal swinging blade is controlled to swing up and down;
if the operation mode is soft breeze operation, controlling the air deflector 1 to be closed and controlling the yaw blades to be closed;
and if the operation mode is large-air-volume operation, controlling the air deflector 1 to be vertical and controlling the horizontal swinging blade to be vertical.
In some alternative embodiments, there is provided a panel structure of an air conditioner, the panel structure including:
a panel body 3 provided with one or more first transverse reinforcing ribs along the length direction thereof and/or one or more first longitudinal reinforcing ribs along the width direction thereof;
the air deflector 1 comprises a plurality of second air deflectors 13 which are arranged in parallel left and right along the panel body 3, each second air deflector 13 swings left and right under the driving of a driving motor of the air deflector 1, and a first microporous structure 11 penetrating through the second air deflector 13 in the thickness direction is arranged on the second air deflector 13;
the horizontal swing blade assembly comprises a swing rod 21 and one or more horizontal swing blades of a bionic leaf structure, wherein the horizontal swing blades are arranged on the swing rod 21, the swing rod 21 is driven by a driving motor of the swing rod 21 to swing up and down, and second microporous structures 221 penetrating through the horizontal swing blades in the thickness direction are arranged on the horizontal swing blades.
It should be noted that, when the air deflector 1 swings up and down, the vertical swing blade 22 swings left and right; when the air deflector 1 swings left and right, the swinging blade swings up and down, so that the adjustment of the air flow passing through the air deflector 1 and the swinging blade in all directions is realized. The swing direction of the horizontal swing blade is different from the swing direction of the vertical swing blade 22, and the specific structure of the horizontal swing blade and the embodiment thereof can refer to the specific structure of the vertical swing blade 22 and the embodiment thereof.
In some exemplary embodiments, there is also provided an air conditioner including the panel structure as described above.
In some exemplary embodiments, a non-transitory computer readable storage medium comprising instructions, such as a memory comprising instructions, executable by a processor to perform the method described above is also provided. The non-transitory computer readable storage medium may be a Read Only Memory (ROM), a Random Access Memory (RAM), a magnetic tape, an optical storage device, and the like.
Those of skill in the art would appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware or combinations of computer software and electronic hardware. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention. It is clear to those skilled in the art that, for convenience and brevity of description, the specific working processes of the above-described systems, apparatuses and units may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.
In the embodiments disclosed herein, it should be understood that the disclosed methods, articles of manufacture (including but not limited to devices, apparatuses, etc.) may be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, and for example, the division of the units is only one logical division, and other divisions may be realized in practice, for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection through some interfaces, devices or units, and may be in an electrical, mechanical or other form. The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment. In addition, functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit.
It should be understood that the flowchart and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods and computer program products according to various embodiments of the present invention. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions. The present invention is not limited to the procedures and structures that have been described above and shown in the drawings, and various modifications and changes may be made without departing from the scope thereof. The scope of the invention is limited only by the appended claims.