CN112815505A - Air conditioner segmented air supply control method and device and air conditioner - Google Patents

Abstract

The invention discloses an air conditioner sectional air supply control method, an air conditioner sectional air supply control device and an air conditioner, and relates to the technical field of air conditioners, wherein the air conditioner sectional air supply control method comprises the following steps: determining a current air supply mode of the target air conditioner based on the operation state of each first air deflector; and respectively controlling the upper and lower air supply angles of each second air deflector based on the current air supply mode. According to the invention, the upper and lower air supply angles of the second air deflectors of each part are respectively controlled according to the current air supply mode of the target air conditioner, so that the air outlet height of segmented air supply is more accurate, the segmented air supply effect of the air conditioner is improved, and the comfort of a user is further improved.

Description

Air conditioner segmented air supply control method and device and air conditioner

Technical Field

The invention relates to the technical field of air conditioners, in particular to a method and a device for controlling segmented air supply of an air conditioner and the air conditioner.

Background

Along with the increasing requirement of people on the comfort of the air conditioner, the conventional cabinet air conditioner supplies air to a plurality of sections of air outlets of the air conditioner respectively so as to meet various air supply requirements of users on different height layers. However, when the air conditioner is operated, the temperature of the outlet air is usually different from the temperature of the ambient air, so that the outlet air of the air conditioner sinks or floats to different degrees in the blowing process. However, the vertical air deflectors of the air conditioner cannot respectively control the upper and lower air supply angles of the left and right air deflectors of each section, so that the air conditioner has poor segmented air supply effect, and further the comfort of users is low.

Disclosure of Invention

In order to solve the problems, the invention provides a method and a device for controlling air supply of an air conditioner in a segmented mode and the air conditioner, which can improve the segmented air supply effect of the air conditioner and further improve the comfort of a user.

According to an embodiment of the invention, on one hand, a segmented air supply control method of an air conditioner is provided, which is applied to a target air conditioner, wherein the target air conditioner comprises a plurality of segments of first air deflectors and a plurality of segments of second air deflectors; the method comprises the following steps: determining a current air supply mode of the target air conditioner based on the operation state of each first air deflector; and respectively controlling the upper and lower air supply angles of each second air deflector based on the current air supply mode.

Through adopting above-mentioned technical scheme, control respectively the upper and lower air supply angle of each part second aviation baffle according to the current air supply mode of target air conditioner to the air-out height that makes the segmentation air supply is more accurate, has promoted the segmentation air supply effect of air conditioner, and then has promoted user's travelling comfort.

Preferably, the operation state comprises an opening state and a closing state; the step of determining the current air supply mode of the target air conditioner based on the operation state of each first air deflector comprises the following steps: acquiring a target section air deflector in the closed state or the open state from each first air deflector; and determining the current air supply mode of the target air conditioner based on the number and the positions of the target air deflectors.

By adopting the technical scheme, the current air supply mode corresponding to the target air conditioner is determined based on the current operation state of the first air deflector at each position, and the accuracy of determining the current operation state of the target air conditioner is improved.

Preferably, the step of determining the current air supply mode of the target air conditioner based on the number and the position of the target air deflectors includes: when the target air deflector is in an open state, determining the height of an air supply area of the target air conditioner based on the position of each target air deflector; and determining the current air supply mode of the target air conditioner based on the height of the air supply area.

By adopting the technical scheme, the height of the air supply area is determined based on the position height of the target section air deflector in the opening state, and the current air supply mode corresponding to the target air conditioner can be accurately determined, so that accurate air supply of the height of the air supply area is realized, and the accuracy of determining the current running state of the target air conditioner is improved.

Preferably, the step of determining the current air supply mode of the target air conditioner based on the number and the position of the target air deflectors includes: when the target air deflector is in a closed state, determining the height of the non-wind-sensing area of the target air conditioner based on the position of each target air deflector; and determining the current air supply mode of the target air conditioner based on the height of the no-wind-feeling area.

By adopting the technical scheme, the height of the non-wind-sensing area is determined based on the position height of the target section air deflector in the closed state, and the current air supply mode corresponding to the target air conditioner can be accurately determined so as to avoid supplying air to the non-wind-sensing area.

Preferably, the second air deflector comprises a connecting rod and a plurality of blades, and the blades are perpendicular to the connecting rod; the step of controlling the upper and lower air supply angles of each second air deflector based on the current air supply mode comprises the following steps: and controlling the connecting rods of the second air deflectors to adjust the pitch angles of the blades based on the current air supply mode so as to avoid the height of the non-wind-sensing area corresponding to the current air supply mode for air supply.

By adopting the technical scheme, the pitch angles of the blades of the second air deflectors of all the parts are controlled, the upper and lower air outlet angles of the second air deflectors of all the parts of the target air conditioner can be respectively controlled, the height of an air supply area is aligned, and the non-wind-sensation area is avoided for supplying air, so that the segmented air supply is more accurate.

Preferably, the target air conditioner includes an upper second air deflector and a lower second air deflector, and the current air supply mode includes: an upper no-wind-sense mode, a middle no-wind-sense mode, a lower no-wind-sense mode, an upper no-wind-sense mode, a middle no-wind-sense mode, a full no-wind-sense mode and a conventional full-open air supply mode; the step of controlling the upper and lower air supply angles of each second air deflector based on the current air supply mode comprises the following steps: when the current air supply mode is the upper non-air-sense mode, controlling the pitch angle of the blades of the upper second air deflector to be a first angle, and controlling the pitch angle of the blades of the lower second air deflector to be a second angle; when the current air supply mode is the medium-sized no-wind-sensation mode, controlling the pitch angle of the blades of the upper second air deflector to be a third angle, and controlling the pitch angle of the blades of the lower second air deflector to be a first angle; when the current air supply mode is the lower no-wind-sensation mode, controlling the pitch angles of the blades of the upper second air deflector and the lower second air deflector to be a third angle; when the current air supply mode is the vertical non-wind-sensing mode, controlling the pitch angle of the blades of the upper second air deflector to be a fourth angle, and controlling the pitch angle of the blades of the lower second air deflector to be a first angle; when the current air supply mode is the middle-lower no-wind-sensation mode, controlling the pitch angle of the blades of the upper second air deflector to be a first angle, and controlling the pitch angle of the blades of the lower second air deflector to be a fourth angle; when the current air supply mode is the upper-middle non-wind-sensing mode, controlling the pitch angle of the blades of the upper second air deflector to be a third angle and controlling the pitch angle of the blades of the lower second air deflector to be a fourth angle; when the current air supply mode is the full no-wind-sensation mode, controlling the pitch angle of the blades of the upper second air deflector and the pitch angle of the blades of the lower second air deflector to be a fourth angle; when the current air supply mode is the conventional full-open air supply mode, controlling the pitch angle of the blades of the upper second air deflector and the pitch angle of the blades of the lower second air deflector to be the second angle; wherein the third angle is larger than or equal to the fourth angle and larger than or equal to the first angle.

By adopting the technical scheme, the blades on the second air guide plate are controlled to be at different pitch angles in different modes of the target air conditioner, so that the air supply mode in the segmentation is more accurate while the air outlet is effectively prevented from sinking, the non-inductive mode of each segmented first air guide plate is strengthened, and the comfort of a user is improved.

Preferably, the third angle ranges from 30 ° to 60 °, the fourth angle ranges from 15 ° to 45 °, the second angle ranges from 0 ° to 30 °, and the first angle ranges from-15 ° to +15 °.

By adopting the technical scheme, the angle value is limited by the pitch angle of the blades, the upper and lower air supply angles of the target air conditioner can be effectively controlled, and the accuracy of segmented air supply is improved.

According to an embodiment of the invention, in another aspect, an air conditioner segmented air supply control device is provided, which is applied to a target air conditioner, wherein the target air conditioner comprises a multi-segment first air deflector and a multi-segment second air deflector; the device comprises: the determining module is used for determining the current air supply mode of the target air conditioner based on each first air deflector; and the control module is used for respectively controlling the air supply angle of each second air deflector based on the current air supply mode.

According to an embodiment of the present invention, there is provided an air conditioner including: the air conditioner comprises a multi-section first air deflector, a multi-section second air deflector, a computer readable storage medium and a processor, wherein the computer readable storage medium is used for storing a computer program, air outlet micropores are formed in the first air deflector, and the computer program is read by the processor and run to realize the method in any one of the first aspect.

According to an embodiment of the present invention, in another aspect, a computer-readable storage medium is provided, which stores a computer program, which when read and executed by a processor, implements the method according to any one of the first aspect.

The invention has the following beneficial effects: the current air supply mode of the first air guide plate is obtained, and the upper air supply angle and the lower air supply angle of each part of the second air guide plate are respectively controlled according to the current air supply mode of the target air conditioner, so that the air outlet height of segmented air supply is more accurate, the segmented air supply effect of the air conditioner is improved, and the comfort of a user is further improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structures, ratios, sizes, and the like shown in the present specification are only used for matching with the contents disclosed in the specification, so as to be understood and read by those skilled in the art, and are not used to limit the conditions that the present invention can be implemented, so that the present invention has no technical significance, and any structural modifications, changes in the ratio relationship, or adjustments of the sizes, without affecting the effects and the achievable by the present invention, should still fall within the range that the technical contents disclosed in the present invention can cover.

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

fig. 2 is a schematic structural view of an air deflector according to the present invention;

fig. 3 is a schematic view of a first air guiding plate structure according to the present invention;

fig. 4 is a schematic view of a second air guiding plate structure provided in the present invention;

fig. 5 is a schematic structural diagram of a segmented air supply control device of an air conditioner according to the present invention.

Description of reference numerals:

21-an upper second air deflection plate; 22-a lower second air deflection plate; 23-an upper section first air deflector; 24-a middle section first air deflector; 25-lower section first air deflector; 31-air outlet micropores; 41-connecting rod; 42-blade.

Detailed Description

The present invention is described in terms of particular embodiments, other advantages and features of the invention will become apparent to those skilled in the art from the following disclosure, and it is to be understood that the described embodiments are merely exemplary of the invention and that it is not intended to limit the invention to the particular embodiments disclosed. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

The first embodiment is as follows:

the embodiment provides a method for controlling segmented air supply of an air conditioner, which can be applied to a target air conditioner, wherein the target air conditioner comprises a plurality of segments of first air deflectors and a plurality of segments of second air deflectors, and the second air deflectors of each segment are respectively connected with a control motor so as to independently control the upper and lower air supply angles of the second air deflectors of each segment; referring to the flow chart of the sectional air supply control method of the air conditioner shown in fig. 1, the method mainly comprises the following steps S102 to S104:

step S102: and determining the current air supply mode of the target air conditioner based on the operation state of each first air deflector.

The target air conditioner comprises a plurality of sections of first air deflectors in the vertical direction, each section of first air deflector is controlled by an independent motor, and each section of first air deflector can be controlled to be closed and opened respectively. When the target air conditioner operates in a refrigeration mode, the current air supply mode of the target air conditioner can be obtained by detecting the operation state of each section of the first air deflector in real time. The first air deflector can be a left air deflector and a right air deflector, and the left and right swing angles of each section of the left and right air deflectors can be respectively controlled through a control motor connected with each section of the left and right air deflectors.

The target air conditioner comprises a plurality of sections of first air deflectors in the vertical direction, and the operation states of the first air deflectors in all the sections can be the same or different, so that the current air supply mode of the first air deflectors of the target air conditioner can be determined according to the current operation states of the air deflectors in all the sections. For example, when any one section of the first air deflector is in a closed state, it can be determined that the height corresponding to the section of the first air deflector needs to perform the non-sensible air supply. The current air supply mode of the target air conditioner can be detected in real time by acquiring the running state of each section of the first air deflector, so that the up-and-down air supply angle of the target air conditioner can be controlled in a segmented manner along with the current air supply mode.

Step S104: and respectively controlling the upper and lower air supply angles of each second air deflector based on the current air supply mode.

The second air deflector comprises an air supply blade, and the upper and lower air outlet angles of the target air conditioner are adjusted by controlling the deflection angle (namely the blade pitch angle) of the air supply blade in the upper and lower directions. The current air supply mode of the target air conditioner can reflect the air supply direction of the target air conditioner, the upper and lower air supply angles of the second air deflectors of each part can be respectively controlled based on the air supply direction of the target air conditioner by acquiring the current air supply mode of the target air conditioner, and the upper and lower air supply angles of the second air deflectors of each part can be independently controlled through corresponding control motors.

The second air deflector can be an upper air deflector and a lower air deflector, the air supply height of the target air conditioner can be accurately controlled by controlling the upper air supply angle and the lower air supply angle of each section of the upper air deflector and the lower air deflector, and the phenomenon that the air conditioner sinks or floats to different degrees in the air blowing process is avoided, so that the air supply direction of the target air conditioner is more accurate.

According to the air conditioner segmented air supply control method provided by the embodiment, the current air supply mode of the first air guide plate is obtained, and the upper and lower air supply angles of the second air guide plates of all the parts are respectively controlled according to the current air supply mode of the target air conditioner, so that the air outlet height of segmented air supply is more accurate, the segmented air supply effect of the air conditioner is improved, and the comfort of a user is further improved.

In order to accurately determine the current air supply mode of the target air conditioner, the present embodiment provides an implementation manner for determining the current air supply mode of the target air conditioner based on the operation state of each first air deflector, and the following steps (1) to (2) may be specifically referred to:

step (1): and acquiring the target section air guide plate in a closed state or an open state from the first air guide plates.

The first air guide plates are used for adjusting left and right air outlet angles of a target air conditioner, air outlet micropores are formed in each first air guide plate, and the operation states comprise an opening state and a closing state. The current angle of each section of first air deflector blade is detected, or the motor connected with each section of first air deflector blade is used for determining the operation state of each section of first air deflector blade, when each blade of the first air deflector blade is closed, the operation state of the first air deflector blade is determined to be a closed state, and the air outlet can blow out from the air outlet micropore on the first air deflector at a low speed.

In a specific embodiment, each section of the first air guiding plate in the closed state can be used as a target section air guiding plate, or each section of the first air guiding plate in the open state can be used as a target section air guiding plate.

Step (2): and determining the current air supply mode of the target air conditioner based on the number and the positions of the target air deflectors.

Acquiring a target section air deflector in a closed state or an open state; according to the number and the positions of the target section air deflectors in the closed state or the open state, the air supply height or the air supply area of the target air conditioner can be determined, and then the current air supply mode of the target air conditioner can be judged, for example, when the target section air deflectors in the closed state are any section of first air deflectors, the height of the target section air deflectors of the target air conditioner is in a no-wind-sensation mode.

In one embodiment, when the target air deflector is in an open state, the height of the air supply area of the target air conditioner is determined based on the position of each target air deflector; a current air supply mode of the target air conditioner is determined based on the air supply zone height. For example, the target air conditioner includes an upper-section first air deflector, a middle-section first air deflector and a lower-section first air deflector, where the first air deflector may be a left air deflector and a right air deflector, and when the target-section air deflector is an upper-section left air deflector and a right air deflector, that is, the upper-section left air deflector and the lower-section left air deflector are in an open state, it is determined that the current air supply mode is a middle-lower non-wind-sensation mode (that is, air is supplied to an upper area in a room; when the target section air deflector is a middle section left air deflector and a middle section right air deflector, determining that the current air supply mode is an up-down non-air-sense mode; when the target section air deflector is a lower section left air deflector and a lower section right air deflector, determining that the current air supply mode is an upper-middle non-wind-sense mode; when the target air deflector is an upper left air deflector, a lower left air deflector and a middle left air deflector, determining that the current air supply mode is a no-wind-sense mode; when the target section air deflectors are an upper section left air deflector, a lower section left air deflector and a lower section right air deflector, determining that the current air supply mode is a medium-no-wind-sense mode; when the target section air deflectors are a middle section left air deflector, a middle section right air deflector and a lower section left air deflector, determining that the current air supply mode is an upper non-wind-sensing mode; and when the target section air deflectors are an upper section left air deflector, a lower section left air deflector, a middle section right air deflector and a lower section left air deflector, determining that the current air supply mode is a full no-wind-sensation mode. The height of the air supply area is determined based on the position height of the target section air deflector in the opening state, so that the current air supply mode corresponding to the target air conditioner can be accurately determined, and the accuracy of determining the current running state of the target air conditioner is improved.

In another embodiment, when the target section air deflectors are in a closed state, determining the height of the non-wind-sensing area of the target air conditioner based on the positions of the target section air deflectors; and determining the current air supply mode of the target air conditioner based on the height of the no-wind-sense area. The target air conditioner can comprise an upper section first air deflector, a middle section first air deflector and a lower section first air deflector, wherein the first air deflector can be a left air deflector and a right air deflector; when the target section air deflector is a middle section left air deflector and a middle section right air deflector, determining that the current air supply mode is a middle non-wind-sense mode; when the target section air deflector is a lower section left air deflector and a lower section right air deflector, determining that the current air supply mode is a no-wind-sense mode; when the target air deflector is an upper left air deflector, a lower air deflector and a middle left air deflector, determining that the current air supply mode is an upper middle non-wind sensation mode; when the target section air deflectors are an upper section left air deflector, a lower section left air deflector and a lower section right air deflector, determining that the current air supply mode is an upper and lower non-wind-sensing mode; when the target section air deflectors are a middle section left air deflector, a middle section right air deflector and a lower section left air deflector, determining that the current air supply mode is a middle-lower non-wind-sensation mode; and when the target section air deflectors are an upper section left air deflector, a lower section left air deflector, a middle section right air deflector and a lower section left air deflector, determining that the current air supply mode is a full no-wind-sensation mode.

In another specific embodiment, the target air conditioner includes an upper first air deflector, a middle first air deflector, and a lower first air deflector, and when the upper first air deflector is in a closed state and both the middle first air deflector and the lower first air deflector are in an open state, it is determined that the current air supply mode is an upper non-induction mode.

And when the middle section first air deflector is in a closed state and the upper section first air deflector and the lower section first air deflector are both in an open state, determining that the current air supply mode of the target air conditioner is a medium-sized no-wind-sense mode.

And when the lower section first air deflector is in a closed state and the upper section first air deflector and the middle section air deflector are both in an open state, determining that the current air supply mode of the target air conditioner is a no-wind-sense mode.

And when the upper section first air deflector and the lower section first air deflector are both in a closed state and the middle section first air deflector is in an open state, determining that the current air supply mode of the target air conditioner is an up-down non-air-sense mode.

And when the middle section first air deflector and the lower section first air deflector are both in a closed state and the upper section first air deflector is in an open state, determining that the current air supply mode of the target air conditioner is a middle-lower no-wind-sense mode.

And when the upper section first air deflector and the middle section first air deflector are both in a closed state and the lower section first air deflector is in an open state, determining that the current air supply mode of the target air conditioner is an upper-middle non-air-sense mode.

And when the upper section first air deflector, the middle section first air deflector and the lower section first air deflector are all in a closed state, determining that the current air supply mode of the target air conditioner is a full no-wind-sensation mode.

And when the upper section first air deflector, the middle section first air deflector and the lower section first air deflector are all in an open state, determining that the current air supply mode of the target air conditioner is a conventional full-open air supply mode. Eight air supply modes of the target air conditioner can be accurately detected by detecting the running states of the upper section first air deflector, the middle section first air deflector and the lower section first air deflector of the target air conditioner, and the detection precision of the air supply modes is improved.

In order to automatically adjust the upper and lower air supply angles of the second air deflectors according to different air supply modes, the present embodiment provides a specific implementation manner that the air supply angles of the second air deflectors are respectively controlled based on the current air supply mode: and controlling the connecting rods of the second air deflectors to adjust the pitch angles of the blades based on the current air supply mode so as to avoid the non-wind-sensing area corresponding to the current air supply mode for air supply. Based on the current air supply mode, the motor connected with the connecting rod of each second air deflector controls the connecting rod to move up and down so as to adjust the pitch angle of the blades on each second air deflector, the upper and lower air supply angles of the second air deflectors change along with the change of the pitch angle of the blades, and the upper and lower air outlet angles of the second air deflectors of each part of the target air conditioner can be respectively controlled by controlling the pitch angles of the blades of each part of the second air deflectors, so that segmented air supply is more accurate.

In practical applications, the number of the segments of the second air guiding plate in the target air conditioner may be determined according to the number of the segments of the first air guiding plate, for example, when the target air conditioner includes an upper segment first air guiding plate, a middle segment first air guiding plate and a lower segment first air guiding plate, the second air guiding plate may include two portions of the second air guiding plate (an upper portion second air guiding plate and a lower portion second air guiding plate) or three portions of the second air guiding plate (an upper portion second air guiding plate, a middle portion second air guiding plate and a lower portion second air guiding plate).

In a specific embodiment, referring to the schematic view of the air deflector structure shown in fig. 2, the target air conditioner includes an upper second air deflector 21 and a lower second air deflector 22, and further includes an upper first air deflector 23, a middle first air deflector 24 and a lower first air deflector 25. The upper second air guiding plate 21 is aligned with the upper half parts of the upper first air guiding plate 23 and the middle first air guiding plate 24 in the height direction, and the upper second air guiding plate 21 can control the upper and lower air outlet angles in the area range (the upper half part height range of the upper first air guiding plate 32 and the middle first air guiding plate 24); the lower portion second air guiding plate 22 is aligned with the lower portion of the middle portion first air guiding plate 24 and the lower portion first air guiding plate 25 in the height direction, and the lower portion second air guiding plate 22 can control the upper and lower air outlet angles in the area range (the height range of the lower portion of the middle portion first air guiding plate 24 and the lower portion first air guiding plate 25).

The current air supply mode includes: the air supply system comprises an upper non-wind-sensing mode, a middle non-wind-sensing mode, a lower non-wind-sensing mode, an upper non-wind-sensing mode, a middle non-wind-sensing mode, a full non-wind-sensing mode and a normal full-open air supply mode. When the air blowing angles of the second air guide plates are respectively controlled based on the current air blowing mode, the control can be carried out according to the following embodiments:

and when the current air supply mode is the upper non-air-sensing mode, controlling the pitch angle of the blades of the upper second air deflector to be a first angle, and controlling the pitch angle of the blades of the lower second air deflector to be a second angle. The first angle is smaller than or equal to the second angle, and the air outlet angle of the upper second air deflector is controlled to be a smaller first angle (the value range of the first angle is-15 degrees to +15 degrees), so that the air outlet sinking of the air conditioner during refrigeration can be avoided to a certain extent, and the upper non-wind-sensing mode of the target air conditioner can be strengthened.

And when the current air supply mode is the medium no-wind-sensation mode, controlling the pitch angle of the blades of the upper second air deflector to be a third angle, and controlling the pitch angle of the blades of the lower second air deflector to be a first angle X1. The third angle is larger than the first angle, and the air outlet angle of the upper second air deflector is controlled to be a larger third angle (the value range of the third angle is 30-60 degrees), so that the air outlet height of the target air conditioner can be increased, the air outlet quantity of the upper first air deflector is increased, and the medium no-wind mode of the target air conditioner is strengthened.

And when the current air supply mode is the lower non-air-sensitive mode, controlling the pitch angle of the blades of the upper second air deflector and the lower second air deflector to be a third angle. The air outlet angles of the upper second air deflector and the lower second air deflector are controlled to be larger than a third angle, so that the air outlet height of the target air conditioner is higher than that of the lower first air deflector, and the lower non-wind-sensing mode of the target air conditioner is strengthened.

And when the current air supply mode is the vertical non-wind-sensing mode, controlling the pitch angle of the blades of the upper second air deflector to be a fourth angle, and controlling the pitch angle of the blades of the lower second air deflector to be a first angle. Wherein the fourth angle is greater than or equal to the first angle.

And when the current air supply mode is a middle-lower no-wind-feeling mode, controlling the pitch angle of the blades of the upper second air deflector to be a first angle, and controlling the pitch angle of the blades of the lower second air deflector to be a fourth angle.

And when the current air supply mode is the upper-middle non-air-sense mode, controlling the pitch angle of the blades of the upper second air deflector to be a third angle and controlling the pitch angle of the blades of the lower second air deflector to be a fourth angle.

And when the current air supply mode is the full no-wind-sensation mode, controlling the pitch angle of the blades of the upper second air deflector and the pitch angle of the blades of the lower second air deflector to be a fourth angle.

And when the current air supply mode is the normal full-open air supply mode, controlling the pitch angle of the blades of the upper second air deflector and the pitch angle of the blades of the lower second air deflector to be a second angle. Wherein the third angle is larger than or equal to the fourth angle and larger than or equal to the first angle. The value range of the third angle is 30 degrees to 60 degrees, the value range of the fourth angle is 15 degrees to 45 degrees, the value range of the second angle is 0 degrees to 30 degrees, and the value range of the first angle is-15 degrees to +15 degrees. Under the different modes of the target air conditioner, the blades on the second air guide plates are controlled to be at different pitch angles, so that the air supply mode is more accurate while the air outlet is effectively prevented from sinking, the non-inductive mode of each segmented first air guide plate is strengthened, and the comfort of a user is improved.

According to the air conditioner segmented air supply control method provided by the embodiment, the second air deflector of the target air conditioner is divided into the upper part and the lower part, so that the upper and lower air outlet angles of the two parts of second air deflectors can be respectively controlled, the air supply mode of the target air conditioner is matched, and the comfort of a required air supply area and a no-wind-sensing area is improved.

Example two:

corresponding to the air conditioner sectional air supply control method provided by the first embodiment, the embodiment of the present invention provides an example of controlling a target air conditioner by using the air conditioner sectional air supply control method, where the target air conditioner is a dual-vertical-air-deflector sectional air supply air conditioner, and the following steps 1 to 2 may be specifically referred to:

step 1: and when the target air conditioner operates in a refrigerating mode, detecting the current air supply mode of the left air deflector and the right air deflector of the target air conditioner in real time.

The target air conditioner comprises an upper section left air deflector, a lower section left air deflector, a middle section right air deflector and a lower section left air deflector, referring to the structural schematic diagram of the left air deflector and the right air deflector as shown in fig. 3, a plurality of air outlet micropores 31 are uniformly arranged on the left air deflector and the right air deflector, when the left air deflector and the right air deflector are closed, an air outlet can blow out from micropores on the air deflectors at a low speed, and air outlet without a wind sensing function is realized. The upper section left and right air deflectors, the middle section left and right air deflectors and the lower section left and right air deflectors are respectively controlled by an upper motor, a middle motor and a lower motor, and each section of left and right air deflectors can be independently closed and opened.

The left and right air deflectors of the target air conditioner can realize eight air supply modes (air outlet modes) by controlling the closing and opening of the left and right air deflectors of three sections of the target air conditioner:

the method comprises the following steps: the upper section left and right air deflectors are controlled to be closed, and the middle section left and right air deflectors and the lower section left and right air deflectors are controlled to be opened.

The no wind sense mode: the left and right air deflectors of the middle section are controlled to be closed, and the left and right air deflectors of the upper section and the left and right air deflectors of the lower section are controlled to be opened.

③ the mode without wind sense: the lower section left air deflector and the lower section right air deflector are controlled to be closed, and the upper section left air deflector and the middle section left air deflector are controlled to be opened.

Fourthly, upper and lower no wind feeling modes: the upper section left and right air deflectors and the lower section left and right air deflectors are controlled to be closed, and the middle section left and right air deflectors are controlled to be opened.

Middle and lower no wind feeling mode: the left and right air deflectors of the middle section and the left and right air deflectors of the lower section are controlled to be closed, and the left and right air deflectors of the upper section are controlled to be opened.

Sixthly, a middle-upper non-wind feeling mode: the upper section left and right air deflectors and the middle section left and right air deflectors are controlled to be closed, and the lower section left and right air deflectors are controlled to be opened.

No wind feeling mode: and controlling the upper section left and right air deflectors, the middle section left and right air deflectors and the lower section left and right air deflectors to be closed.

B, a conventional full-open mode: and controlling the upper section left and right air deflectors, the middle section left and right air deflectors and the lower section left and right air deflectors to be opened.

Step 2: and respectively controlling the upper and lower air guide angles of the upper vertical air guide plate and the lower vertical air guide plate according to the current air supply modes of the left and right air guide plates.

The target air conditioner includes an upper vertical air guide plate and a lower vertical air guide plate. Referring to the schematic diagram of the vertical air guiding plate structure shown in fig. 4, the vertical air guiding plate includes a connecting rod 41 and a plurality of blades 42, the connecting rod 41 is connected to a motor (not shown in the figure), the connecting rod 41 is controlled by the motor to move up and down, the pitch angle of the blades can be adjusted, and when the blades deflect upwards, the pitch angle of the blades is positive X °; the blade pitch angle is negative Y ° when the blade is deflected downwards.

When the segmented air supply mode is the upper non-air-feeling mode, executing the step a; when the segmented air supply mode is a medium-sized no-wind-feeling mode, executing the step b; when the segmented air supply mode is a lower non-wind-sensing mode, executing the step c; when the segmented air supply mode is the upper-middle non-wind-feeling mode, executing the step d; when the segmented air supply mode is the upper and lower non-wind-feeling mode, executing according to the step e; when the segmented air supply mode is a middle-lower non-wind-sensing mode, executing the step f; when the segmented air supply mode is the full no-wind-feeling mode, executing according to the step g; and when the segmented air supply mode is the normal full-open mode, executing according to the step h.

Step a: controlling the blade of the upper vertical air deflector to be adjusted to the middle position X0 degrees; the vanes controlling the lower vertical air deflector are adjusted to deflect upwards by X1 °.

Step b: controlling the blades of the upper vertical air deflector to deflect upwards by X3 degrees; the vanes controlling the lower vertical air deflector are adjusted to the middle position X0 °.

Step c: controlling the blades of the upper vertical air deflector to deflect upwards by X3 degrees; the vanes controlling the lower vertical air deflector are adjusted to deflect upwards by X3 °.

Step d: controlling the blades of the upper vertical air deflector to deflect upwards by X2 degrees; the vanes controlling the lower vertical air deflector are adjusted to the middle position X0 °.

Step e: controlling the blade of the upper vertical air deflector to be adjusted to the middle position X0 degrees; the vanes controlling the lower vertical air deflector are adjusted to deflect upwards by X2 °.

Step f: controlling the blades of the upper vertical air deflector to deflect upwards by X3 degrees; the vanes controlling the lower vertical air deflector are adjusted to deflect upwards by X2 °.

Step g: controlling the blades of the upper vertical air deflector to deflect upwards by X2 degrees; the vanes controlling the lower vertical air deflector are adjusted to deflect upwards by X2 °.

Step h: controlling the blades of the upper vertical air deflector to deflect upwards by X1 degrees; the blades of the lower vertical air deflector are controlled to be adjusted to deflect upwards by X1 DEG

Wherein X3 is not less than X2 is not less than X1 is not less than X0, wherein the value range of X3 is 30-60 degrees, the value range of X2 is 15-45 degrees, the value range of X1 is 0-30 degrees, and the value range of X0 is-15 degrees.

According to the segmented air supply method, the angles of the upper vertical air guide plates and the lower vertical air guide plates are automatically adjusted according to the air supply modes of the left air guide plates and the right air guide plates of each segment, segmented air supply is more accurate, the air speed in the height layer area requiring air supply is high, the air supply distance is long, the air speed in the height layer area requiring no wind sensation is low, and the air supply method is in a no-wind-sensation state, so that the user experience is improved.

Example three:

corresponding to the air conditioner sectional air supply control method provided by the first embodiment, the embodiment of the invention provides an air conditioner sectional air supply control device, which can be applied to a target air conditioner, wherein the target air conditioner comprises a plurality of sections of first air deflectors and a plurality of sections of second air deflectors; referring to the schematic structural diagram of the segmented air supply control device of the air conditioner shown in fig. 5, the device comprises the following modules:

and the determining module 51 is used for determining the current air supply mode of the target air conditioner based on the operation state of each first air deflector.

And the control module 52 is configured to control the air supply angles of the second air deflectors respectively based on the current air supply mode.

The above-mentioned air conditioner segmentation air supply control device that this embodiment provided controls respectively through the current air supply mode who acquires first aviation baffle to the upper and lower air supply angle of each part second aviation baffle according to the current air supply mode of target air conditioner, so that the air-out height that makes the segmentation air supply is more accurate, has promoted the segmentation air supply effect of air conditioner, and then has promoted user's travelling comfort.

In one embodiment, the operational state includes an open state and a closed state; the determining module 51 is further configured to obtain a target-section air deflector in a closed state or an open state from each first air deflector; and determining the current air supply mode of the target air conditioner based on the number and the positions of the target air deflectors.

In an embodiment, the determining module 51 is further configured to determine a height of an air supply area of the target air conditioner based on a position of each target-section air deflector when the target-section air deflector is in an open state; a current air supply mode of the target air conditioner is determined based on the air supply zone height.

In an embodiment, the determining module 51 is further configured to determine the height of the non-wind-sensing area of the target air conditioner based on the position of each target air deflector when the target air deflector is in the closed state; and determining the current air supply mode of the target air conditioner based on the height of the no-wind-sense area.

In one embodiment, the second air guiding plate comprises a connecting rod and a plurality of blades, and the blades are perpendicular to the connecting rod; the control module 52 is further configured to control the connecting rods of the second air deflectors to adjust the pitch angles of the blades based on the current air supply mode, so as to avoid the height of the non-wind-sensing area corresponding to the current air supply mode for air supply.

In one embodiment, the target air conditioner further includes an upper second air guiding plate and a lower second air guiding plate, and the current blowing mode includes: an upper no-wind-sense mode, a middle no-wind-sense mode, a lower no-wind-sense mode, an upper no-wind-sense mode, a middle no-wind-sense mode, a full no-wind-sense mode and a conventional full-open air supply mode; the control module 52 is further configured to control the pitch angle of the blades of the upper second air guiding plate to be a first angle and control the pitch angle of the blades of the lower second air guiding plate to be a second angle when the current air supply mode is the upper no-wind-sensation mode;

when the current air supply mode is a medium-sized non-air-sensing mode, controlling the pitch angle of the blades of the upper second air deflector to be a third angle and controlling the pitch angle of the blades of the lower second air deflector to be a first angle;

when the current air supply mode is a no-wind-sense mode, controlling the pitch angles of the blades of the upper second air deflector and the lower second air deflector to be a third angle;

when the current air supply mode is an up-down non-wind-sensing mode, controlling the pitch angle of the blades of the upper second air deflector to be a fourth angle, and controlling the pitch angle of the blades of the lower second air deflector to be a first angle;

when the current air supply mode is a middle-lower no-wind-feeling mode, controlling the pitch angle of the blades of the upper second air deflector to be a first angle and controlling the pitch angle of the blades of the lower second air deflector to be a fourth angle;

when the current air supply mode is an upper-middle non-wind-sensing mode, controlling the pitch angle of the blades of the upper second air deflector to be a third angle and controlling the pitch angle of the blades of the lower second air deflector to be a fourth angle;

when the current air supply mode is a full no-wind-sensation mode, controlling the pitch angle of the blades of the upper second air deflector and the pitch angle of the blades of the lower second air deflector to be a fourth angle;

when the current air supply mode is the conventional full-open air supply mode, controlling the pitch angle of the blades of the upper second air deflector and the pitch angle of the blades of the lower second air deflector to be a second angle; wherein the third angle is larger than or equal to the fourth angle and larger than or equal to the first angle.

In one embodiment, the third angle ranges from 30 ° to 60 °, the fourth angle ranges from 15 ° to 45 °, the second angle ranges from 0 ° to 30 °, and the first angle ranges from-15 ° to +15 °.

According to the air conditioner segmented air supply control device provided by the embodiment, the second air deflector of the target air conditioner is divided into the upper part and the lower part, so that the upper air outlet angle and the lower air outlet angle of the two parts of the second air deflectors can be respectively controlled, the air supply mode of the target air conditioner is matched, and the comfort of a required air supply area and a no-wind-sensing area is improved.

Example four:

corresponding to the air conditioner sectional air supply control method provided by the first embodiment, the present embodiment provides an air conditioner, including: the air conditioner comprises a plurality of sections of first air deflectors, a plurality of sections of second air deflectors, a computer readable storage medium and a processor, wherein the computer readable storage medium is used for storing a computer program, air outlet micropores are formed in the first air deflectors, and the computer program is read by the processor and runs to realize the air conditioner sectional air supply control method provided by the first embodiment. The first air guiding plate may be a left air guiding plate and a right air guiding plate, and the second air guiding plate may be an upper air guiding plate and a lower air guiding plate.

Example five:

the present embodiment further provides a computer-readable storage medium, where a computer program is stored on the computer-readable storage medium, and when the computer program is executed by a processor, the computer program implements each process of the above-mentioned air-conditioning segmented air supply control method embodiment, and can achieve the same technical effect, and in order to avoid repetition, details are not repeated here. The computer-readable storage medium may be a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk.

Of course, those skilled in the art will understand that all or part of the processes in the methods of the above embodiments may be implemented by instructing the control device to perform operations through a computer, and the programs may be stored in a computer-readable storage medium, and when executed, the programs may include the processes of the above method embodiments, where the storage medium may be a memory, a magnetic disk, an optical disk, and the like.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Finally, it should also be noted that, 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 necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The embodiments in the present description 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. The sectional air supply control device and the air conditioner disclosed by the embodiment correspond to the sectional air supply control method disclosed by the embodiment, so that the description is relatively simple, and relevant parts can be referred to the description of the method part.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (10)

1. The method is characterized by being applied to a target air conditioner, wherein the target air conditioner comprises a plurality of sections of first air deflectors and a plurality of sections of second air deflectors; the method comprises the following steps:

determining a current air supply mode of the target air conditioner based on the operation state of each first air deflector;

and respectively controlling the upper and lower air supply angles of each second air deflector based on the current air supply mode.

2. The method of controlling a zoned air supply of an air conditioner according to claim 1, wherein the operation state includes an on state and an off state; the step of determining the current air supply mode of the target air conditioner based on the operation state of each first air deflector comprises the following steps:

acquiring a target section air deflector in the closed state or the open state from each first air deflector;

and determining the current air supply mode of the target air conditioner based on the number and the positions of the target air deflectors.

3. The method of controlling segmented air supply of an air conditioner according to claim 2, wherein the step of determining the current air supply mode of the target air conditioner based on the number and the position of the target air deflectors comprises:

when the target air deflector is in an open state, determining the height of an air supply area of the target air conditioner based on the position of each target air deflector;

and determining the current air supply mode of the target air conditioner based on the height of the air supply area.

4. The method of controlling segmented air supply of an air conditioner according to claim 2, wherein the step of determining the current air supply mode of the target air conditioner based on the number and the position of the target air deflectors comprises:

when the target air deflector is in a closed state, determining the height of the non-wind-sensing area of the target air conditioner based on the position of each target air deflector;

and determining the current air supply mode of the target air conditioner based on the height of the no-wind-feeling area.

5. The method of controlling the sectioned air supply of the air conditioner according to claim 1, wherein the second air deflector comprises a connecting rod and a plurality of blades, and the blades are perpendicular to the connecting rod;

the step of controlling the upper and lower air supply angles of each second air deflector based on the current air supply mode comprises the following steps:

and controlling the connecting rods of the second air deflectors to adjust the pitch angles of the blades based on the current air supply mode so as to avoid the height of the non-wind-sensing area corresponding to the current air supply mode for air supply.

6. The method of controlling segmented blowing of an air conditioner according to claim 1, wherein the target air conditioner includes an upper first air deflector, a middle first air deflector, and a lower first air deflector, the target air conditioner further includes an upper second air deflector and a lower second air deflector, and the current blowing mode includes: an upper no-wind-sense mode, a middle no-wind-sense mode, a lower no-wind-sense mode, an upper no-wind-sense mode, a middle no-wind-sense mode, a full no-wind-sense mode and a conventional full-open air supply mode;

the step of controlling the upper and lower air supply angles of each second air deflector based on the current air supply mode comprises the following steps:

when the current air supply mode is the upper non-air-sense mode, controlling the pitch angle of the blades of the upper second air deflector to be a first angle, and controlling the pitch angle of the blades of the lower second air deflector to be a second angle;

when the current air supply mode is the medium-sized no-wind-sensation mode, controlling the pitch angle of the blades of the upper second air deflector to be a third angle, and controlling the pitch angle of the blades of the lower second air deflector to be a first angle;

when the current air supply mode is the lower no-wind-sensation mode, controlling the pitch angles of the blades of the upper second air deflector and the lower second air deflector to be a third angle;

when the current air supply mode is the vertical non-wind-sensing mode, controlling the pitch angle of the blades of the upper second air deflector to be a fourth angle, and controlling the pitch angle of the blades of the lower second air deflector to be a first angle;

when the current air supply mode is the middle-lower no-wind-sensation mode, controlling the pitch angle of the blades of the upper second air deflector to be a first angle, and controlling the pitch angle of the blades of the lower second air deflector to be a fourth angle;

when the current air supply mode is the upper-middle non-wind-sensing mode, controlling the pitch angle of the blades of the upper second air deflector to be a third angle and controlling the pitch angle of the blades of the lower second air deflector to be a fourth angle;

when the current air supply mode is the full no-wind-sensation mode, controlling the pitch angle of the blades of the upper second air deflector and the pitch angle of the blades of the lower second air deflector to be a fourth angle;

when the current air supply mode is the conventional full-open air supply mode, controlling the pitch angle of the blades of the upper second air deflector and the pitch angle of the blades of the lower second air deflector to be the second angle; wherein the third angle is larger than or equal to the fourth angle and larger than or equal to the first angle.

7. The method as claimed in claim 6, wherein the third angle ranges from 30 ° to 60 °, the fourth angle ranges from 15 ° to 45 °, the second angle ranges from 0 ° to 30 °, and the first angle ranges from-15 ° to +15 °.

8. The sectional air supply control device of the air conditioner is characterized by being applied to a target air conditioner, wherein the target air conditioner comprises a plurality of sections of first air deflectors and a plurality of sections of second air deflectors; the device comprises:

the determining module is used for determining the current air supply mode of the target air conditioner based on each first air deflector;

and the control module is used for respectively controlling the air supply angle of each second air deflector based on the current air supply mode.

9. An air conditioner, comprising: the multi-section first air deflector, the multi-section second air deflector, and the computer-readable storage medium and the processor storing the computer program, wherein the air outlet micro-holes are arranged on the first air deflector, and the computer program is read and executed by the processor to realize the method according to any one of claims 1 to 7.

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

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