Air conditioner partition air supply control method and device, air conditioner, storage medium, program product and chip system

By using a zoned air supply control method, user location information is obtained and an air supply strategy is generated. The air supply angles of the left and right air supply zones are controlled separately, which solves the problem of poor air supply accuracy and achieves precise air supply and improved energy efficiency.

CN122237149APending Publication Date: 2026-06-19XIAOMI TECH (WUHAN) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
XIAOMI TECH (WUHAN) CO LTD
Filing Date
2026-05-13
Publication Date
2026-06-19

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Abstract

This disclosure relates to a method, apparatus, air conditioner, storage medium, program product, and chip system for air conditioning zoned air supply control, belonging to the field of air conditioning technology. The air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right areas, respectively. The method involves acquiring the user's location information in the left and right areas; generating an air conditioning air supply strategy based on the user's location information; and controlling the air supply angles of the left and right air supply zones according to the air supply strategy. This achieves precise air supply to different areas by acquiring user location information and independently controlling the air supply angles of the left and right air supply zones, avoiding energy waste caused by supplying air to unoccupied areas, and improving the comfort and energy efficiency of air conditioning. It also solves the problem of poor accuracy in supplying air to different areas in related technologies.
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Description

Technical Field

[0001] This disclosure relates to the field of air conditioning technology, and in particular to an air conditioning zoned air supply control method, device, air conditioner, storage medium, program product and chip system. Background Technology

[0002] In related technologies, the air conditioning's air delivery angle uses an overall adjustment or fixed mode, which cannot be adjusted differently according to the user's position relative to the left or right side of the air conditioner, resulting in poor accuracy in delivering air to different areas. Summary of the Invention

[0003] To overcome the problems existing in related technologies, this disclosure provides an air conditioning zone air supply control method, device, air conditioner, storage medium, program product and chip system.

[0004] According to a first aspect of the present disclosure, an air conditioning zone air supply control method is provided. The air conditioner has a left air supply zone and a right air supply zone, the left air supply zone and the right air supply zone being used to independently supply air to a left area and a right area, respectively. The method includes: acquiring user location information of a target user in the left area and the right area; generating an air conditioning air supply strategy based on the user location information; and controlling the air supply angle of the left air supply zone and the right air supply zone respectively according to the air conditioning air supply strategy.

[0005] In the above embodiments, the air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right areas, respectively. The system obtains the user's location information in the left and right areas; generates an air supply strategy based on the user's location information; and controls the air supply angles of the left and right air supply zones according to the air supply strategy. This achieves precise air supply to different areas by obtaining user location information and independently controlling the air supply angles of the left and right air supply zones, avoiding energy waste caused by supplying air to unoccupied areas, improving the comfort and energy efficiency of the air conditioner, and solving the problem of poor accuracy in supplying air to different areas in related technologies.

[0006] In one possible implementation, generating an air conditioning air supply strategy based on the user location information includes: in response to the user location information, determining that the target user is only in the left-side area, and generating a left-side air supply strategy for the air conditioner; or, in response to the user location information, determining that the target user is only in the right-side area, and generating a right-side air supply strategy for the air conditioner; or, in response to the user location information, determining that the target user is in both the left-side and right-side areas, and generating a left-right side air supply strategy for the air conditioner; wherein the left-right side air supply strategy is the left-side air supply strategy and the right-side air supply strategy; and determining the left-side air supply strategy, or the right-side air supply strategy, or the left-right side air supply strategy as the air conditioning air supply strategy.

[0007] In the above embodiments, based on the distribution of target users in different areas, a single left-side air supply strategy, a right-side air supply strategy, or a combination of left and right-side air supply strategies are dynamically selected. This achieves targeted air supply to the areas where target users are located, optimizes air supply efficiency and effect, and avoids air supply to uninhabited areas.

[0008] In one possible implementation, a middle region is determined from the left region and the right region; wherein the center line of the middle region is the boundary line between the left region and the right region; the step of generating an air conditioning air supply strategy based on the user location information includes: in response to the user location information, determining that the target user is in the middle region, generating a middle air supply strategy for the air conditioner; and determining the middle air supply strategy as the air conditioning air supply strategy.

[0009] In the above embodiments, by identifying the middle area where the user is located near the boundary line between the left and right areas and generating a corresponding middle air supply strategy, the problem of uneven air supply caused by only supplying air to one side when the user is in the middle position is solved, and the comfort of air conditioning supply when the user is in the center of the room is improved.

[0010] In one possible implementation, the left air supply zone includes an upper left air supply zone and a lower left air supply zone; wherein, the upper left air supply zone is provided with an upper left horizontal air guide plate, the lower left air supply zone is provided with a lower left horizontal air guide plate, and the left air supply zone is provided with a left vertical air guide plate; the right air supply zone includes an upper right air supply zone and a lower right air supply zone; wherein, the upper right air supply zone is provided with an upper right horizontal air guide plate, the lower right air supply zone is provided with a lower right horizontal air guide plate, and the right air supply zone is provided with a right vertical air guide plate; the air conditioning air supply strategy is used to indicate the rotation angle of the upper left horizontal air guide plate, the rotation angle of the lower left horizontal air guide plate, the deflection angle of the left vertical air guide plate, the rotation angle of the upper right horizontal air guide plate, the rotation angle of the lower right horizontal air guide plate, and the deflection angle of the right vertical air guide plate when supplying air to the area where the target user is located.

[0011] In the above embodiments, by further subdividing the left and right air supply zones into upper and lower sub-regions and setting horizontal and vertical air guide plates, fine control of the air supply direction and distance is achieved, enabling more precise air supply adjustment according to the user's specific location (such as distance or height).

[0012] In one possible implementation, the left-side region includes at least a left-side region at a first distance, a left-side region at a second distance, and a left-side region at a third distance, wherein the first distance is less than the second distance, and the second distance is less than the third distance; the step of determining, in response to the user location information, that the target user is only in the left-side region and generating a left-side air supply strategy for the air conditioner includes: in response to the user location information, determining that the target user is in the left-side region at the first distance and the left-side region at the second distance, and generating a first left-side air supply strategy for the air conditioner; wherein the first left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left-side region at the first distance, the upper left air supply area to supply air to the left-side region at the second distance, the rotation angle of the lower left horizontal air guide plate is a first left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is a second left-side rotation angle, the first left-side rotation angle is less than the second left-side rotation angle, and the deflection angle of the left vertical air guide plate is a first left-side deflection angle; and the first left-side air supply strategy is determined as the left-side air supply strategy.

[0013] In the above embodiments, based on the distribution of target users in the left-side area at different distances, the different angles of the air guide plates in the upper and lower air supply areas are used to achieve layered air supply to the near and middle areas, avoiding the problem of excessively cold near areas or no air in the middle areas caused by air supply at a single angle, thus improving the uniformity and comfort of air supply.

[0014] In one possible implementation, the step of determining that the target user is only in the left-side region in response to the user location information and generating a left-side air supply strategy for the air conditioner includes: determining that the target user is in the left-side region of a first distance and the left-side region of a third distance in response to the user location information, and generating a second left-side air supply strategy for the air conditioner; wherein the second left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left-side region of the first distance, the upper left air supply area to supply air to the left-side region of the third distance, the rotation angle of the lower left horizontal air guide plate is a third left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is a fourth left-side rotation angle, the third left-side rotation angle is less than the fourth left-side rotation angle, and the deflection angle of the left vertical air guide plate is a second left-side deflection angle; and the second left-side air supply strategy is determined as the left-side air supply strategy.

[0015] In the above embodiments, when the target user appears in both the near and far zones, the angle of the air guide plate in the upper left air supply zone is adjusted so that it is specifically responsible for long-distance air supply, thus achieving coverage of a large area and ensuring the air supply effect for users in the far zone. This achieves layered air supply for the near and far zones, avoiding the problem of excessively cold near zones or no air supply in the far zones caused by single-angle air supply, and improving the uniformity, comfort, and coverage of the air supply.

[0016] In one possible implementation, the step of determining that the target user is only in the left-side region in response to the user location information and generating a left-side air supply strategy for the air conditioner includes: determining that the target user is in the left-side region of the second distance and the left-side region of the third distance in response to the user location information, and generating a third left-side air supply strategy for the air conditioner; wherein the third left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left-side region of the second distance, the upper left air supply area to supply air to the left-side region of the third distance, the rotation angle of the lower left horizontal air guide plate is a fifth left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is a sixth left-side rotation angle, the fifth left-side rotation angle is less than the sixth left-side rotation angle, and the deflection angle of the left vertical air guide plate is a third left-side deflection angle; and the third left-side air supply strategy is determined as the left-side air supply strategy.

[0017] In the above embodiments, when the user is located in the middle zone and the far zone, by adjusting the different air guide plate angles of the upper and lower air supply zones, layered air supply to the middle zone and the far zone is achieved, that is, air supply coverage of the middle and far distance areas is achieved, avoiding the waste of resources caused by supplying air to the near zone when there is no one in the near zone.

[0018] In one possible implementation, the step of determining that the target user is only in the left-side region in response to the user location information and generating a left-side air supply strategy for the air conditioner includes: determining that the target user is in the left-side region of the first distance, the left-side region of the second distance, and the left-side region of the third distance in response to the user location information, and generating a fourth left-side air supply strategy for the air conditioner; wherein the fourth left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left-side regions of the first distance and the second distance, the upper left air supply area to supply air to the left-side region of the third distance, the rotation angle of the lower left horizontal air guide plate is a seventh left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is an eighth left-side rotation angle, the seventh left-side rotation angle is less than the eighth left-side rotation angle, and the deflection angle of the left vertical air guide plate is a fourth left-side deflection angle; and the fourth left-side air supply strategy is determined as the left-side air supply strategy.

[0019] In the above embodiment, when the target users are spread throughout the entire left-side area (near, middle, and far areas), by allocating the air supply range of the upper and lower air supply zones, the lower left air supply zone covers the near and middle areas, and the upper left air supply zone covers the far area, thus achieving full coverage of the entire left-side area and ensuring the air supply experience for all target users.

[0020] In one possible implementation, the intermediate region includes an intermediate region of a first distance, an intermediate region of a second distance, and an intermediate region of a third distance, wherein the first distance is smaller than the second distance, and the second distance is smaller than the third distance; the step of determining that the target user is in the intermediate region in response to the user location information and generating an intermediate air supply strategy for the air conditioner includes: determining that the target user is in the intermediate region of the first distance and the intermediate region of the second distance in response to the user location information, generating a first intermediate air supply strategy for the air conditioner; and determining the first intermediate air supply strategy as the intermediate air supply strategy; wherein the first intermediate air supply strategy is used to indicate the lower left air supply area and the lower right air supply area. The air supply zone is used to supply air to the middle area of ​​the first distance, and the upper left air supply zone and the upper right air supply zone are used to supply air to the middle area of ​​the second distance; the rotation angle of the lower left horizontal air guide plate is a first left rotation angle, and the rotation angle of the upper left horizontal air guide plate is a second left rotation angle, wherein the first left rotation angle is smaller than the second left rotation angle; the rotation angle of the lower right horizontal air guide plate is a first right rotation angle, and the rotation angle of the upper right horizontal air guide plate is a second right rotation angle, wherein the first right rotation angle is smaller than the second right rotation angle; the deflection angle of the left vertical air guide plate is a first middle deflection angle; and the deflection angle of the right vertical air guide plate is a second middle deflection angle.

[0021] In the above embodiments, when the target user is located in the near zone and the middle zone of the middle area, the upper and lower air supply zones on the left and right sides work together to achieve concentrated air supply to the middle area, avoiding airflow deflection caused by unilateral air supply and improving the air supply uniformity of the middle area.

[0022] In one possible implementation, the step of determining that the target user is in the intermediate area in response to the user location information and generating an intermediate air supply strategy for the air conditioner includes: determining that the target user is in the intermediate area of ​​the first distance and the intermediate area of ​​the third distance in response to the user location information, and generating a second intermediate air supply strategy for the air conditioner; and determining the second intermediate air supply strategy as the intermediate air supply strategy; wherein the second intermediate air supply strategy is used to instruct the lower left air supply area and the lower right air supply area to supply air to the intermediate area of ​​the first distance, and the upper left air supply area and the upper right air supply area... The zone is used to supply air to the middle area of ​​the third distance; the rotation angle of the lower left horizontal air guide plate is the third left rotation angle, the rotation angle of the upper left horizontal air guide plate is the fourth left rotation angle, and the third left rotation angle is smaller than the fourth left rotation angle; the rotation angle of the lower right horizontal air guide plate is the third right rotation angle, the rotation angle of the upper right horizontal air guide plate is the fourth right rotation angle, and the third right rotation angle is smaller than the fourth right rotation angle; the deflection angle of the left vertical air guide plate is the third middle deflection angle; the deflection angle of the right vertical air guide plate is the fourth middle deflection angle.

[0023] In the above embodiments, when the target user is located in the near and far zones of the central area, the angles of the air guide plates in the upper left and upper right air supply zones on both sides are adjusted to make them specifically responsible for long-distance air supply, and the angles of the air guide plates in the lower left and lower right air supply zones on both sides are adjusted to make them specifically responsible for short-distance air supply. This achieves coverage of the central area with a large span, ensures the air supply effect for users in the far zone, and realizes layered air supply for the near and far zones. It avoids the problem of excessively cold near zone or no air supply in far zone caused by air supply at a single angle, improves the uniformity, comfort and coverage of air supply, and also avoids airflow deflection caused by air supply on one side, thus improving the uniformity of air supply in the central area.

[0024] In one possible implementation, the step of determining that the target user is in the intermediate area in response to the user location information and generating an intermediate air supply strategy for the air conditioner includes: determining that the target user is in the intermediate area of ​​the second distance and the intermediate area of ​​the third distance in response to the user location information, and generating a third intermediate air supply strategy for the air conditioner; and determining the third intermediate air supply strategy as the intermediate air supply strategy; wherein the third intermediate air supply strategy is used to instruct the lower left air supply area and the lower right air supply area to supply air to the intermediate area of ​​the second distance, and the upper left air supply area and the upper right air supply area... The zone is used to supply air to the middle area of ​​the third distance; the rotation angle of the lower left horizontal air guide plate is the fifth left rotation angle, the rotation angle of the upper left horizontal air guide plate is the sixth left rotation angle, and the fifth left rotation angle is smaller than the sixth left rotation angle; the rotation angle of the lower right horizontal air guide plate is the fifth right rotation angle, the rotation angle of the upper right horizontal air guide plate is the sixth right rotation angle, and the fifth right rotation angle is smaller than the sixth right rotation angle; the deflection angle of the left vertical air guide plate is the fifth middle deflection angle; the deflection angle of the right vertical air guide plate is the sixth middle deflection angle.

[0025] In the above embodiments, when the user is located in the middle and far zones of the central area, by adjusting the different angles of the upper and lower air supply plates on the left and right sides, layered air supply to the middle and far zones is achieved, that is, air supply coverage of the middle and far distance areas is achieved, avoiding the waste of resources caused by supplying air to the near zone when no one is in the near zone, and also avoiding airflow deflection caused by unilateral air supply, thus improving the uniformity of air supply in the central area.

[0026] In one possible implementation, the step of determining that the target user is in the intermediate area in response to the user location information and generating an intermediate air supply strategy for the air conditioner includes: determining that the target user is in the intermediate area of ​​the first distance, the intermediate area of ​​the second distance, and the intermediate area of ​​the third distance in response to the user location information, and generating a fourth intermediate air supply strategy for the air conditioner; and determining the fourth intermediate air supply strategy as the intermediate air supply strategy; wherein the fourth intermediate air supply strategy is used to instruct the lower left air supply area and the lower right air supply area to supply air to the intermediate area of ​​the first distance and the intermediate area of ​​the second distance. The upper left and upper right air supply areas are used to supply air to the middle area of ​​the third distance; the rotation angle of the lower left horizontal air guide plate is the seventh left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the eighth left rotation angle, the seventh left rotation angle being smaller than the eighth left rotation angle; the rotation angle of the lower right horizontal air guide plate is the seventh right rotation angle, and the rotation angle of the upper right horizontal air guide plate is the eighth right rotation angle, the seventh right rotation angle being smaller than the eighth right rotation angle; the deflection angle of the left vertical air guide plate is the seventh middle deflection angle; the deflection angle of the right vertical air guide plate is the eighth middle deflection angle.

[0027] In the above embodiments, when the target users are spread throughout the entire intermediate area (near zone, middle zone and far zone), by allocating the air supply range of the upper and lower air supply zones, the lower air supply zone covers the near zone and the middle zone, and the upper air supply zone covers the far zone, thus achieving full coverage of the entire intermediate area and ensuring the air supply experience of all target users in the intermediate area.

[0028] In one possible implementation, ventilation holes are arranged on the left vertical air guide plate; the method further includes: obtaining user type information of the target user; in response to the user type information including youth type information and / or elderly type information, determining that the left vertical air guide plate is in a closed state; and in response to the left vertical air guide plate being in a closed state, updating the left air supply strategy.

[0029] In the above embodiments, by identifying user types, the left vertical air guide plate is closed and the left air supply strategy is updated for sensitive groups such as teenagers and the elderly, thereby achieving windless or gentle air supply and improving the user comfort and health of specific groups.

[0030] In one possible implementation, ventilation holes are arranged on the left vertical air guide plate and ventilation holes are arranged on the right vertical air guide plate; the method further includes: obtaining user type information of the target user; in response to the user type information including youth type information and / or elderly type information, determining that the left vertical air guide plate is in a closed state and the right vertical air guide plate is in a closed state; in response to the left vertical air guide plate being in a closed state and the right vertical air guide plate being in a closed state, updating the intermediate air supply strategy.

[0031] In the above embodiments, when teenage users and / or elderly users are in the middle area, the direct airflow is transformed into a gentle breeze by closing the vertical air guide plates with ventilation holes on both sides, thereby improving the air supply comfort of specific groups.

[0032] According to a second aspect of the present disclosure, an air conditioning zoned air supply control device is provided. The air conditioner has a left air supply zone and a right air supply zone, wherein the left air supply zone and the right air supply zone are respectively used to independently supply air to the left and right sides of the region, including:

[0033] The acquisition module is used to acquire the user location information of the target user in the left and right regions;

[0034] The generation module is used to generate an air conditioning air supply strategy based on the user location information;

[0035] The control module is used to control the air supply angles of the left air supply zone and the right air supply zone respectively according to the air conditioning air supply strategy.

[0036] According to a third aspect of the present disclosure, an air conditioner is provided, comprising: a processor; a memory for storing processor-executable instructions; wherein the processor is configured to execute the air conditioning zone air supply control method described in any of the preceding claims.

[0037] According to a fourth aspect of the present disclosure, a non-transitory computer-readable storage medium is provided, wherein when instructions in the storage medium are executed by a processor of an air conditioner, the air conditioner is enabled to perform an air conditioning zone air supply control method, the air conditioner having a left air supply zone and a right air supply zone, the left air supply zone and the right air supply zone being used to independently supply air to a left area and a right area, respectively, the method comprising: acquiring user location information of a target user in the left area and the right area; generating an air conditioning air supply strategy based on the user location information; and controlling the air supply angle of the left air supply zone and the right air supply zone respectively according to the air conditioning air supply strategy.

[0038] According to a fifth aspect of the present disclosure, a computer program product is provided, comprising: a computer program that, when executed by a processor, implements the air conditioning zone air supply control method described in any of the preceding claims.

[0039] According to a sixth aspect of the present disclosure, a chip system is provided, comprising: a processing unit and an interface circuit, wherein the processing unit obtains program instructions through the interface circuit, the program instructions are executed by the processing unit, and the processing unit is used to execute the air conditioning zone air supply control method described in any of the preceding claims.

[0040] The technical solutions provided by the embodiments of this disclosure can include the following beneficial effects: the air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right areas, respectively; by obtaining the user location information of the target user in the left and right areas; generating an air conditioning air supply strategy based on the user location information; and controlling the air supply angles of the left and right air supply zones respectively according to the air conditioning air supply strategy; thereby achieving precise air supply to different areas by obtaining user location information and independently controlling the air supply angles of the left and right air supply zones, avoiding energy waste caused by supplying air to unoccupied areas, and improving the comfort and energy efficiency of the air conditioning air supply; and solving the problem of poor accuracy in supplying air to different areas in related technologies.

[0041] It should be understood that the above general description and the following detailed description are exemplary and explanatory only, and are not intended to limit this disclosure. Attached Figure Description

[0042] The accompanying drawings, which are incorporated in and form a part of this specification, illustrate embodiments consistent with this disclosure and, together with the description, serve to explain the principles of this disclosure.

[0043] Figure 1 This is a flowchart illustrating an air conditioning zone air supply control method according to some embodiments of the present disclosure.

[0044] Figure 2 This is a schematic diagram illustrating the relative position of a radar sensor and a user according to some embodiments of the present disclosure.

[0045] Figure 3 This is a schematic diagram illustrating the division of room areas according to some embodiments of the present disclosure.

[0046] Figure 4 This is a schematic diagram illustrating the determination of the deflection angle of a vertical air guide plate according to some embodiments of the present disclosure.

[0047] Figure 5 This is a schematic diagram illustrating the deflection angle of a horizontal air guide plate according to some embodiments of the present disclosure.

[0048] Figure 6 This is a block diagram illustrating an air conditioning zone air supply control device according to some embodiments of the present disclosure.

[0049] Figure 7 This is a block diagram illustrating an air conditioner according to some embodiments of the present disclosure.

[0050] Figure 8 This is a block diagram of a chip system according to some embodiments of the present disclosure. Detailed Implementation

[0051] Some embodiments of this disclosure will now be described in detail, examples of which are illustrated in the accompanying drawings. When the following description refers to the drawings, unless otherwise indicated, the same numbers in different drawings denote the same or similar elements. Various changes, modifications, and equivalents of the methods, apparatus, and / or systems described herein will become apparent upon understanding this disclosure. For example, the order of operations described herein is merely illustrative and is not limited to those orders set forth herein, but can be changed as will become apparent upon understanding this disclosure, except for operations that must be performed in a particular order. Furthermore, for clarity and brevity, descriptions of features known in the art may be omitted.

[0052] The technical solutions disclosed herein involve the collection, storage, use, processing, transmission, provision, and disclosure of user personal information and data, all of which comply with relevant laws and regulations and do not violate public order and good morals.

[0053] It should be noted that the user information (including but not limited to user device information, user personal information, etc.) and data (including but not limited to data used for analysis, data stored, data displayed, etc.) involved in this disclosure are all information and data authorized by the user or fully authorized by all parties. Furthermore, the collection, use and processing of the relevant data must comply with the relevant laws, regulations and standards of the relevant regions, and corresponding operation portals are provided for users to choose to authorize or refuse.

[0054] The embodiments described in the following examples of this disclosure are not representative of all embodiments consistent with this disclosure. Rather, they are merely examples of apparatuses and methods consistent with some aspects of this disclosure as detailed in the appended claims.

[0055] Figure 1 This is a flowchart illustrating an air conditioning zone air supply control method according to some embodiments of the present disclosure, such as... Figure 1 As shown, the air conditioning zone air supply control method is used in an air conditioner. The air conditioner has a left air supply zone and a right air supply zone. The left air supply zone and the right air supply zone are used to independently supply air to the left and right areas, respectively, including the following steps.

[0056] In step S11, the user location information of the target user in the left and right regions is obtained.

[0057] In step S12, an air conditioning air supply strategy is generated based on the user's location information.

[0058] In step S13, the air supply angles of the left and right air supply zones are controlled according to the air conditioning air supply strategy.

[0059] For example, the air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right sides of the area, respectively. First, the user's location information in the left and right sides of the area is obtained. The user's location information can be obtained through infrared sensors, and / or cameras, and / or radar sensors installed on the air conditioner. For example, the infrared sensor scans the room to determine the location coordinates of the human body heat source in the left or right side of the area.

[0060] Then, based on the acquired user location information, a corresponding air conditioning air supply strategy is generated. For example, if the user location information indicates that the target user is located in the left area, a strategy is generated to supply air only to the left area; if the target user is located in the right area, a strategy is generated to supply air only to the right area; if the target user is located in both the left and right areas, a strategy is generated to supply air to both areas simultaneously.

[0061] Furthermore, based on the generated air conditioning air supply strategy, the air supply angles of the left and right air supply zones are controlled separately. For example, by controlling the rotation of the air guide motor in the left air supply zone, the air outlet direction of the left air supply zone is directed towards the left side of the area; by controlling the rotation of the air guide motor in the right air supply zone, the air outlet direction of the right air supply zone is directed towards the right side of the area.

[0062] In this embodiment, the air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right sides of the area, respectively. The system obtains the user's location information in the left and right sides of the area. Based on the user's location information, an air supply strategy is generated. According to the air supply strategy, the air supply angles of the left and right air supply zones are controlled respectively. This achieves precise air supply to different areas by obtaining user location information and independently controlling the air supply angles of the left and right air supply zones, avoiding energy waste caused by supplying air to unoccupied areas, improving the comfort and energy efficiency of the air conditioner, and solving the problem of poor accuracy in supplying air to different areas in related technologies.

[0063] In this disclosure, no specific limitations are placed on the form of the air conditioner; it can be an integrated ceiling-mounted air conditioner, a wall-mounted air conditioner, or a column-mounted air conditioner. In this disclosure, the air conditioner can be configured with multiple air supply zones.

[0064] Furthermore, in one possible implementation, the process of obtaining user location information includes:

[0065] Step S111: In response to a preset programmed command, the radar sensor is activated.

[0066] For example, the preset programmed instructions include a sensing start instruction, a timed start instruction, and a device linkage instruction; wherein, the sensing start instruction includes a sensing user start instruction, which is generated by the air conditioner's infrared sensor recognizing the user; the device linkage instruction includes a sensing user body sensation instruction, which is generated by the user's wearable device recognizing the user's sweat, and / or heart rate, and / or body surface temperature, and the wearable device includes a wristband, and / or a watch, and / or headphones; then, after receiving the device linkage instruction sent by the user's wearable device, the air conditioner responds to the device linkage instruction by activating the radar sensor.

[0067] For example, the radar sensor includes a millimeter-wave radar sensor.

[0068] For example, the number of radar sensors is at least two. For instance, if there are two radar sensors, the first radar sensor is located on the left side of the air conditioning vent, and the second radar sensor is located on the right side of the air conditioning vent; that is, multiple radar sensors are symmetrically arranged on both sides of the air conditioning vent. The left and right air supply areas together constitute the air conditioning vent.

[0069] Step S112: Collect user point cloud information using radar sensors.

[0070] For example, user point cloud information includes the number of users within the detection area of ​​the radar sensor, and / or the location coordinates of the user point cloud, and / or the user attitude information, and / or the user signal strength information, and / or the user point cloud area.

[0071] Step S113: Determine the user's location information based on the user's point cloud information.

[0072] Specifically, in step S113, the specific implementation steps for determining the user location information based on the user point cloud information include:

[0073] Step S1131: Based on the user's point cloud position coordinates, determine the horizontal distance and vertical distance between the user and the air conditioner vent, as well as the user's position deflection angle relative to the center point of the air conditioner vent.

[0074] For example, a three-dimensional coordinate system is established with the center point of the air conditioner vent as the origin; the horizontal and vertical distance values ​​are calculated based on the coordinates of the user's point cloud position in the three-dimensional coordinate system; the user's position deflection angle is determined based on the projection of the line connecting the user's point cloud position coordinates and the origin onto the horizontal plane, for example, the projected coordinates of the user's point cloud position on the horizontal plane are ( , Then the user's position deflection angle .

[0075] Step S1132: Summarize the horizontal distance value, vertical distance value, and user position deflection angle to obtain user position information.

[0076] in, Figure 2 This is a positional diagram illustrating the relative position of a radar sensor and a user according to some embodiments of this disclosure, such as... Figure 2 As shown, there are two radar sensors. The first radar sensor is located on the left side of the air conditioner vent, and the second radar sensor is located on the right side of the air conditioner vent. The two radar sensors are symmetrically distributed based on the centerline of the air conditioner vent. The detection area of ​​the radar sensor is at least 180°. The detection area of ​​the radar sensor on the left side of the air conditioner vent (the area enclosed by OABCD) is 0-90°, and the detection area of ​​the radar sensor on the right side of the air conditioner vent is 90°-180° (the area enclosed by OGFED). That is, when the user is on the left side of the air conditioner vent, user point cloud information is generated based on the radar sensor on the left side of the air conditioner vent, and then the user's position information is determined based on the user's point cloud position coordinates. When the user is on the right side of the air conditioner vent, user point cloud information is generated based on the radar sensor on the right side of the air conditioner vent, and then the user's position information, namely the horizontal distance value, the vertical distance value, and the user's position deflection angle, is determined based on the user's point cloud position coordinates. The area enclosed by OABFG is the air supply area of ​​the air conditioner.

[0077] In this disclosed procedure, a three-dimensional coordinate system centered on the air outlet is established, converting the user's point cloud coordinates into three intuitive spatial parameters: horizontal distance, vertical distance, and deflection angle. This method transforms the complex spatial positioning problem into the calculation and summarization of these three scalars, providing direct and quantifiable input parameters for the subsequent precise control of airflow direction and volume.

[0078] Furthermore, the implementation steps of step S12 include:

[0079] Step S121: In response to the user location information, determine that the target user is only in the left area, and generate the left-side air supply strategy of the air conditioner.

[0080] Step S122, or, in response to the user location information, determining that the target user is only in the right-side area, generating the right-side air supply strategy for the air conditioner.

[0081] Step S123, or, in response to the user location information, determine that the target user is in the left and right areas, and generate the left and right side air supply strategy of the air conditioner; wherein, the left and right side air supply strategy is the left side air supply strategy and the right side air supply strategy.

[0082] Step S124: Determine the left-side air supply strategy, or the right-side air supply strategy, or the left and right side air supply strategy as the air conditioning air supply strategy.

[0083] For example, after obtaining user location information, the location distribution of the target user is first determined. If the user location information indicates that the target user is only in the left-side area, a left-side air supply strategy for the air conditioner is generated. This strategy controls air supply to the left air supply zone, while stopping air supply to the right air supply zone or reducing the air supply volume to a minimum. If the user location information indicates that the target user is only in the right-side area, a right-side air supply strategy is generated. This strategy controls air supply to the right air supply zone, while stopping air supply to the left air supply zone or reducing the air supply volume to a minimum. If the user location information indicates that the target user is simultaneously in both the left and right-side areas, for example, if two people are located on the left and right sides of the room respectively, a left-right side air supply strategy for the air conditioner is generated. This strategy is a combination of the left-side and right-side air supply strategies, meaning that both the left and right air supply zones are controlled to supply air simultaneously. Then, the generated left-side, right-side, or left-right side air supply strategies are determined as the air conditioner's air supply strategy.

[0084] In the implementation steps of this disclosure, based on the distribution of target users in different areas, a single left-side air supply strategy, a right-side air supply strategy, or a combination of left and right-side air supply strategies are dynamically selected. This achieves targeted air supply to the areas where target users exist, optimizes air supply efficiency and effect, and avoids air supply to uninhabited areas.

[0085] Furthermore, the method provided in this disclosure also includes:

[0086] Step S12A: Determine the middle region from the left and right regions; wherein the center line of the middle region is the dividing line between the left and right regions.

[0087] Step S12B: In response to the user location information, determine that the target user is in the middle area and generate the air conditioning middle air supply strategy.

[0088] Step S12C: The intermediate air supply strategy is determined to be the air conditioning air supply strategy.

[0089] For example, a middle region is determined from the left and right regions, with the center line of the middle region serving as the boundary between the left and right regions. Figure 2 Based on the diagram shown, Figure 3 This is a schematic diagram illustrating the zoning of room areas according to some embodiments of this disclosure, such as... Figure 3 As shown, the room area is divided into four zones along the center line of the air conditioner vents: Left 1, Left 2, Right 1, and Right 2. The left zone includes Left 1 and Left 2, the right zone includes Right 1 and Right 2, and the central zone is the area formed by Left 2 and Right 2, as shown by the thick black solid line. After obtaining the user's location information, if the target user is determined to be in the central zone, a central airflow strategy for the air conditioner is generated. For example, if the user is sitting on the sofa in the center of the room, a central airflow strategy is generated. Finally, the central airflow strategy is determined as the air conditioner's airflow strategy.

[0090] In the implementation steps of this disclosure, by identifying the middle area where the user is located near the boundary line between the left and right areas and generating a corresponding middle air supply strategy, the problem of uneven air supply caused by only supplying air to one side when the user is in the middle position is solved, thereby improving the comfort of air conditioning supply when the user is in the center of the room.

[0091] Further, in this embodiment of the present disclosure, the left air supply zone includes an upper left air supply zone and a lower left air supply zone; wherein, the upper left air supply zone is provided with an upper left horizontal air guide plate, the lower left air supply zone is provided with a lower left horizontal air guide plate, and the left air supply zone is provided with a left vertical air guide plate; the right air supply zone includes an upper right air supply zone and a lower right air supply zone; wherein, the upper right air supply zone is provided with an upper right horizontal air guide plate, the lower right air supply zone is provided with a lower right horizontal air guide plate, and the right air supply zone is provided with a right vertical air guide plate; the air conditioning air supply strategy is used to indicate the rotation angle of the upper left horizontal air guide plate, the rotation angle of the lower left horizontal air guide plate, the deflection angle of the left vertical air guide plate, the rotation angle of the upper right horizontal air guide plate, the rotation angle of the lower right horizontal air guide plate, and the deflection angle of the right vertical air guide plate when supplying air to the area where the target user is located.

[0092] For example, when air needs to be supplied to the left area, the left air supply strategy will specify that the upper left horizontal air guide plate rotates to 80°, the lower left horizontal air guide plate rotates to 60°, the left vertical air guide plate deflects to 60°, while the air guide plates on the right (upper right horizontal air guide plate, lower right horizontal air guide plate and right vertical air guide plate) remain closed or at a specific preset angle.

[0093] In the implementation steps of this disclosure, by further subdividing the left and right air supply zones into upper and lower sub-regions and setting horizontal and vertical air guide plates, fine control of the air supply direction and distance is achieved, enabling more precise air supply adjustment according to the user's specific location (such as distance or height).

[0094] Furthermore, the left-side region includes at least the left-side region of the first distance, the left-side region of the second distance, and the left-side region of the third distance, where the first distance is smaller than the second distance, and the second distance is smaller than the third distance. For example, the first distance corresponds to the near zone within 3 meters of the air conditioner, the second distance corresponds to the middle zone within 3 to 6 meters, and the third distance corresponds to the far zone beyond 6 meters. The user location information includes horizontal distance values, vertical distance values, and the user's position deflection angle.

[0095] Furthermore, in one possible implementation, step S121 includes the following steps: responding to user location information, determining that the target user is in the left-side region of the first distance and the left-side region of the second distance, and generating a first left-side air supply strategy for the air conditioner; and determining the first left-side air supply strategy as a left-side air supply strategy; wherein the first left-side air supply strategy is used to indicate that the lower left air supply area is used to supply air to the left-side region of the first distance, the upper left air supply area is used to supply air to the left-side region of the second distance, the rotation angle of the lower left horizontal air guide plate is the first left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the second left-side rotation angle, the first left-side rotation angle is less than the second left-side rotation angle, and the deflection angle of the left vertical air guide plate is the first left-side deflection angle.

[0096] For example, when user location information determines that the target user is only in the left-hand area, and the horizontal distance value determines that the target user is specifically located in the left-hand area of ​​the first distance and the left-hand area of ​​the second distance, a first left-hand air supply strategy for the air conditioner is generated; for example, there are two target users, one of whom is located in the left-hand area of ​​the first distance and the other in the left-hand area of ​​the second distance. The first left-hand air supply strategy instructs the lower left air supply area to supply air to the left-hand area (near zone) of the first distance, and the upper left air supply area to supply air to the left-hand area (middle zone) of the second distance. At this time, the rotation angle of the lower left horizontal air guide plate is the first left-hand rotation angle, and the rotation angle of the upper left horizontal air guide plate is the second left-hand rotation angle, where the first left-hand rotation angle is smaller than the second left-hand rotation angle. Since the lower left air supply area is responsible for the near zone, its air guide plate angle is smaller, causing the airflow to blow downwards; the upper left air supply area is responsible for the middle zone, and its air guide plate angle is larger, causing the airflow to blow upwards to cover a greater distance; for example, the first left-hand rotation angle is 60°, and the second left-hand rotation angle is 80°. The deflection angle of the left vertical air guide plate is the first left deflection angle, used to guide airflow to the left. This first left deflection angle is determined based on the user position deflection angle of each target user; for example, the first left deflection angle is equal to the average user position deflection angle (the average value of the user position deflection angles of all target users). Finally, the first left-side air supply strategy is determined as the left-side air supply strategy.

[0097] In the implementation steps of this disclosure, based on the distribution of target users in the left-side area at different distances, different air guide plate angles in the upper and lower air supply zones are used to achieve layered air supply to the near and middle zones, avoiding the problem of excessively cold near zones or no air in the middle zones caused by single-angle air supply, thus improving the uniformity and comfort of air supply.

[0098] Furthermore, in another possible implementation, the specific implementation steps of step S121 include: responding to user location information, determining that the target user is in the left-side area of ​​the first distance and the left-side area of ​​the third distance, and generating a second left-side air supply strategy for the air conditioner; determining the second left-side air supply strategy as the left-side air supply strategy; wherein, the second left-side air supply strategy is used to indicate that the lower left air supply area is used to supply air to the left-side area of ​​the first distance, the upper left air supply area is used to supply air to the left-side area of ​​the third distance, the rotation angle of the lower left horizontal air guide plate is the third left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the fourth left-side rotation angle, the third left-side rotation angle is less than the fourth left-side rotation angle, and the deflection angle of the left vertical air guide plate is the second left-side deflection angle.

[0099] For example, when user location information determines that the target user is only in the left-hand area, and the horizontal distance value determines that the target user is specifically located in the left-hand area of ​​the first distance and the left-hand area of ​​the third distance, a second left-hand air supply strategy for the air conditioner is generated; for example, there are two target users, one of whom is located in the left-hand area of ​​the first distance and the other in the left-hand area of ​​the third distance. The second left-hand air supply strategy instructs the lower left air supply area to supply air to the left-hand area of ​​the first distance (near zone), and the upper left air supply area to supply air to the left-hand area of ​​the third distance (far zone). At this time, the rotation angle of the lower left horizontal air guide plate is the third left-hand rotation angle, and the rotation angle of the upper left horizontal air guide plate is the fourth left-hand rotation angle, where the third left-hand rotation angle is smaller than the fourth left-hand rotation angle. Since the far zone is farther away, the fourth left-hand rotation angle of the upper left horizontal air guide plate is greater than the second left-hand rotation angle to blow the airflow further; for example, the third left-hand rotation angle is 70° and the fourth left-hand rotation angle is 90°. The deflection angle of the left vertical air guide plate is the second left deflection angle, used to guide airflow to the left. This second left deflection angle is determined based on the user position deflection angle of each target user; for example, the second left deflection angle is equal to the average user position deflection angle (the average value of the user position deflection angles of all target users). Finally, the second left air supply strategy is determined as the left-side air supply strategy.

[0100] In the implementation steps of this disclosure, when the target user appears in both the near and far zones, the angle of the air guide plate in the upper left air supply zone is adjusted so that it is specifically responsible for long-distance air supply, thereby achieving coverage of a large area and ensuring the air supply effect for users in the far zone. This achieves layered air supply for the near and far zones, avoiding the problem of excessively cold near zones or no air supply in the far zones caused by single-angle air supply, and improving the uniformity, comfort and coverage of the air supply.

[0101] Furthermore, in another possible implementation, the specific implementation steps of step S121 include: responding to user location information, determining that the target user is in the left-side area of ​​the second distance and the left-side area of ​​the third distance, and generating a third left-side air supply strategy for the air conditioner; determining the third left-side air supply strategy as the left-side air supply strategy; wherein, the third left-side air supply strategy is used to indicate that the lower left air supply area is used to supply air to the left-side area of ​​the second distance, the upper left air supply area is used to supply air to the left-side area of ​​the third distance, the rotation angle of the lower left horizontal air guide plate is the fifth left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the sixth left-side rotation angle, the fifth left-side rotation angle is less than the sixth left-side rotation angle, and the deflection angle of the left vertical air guide plate is the third left-side deflection angle.

[0102] For example, when user location information determines that the target user is only in the left-hand area, and the horizontal distance value determines that the target user is specifically located in the left-hand area of ​​the second distance and the left-hand area of ​​the third distance, a third left-hand air supply strategy for the air conditioner is generated; for example, there are two target users, one of whom is located in the left-hand area of ​​the second distance and the other in the left-hand area of ​​the third distance. The third left-hand air supply strategy instructs the lower left air supply area to supply air to the left-hand area (middle zone) of the second distance, and the upper left air supply area to supply air to the left-hand area (far zone) of the third distance. At this time, the rotation angle of the lower left horizontal air guide plate is the fifth left-hand rotation angle, and the rotation angle of the upper left horizontal air guide plate is the sixth left-hand rotation angle, where the fifth left-hand rotation angle is smaller than the sixth left-hand rotation angle. Since the lower left air supply area is responsible for the middle zone, its fifth left-hand rotation angle is greater than the first left-hand rotation angle to blow airflow to the middle zone; for example, the fifth left-hand rotation angle is 80° and the sixth left-hand rotation angle is 90°. The deflection angle of the left vertical air guide plate is the third left deflection angle, used to guide airflow to the left. This third left deflection angle is determined based on the user position deflection angle of each target user; for example, the third left deflection angle is equal to the average user position deflection angle (the average value of the user position deflection angles of all target users). Finally, the third left air supply strategy is determined as the left-side air supply strategy.

[0103] In the implementation steps of this disclosure, when the user is located in the middle zone and the far zone, by adjusting the different air guide plate angles of the upper and lower air supply zones, layered air supply to the middle zone and the far zone is achieved, that is, air supply coverage of the middle and far distance areas is achieved, avoiding the waste of resources caused by supplying air to the near zone when there is no one in the near zone.

[0104] Furthermore, in another possible implementation, step S121 includes the following specific steps: responding to user location information, determining that the target user is in the left-side area of ​​the first distance, the left-side area of ​​the second distance, and the left-side area of ​​the third distance, and generating a fourth left-side air supply strategy for the air conditioner; and determining the fourth left-side air supply strategy as the left-side air supply strategy; wherein the fourth left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left-side area of ​​the first distance and the left-side area of ​​the second distance, the upper left air supply area to supply air to the left-side area of ​​the third distance, the rotation angle of the lower left horizontal air guide plate is the seventh left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the eighth left-side rotation angle, the seventh left-side rotation angle is less than the eighth left-side rotation angle, and the deflection angle of the left vertical air guide plate is the fourth left-side deflection angle.

[0105] For example, when user location information determines that the target user is only in the left-hand area, and the horizontal distance value determines that the target user is specifically located in the left-hand area of ​​the first distance, the left-hand area of ​​the second distance, and the left-hand area of ​​the third distance, a fourth left-hand air supply strategy for the air conditioner is generated; for example, there are three target users, one of whom is located in the left-hand area of ​​the first distance, another in the left-hand area of ​​the second distance, and the third in the left-hand area of ​​the third distance. The fourth left-hand air supply strategy instructs the lower left air supply area to supply air to the left-hand areas of the first and second distances (near and middle zones), and the upper left air supply area to supply air to the left-hand area of ​​the third distance (far zone). At this time, the rotation angle of the lower left horizontal air guide plate is the seventh left-hand rotation angle, and the rotation angle of the upper left horizontal air guide plate is the eighth left-hand rotation angle, where the seventh left-hand rotation angle is smaller than the eighth left-hand rotation angle. Since the lower left air supply zone needs to cover both the near and middle zones, the seventh left-side rotation angle is between the first and fifth left-side rotation angles to achieve coverage of both zones. For example, the seventh left-side rotation angle is 75°, and the eighth left-side rotation angle is 90°; alternatively, the seventh left-side rotation angle can be a range value, such as [60°, 80°], used to indicate that the lower left horizontal air guide plate swings between 60° and 80°. The deflection angle of the left vertical air guide plate is the fourth left-side deflection angle, used to guide airflow to the left. This fourth left-side deflection angle is determined based on the user position deflection angle of each target user; for example, the fourth left-side deflection angle is equal to the average user position deflection angle (the average value of the user position deflection angles of all target users). Finally, the fourth left-side air supply strategy is determined as the left-side air supply strategy.

[0106] In the implementation steps of this disclosure, when the target users are spread throughout the entire left-side area (near, middle, and far zones), by allocating the air supply range of the upper and lower air supply zones, the lower left air supply zone covers the near and middle zones, and the upper left air supply zone covers the far zone, thus achieving full coverage of the entire left-side area and ensuring the air supply experience of all target users.

[0107] Furthermore, for the specific implementation steps of step S122, refer to the specific implementation steps of step S121. That is, the generation logic of generating the right-side air supply strategy of the air conditioner is the same as the generation logic of generating the left-side air supply strategy of the air conditioner, and will not be repeated here.

[0108] Furthermore, regarding the specific implementation steps of step S123, referring to the specific implementation steps of step S121, the left-side air supply strategy and the right-side air supply strategy are generated first, and then the left-side air supply strategy and the right-side air supply strategy are summarized to obtain the left and right side air supply strategies; wherein, the generation logic of generating the right-side air supply strategy of the air conditioner is the same as the generation logic of generating the left-side air supply strategy of the air conditioner, and will not be repeated here.

[0109] In some embodiments, Figure 4 This is a schematic diagram illustrating the determination of the deflection angle of a vertical air guide plate according to some embodiments of this disclosure, such as... Figure 4 As shown, for reference Figure 2 The diagram shows the relative positions of the radar sensor and the user. If the user is in the left area and the user's position is deflected by an angle of θ... Then the deflection angle of the left vertical air guide plate is equal to the deflection angle of the user's position. Among them, the user's position deflection angle This is determined based on data collected by a radar sensor on the left side of the air conditioner vent; if the user is in the right-side area and the user's position is deflected at an angle of... Then the deflection angle of the right vertical air guide plate is equal to the deflection angle of the user's position. Among them, the user's position deflection angle The angle of deflection of the vertical air guide plate is determined by a radar sensor located on the right side of the air conditioner vent. The angle between the vertical air guide plate and the horizontal rotation axis is the angle between the vertical air guide plate and the horizontal rotation axis. The horizontal rotation axis passes through the center point of each vertical air guide plate, so that the vertical air guide plate rotates around the horizontal rotation axis through the center point of the vertical air guide plate. The vertical air guide plate includes a left vertical air guide plate and a right vertical air guide plate, which are symmetrically arranged based on the center line of the air conditioner vent.

[0110] In some embodiments, Figure 5 This is a schematic diagram illustrating the deflection angle of a horizontal air guide plate according to some embodiments of this disclosure, such as... Figure 5As shown, if the air conditioner blows air to the right, then with the vertical axis of rotation as the starting edge, the horizontal air guide plate rotates counterclockwise around its left vertex. The angle between the horizontal air guide plate and the vertical axis of rotation is... This refers to the deflection angle of the horizontal air guide plate; the horizontal air guide plate includes the upper left horizontal air guide plate, the lower left horizontal air guide plate, the upper right horizontal air guide plate, and the lower right horizontal air guide plate.

[0111] Furthermore, ventilation holes are arranged on the left vertical air guide plate; based on the above embodiment, before step S124, the method provided in this disclosure further includes:

[0112] Step S1201: Obtain the user type information of the target user.

[0113] Step S1202: In response to the user type information including youth type information and / or elderly type information, determine that the left vertical air guide plate is in a closed state.

[0114] Step S1203: In response to the left vertical air guide plate being in a closed state, the left air supply strategy is updated.

[0115] The ventilation holes on the left vertical air guide plate allow a small amount of airflow to pass through when the air guide plate is closed, achieving windless air delivery.

[0116] For example, facial recognition via camera or manual user settings can be used to determine whether a user is a teenager, middle-aged, or elderly. When the user type information includes teenager and / or elderly type information, the left vertical air guide is determined to be in a closed state. Since teenagers and the elderly are more sensitive to direct airflow from the air conditioner, closing the left vertical air guide can prevent direct airflow from the air conditioner. In response to the left vertical air guide being in a closed state, the left air supply strategy is updated. For example, based on the original left air supply strategy, the deflection angle of the left vertical air guide is adjusted to 0 degrees (i.e., closed) to achieve gentle airflow through the ventilation holes.

[0117] In the implementation steps of this disclosure, by identifying user types, the left vertical air guide plate is closed and the left air supply strategy is updated for sensitive groups such as teenagers and the elderly, so as to achieve windless or gentle air supply and improve the user comfort and health of specific groups.

[0118] Specifically, in some embodiments, step S1201 includes steps A01 and A02. Specifically:

[0119] In step A01, user point cloud information is collected using a radar sensor.

[0120] For example, user point cloud information includes the number of users within the detection area of ​​the radar sensor, and / or the location coordinates of the user point cloud, and / or the user attitude information, and / or the user signal strength information, and / or the user point cloud area.

[0121] The startup process of the radar sensor is described in step S111, and will not be repeated here.

[0122] In step A02, user type information is determined based on user point cloud information.

[0123] The specific implementation steps of step A02 include:

[0124] Step A021: Determine the user's movement frequency and speed based on the user's point cloud position coordinates at multiple time points.

[0125] For example, the displacement difference between the user point cloud position coordinates at adjacent time points is calculated; the user's movement speed is calculated based on the displacement difference and the time interval between adjacent time points; the number of times the displacement difference exceeds a preset displacement threshold within a preset time period is counted, and the user's movement frequency is calculated based on the number of times and the duration of the preset time period.

[0126] Step A022: Determine the user's body movement frequency based on user posture information at multiple time points.

[0127] For example, target joint angle change information is extracted from user posture information. For example, target joint angle change information includes elbow joint angle change information, shoulder joint angle change information, hip joint angle change information, and knee joint angle change information. The user's body movement frequency is calculated based on the number of times the key joint angle change exceeds a preset angle change threshold within a preset time period and based on the number of times and the duration of the preset time period.

[0128] Step A023: Match the user signal strength information, user point cloud area, user body movement frequency, user movement frequency, and user movement speed with the preset user type matching information to determine the user type information.

[0129] The preset user type matching information includes the mapping relationship between user signal strength information, user point cloud area, user body movement frequency, user movement frequency, user movement speed and user type information.

[0130] For example, the preset user type matching information includes preset youth type matching information, preset young adult type matching information, and preset elderly type matching information; the preset youth type matching information includes the signal strength information of the first interval user, the point cloud area of ​​the first interval user, the body movement frequency of the first interval user, the movement frequency of the first interval user, and the movement speed of the first interval user; the preset young adult type matching information includes the signal strength information of the second interval user, the point cloud area of ​​the second interval user, the body movement frequency of the second interval user, the movement frequency of the second interval user, and the movement speed of the second interval user; the preset elderly type matching information includes the signal strength information of the third interval user, the point cloud area of ​​the third interval user, the body movement frequency of the third interval user, the movement frequency of the third interval user, and the movement speed of the third interval user.

[0131] Specifically, the maximum signal strength of the user signal strength information in the first interval is less than the minimum signal strength of the user signal strength information in the second interval, and less than the minimum signal strength of the user signal strength information in the third interval; the maximum point cloud area of ​​the user point cloud in the first interval is less than the minimum point cloud area of ​​the user point cloud in the second interval, and less than the minimum point cloud area of ​​the user point cloud in the third interval; the maximum body movement frequency of the user in the first interval is less than the minimum body movement frequency of the user in the second interval; the maximum body movement frequency of the user in the third interval is less than the minimum body movement frequency of the user in the second interval; the maximum movement frequency of the user in the first interval is less than the minimum movement frequency of the user in the second interval; the maximum movement speed of the user in the first interval is less than the minimum movement speed of the user in the second interval; and the maximum movement speed of the user in the third interval is less than the minimum movement speed of the user in the second interval.

[0132] For example, if the user signal strength information belongs to the first interval, the user point cloud area belongs to the first interval, the user body movement frequency belongs to the first interval, the user movement frequency belongs to the first interval, and the user movement speed belongs to the first interval, then the user type information is determined to be the preset youth type matching information, i.e., the user is a youth or child. If the user signal strength information belongs to the third interval, the user point cloud area belongs to the third interval, the user body movement frequency belongs to the third interval, the user movement frequency belongs to the third interval, and the user movement speed belongs to the third interval, then the user type information is determined to be the preset elderly type matching information, i.e., the user is an elderly person.

[0133] In this embodiment, by fusing five dimensions of features—signal strength, point cloud area, body movement frequency, movement frequency, and movement speed—for comprehensive matching, a refined distinction of user age groups (teenagers, young adults, and the elderly) is achieved. This method overcomes the limitations of single physical features (such as height) being susceptible to occlusion or posture influence, and improves the accuracy and reliability of type recognition by utilizing the complementarity between behavioral patterns (movement and body movement) and physical features (signal and area).

[0134] Furthermore, before step S124, the update process for the right-side air supply strategy or the left and right-side air supply strategy is the same as the update process for updating the left-side air supply strategy in steps S1201 to S1203, which will not be repeated here.

[0135] In some embodiments, the intermediate region includes an intermediate region of a first distance, an intermediate region of a second distance, and an intermediate region of a third distance, wherein the first distance is smaller than the second distance, and the second distance is smaller than the third distance; for example, the first distance corresponds to the near zone within 3 meters of the air conditioner, the second distance corresponds to the intermediate zone of 3 to 6 meters, and the third distance corresponds to the far zone of more than 6 meters. The user location information includes horizontal distance values, vertical distance values, and the user's position deflection angle.

[0136] Furthermore, in one possible implementation, step S12B includes the following steps: in response to user location information, determining that the target user is in the middle area of ​​the first distance and the middle area of ​​the second distance, generating a first intermediate air supply strategy for the air conditioner; and determining the first intermediate air supply strategy as the intermediate air supply strategy.

[0137] Specifically, the first intermediate air supply strategy is used to indicate that the lower left and lower right air supply areas are used to supply air to the middle area of ​​the first distance, and the upper left and upper right air supply areas are used to supply air to the middle area of ​​the second distance; the rotation angle of the lower left horizontal air guide plate is the first left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the second left rotation angle, with the first left rotation angle being smaller than the second left rotation angle; the rotation angle of the lower right horizontal air guide plate is the first right rotation angle, and the rotation angle of the upper right horizontal air guide plate is the second right rotation angle, with the first right rotation angle being smaller than the second right rotation angle; the deflection angle of the left vertical air guide plate is the first intermediate deflection angle; and the deflection angle of the right vertical air guide plate is the second intermediate deflection angle.

[0138] For example, when the user location information determines that the target user is in the middle area, and the horizontal distance value determines that the target user is specifically located in the middle area of ​​the first distance and the middle area of ​​the second distance, a first middle air supply strategy for the air conditioner is generated. This first middle air supply strategy instructs the lower left and lower right air supply zones to supply air to the middle area (near zone) of the first distance, and the upper left and upper right air supply zones to supply air to the middle area (middle zone) of the second distance. At this time, the rotation angle of the lower left horizontal air guide plate is the first left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the second left rotation angle, with the first left rotation angle being smaller than the second left rotation angle; for example, the first left rotation angle is 60°, and the second left rotation angle is 80°. The rotation angle of the lower right horizontal air guide plate is the first right rotation angle, and the rotation angle of the upper right horizontal air guide plate is the second right rotation angle, with the first right rotation angle being smaller than the second right rotation angle; for example, the first right rotation angle is 60°, and the second right rotation angle is 80°. The deflection angle of the left vertical air guide plate is the first intermediate deflection angle, and the deflection angle of the right vertical air guide plate is the second intermediate deflection angle. These two deflection angles cause the airflow from both the left and right air supply zones to converge towards the central area. The first and second intermediate deflection angles are determined based on the user's position deflection angle for each target user. Therefore, the first intermediate air supply strategy is defined as the intermediate air supply strategy.

[0139] In the implementation steps of this disclosure, when the target user is located in the near zone and the middle zone of the middle area, the upper and lower air supply zones on the left and right sides work together to achieve concentrated air supply to the middle area, avoiding airflow deflection caused by unilateral air supply and improving the air supply uniformity of the middle area.

[0140] Furthermore, in another possible implementation, the specific implementation steps of step S12B include: responding to the user location information, determining that the target user is in the middle area of ​​the first distance and the middle area of ​​the third distance, generating a second intermediate air supply strategy for the air conditioner; and determining the second intermediate air supply strategy as the intermediate air supply strategy.

[0141] The second intermediate air supply strategy is used to indicate that the lower left and lower right air supply areas are used to supply air to the middle area of ​​the first distance, and the upper left and upper right air supply areas are used to supply air to the middle area of ​​the third distance; the rotation angle of the lower left horizontal guide plate is the third left rotation angle, the rotation angle of the upper left horizontal guide plate is the fourth left rotation angle, and the third left rotation angle is smaller than the fourth left rotation angle; the rotation angle of the lower right horizontal guide plate is the third right rotation angle, the rotation angle of the upper right horizontal guide plate is the fourth right rotation angle, and the third right rotation angle is smaller than the fourth right rotation angle; the deflection angle of the left vertical guide plate is the third intermediate deflection angle; and the deflection angle of the right vertical guide plate is the fourth intermediate deflection angle.

[0142] For example, when the user location information determines that the target user is in the intermediate area, and the horizontal distance value determines that the target user is specifically located in the intermediate area of ​​the first distance and the intermediate area of ​​the third distance, a second intermediate air supply strategy for the air conditioner is generated. This second intermediate air supply strategy instructs the lower left and lower right air supply areas to supply air to the intermediate area (near zone) of the first distance, and the upper left and upper right air supply areas to supply air to the intermediate area (far zone) of the third distance. At this time, the rotation angle of the lower left horizontal air guide plate is the third left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the fourth left rotation angle, where the third left rotation angle is smaller than the fourth left rotation angle; for example, the third left rotation angle is 70° and the fourth left rotation angle is 90°. The rotation angle of the lower right horizontal air guide plate is the third right rotation angle, and the rotation angle of the upper right horizontal air guide plate is the fourth right rotation angle, where the third right rotation angle is smaller than the fourth right rotation angle; for example, the third right rotation angle is 70° and the fourth right rotation angle is 90°. The deflection angle of the left vertical air guide plate is the third intermediate deflection angle, and the deflection angle of the right vertical air guide plate is the fourth intermediate deflection angle. These two deflection angles cause the airflow from both the left and right air supply zones to converge towards the central area. The third and fourth intermediate deflection angles are determined based on the user's position deflection angle for each target user. Finally, the second intermediate air supply strategy is determined as the intermediate air supply strategy.

[0143] In the implementation steps of this disclosure, when the target user is located in the near and far zones of the central area, the angles of the air guide plates in the upper left and upper right air supply zones on both sides are adjusted to make them specifically responsible for long-distance air supply, and the angles of the air guide plates in the lower left and lower right air supply zones on both sides are adjusted to make them specifically responsible for short-distance air supply. This achieves coverage of the central area with a large span, ensures the air supply effect for users in the far zone, and realizes layered air supply for the near and far zones. It avoids the problem of excessively cold near zone or no air supply in far zone caused by air supply at a single angle, improves the uniformity, comfort and coverage of air supply, and also avoids airflow deflection caused by air supply on one side, thus improving the uniformity of air supply in the central area.

[0144] Furthermore, in another possible implementation, the specific implementation steps of step S12B include: responding to the user location information, determining that the target user is in the middle area of ​​the second distance and the middle area of ​​the third distance, generating a third intermediate air supply strategy for the air conditioner; and determining the third intermediate air supply strategy as the intermediate air supply strategy.

[0145] Among them, the third intermediate air supply strategy is used to indicate that the lower left and lower right air supply areas are used to supply air to the middle area of ​​the second distance, and the upper left and upper right air supply areas are used to supply air to the middle area of ​​the third distance; the rotation angle of the lower left horizontal air guide plate is the fifth left rotation angle, the rotation angle of the upper left horizontal air guide plate is the sixth left rotation angle, and the fifth left rotation angle is smaller than the sixth left rotation angle; the rotation angle of the lower right horizontal air guide plate is the fifth right rotation angle, the rotation angle of the upper right horizontal air guide plate is the sixth right rotation angle, and the fifth right rotation angle is smaller than the sixth right rotation angle; the deflection angle of the left vertical air guide plate is the fifth intermediate deflection angle; the deflection angle of the right vertical air guide plate is the sixth intermediate deflection angle.

[0146] For example, when the user location information determines that the target user is in the middle area, and the horizontal distance value determines that the target user is specifically located in the middle area of ​​the second distance and the middle area of ​​the third distance, a third middle air supply strategy for the air conditioner is generated. This third middle air supply strategy instructs the lower left and lower right air supply zones to supply air to the middle area (central zone) of the second distance, and the upper left and upper right air supply zones to supply air to the middle area (far zone) of the third distance. At this time, the rotation angle of the lower left horizontal air guide plate is the fifth left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the sixth left rotation angle, where the fifth left rotation angle is smaller than the sixth left rotation angle; for example, the fifth left rotation angle is 80° and the sixth left rotation angle is 90°. The rotation angle of the lower right horizontal air guide plate is the fifth right rotation angle, and the rotation angle of the upper right horizontal air guide plate is the sixth right rotation angle, where the fifth right rotation angle is smaller than the sixth right rotation angle; for example, the fifth right rotation angle is 80° and the sixth right rotation angle is 90°. The deflection angle of the left vertical air guide plate is the fifth intermediate deflection angle, and the deflection angle of the right vertical air guide plate is the sixth intermediate deflection angle. These two deflection angles cause the airflow from both the left and right air supply zones to converge towards the central area. The fifth and sixth intermediate deflection angles are determined based on the user's position deflection angle for each target user. Finally, the third intermediate air supply strategy is determined as the intermediate air supply strategy.

[0147] In the implementation steps of this disclosure, when the user is located in the middle and far zones of the central area, by adjusting the different angles of the upper and lower air supply plates on the left and right sides, layered air supply to the middle and far zones is achieved, that is, air supply coverage of the middle and far distance areas is achieved, avoiding the waste of resources caused by supplying air to the near zone when no one is in the near zone, and also avoiding airflow deflection caused by unilateral air supply, thus improving the uniformity of air supply in the central zone.

[0148] Furthermore, in another possible implementation, the specific implementation steps of step S12B include: responding to the user location information, determining that the target user is in the middle area of ​​the first distance, the middle area of ​​the second distance, and the middle area of ​​the third distance, generating a fourth intermediate air supply strategy for the air conditioner; and determining the fourth intermediate air supply strategy as the intermediate air supply strategy.

[0149] Among them, the fourth intermediate air supply strategy is used to indicate that the lower left and lower right air supply areas are used to supply air to the middle area of ​​the first distance and the middle area of ​​the second distance, and the upper left and upper right air supply areas are used to supply air to the middle area of ​​the third distance; the rotation angle of the lower left horizontal air guide plate is the seventh left rotation angle, the rotation angle of the upper left horizontal air guide plate is the eighth left rotation angle, and the seventh left rotation angle is less than the eighth left rotation angle; the rotation angle of the lower right horizontal air guide plate is the seventh right rotation angle, the rotation angle of the upper right horizontal air guide plate is the eighth right rotation angle, and the seventh right rotation angle is less than the eighth right rotation angle; the deflection angle of the left vertical air guide plate is the seventh intermediate deflection angle; the deflection angle of the right vertical air guide plate is the eighth intermediate deflection angle.

[0150] For example, when user location information determines that the target user is in the intermediate area, and the horizontal distance value determines that the target user is specifically located in the intermediate area of ​​the first distance, the intermediate area of ​​the second distance, and the intermediate area of ​​the third distance, a fourth intermediate air supply strategy for the air conditioner is generated. This fourth intermediate air supply strategy instructs the lower left and lower right air supply zones to supply air to the intermediate areas of the first and second distances (near and middle zones), and the upper left and upper right air supply zones to supply air to the intermediate area of ​​the third distance (far zone). At this time, the rotation angle of the lower left horizontal air guide plate is the seventh left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the eighth left rotation angle, where the seventh left rotation angle is smaller than the eighth left rotation angle. The rotation angle of the lower right horizontal air guide plate is the seventh right rotation angle, and the rotation angle of the upper right horizontal air guide plate is the eighth right rotation angle, where the seventh right rotation angle is smaller than the eighth right rotation angle. The deflection angle of the left vertical air guide plate is the seventh intermediate deflection angle, and the deflection angle of the right vertical air guide plate is the eighth intermediate deflection angle. These two deflection angles cause the airflow from both the left and right air supply zones to converge towards the central area. The seventh and eighth intermediate deflection angles are determined based on the user's position deflection angle for each target user. Finally, the fourth intermediate air supply strategy is determined as the intermediate air supply strategy.

[0151] Since the lower left air supply area needs to cover both the near and middle zones, the seventh left-side rotation angle is between the first and fifth left-side rotation angles to achieve a balance between the two zones; for example, the seventh left-side rotation angle is 75° and the eighth left-side rotation angle is 90°; or, the seventh left-side rotation angle is a range value, such as [60°, 80°], used to indicate that the lower left horizontal air guide plate swings between 60° and 80°. Similarly, since the lower right air supply area needs to cover both the near and middle zones, the seventh right-side rotation angle is between the first and fifth right-side rotation angles to achieve a balance between the two zones; for example, the seventh right-side rotation angle is 75° and the eighth right-side rotation angle is 90°; or, the seventh right-side rotation angle is a range value, such as [60°, 80°], used to indicate that the lower right horizontal air guide plate swings between 60° and 80°.

[0152] In the implementation steps of this disclosure, when the target users are spread throughout the entire intermediate area (near zone, middle zone and far zone), by allocating the air supply range of the upper and lower air supply zones, the lower air supply zone covers the near zone and the middle zone, and the upper air supply zone covers the far zone, thus achieving full coverage of the entire intermediate area and ensuring the air supply experience of all target users in the intermediate area.

[0153] Furthermore, ventilation holes are arranged on the left vertical air guide plate and on the right vertical air guide plate; based on the above embodiment, before step S12C, the method provided in this disclosure further includes:

[0154] Step S120a: Obtain the user type information of the target user.

[0155] Step S120b: In response to the user type information including youth type information and / or elderly type information, determine that the left vertical air guide plate is in a closed state and the right vertical air guide plate is in a closed state.

[0156] In step S120c, in response to the left vertical air guide plate being in a closed state and the right vertical air guide plate being in a closed state, the middle air supply strategy is updated.

[0157] The implementation method of step S120a is the same as that of step S1201, and will not be repeated here.

[0158] Furthermore, when the user type information includes youth and / or elderly type information, the left vertical air guide plate is determined to be closed, and the right vertical air guide plate is also determined to be closed. Since youth and the elderly are more sensitive to direct airflow from the air conditioner, closing the left and right vertical air guide plates can prevent the air conditioner from blowing directly on the target user. In response to the left and right vertical air guide plates being closed, the central airflow strategy is updated. For example, based on the original central airflow strategy, the deflection angles of both the left and right vertical air guide plates are adjusted to 0 degrees (i.e., closed) to achieve gentle airflow through the ventilation holes.

[0159] In the implementation steps of this disclosure, when teenage users and / or elderly users are in the middle area, the direct airflow is converted into a gentle breeze by closing the vertical air guide plates with ventilation holes on both sides, thereby improving the air supply comfort of specific groups.

[0160] Figure 6 This is a block diagram illustrating an air conditioning zone air supply control device according to some embodiments of the present disclosure. Figure 6 As shown, the air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right areas, respectively. The air conditioner zone air supply control device 600 includes an acquisition module 601, a generation module 602, and a control module 603. The acquisition module 601 is used to acquire the user location information of the target user in the left and right areas; the generation module 602 is used to generate an air conditioning air supply strategy based on the user location information; and the control module 603 is used to control the air supply angle of the left and right air supply zones respectively according to the air conditioning air supply strategy.

[0161] In one possible implementation, when generating an air conditioning air supply strategy based on user location information, the generation module 602 is specifically used to: respond to user location information, determine that the target user is only in the left area, and generate a left-side air supply strategy for the air conditioner; or, respond to user location information, determine that the target user is only in the right area, and generate a right-side air supply strategy for the air conditioner; or, respond to user location information, determine that the target user is in both the left and right areas, and generate both left and right-side air supply strategies for the air conditioner; wherein, the left and right-side air supply strategies are a left-side air supply strategy and a right-side air supply strategy; and the left-side air supply strategy, or the right-side air supply strategy, or the both left and right-side air supply strategy is determined as the air conditioning air supply strategy.

[0162] In one possible implementation, a middle region is determined from the left and right regions; wherein the center line of the middle region is the dividing line between the left and right regions; when generating an air conditioning air supply strategy based on user location information, the generation module 602 is specifically used to: in response to user location information, determine that the target user is in the middle region, generate a middle air supply strategy for the air conditioner; and determine the middle air supply strategy as the air conditioning air supply strategy.

[0163] In one possible implementation, the left air supply zone includes an upper left air supply zone and a lower left air supply zone; wherein, the upper left air supply zone is provided with an upper left horizontal air guide plate, the lower left air supply zone is provided with a lower left horizontal air guide plate, and the left air supply zone is provided with a left vertical air guide plate; the right air supply zone includes an upper right air supply zone and a lower right air supply zone; wherein, the upper right air supply zone is provided with an upper right horizontal air guide plate, the lower right air supply zone is provided with a lower right horizontal air guide plate, and the right air supply zone is provided with a right vertical air guide plate; the air conditioning air supply strategy is used to indicate the rotation angle of the upper left horizontal air guide plate, the rotation angle of the lower left horizontal air guide plate, the deflection angle of the left vertical air guide plate, the rotation angle of the upper right horizontal air guide plate, the rotation angle of the lower right horizontal air guide plate, and the deflection angle of the right vertical air guide plate when supplying air to the area where the target user is located.

[0164] In one possible implementation, the left-side region includes at least a left-side region at a first distance, a left-side region at a second distance, and a left-side region at a third distance, wherein the first distance is less than the second distance, and the second distance is less than the third distance; when the generation module 602 determines, in response to the user's location information, that the target user is only in the left-side region and generates the left-side air supply strategy of the air conditioner, it is specifically used to: determine, in response to the user's location information, that the target user is in the left-side region at the first distance and the left-side region at the second distance, and generate a first left-side air supply strategy of the air conditioner; wherein, the first left-side air supply strategy is used to indicate that the lower left air supply area is used to supply air to the left-side region at the first distance, the upper left air supply area is used to supply air to the left-side region at the second distance, the rotation angle of the lower left horizontal air guide plate is the first left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the second left-side rotation angle, the first left-side rotation angle is less than the second left-side rotation angle, and the deflection angle of the left vertical air guide plate is the first left-side deflection angle; and the first left-side air supply strategy is determined as the left-side air supply strategy.

[0165] In one possible implementation, when the generation module 602 determines, in response to user location information, that the target user is only in the left-side area and generates a left-side air supply strategy for the air conditioner, it is specifically used to: determine, in response to user location information, that the target user is in the left-side area at a first distance and the left-side area at a third distance, and generate a second left-side air supply strategy for the air conditioner; wherein, the second left-side air supply strategy is used to indicate that the lower left air supply area is used to supply air to the left-side area at the first distance, the upper left air supply area is used to supply air to the left-side area at the third distance, the rotation angle of the lower left horizontal air guide plate is the third left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the fourth left-side rotation angle, the third left-side rotation angle is less than the fourth left-side rotation angle, and the deflection angle of the left vertical air guide plate is the second left-side deflection angle; and the second left-side air supply strategy is determined as the left-side air supply strategy.

[0166] In one possible implementation, when the generation module 602 determines that the target user is only in the left-side area in response to the user's location information and generates the left-side air supply strategy for the air conditioner, it is specifically used to: determine that the target user is in the left-side area at a second distance and the left-side area at a third distance in response to the user's location information, and generate a third left-side air supply strategy for the air conditioner; wherein, the third left-side air supply strategy is used to indicate that the lower left air supply area is used to supply air to the left-side area at the second distance, the upper left air supply area is used to supply air to the left-side area at the third distance, the rotation angle of the lower left horizontal air guide plate is the fifth left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the sixth left-side rotation angle, the fifth left-side rotation angle is less than the sixth left-side rotation angle, and the deflection angle of the left vertical air guide plate is the third left-side deflection angle; and the third left-side air supply strategy is determined as the left-side air supply strategy.

[0167] In one possible implementation, when the generation module 602 determines, in response to user location information, that the target user is only in the left-side area and generates a left-side air supply strategy for the air conditioner, it is specifically used to: determine, in response to user location information, that the target user is in the left-side area at a first distance, a second distance, and a third distance, and generate a fourth left-side air supply strategy for the air conditioner; wherein, the fourth left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left-side areas at the first and second distances, the upper left air supply area to supply air to the left-side area at the third distance, the rotation angle of the lower left horizontal air guide plate is the seventh left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the eighth left-side rotation angle, the seventh left-side rotation angle is less than the eighth left-side rotation angle, and the deflection angle of the left vertical air guide plate is the fourth left-side deflection angle; and the fourth left-side air supply strategy is determined as the left-side air supply strategy.

[0168] In one possible implementation, the intermediate region includes an intermediate region of a first distance, an intermediate region of a second distance, and an intermediate region of a third distance, wherein the first distance is less than the second distance, and the second distance is less than the third distance; when the generation module 602 determines that the target user is in the intermediate region in response to the user location information and generates the intermediate air supply strategy for the air conditioner, it is specifically used to: determine that the target user is in the intermediate region of the first distance and the intermediate region of the second distance in response to the user location information, and generate a first intermediate air supply strategy for the air conditioner; and determine the first intermediate air supply strategy as the intermediate air supply strategy; wherein the first intermediate air supply strategy is used to indicate the lower left air supply area and the lower right air supply area. The air supply zone is used to supply air to the middle area of ​​the first distance, and the upper left and upper right air supply zones are used to supply air to the middle area of ​​the second distance; the rotation angle of the lower left horizontal air guide plate is the first left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the second left rotation angle, with the first left rotation angle being smaller than the second left rotation angle; the rotation angle of the lower right horizontal air guide plate is the first right rotation angle, and the rotation angle of the upper right horizontal air guide plate is the second right rotation angle, with the first right rotation angle being smaller than the second right rotation angle; the deflection angle of the left vertical air guide plate is the first middle deflection angle; and the deflection angle of the right vertical air guide plate is the second middle deflection angle.

[0169] In one possible implementation, when the generation module 602 determines that the target user is in the middle area in response to the user location information and generates the air conditioning's middle air supply strategy, it is specifically used to: determine that the target user is in the middle area of ​​the first distance and the middle area of ​​the third distance in response to the user location information, and generate the air conditioning's second middle air supply strategy; and determine the second middle air supply strategy as the middle air supply strategy; wherein, the second middle air supply strategy is used to indicate that the lower left air supply area and the lower right air supply area are used to supply air to the middle area of ​​the first distance, and the upper left air supply area and the upper right air supply area are used to supply air to the middle area of ​​the third distance; the rotation angle of the lower left horizontal air guide plate is the third left rotation angle, the rotation angle of the upper left horizontal air guide plate is the fourth left rotation angle, and the third left rotation angle is less than the fourth left rotation angle; the rotation angle of the lower right horizontal air guide plate is the third right rotation angle, the rotation angle of the upper right horizontal air guide plate is the fourth right rotation angle, and the third right rotation angle is less than the fourth right rotation angle; the deflection angle of the left vertical air guide plate is the third middle deflection angle; and the deflection angle of the right vertical air guide plate is the fourth middle deflection angle.

[0170] In one possible implementation, when the generation module 602 determines that the target user is in the intermediate area in response to the user location information and generates the intermediate air supply strategy for the air conditioner, it is specifically used to: determine that the target user is in the intermediate area of ​​the second distance and the intermediate area of ​​the third distance in response to the user location information, and generate a third intermediate air supply strategy for the air conditioner; and determine the third intermediate air supply strategy as the intermediate air supply strategy; wherein, the third intermediate air supply strategy is used to instruct the lower left air supply area and the lower right air supply area to supply air to the intermediate area of ​​the second distance, and the upper left air supply area and the upper right air supply area... Used to supply air to the middle area of ​​the third distance; the rotation angle of the lower left horizontal air guide plate is the fifth left rotation angle, the rotation angle of the upper left horizontal air guide plate is the sixth left rotation angle, and the fifth left rotation angle is less than the sixth left rotation angle; the rotation angle of the lower right horizontal air guide plate is the fifth right rotation angle, the rotation angle of the upper right horizontal air guide plate is the sixth right rotation angle, and the fifth right rotation angle is less than the sixth right rotation angle; the deflection angle of the left vertical air guide plate is the fifth middle deflection angle; the deflection angle of the right vertical air guide plate is the sixth middle deflection angle.

[0171] In one possible implementation, when the generation module 602 determines that the target user is in the intermediate area in response to the user location information and generates the intermediate air supply strategy for the air conditioner, it is specifically used to: determine that the target user is in the intermediate area of ​​the first distance, the intermediate area of ​​the second distance, and the intermediate area of ​​the third distance in response to the user location information, and generate a fourth intermediate air supply strategy for the air conditioner; and determine the fourth intermediate air supply strategy as the intermediate air supply strategy; wherein, the fourth intermediate air supply strategy is used to instruct the lower left air supply area and the lower right air supply area to supply air to the intermediate area of ​​the first distance and the intermediate area of ​​the second distance, and the lower left air supply area... The upper and upper right air supply zones are used to supply air to the middle area of ​​the third distance; the rotation angle of the lower left horizontal air guide plate is the seventh left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the eighth left rotation angle, with the seventh left rotation angle being smaller than the eighth left rotation angle; the rotation angle of the lower right horizontal air guide plate is the seventh right rotation angle, and the rotation angle of the upper right horizontal air guide plate is the eighth right rotation angle, with the seventh right rotation angle being smaller than the eighth right rotation angle; the deflection angle of the left vertical air guide plate is the seventh middle deflection angle; and the deflection angle of the right vertical air guide plate is the eighth middle deflection angle.

[0172] In one possible implementation, ventilation holes are arranged on the left vertical air guide plate; the air conditioning zone air supply control device 600 is also used to: obtain user type information of the target user; determine that the left vertical air guide plate is in a closed state in response to the user type information including youth type information and / or elderly type information; and update the left air supply strategy in response to the left vertical air guide plate being in a closed state.

[0173] In one possible implementation, ventilation holes are arranged on the left vertical air guide plate and ventilation holes are arranged on the right vertical air guide plate; the air conditioning zone air supply control device 600 is further configured to: obtain user type information of the target user; in response to the user type information including youth type information and / or elderly type information, determine that the left vertical air guide plate is in a closed state and the right vertical air guide plate is in a closed state; in response to the left vertical air guide plate being in a closed state and the right vertical air guide plate being in a closed state, update the intermediate air supply strategy.

[0174] Regarding the air conditioning zone air supply control device 600 in the above embodiments, the specific methods by which each module performs its operation have been described in detail in the embodiments related to the method, and will not be elaborated here.

[0175] Figure 7 This is a block diagram illustrating an air conditioner according to some embodiments of the present disclosure. (Refer to...) Figure 7 The air conditioner 800 may include one or more of the following components: a processing component 802, a memory 804, a power component 806, a multimedia component 808, an audio component 810, an input / output (I / O) interface 812, a sensor component 814, and a communication component 816.

[0176] Processing component 802 typically controls the overall operation of air conditioner 800, such as operations associated with display, telephone calls, data communication, camera operation, and recording. Processing component 802 may include one or more processors 820 to execute instructions to complete all or part of the steps of the methods described above. Furthermore, processing component 802 may include one or more modules to facilitate interaction between processing component 802 and other components. For example, processing component 802 may include a multimedia module to facilitate interaction between multimedia component 808 and processing component 802.

[0177] Memory 804 is configured to store various types of data to support the operation of air conditioner 800. Examples of this data include instructions for any application or method operating on air conditioner 800, contact data, phonebook data, messages, pictures, videos, etc. Memory 804 can be implemented by any type of volatile or non-volatile storage device or a combination thereof, such as static random access memory (SRAM), electrically erasable programmable read-only memory (EEPROM), erasable programmable read-only memory (EPROM), programmable read-only memory (PROM), read-only memory (ROM), magnetic storage, flash memory, magnetic disk, or optical disk.

[0178] The power supply component 806 provides power to various components of the air conditioner 800. The power supply component 806 may include a power management system, one or more power sources, and other components associated with generating, managing, and distributing power to the air conditioner 800.

[0179] The multimedia component 808 includes a screen that provides an output interface between the air conditioner 800 and the user. In some embodiments, the screen may include a liquid crystal display (LCD) and a touch panel (TP). If the screen includes a touch panel, the screen may be implemented as a touchscreen to receive input signals from the user. The touch panel includes one or more touch sensors to sense touches, swipes, and gestures on the touch panel. The touch sensors may sense not only the boundaries of touch or swipe actions but also the duration and pressure associated with the touch or swipe operation. In some embodiments, the multimedia component 808 includes a front-facing camera and / or a rear-facing camera. When the air conditioner 800 is in an operating mode, such as a shooting mode or a video mode, the front-facing camera and / or the rear-facing camera may receive external multimedia data. Each front-facing camera and rear-facing camera may be a fixed optical lens system or have focal length and optical zoom capabilities.

[0180] Audio component 810 is configured to output and / or input audio signals. For example, audio component 810 includes a microphone (MIC) configured to receive external audio signals when the air conditioner 800 is in an operating mode, such as call mode, recording mode, and voice recognition mode. The received audio signals may be further stored in memory 804 or transmitted via communication component 816. In some embodiments, audio component 810 also includes a speaker for outputting audio signals.

[0181] I / O interface 812 provides an interface between processing component 802 and peripheral interface modules, such as keyboards, click wheels, buttons, etc. These buttons may include, but are not limited to, home buttons, volume buttons, power buttons, and lock buttons.

[0182] Sensor assembly 814 includes one or more sensors for providing status assessments of various aspects of the air conditioner 800. For example, sensor assembly 814 can detect the on / off state of the air conditioner 800, the relative positioning of components such as the display and keypad of the air conditioner 800, changes in the position of the air conditioner 800 or one of its components, the presence or absence of user contact with the air conditioner 800, the orientation or acceleration / deceleration of the air conditioner 800, and temperature changes of the air conditioner 800. Sensor assembly 814 may include a proximity sensor configured to detect the presence of nearby objects without any physical contact. Sensor assembly 814 may also include a light sensor, such as a CMOS or CCD image sensor, for use in imaging applications. In some embodiments, sensor assembly 814 may also include an accelerometer, a gyroscope, a magnetometer, a pressure sensor, or a temperature sensor.

[0183] Communication component 816 is configured to facilitate wired or wireless communication between air conditioner 800 and other devices. Air conditioner 800 can access wireless networks based on communication standards such as WiFi, 3G, 4G, 5G, other communication standards, or combinations thereof. In some embodiments of this disclosure, communication component 816 receives broadcast signals or broadcast-related information from an external broadcast management system via a broadcast channel. In some embodiments of this disclosure, communication component 816 also includes a near-field communication (NFC) module to facilitate short-range communication. For example, the NFC module may be implemented based on radio frequency identification (RFID) technology, Infrared Data Association (IrDA) technology, ultra-wideband (UWB) technology, Bluetooth (BT) technology, and other technologies.

[0184] In some embodiments of this disclosure, the air conditioner 800 may be implemented by one or more application-specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field-programmable gate arrays (FPGAs), controllers, microcontrollers, microprocessors, or other electronic components to perform the methods described above.

[0185] In some embodiments of this disclosure, a non-transitory computer-readable storage medium including instructions is also provided, such as a memory 804 including instructions that can be executed by a processor 820 of an air conditioner 800 to perform the above-described method. For example, the non-transitory computer-readable storage medium may be a ROM, random access memory (RAM), CD-ROM, magnetic tape, floppy disk, and optical data storage device, etc.

[0186] A non-transitory computer-readable storage medium, when the instructions in the storage medium are executed by the processor of an air conditioner, enables the air conditioner to perform an air conditioning zone air supply control method. The air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right areas, respectively. The method includes: obtaining user location information of a target user in the left and right areas; generating an air conditioning air supply strategy based on the user location information; and controlling the air supply angle of the left and right air supply zones respectively according to the air conditioning air supply strategy.

[0187] This disclosure also provides a computer program product, including a computer program that, when executed by a processor, implements the air conditioning zone air supply control method provided in any of the above embodiments.

[0188] Figure 8 This is a block diagram of a chip system illustrated according to some embodiments of the present disclosure, such as... Figure 8 As shown, the chip system 900 includes at least one processor 901 and at least one interface circuit 902. The processor 901 and the interface circuit 902 are interconnected via lines. For example, the interface circuit 902 can be used to receive signals from other devices (e.g., the memory of an electronic device). As another example, the interface circuit 902 can be used to send signals to other devices (e.g., the processor 901). Exemplarily, the interface circuit 902 can read instructions stored in memory and send those instructions to the processor 901. When the instructions are executed by the processor 901, the processor 901 can perform the steps in the above embodiments. Of course, the chip system may also include other discrete devices, and some embodiments of this disclosure do not specifically limit this.

[0189] In some embodiments of this disclosure, the interface circuit 902 can acquire data, program instructions, and / or information from the internal storage area of ​​the chip system; it can also acquire data, program instructions, and / or information from outside the chip system.

[0190] Optionally, the chip system may also include memory for storing necessary computer programs and data.

[0191] Those skilled in the art will also understand that the various illustrative logical blocks and steps listed in the embodiments of this application can be implemented by electronic hardware, computer software, or a combination of both. Whether such functionality is implemented through hardware or software depends on the specific application and the overall system design requirements. Those skilled in the art can implement the functionality using various methods for each specific application, but such implementation should not be construed as exceeding the scope of protection of the embodiments of this application.

[0192] In the above detailed description, reference has been made to the accompanying drawings, which illustrate specific aspects of this disclosure by way of illustration. In this regard, terms indicating direction or positional relationship, such as “center,” “longitudinal,” “lateral,” “length,” “width,” “thickness,” “upper,” “lower,” “front,” “rear,” “left,” “right,” “vertical,” “horizontal,” “top,” “bottom,” “inner,” “outer,” “clockwise,” “counterclockwise,” “axial,” “radial,” and “circumferential,” are used with reference to the orientation of the described figures. Since components of the described device can be positioned in multiple different orientations, directional terms are used for illustrative purposes and not for limitation. It should be understood that other aspects can be utilized and structural or logical changes can be made without departing from the concept of this disclosure. Therefore, the following detailed description should not be considered limiting.

[0193] It should be understood that, unless otherwise specifically indicated, features of various embodiments of this disclosure described herein can be combined with each other. As used herein, the term “and / or” includes any one of the relevant listed items and any combination of any two or more; similarly, “at least one of…” includes any one of the relevant listed items and any combination of any two or more.

[0194] It should be understood that, unless otherwise expressly specified and limited, the terms "joining," "attaching," "installing," "connecting," "linking," "fixing," etc., used in the embodiments of this disclosure should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection, an electrical connection, or a connection that allows communication between them; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components, unless otherwise expressly limited. Those skilled in the art can understand the specific meaning of the above terms herein based on the specific circumstances.

[0195] Furthermore, the term "above" as used herein with respect to components, elements, or material layers formed or located "above" a surface may be used to indicate that the component, element, or material layer is "indirectly" positioned (e.g., placed, formed, deposited, etc.) on the surface such that one or more additional components, elements, or layers are arranged between the surface and the component, element, or material layer. However, the term "above" as used with respect to components, elements, or material layers formed or located "above" a surface may also optionally have a specific meaning: that the component, element, or material layer is "directly" positioned (e.g., placed, formed, deposited, etc.) on the surface, for example, in direct contact with the surface.

[0196] Although terms such as “first,” “second,” and “third” may be used herein to describe various components, parts, regions, layers, or sections, these components, parts, regions, layers, or sections are not limited to these terms. Rather, these terms are used only to distinguish one component, part, region, layer, or section from another. Therefore, without departing from the teachings of the examples described herein, the first component, part, region, layer, or section mentioned in the examples may also be referred to as the second component, part, region, layer, or section. Furthermore, the terms “first” and “second” are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of indicated technical features. Thus, a feature defined as “first” or “second” may explicitly or implicitly include at least one of that feature. In the description herein, “a plurality” means at least two, such as two, three, etc., unless otherwise explicitly specified.

[0197] It should be understood that spatial relative terms, such as “above,” “upper,” “below,” and “lower,” are used herein to describe the relationship between one element and another shown in the figures. In addition to the orientation depicted in the figures, these spatial relative terms are also intended to encompass different orientations of the device in use or operation. For example, if the device in the figures is flipped, an element described as “above” or “upper” relative to another element would be “below” or “lower” relative to that other element. Thus, depending on the spatial orientation of the device, the term “above” encompasses both above and below orientations. Devices may have other orientations (e.g., rotated 90 degrees or in other orientations), and the spatial relative terms used herein should be interpreted accordingly.

[0198] Furthermore, the term “exemplary” is used herein to mean serving as an example, instance, or illustration. Any aspect or design described herein as “exemplary” is not necessarily to be construed as advantageous compared to other aspects or designs. Rather, the use of the term “exemplary” is intended to present the concept in a concrete manner. As used herein, the term “or” is intended to mean an inclusive “or” rather than an exclusive “or.” That is, unless otherwise specified or clear from the context, “X applies A or B” is intended to mean any of the natural inclusive arrangements. That is, “X applies A or B” satisfies any of the foregoing instances if X applies A; X applies B; or both X applies A and B. Additionally, unless otherwise specified or clear from the context to refer to the singular form, the articles “a” and “an” as used in this application and the appended claims are generally understood to mean “one or more.”

[0199] Similarly, although this disclosure has been shown and described with respect to one or more implementations, equivalent variations and modifications will occur to those skilled in the art upon reading and understanding this specification and the accompanying drawings. This disclosure includes all such modifications and variations and is limited only by the scope of the claims. In particular, with respect to the various functions performed by the components described above (e.g., elements, resources, etc.), unless otherwise indicated, the terminology used to describe such components is intended to correspond to any component (functionally equivalent) that performs the specific function of the described component, even if structurally not equivalent to the disclosed structure. Furthermore, although specific features of this disclosure may have been disclosed with respect to only one of several implementations, such features may be combined with one or more other features of other implementations, as may be desired and advantageous to any given or particular application. Moreover, with regard to the terms “comprising,” “owning,” “having,” “having,” or variations thereof as used in the detailed description or claims, such terms are intended to be inclusive in a manner similar to the term “including.”

[0200] Other embodiments of this disclosure will readily occur to those skilled in the art upon consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of this disclosure that follow the general principles of this disclosure and include common knowledge or customary techniques in the art not disclosed herein. The specification and examples are to be considered exemplary only, and the true scope and spirit of this disclosure are indicated by the following claims.

[0201] It should be understood that this disclosure is not limited to the precise structures described above and shown in the accompanying drawings, and various modifications and changes can be made without departing from its scope. The scope of this disclosure is limited only by the appended claims.

Claims

1. A method for controlling air supply in air conditioning zones, characterized in that, The air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right sides of the area, respectively, including: Obtain the user location information of the target user in the left and right regions; Based on the user's location information, an air conditioning air supply strategy is generated; According to the air conditioning air supply strategy, the air supply angles of the left air supply zone and the right air supply zone are controlled respectively.

2. The air conditioning zoned air supply control method according to claim 1, characterized in that, The step of generating an air conditioning air supply strategy based on the user location information includes: In response to the user location information, it is determined that the target user is only in the left-side area, and a left-side air supply strategy for the air conditioner is generated; Alternatively, in response to the user location information, if it is determined that the target user is only in the right-side area, a right-side air supply strategy for the air conditioner is generated; Alternatively, in response to the user location information, it is determined that the target user is in the left and right regions, and a left and right side air supply strategy for the air conditioner is generated; wherein, the left and right side air supply strategy is the left side air supply strategy and the right side air supply strategy; The left-side air supply strategy, or the right-side air supply strategy, or the left and right side air supply strategy are determined as the air conditioning air supply strategy.

3. The air conditioning zoned air supply control method according to claim 2, characterized in that, Also includes: A middle region is determined from the left region and the right region; wherein the center line of the middle region is the dividing line between the left region and the right region; The step of generating an air conditioning air supply strategy based on the user location information includes: In response to the user location information, it is determined that the target user is in the intermediate area, and an intermediate air supply strategy for the air conditioner is generated; The intermediate air supply strategy is defined as the air conditioning air supply strategy.

4. The air conditioning zoned air supply control method according to claim 3, characterized in that, The left air supply zone includes an upper left air supply zone and a lower left air supply zone; wherein, the upper left air supply zone is provided with an upper left horizontal air guide plate, the lower left air supply zone is provided with a lower left horizontal air guide plate, and the left air supply zone is provided with a left vertical air guide plate. The right air supply zone includes an upper right air supply zone and a lower right air supply zone; wherein, the upper right air supply zone is provided with an upper right horizontal air guide plate, the lower right air supply zone is provided with a lower right horizontal air guide plate, and the right air supply zone is provided with a right vertical air guide plate. The air conditioning air delivery strategy is used to indicate the rotation angle of the upper left horizontal air guide plate, the rotation angle of the lower left horizontal air guide plate, the deflection angle of the left vertical air guide plate, the rotation angle of the upper right horizontal air guide plate, the rotation angle of the lower right horizontal air guide plate, and the deflection angle of the right vertical air guide plate when delivering air to the area where the target user is located.

5. The air conditioning zoned air supply control method according to claim 4, characterized in that, The left-side region includes at least a left-side region at a first distance, a left-side region at a second distance, and a left-side region at a third distance, wherein the first distance is smaller than the second distance, and the second distance is smaller than the third distance; The step of responding to the user location information, determining that the target user is only in the left-side area, and generating the left-side airflow strategy for the air conditioner includes: In response to the user location information, it is determined that the target user is in the left-hand region of the first distance and the left-hand region of the second distance, and a first left-hand air supply strategy for the air conditioner is generated; Wherein, the first left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left area of ​​the first distance, the upper left air supply area to supply air to the left area of ​​the second distance, the rotation angle of the lower left horizontal air guide plate is the first left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the second left-side rotation angle, the first left-side rotation angle is less than the second left-side rotation angle, and the deflection angle of the left vertical air guide plate is the first left-side deflection angle. The first left-side air supply strategy is determined as the left-side air supply strategy.

6. The air conditioning zoned air supply control method according to claim 5, characterized in that, The step of responding to the user location information, determining that the target user is only in the left-side area, and generating the left-side airflow strategy for the air conditioner includes: In response to the user location information, it is determined that the target user is in the left-hand region of the first distance and the left-hand region of the third distance, and a second left-hand air supply strategy for the air conditioner is generated; Wherein, the second left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left area of ​​the first distance, the upper left air supply area to supply air to the left area of ​​the third distance, the rotation angle of the lower left horizontal air guide plate is the third left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the fourth left-side rotation angle, the third left-side rotation angle is smaller than the fourth left-side rotation angle, and the deflection angle of the left vertical air guide plate is the second left-side deflection angle. The second left-side air supply strategy is determined as the left-side air supply strategy.

7. The air conditioning zoned air supply control method according to claim 5, characterized in that, The step of responding to the user location information, determining that the target user is only in the left-side area, and generating the left-side airflow strategy for the air conditioner includes: In response to the user location information, it is determined that the target user is in the left-hand region of the second distance and the left-hand region of the third distance, and a third left-hand air supply strategy for the air conditioner is generated; Wherein, the third left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left area of ​​the second distance, the upper left air supply area to supply air to the left area of ​​the third distance, the rotation angle of the lower left horizontal air guide plate is the fifth left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the sixth left-side rotation angle, the fifth left-side rotation angle is smaller than the sixth left-side rotation angle, and the deflection angle of the left vertical air guide plate is the third left-side deflection angle; The third left-side air supply strategy is defined as the left-side air supply strategy.

8. The air conditioning zoned air supply control method according to claim 5, characterized in that, The step of responding to the user location information, determining that the target user is only in the left-side area, and generating the left-side airflow strategy for the air conditioner includes: In response to the user location information, it is determined that the target user is in the left-hand region of the first distance, the left-hand region of the second distance, and the left-hand region of the third distance, and a fourth left-hand air supply strategy for the air conditioner is generated; Wherein, the fourth left-side air supply strategy is used to instruct the lower left air supply area to supply air to the left area of ​​the first distance and the left area of ​​the second distance, the upper left air supply area to supply air to the left area of ​​the third distance, the rotation angle of the lower left horizontal air guide plate is the seventh left-side rotation angle, the rotation angle of the upper left horizontal air guide plate is the eighth left-side rotation angle, the seventh left-side rotation angle is smaller than the eighth left-side rotation angle, and the deflection angle of the left vertical air guide plate is the fourth left-side deflection angle; The fourth left-side air supply strategy is defined as the left-side air supply strategy.

9. The air conditioning zoned air supply control method according to claim 4, characterized in that, The intermediate region includes an intermediate region of a first distance, an intermediate region of a second distance, and an intermediate region of a third distance, wherein the first distance is smaller than the second distance, and the second distance is smaller than the third distance; The step of responding to the user location information, determining that the target user is in the intermediate area, and generating the intermediate air supply strategy for the air conditioner includes: In response to the user location information, it is determined that the target user is in the middle area of ​​the first distance and the middle area of ​​the second distance, and a first intermediate air supply strategy for the air conditioner is generated; The first intermediate air supply strategy is defined as the intermediate air supply strategy; Wherein, the first intermediate air supply strategy is used to instruct the lower left air supply area and the lower right air supply area to supply air to the middle area of ​​the first distance, and the upper left air supply area and the upper right air supply area to supply air to the middle area of ​​the second distance; The rotation angle of the lower left horizontal air guide plate is the first left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the second left rotation angle. The first left rotation angle is smaller than the second left rotation angle. The rotation angle of the lower right horizontal air guide plate is the first right side rotation angle, and the rotation angle of the upper right horizontal air guide plate is the second right side rotation angle. The first right side rotation angle is smaller than the second right side rotation angle. The deflection angle of the left vertical air guide plate is the first intermediate deflection angle; the deflection angle of the right vertical air guide plate is the second intermediate deflection angle.

10. The air conditioning zoned air supply control method according to claim 9, characterized in that, The step of responding to the user location information, determining that the target user is in the intermediate area, and generating the intermediate air supply strategy for the air conditioner includes: In response to the user location information, it is determined that the target user is in the middle area of ​​the first distance and the middle area of ​​the third distance, and a second intermediate air supply strategy for the air conditioner is generated. The second intermediate air supply strategy is defined as the intermediate air supply strategy; Wherein, the second intermediate air supply strategy is used to instruct the lower left air supply area and the lower right air supply area to supply air to the middle area of ​​the first distance, and the upper left air supply area and the upper right air supply area to supply air to the middle area of ​​the third distance. The rotation angle of the lower left horizontal air guide plate is the third left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the fourth left rotation angle. The third left rotation angle is smaller than the fourth left rotation angle. The rotation angle of the lower right horizontal air guide plate is the third right side rotation angle, and the rotation angle of the upper right horizontal air guide plate is the fourth right side rotation angle. The third right side rotation angle is smaller than the fourth right side rotation angle. The deflection angle of the left vertical air guide plate is the third intermediate deflection angle; the deflection angle of the right vertical air guide plate is the fourth intermediate deflection angle.

11. The air conditioning zoned air supply control method according to claim 9, characterized in that, The step of responding to the user location information, determining that the target user is in the intermediate area, and generating the intermediate air supply strategy for the air conditioner includes: In response to the user location information, it is determined that the target user is in the middle area of ​​the second distance and the middle area of ​​the third distance, and a third intermediate air supply strategy for the air conditioner is generated; The third intermediate air supply strategy is defined as the intermediate air supply strategy; The third intermediate air supply strategy is used to instruct the lower left air supply area and the lower right air supply area to supply air to the middle area of ​​the second distance, and the upper left air supply area and the upper right air supply area to supply air to the middle area of ​​the third distance. The rotation angle of the lower left horizontal air guide plate is the fifth left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the sixth left rotation angle. The fifth left rotation angle is smaller than the sixth left rotation angle. The rotation angle of the lower right horizontal air guide plate is the fifth right side rotation angle, and the rotation angle of the upper right horizontal air guide plate is the sixth right side rotation angle. The fifth right side rotation angle is smaller than the sixth right side rotation angle. The deflection angle of the left vertical air guide plate is the fifth intermediate deflection angle; the deflection angle of the right vertical air guide plate is the sixth intermediate deflection angle.

12. The air conditioning zoned air supply control method according to claim 9, characterized in that, The step of responding to the user location information, determining that the target user is in the intermediate area, and generating the intermediate air supply strategy for the air conditioner includes: In response to the user location information, it is determined that the target user is in the middle area of ​​the first distance, the middle area of ​​the second distance and the middle area of ​​the third distance, and a fourth intermediate air supply strategy for the air conditioner is generated. The fourth intermediate air supply strategy is defined as the intermediate air supply strategy; The fourth intermediate air supply strategy is used to instruct the lower left air supply area and the lower right air supply area to supply air to the middle area of ​​the first distance and the middle area of ​​the second distance, and the upper left air supply area and the upper right air supply area to supply air to the middle area of ​​the third distance. The rotation angle of the lower left horizontal air guide plate is the seventh left rotation angle, and the rotation angle of the upper left horizontal air guide plate is the eighth left rotation angle. The seventh left rotation angle is smaller than the eighth left rotation angle. The rotation angle of the lower right horizontal air guide plate is the seventh right side rotation angle, and the rotation angle of the upper right horizontal air guide plate is the eighth right side rotation angle. The seventh right side rotation angle is smaller than the eighth right side rotation angle. The deflection angle of the left vertical air guide plate is the seventh intermediate deflection angle; the deflection angle of the right vertical air guide plate is the eighth intermediate deflection angle.

13. The air conditioning zoned air supply control method according to any one of claims 5 to 8, characterized in that, Ventilation holes are arranged on the left vertical air guide plate; The method further includes: Obtain the user type information of the target user; In response to the fact that the user type information includes youth type information and / or elderly type information, it is determined that the left vertical air guide plate is in a closed state; In response to the left vertical air guide plate being in a closed state, the left air supply strategy is updated.

14. The air conditioning zoned air supply control method according to any one of claims 9 to 12, characterized in that, Ventilation holes are arranged on the left vertical air guide plate and on the right vertical air guide plate; The method further includes: Obtain the user type information of the target user; In response to the user type information including youth type information and / or elderly type information, it is determined that the left vertical air guide plate is in a closed state and the right vertical air guide plate is in a closed state; In response to the left vertical air guide plate being in a closed state and the right vertical air guide plate being in a closed state, the intermediate air supply strategy is updated.

15. An air conditioning zoned air supply control device, characterized in that, The air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right sides of the area, respectively, including: The acquisition module is used to acquire the user location information of the target user in the left and right regions; The generation module is used to generate an air conditioning air supply strategy based on the user location information; The control module is used to control the air supply angles of the left air supply zone and the right air supply zone respectively according to the air conditioning air supply strategy.

16. An air conditioner, characterized in that, include: processor; Memory used to store processor-executable instructions; The processor is configured to execute the air conditioning zone air supply control method according to any one of claims 1 to 14.

17. A non-transitory computer-readable storage medium, characterized in that, When the instructions in the storage medium are executed by the air conditioner's processor, the air conditioner is able to perform an air conditioning zoned air supply control method. The air conditioner has a left air supply zone and a right air supply zone, which are used to independently supply air to the left and right sides of the area, respectively. The method includes: Obtain the user location information of the target user in the left and right regions; Based on the user's location information, an air conditioning air supply strategy is generated; According to the air conditioning air supply strategy, the air supply angles of the left air supply zone and the right air supply zone are controlled respectively.

18. A computer program product, characterized in that, It includes a computer program that, when executed by a processor, implements the air conditioning zone air supply control method as described in any one of claims 1 to 14.

19. A chip system, characterized in that, The chip system includes a processing unit and an interface circuit. The processing unit obtains program instructions through the interface circuit, and the program instructions are executed by the processing unit. The processing unit is used to execute the air conditioning zone air supply control method as described in any one of claims 1 to 14.