CN110822556A

CN110822556A - Double-air-duct air conditioner, control method and control device thereof, and readable storage medium

Info

Publication number: CN110822556A
Application number: CN201911183208.0A
Authority: CN
Inventors: 乐丽
Original assignee: Midea Group Co Ltd; GD Midea Air Conditioning Equipment Co Ltd
Current assignee: Midea Group Co Ltd; GD Midea Air Conditioning Equipment Co Ltd
Priority date: 2019-11-27
Filing date: 2019-11-27
Publication date: 2020-02-21
Anticipated expiration: 2039-11-27
Also published as: CN110822556B

Abstract

The invention discloses a control method of a double-air-channel air conditioner, which comprises the following steps: acquiring position information of a target user in a space where the double-air-channel air conditioner is located; determining a first air outlet parameter of the first air outlet area and a second air outlet parameter of the second air outlet area according to the position information; and controlling the first air guide member to operate according to the first air outlet parameter, and controlling the second air guide member to operate according to the second air outlet parameter, so that the double-air-channel air conditioner exhausts air towards the target user. The invention also discloses a control device, the double-air-channel air conditioner and a readable storage medium. The invention aims to realize that the outlet air of the double-air-channel air conditioner can be automatically blown to the position of a user, thereby improving the comfort of the position of the user.

Description

Double-air-duct air conditioner, control method and control device thereof, and readable storage medium

Technical Field

The invention relates to the technical field of air conditioners, in particular to a double-air-channel air conditioner control method, a control device, a double-air-channel air conditioner and a readable storage medium.

Background

The double-air-channel air conditioner is generally provided with two independent air channels, indoor return air exchanges heat in the two independent air channels, and air after heat exchange is sent into a room through two independent air outlets respectively and then is mixed so as to adjust the indoor environment.

However, the air outlet of the two air outlets of the existing dual-duct air conditioner cannot be automatically adjusted, and when a user wants the air outlet of the air conditioner to blow to the position of the air outlet, the user can only input a control command by himself to achieve air outlet adjustment, so that the comfort of the user cannot be guaranteed. Moreover, the air outlet adjustment of the two air outlets can only be performed in the same direction (for example, both the air outlets are left or right), even if a user inputs an instruction to perform the air outlet adjustment, only the air outlet of a single air outlet is blown to the user, which results in poor comfort adjustment efficiency of the user. Therefore, the air outlet of the current double-air-duct air conditioner cannot guarantee the air blowing requirements of users at different positions, and the comfort of the users is affected.

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

Disclosure of Invention

The invention mainly aims to provide a control method of a double-air-channel air conditioner, aiming at realizing that the outlet air of the double-air-channel air conditioner can be automatically blown to the position of a user, and improving the comfort of the position of the user.

In order to achieve the above object, the present invention provides a method for controlling a dual-duct air conditioner, the dual-duct air conditioner having a first air outlet and a second air outlet, the first air outlet having a first air guide and correspondingly forming a first air outlet area, the second air outlet having a second air guide and correspondingly forming a second air outlet area, the method comprising the steps of:

acquiring position information of a target user in a space where the double-air-channel air conditioner is located;

determining a first air outlet parameter of the first air outlet area and a second air outlet parameter of the second air outlet area according to the position information;

and controlling the first air guide member to operate according to the first air outlet parameter, and controlling the second air guide member to operate according to the second air outlet parameter, so that the double-air-channel air conditioner exhausts air towards the target user.

Optionally, the step of determining a first air outlet parameter of the first air outlet region and a second air outlet parameter of the second air outlet region according to the position information includes:

determining a sub-area where the target user is located according to the position information, and using the sub-area as a target area;

determining the position relation of the target area relative to the first air outlet area and the second air outlet area;

and determining the first air outlet parameter and the second air outlet parameter according to the position relation.

Optionally, the step of determining the position relationship of the target region with respect to the first wind outlet region and the second wind outlet region includes:

when the target area is located in the first air outlet area and is located outside the second air outlet area, determining that the position relation corresponding to the target area is a first relation;

when the target area is located in the second air outlet area and is located outside the first air outlet area, determining that the position relation corresponding to the target area is a second relation;

and when the target area is positioned in the first air outlet area and the second air outlet area at the same time, determining that the position relation corresponding to the target area is a third relation.

Optionally, when the number of the target areas is one, the step of determining the first air outlet parameter and the second air outlet parameter according to the position relationship includes:

when the position relationship is the first relationship, the second relationship or the third relationship, determining a first air outlet direction according to the direction of the first air outlet pointing to the target area, and determining a second air outlet direction according to the direction of the second air outlet pointing to the target area;

and determining the first air outlet direction as the first air outlet parameter, and determining the second air outlet direction as the second air outlet parameter.

Optionally, when the number of the target regions is more than one, the step of determining the first air outlet parameter and the second air outlet parameter according to the position relationship includes:

defining the target area corresponding to the first relation as a first sub-area, defining the target area corresponding to the second relation as a second sub-area, and defining the target area corresponding to the third relation as a third sub-area;

determining a third air outlet direction according to the direction of the first air outlet pointing to the first sub-region, determining a fourth air outlet direction according to the direction of the first air outlet pointing to the third sub-region, determining a fifth air outlet direction according to the direction of the second air outlet pointing to the second sub-region, and determining a sixth air outlet direction according to the direction of the second air outlet pointing to the third sub-region;

when the position relationship comprises the first relationship and the second relationship, determining the third air outlet direction as the first air outlet parameter, and determining the fifth air outlet direction as the second air outlet parameter;

when the position relationship comprises the first relationship and the third relationship, determining the first air outlet parameter according to the third air outlet direction and the fourth air outlet direction, and determining the sixth air outlet direction as the second air outlet parameter;

when the position relationship comprises the second relationship and the third relationship, determining the fourth air outlet direction as the first air outlet parameter, and determining the second air outlet parameter according to the fifth air outlet direction and the sixth air outlet direction;

when the position relation includes the first relation, the second relation and the third relation, the first air outlet parameter is determined according to the third air outlet direction and the fourth air outlet direction, and the second air outlet parameter is determined according to the fifth air outlet direction and the sixth air outlet direction.

Optionally, the step of obtaining the location information of the target user in the space where the dual-duct air conditioner is located includes:

acquiring image information in the space through a camera;

and analyzing the characteristic information of the human body image in the image information to determine the position information.

Optionally, when the camera covers a part of the first air outlet region and a part of the second air outlet region in an image capturing region in the space, before the step of analyzing feature information of a human body image in the image information and determining the position information, the method further includes:

judging whether the human body image exists in the image information or not;

if yes, executing the step of analyzing the characteristic information of the human body image in the image information and determining the position information;

if the first air-out area does not exist, determining that the area of the first air-out area, which is positioned outside the image shooting area, is a first area, and determining that the area of the second air-out area, which is positioned outside the image shooting area, is a second area;

determining a seventh air outlet direction according to the direction of the first air outlet pointing to the first area, and determining an eighth air outlet direction according to the direction of the second air outlet pointing to the second area;

and determining the seventh air outlet direction as the first air outlet parameter, and determining the eighth air outlet direction as the second air outlet parameter.

Further, in order to achieve the above object, the present application also proposes a control device including: the dual-air-channel air conditioner control method comprises a memory, a processor and a dual-air-channel air conditioner control program which is stored on the memory and can run on the processor, wherein when the dual-air-channel air conditioner control program is executed by the processor, the steps of the dual-air-channel air conditioner control method are realized.

In addition, in order to achieve the above object, the present application also proposes a dual duct air conditioner including:

the air conditioner comprises a machine body, wherein a first air duct and a second air duct are arranged in the machine body, the first air duct is provided with a first air outlet communicated with an indoor environment, the second air duct is provided with a second air outlet communicated with the indoor environment, the first air outlet is provided with a first air guide, and the second air outlet is provided with a second air guide;

a camera mounted to the body; and the number of the first and second groups,

as described above, in the control device, the camera, the first air guide, and the second air guide are all connected to the control device.

In addition, in order to achieve the above object, the present application also proposes a readable storage medium, on which a dual-duct air-conditioning control program is stored, and when being executed by a processor, the dual-duct air-conditioning control program implements the steps of the dual-duct air-conditioning control method according to any one of the above items.

The invention provides a double-air-duct air conditioner control method which is applied to a double-air-duct air conditioner with two air outlets, wherein air outlet parameters in two air outlet areas correspondingly formed by the two air outlets are respectively determined according to position information of a target user, air guide pieces correspondingly arranged on the two air outlets are respectively controlled to operate according to the determined air outlet parameters, the air outlet of the double-air-duct air conditioner can automatically adapt to the position change of the target user without user operation, and the two air outlets of the double-air-duct air conditioner can be blown towards the position of the target user no matter where the target user is located, so that the comfort requirement of the position of the user is improved.

Drawings

FIG. 1 is a schematic diagram of the hardware involved in the operation of an embodiment of the control apparatus of the present invention;

FIG. 2 is a schematic flow chart illustrating a control method of a dual-duct air conditioner according to a first embodiment of the present invention;

FIG. 3 is a flowchart illustrating a control method for a dual-duct air conditioner according to a second embodiment of the present invention;

fig. 4 is a schematic diagram of region division of an air outlet region related to the control method of the dual-duct air conditioner of the present invention;

fig. 5 is a flowchart illustrating a control method for a dual-duct air conditioner according to a third embodiment of the present invention.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The main solution of the embodiment of the invention is as follows: based on the double-air-channel air conditioner, acquiring the position information of a target user in the space where the double-air-channel air conditioner is located; determining a first air outlet parameter of the first air outlet area and a second air outlet parameter of the second air outlet area according to the position information; and controlling the first air guide member to operate according to the first air outlet parameter, and controlling the second air guide member to operate according to the second air outlet parameter, so that the double-air-channel air conditioner exhausts air towards the target user.

Because in the prior art, the air outlet of the double-air-duct air conditioner cannot adapt to the position automatic adjustment of the user, even if the user adjusts, the air outlet of a single air outlet can only be blown to the user, so that the comfort adjustment efficiency of the position of the user is poor, the air outlet of the current double-air-duct air conditioner cannot guarantee the blowing requirements of the user at different positions, and the comfort of the user is affected.

The invention provides the solution, and aims to realize that the outlet air of the double-air-channel air conditioner can be automatically blown to the position of a user, so that the comfort of the position of the user is improved.

The embodiment of the invention provides a double-air-channel air conditioner which comprises a machine body, a camera and a control device. The control device can be arranged independently of the machine body and can also be arranged on the machine body.

The air conditioner is characterized in that a first air channel and a second air channel are arranged in the machine body, the first air channel is provided with a first air outlet communicated with an indoor environment, the second air channel is provided with a second air outlet communicated with the indoor environment, the first air outlet is provided with a first air guide, and the second air outlet is provided with a second air guide. The first air duct and the second air duct are two separated independent air ducts. And a heat exchanger is arranged in each air channel to exchange heat for the air in the air channel. After heat exchange, air in the first air channel blows to the space where the double-air-conditioner is located through the first air outlet, and after heat exchange, air in the second air channel blows to the space where the double-air-conditioner is located through the second air outlet. The first air outlet and the second air outlet are arranged at intervals in the horizontal direction, and it needs to be explained that the air outlet of the first air outlet and the air outlet of the second air outlet are both blown to the same space. The first air guide piece of the first air outlet is used for adjusting the air outlet direction of the first air outlet, and the first air guide piece of the second air outlet is used for conditioning the air outlet direction of the second air outlet. Under the action of the first air guide piece, the maximum range which can be covered by the air outlet of the first air outlet is defined as a first air outlet area; under the action of the second air guide piece, the maximum range which can be covered by the air outlet of the second air outlet is defined as a second air outlet area.

The camera is arranged on the machine body and can be used for acquiring image information in the space where the double-air-channel air conditioner is located.

The control device is mainly used for controlling the air outlet of two air outlets of the double-air-channel air conditioner. The control device is connected with the camera and can be used for acquiring image information acquired by the camera. First air guide and second air guide all are connected with controlling means, and controlling means can be used to control the operation of first air guide and second air guide to the adjustment to the air-out direction of first air outlet and second air outlet.

In an embodiment of the present invention, referring to fig. 1, the control device includes: a processor 1001, such as a CPU, memory 1002, or the like. The memory 1002 may be a high-speed RAM memory or a non-volatile memory (e.g., a disk memory). The memory 1002 may alternatively be a storage device separate from the processor 1001.

The processor 1001 is connected to the memory 1002, the first air guide 1003, the second air guide 1004, and the camera 1005 in the dual air-conditioning system, respectively.

Those skilled in the art will appreciate that the configuration of the device shown in fig. 1 is not intended to be limiting of the device and may include more or fewer components than those shown, or some components may be combined, or a different arrangement of components.

The memory 1002, which is a readable storage medium, may include a dual duct air conditioner control program therein. In the apparatus shown in fig. 1, the processor 1001 may be configured to call a dual-duct air conditioner control program stored in the memory 1002, and perform operations of relevant steps of the dual-duct air conditioner control method in the following embodiments.

Based on the double-air-channel air conditioner (hereinafter referred to as an air conditioner), the invention also provides a double-air-channel air conditioner control method for adjusting the air outlet of the double-air-channel air conditioner.

Referring to fig. 2, a first embodiment of a dual-duct air conditioner control method according to the present invention is provided, where the dual-duct air conditioner control method includes:

step S10, acquiring the position information of a target user in the space where the double-air-channel air conditioner is located;

in a preset mode (e.g., a wind sensation mode), the outlet air of the air conditioner is blown toward the user. Therefore, when the air conditioner is in the preset mode, the position information of the target user in the space where the air conditioner is located can be obtained in real time.

The position information is specifically characteristic information representing the position of the target user in the space, and can be used for determining the relative position information of the target user relative to the air conditioner. The location information may specifically include a direction and/or distance of the target user relative to the air conditioner, etc. The position information may be obtained based on data collected by a human detection device (e.g., a camera, an infrared sensor) disposed in a space where the air conditioner is located (e.g., on a body of the dual duct air conditioner).

The target user may be a specific user, or may be all users in the space. The number of target users may be one or more than one. The number of the acquired position information can be correspondingly one or more than one according to the different number of the target users.

Step S20, determining a first air outlet parameter of the first air outlet region and a second air outlet parameter of the second air outlet region according to the position information;

under the action of the first air guide piece, the maximum range which can be covered by the air outlet of the first air outlet is defined as a first air outlet area; under the action of the second air guide piece, the maximum range which can be covered by the air outlet of the second air outlet is defined as a second air outlet area. Wherein, in order to improve the coverage degree of air conditioner air-out, realize that its air-out has great adjustable and controllable region, first air-out region and second air-out region overlap the setting.

The first air outlet parameter refers to a flow characteristic parameter of air blown out from the first air outlet in a first air outlet area, and specifically includes an air outlet direction, a wind sweeping direction and/or a wind sweeping area. The second air outlet parameter refers to a characteristic parameter of the flow of the air blown out from the second air outlet in the second air outlet area, and specifically includes an air outlet direction, a wind sweeping direction and/or a wind sweeping area.

Wherein the different location information represents relative locations between different users and the air conditioner. Because first air-out region and second air-out region are fixed region, consequently, positional information can represent the position relation of user for first air-out region and second air-out region. It should be noted that the positional relationship herein may specifically include the positional relationship between the user and the first air outlet region and the second air outlet region when the number of the users is one, or may include the positional relationship between each user and the first air outlet region and the second air outlet region when the number of the users is more than one. Different air outlet parameters of the first air outlet and different air outlet parameters of the second air outlet can be preset according to different position relations, and the obtained first air outlet parameters and the obtained second air outlet parameters can be directly or indirectly corresponding to corresponding position information. Therefore, after the position information is obtained, the corresponding preset air outlet parameter can be obtained according to the corresponding relation and is used as the first air outlet parameter of the current first air outlet and the second air outlet parameter of the current second air outlet.

And step S30, controlling the first air guide to operate according to the first air outlet parameter, and controlling the second air guide to operate according to the second air outlet parameter, so that the dual-duct air conditioner exhausts air towards the target user.

Different air outlet parameters correspond to different running states (such as air guide angle, swing direction and the like) of the air guide piece. Specifically, when the first air outlet parameter includes the air outlet direction of the first air outlet, the first air guide member can be controlled to adjust to the air guide angle corresponding to the air outlet direction, so that the first air outlet can perform air outlet according to the air outlet direction in the first air outlet parameter. When the second air-out parameter includes the air-out direction of the second air outlet, the second air guide member can be controlled to adjust to the air guide angle corresponding to the air-out direction, so that the second air outlet can perform air-out according to the air-out direction in the second air-out parameter.

The method is applied to a double-air-channel air conditioner with two air outlets, air outlet parameters in two air outlet areas formed by the two air outlets correspondingly are respectively determined according to position information of a target user, air guide pieces correspondingly arranged on the two air outlets are respectively controlled to operate according to the determined air outlet parameters, the air outlet of the double-air-channel air conditioner can automatically adapt to the position change of the target user without user operation, and the two air outlets of the double-air-channel air conditioner can be air outlet towards the position of the target user no matter where the target user is located, so that the comfort requirement of the position of the user is improved.

Further, based on the first embodiment, a second embodiment of the dual air duct air conditioner control method is provided. In the second embodiment, referring to fig. 3, the step S20 includes:

step S21, determining the sub-area where the target user is located according to the position information as a target area;

the total air outlet area of the double-air-channel air conditioner, which is formed by the first air outlet area and the second air outlet area, is divided into a plurality of preset areas in advance. Each air outlet area can be provided with a plurality of preset areas according to requirements. Specifically, when the first air outlet region and the second air outlet region are overlapped, the total air outlet region can be divided into a plurality of preset regions based on the boundary of the first air outlet region and the boundary of the second air outlet region. Further, when the first air-out area and the second air-out area are overlapped and the detection area of the detection device corresponding to the position information does not completely cover the total air-out area, the total air-out area can be divided into a plurality of preset areas based on the boundary of the first air-out area, the boundary of the detection area and the boundary of the second air-out area. For example, the large area formed by the areas a to E in fig. 4 is a total air outlet area of the dual-duct air conditioner, where the first air outlet area is divided into A, B, D three preset areas, the second air outlet area is divided into A, C, E three preset areas, where a is an overlapping area of the first air outlet area and the second air outlet area, and A, B, C is an image capturing area of a camera for obtaining position information. In addition, in other embodiments, the preset areas may be divided into a greater number or a lesser number according to actual requirements. Besides the division mode, the preset area can be further divided by combining the air guide piece with the air outlet coverage range of the air outlet under a certain angle.

Different preset areas correspond to different numerical ranges of the position information. And determining the numerical range of the current position information based on the division of the preset area, so that the preset area corresponding to the range can be used for determining the current target area of the target user. When the number of the target users is one, the number of the corresponding target areas is one; when the number of target users is plural, the number of corresponding target areas may be one or more than one.

Step S22, determining a positional relationship between the target region and the first and second outlet regions;

when the target area is located in the first air outlet area and is located outside the second air outlet area, determining that the position relation corresponding to the target area is a first relation; when the target area is located in the second air outlet area and is located outside the first air outlet area, determining that the position relation corresponding to the target area is a second relation; and when the target area is positioned in the first air outlet area and the second air outlet area at the same time, determining that the position relation corresponding to the target area is a third relation. In other embodiments, the position relationship may further include that the target region is located outside the first wind outlet region and the second wind outlet region, and the like.

When the number of the target users is one, the determined position relation comprises a relation; when the number of target users is more than one, the determined location relationship includes one or more relationships.

For example, based on the preset areas divided in fig. 4, the position relationship corresponding to the target area where the target user is located may be determined by referring to the following manner: if the number of the target users is one, when the target area where the target users are located is the area A, the corresponding position relationship is the third relationship; when the target area where the target user is located is the B area, the corresponding position relationship is the first relationship. If the number of the target users is more than one, when the number of the target areas where the target users are located is only one and is C area, the corresponding position relation is the second relation; when the number of the target areas is only one and is the area a, the corresponding position relationship is the third relationship. If the number of the target users is more than one, when the number of the target users is more than one and is A, C areas, the corresponding position relationship comprises the second relationship and the third relationship at the same time; if the number of the target users is more than one, when the number of the target users is more than one and is B, C areas, the corresponding position relationship comprises the first relationship and the second relationship at the same time; if the number of target areas is greater than one and is A, B, C areas, the corresponding positional relationship includes the first relationship, the second relationship and the third relationship at the same time.

Step S23, determining the first air outlet parameter and the second air outlet parameter according to the position relationship.

The different position relations correspond to different air outlet parameters of the first air outlet and different air outlet parameters of the second air outlet. Specifically, the different positional relationships correspond to different air outlet directions of the first air outlet and the second air outlet.

Specifically, when the number of target areas is one, for example, when only one target user exists, or a plurality of target users are located in the same area, step S23 includes:

step S231, when the position relationship is the first relationship, the second relationship, or the third relationship, determining a first air outlet direction according to a direction in which the first air outlet points to the target area, and determining a second air outlet direction according to a direction in which the second air outlet points to the target area;

when the position relationship is the first relationship, if the target area is the area B in fig. 4, the direction in which the first air outlet points to the target area is taken as a first air outlet direction; since the target area is not located in the second air outlet area, the air outlet direction of the second air outlet close to the target area can be taken as the second air outlet direction, for example, the direction of the area a close to the boundary of the area B is taken as the air outlet direction of the second air outlet. When the position relationship is the second relationship, if the target area is the area C in fig. 4, the determination manner of the first air outlet direction and the second air outlet direction when the position relationship is the first relationship may also be used, which is not described herein again.

When the position relationship is the third relationship, if the target area is the area a in fig. 4, the direction in which the first air outlet points to the target area is taken as the first air outlet direction, and the direction in which the second air outlet points to the target area is taken as the second air outlet direction.

Step S232, determining the first air outlet direction as the first air outlet parameter, and determining the second air outlet direction as the second air outlet parameter.

When the position relation is the first relation, the first air guide piece and the second air guide piece operate according to the corresponding air outlet direction, the first air outlet can be enabled to air out towards the area B, the second air outlet can be enabled to air out towards the position closest to the area B, and air blowing towards the position where the user is located is achieved through the two air outlets.

When the position relation is the second relation, first air guide and second air guide move according to corresponding air-out direction, can make the second air outlet towards the regional air-out of C, and first air outlet is towards the position air-out of the nearest regional C of first air outlet, realizes that two air outlets all face the user position and blow.

When the position relation is the third relation, first air guide and second air guide move according to corresponding air-out direction, can make first air outlet and second air outlet all face regional air-out of A, realize that two air outlets all face user's position and blow.

In addition, when the number of the target areas is more than one, for example, the number of the target users is more than one and located in different preset areas, the number of the corresponding target areas is more than one. Based on this, step S23 includes:

step S233, defining the target area corresponding to the first relationship as a first sub-area, defining the target area corresponding to the second relationship as a second sub-area, and defining the target area corresponding to the third relationship as a third sub-area;

specifically, based on the divided regions in fig. 4, the region B in which the target user exists is the first sub-region, the region C in which the target user exists is the second sub-region, and the region a in which the target user exists is the third sub-region.

Step S234, determining a third air outlet direction according to the direction of the first air outlet pointing to the first sub-region, determining a fourth air outlet direction according to the direction of the first air outlet pointing to the third sub-region, determining a fifth air outlet direction according to the direction of the second air outlet pointing to the second sub-region, and determining a sixth air outlet direction according to the direction of the second air outlet pointing to the third sub-region;

specifically, the direction of the first air outlet pointing to the area B is taken as a third air outlet direction; taking the direction of the second air outlet pointing to the area C as a fifth air outlet direction; and taking the direction of the first air outlet pointing to the area A as a fourth air outlet direction, and taking the direction of the second air outlet pointing to the area A as a sixth air outlet direction.

When the positional relationship includes both the first relationship and the second relationship, performing step S235; when the positional relationship includes both the first relationship and the third relationship, performing step S236; when the positional relationship includes both the second relationship and the third relationship, step S237 is executed; when the positional relationship includes the first relationship, the second relationship, and the third relationship at the same time, step S238 is performed.

Step S235, determining the third air outlet direction as the first air outlet parameter, and determining the fifth air outlet direction as the second air outlet parameter;

the position relation comprises a first relation and a second relation at the same time, target users exist in the area A and the area C, the first air outlet blows air out of the area A, the second air outlet blows air out of the area C, and the double-air-channel air conditioner can blow air to all the target users.

Step S236, determining the first air outlet parameter according to the third air outlet direction and the fourth air outlet direction, and determining the sixth air outlet direction as the second air outlet parameter;

the position relation comprises a first relation and a third relation at the same time, target users exist in the area A and the area B, air outlet of the first air outlet can sweep air back and forth in the area A and the area B under the action of the first air guide piece, the second air outlet can directionally exhaust air to the area A, and the double-air-duct air conditioner can blow air to all the target users.

Step S237, determining the fourth air outlet direction as the first air outlet parameter, and determining the second air outlet parameter according to the fifth air outlet direction and the sixth air outlet direction;

the position relations comprise a second relation and a third relation at the same time, target users exist in the area A and the area C, air outlet of the second air outlet can sweep air back and forth in the area A and the area C under the action of the second air guide piece, the first air outlet can directionally exhaust air to the area A, and the double-air-duct air conditioner can blow air to all the target users.

Step S238 is to determine the first air outlet parameter according to the third air outlet direction and the fourth air outlet direction, and determine the second air outlet parameter according to the fifth air outlet direction and the sixth air outlet direction.

The position relations simultaneously comprise a first relation, a second relation and a third relation, target users exist in the area A, B, C, the air outlet of the first air outlet can sweep air back and forth in the area A and the area C under the action of the first air guide, the air outlet of the second air outlet can sweep air back and forth in the area A and the area C under the action of the second air guide, and therefore the double-air-duct air conditioner can blow air to all target users. The swinging directions of the first air guide piece and the second air guide piece are consistent, so that the first air outlet can sweep air from the area B to the area A, the second air outlet can sweep air from the area A to the area C, the first air outlet can sweep air from the area A to the area B, and the second air outlet can sweep air from the area C to the area A, and therefore all target users can continuously feel the wind sensation.

In this embodiment, through the above manner, as long as the target user is in the air-out area of the dual-duct air conditioner, no matter where the target user is, no matter how many the target users are, no matter how the target users are distributed, the dual-duct air conditioner can output air towards the target user, so as to improve the comfort of the target user.

Further, based on any of the above embodiments, a third embodiment of the dual air duct air conditioner control method is provided. In the third embodiment, referring to fig. 5, the step S10 includes:

step S11, acquiring image information in the space through a camera;

the camera can be arranged on the air conditioner body, and can collect image information in the space where the double-air-channel air conditioner is located in real time.

Step S12, analyzing feature information of the human body image in the image information, and determining the position information.

After the image information acquired by the camera is obtained, the human body image in the image information is identified, the image coordinate information of the human body image in the image information is determined, and the position information of each target user is determined according to the image coordinate information.

Further, when the camera covers a part of the first air outlet region and a part of the second air outlet region in the image capturing region in the space, before step S12, the method further includes:

step S101, judging whether the human body image exists in the image information;

if yes, executing the step S12; if not, step S102 and step S103 are executed.

The image shooting area specifically refers to the largest space area that the camera can shoot in the space where the double-air-channel air conditioner is located.

Step S102, determining that the area of the first air-out area outside the image shooting area is a first area, and determining that the area of the second air-out area outside the image shooting area is a second area;

based on the preset area divided in fig. 4, the area D is the first area, and the area E is the second area.

Step S103, determining a seventh air outlet direction according to the direction of the first air outlet pointing to the first area, and determining an eighth air outlet direction according to the direction of the second air outlet pointing to the second area;

step S104, determining the seventh air outlet direction as the first air outlet parameter, and determining the eighth air outlet direction as the second air outlet parameter.

After the first air outlet parameter and the second air outlet parameter are determined in step S104, S30 is executed. The first air guide piece guides air according to the seventh air outlet direction, so that the first air outlet can exhaust air towards the area D, and the second air guide piece guides air according to the eighth air outlet direction, so that the second air outlet can exhaust air towards the area E.

In this embodiment, the position information of the target user can be acquired according to the image information acquired by the camera. When the image shooting area does not completely cover the air outlet area of the double-air-duct air conditioner, the human body image cannot be identified in the image information, and only the fact that no user appears in the image shooting area can be represented, and the target user can be out of the image shooting area. Therefore, by the mode, the double-air-channel air conditioner can blow air even if the target user is in the image shooting area range, and the comfort of the target user is improved.

In addition, an embodiment of the present invention further provides a readable storage medium, where a dual-duct air conditioner control program is stored on the readable storage medium, and when the dual-duct air conditioner control program is executed by a processor, the dual-duct air conditioner control program implements relevant steps of any embodiment of the above dual-duct air conditioner control method.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk) as described above and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, a dual air-conditioner, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The double-air-duct air conditioner control method is characterized in that the double-air-duct air conditioner is provided with a first air outlet and a second air outlet, the first air outlet is provided with a first air guide piece and correspondingly forms a first air outlet area, the second air outlet is provided with a second air guide piece and correspondingly forms a second air outlet area, and the double-air-duct air conditioner control method comprises the following steps:

2. The method for controlling the dual-duct air conditioner according to claim 1, wherein the step of determining a first air outlet parameter of the first air outlet area and a second air outlet parameter of the second air outlet area according to the position information includes:

3. The dual duct air conditioning control method according to claim 2, wherein the step of determining the positional relationship of the target area with respect to the first air-out area and the second air-out area includes:

4. The method according to claim 3, wherein when the number of the target areas is one, the step of determining the first air outlet parameter and the second air outlet parameter according to the position relationship comprises:

5. The method for controlling the dual-duct air conditioner according to claim 3, wherein when the number of the target areas is more than one, the step of determining the first air outlet parameter and the second air outlet parameter according to the position relationship comprises:

6. The dual-duct air conditioner control method according to any one of claims 1 to 5, wherein the step of obtaining the location information of the target user in the space where the dual-duct air conditioner is located comprises:

acquiring image information in the space through a camera;

7. The dual-duct air conditioner control method of claim 6, wherein when the camera is located in an image capturing area of the space covering a part of the first air outlet area and a part of the second air outlet area, the analyzing the characteristic information of the human body image in the image information and determining the position information further comprises, before the step of:

judging whether the human body image exists in the image information or not;

8. A control device, characterized in that the control device comprises: a memory, a processor and a dual-duct air conditioning control program stored on the memory and executable on the processor, the dual-duct air conditioning control program when executed by the processor implementing the steps of the dual-duct air conditioning control method of any one of claims 1 to 7.

9. A dual duct air conditioner, comprising:

a camera mounted to the body; and the number of the first and second groups,

the control device of claim 8, wherein the camera, the first air guide, and the second air guide are all connected to the control device.

10. A readable storage medium, wherein a dual-duct air-conditioning control program is stored thereon, and when executed by a processor, the dual-duct air-conditioning control program implements the steps of the dual-duct air-conditioning control method according to any one of claims 1 to 7.