CN112432325A - Control method and control equipment of air conditioner - Google Patents

Abstract

The invention provides a control method and a control device of an air conditioner, wherein the method comprises the following steps: acquiring a plurality of air supply areas which are divided in advance by the air supply range of an indoor unit of the air conditioner; dividing at least part of a display interface of a display screen of target terminal equipment into a plurality of visual areas, wherein the visual areas correspond to the air supply areas one by one; acquiring a visual area selected by a user on target terminal equipment, taking the visual area as a target visual area, and acquiring a temperature regulating instruction which is input by the user on the target terminal equipment and corresponds to the target visual area; and determining an air supply area corresponding to the target visible area, taking the air supply area as a target air supply area, and calculating the air supply time of the indoor unit to the target air supply area according to the temperature regulating instruction. Based on the scheme provided by the invention, the user can conveniently adjust the air conditioner and the intelligent level of air supply of the air conditioner is improved.

Description

Control method and control equipment of air conditioner

Technical Field

The invention relates to the technical field of air conditioners, in particular to a control method and control equipment of an air conditioner.

Background

Along with the improvement of the living standard of people, the requirements of users on the use experience of household appliances are higher and higher, and the requirements are not limited to the heating and cooling capacity, the power consumption and the like. With the rapid development of the internet, people have raised higher demands on the intelligent control of the air conditioner.

The existing air-conditioning products support automatic air sweeping up and down and left and right, but have some disadvantages in actual operation. For example, for the up-down and left-right wind sweeping functions, the air conditioner can only sweep wind in a single up-down wind sweeping mode, a single left-right wind sweeping mode or both the up-down wind sweeping mode and the left-right wind sweeping mode, and a user cannot control the wind sweeping time of the air conditioner to a region defined by the user.

Disclosure of Invention

In view of the above problems, the present invention has been made to provide a control method and a control apparatus of an air conditioner that overcome or at least partially solve the above problems.

An object of the present invention is to facilitate user adjustment of an air conditioner.

A further object of the present invention is to increase the level of intelligence in the air supply of an air conditioner.

According to an aspect of the present invention, there is provided a control method of an air conditioner, including:

acquiring a plurality of air supply areas which are divided in advance by the air supply range of an indoor unit of the air conditioner;

dividing at least part of a display interface of a display screen of target terminal equipment into a plurality of visual areas, wherein the visual areas correspond to the air supply areas one by one;

acquiring a visual area selected by a user on the target terminal equipment, taking the visual area as a target visual area, and acquiring a temperature regulating instruction which is input by the user on the target terminal equipment and corresponds to the target visual area;

and determining an air supply area corresponding to the target visible area, taking the air supply area as a target air supply area, and calculating the air supply time of the indoor unit to the target air supply area according to the temperature regulating instruction.

Optionally, the indoor unit includes:

the air deflector is transversely arranged at the air outlet of the indoor unit and is configured to rotate up and down along the air outlet so as to adjust the longitudinal air supply direction of the indoor unit; and

a plurality of swing blades longitudinally arranged at the air outlet and configured to swing left and right along the air outlet to adjust the transverse air supply direction of the indoor unit, and

the plurality of air supply areas are respectively divided according to the longitudinal air supply direction and the transverse air supply direction to obtain a plurality of air supply areas arranged in rows and columns.

Optionally, the air deflector corresponds to a plurality of preset up-down rotation angles; and

the swing blades correspond to a plurality of preset left-right swing angles, and

the row distribution of the air supply area is arranged according to the vertical rotation angle, and the column distribution of the air supply area is arranged according to the horizontal swing angle.

Optionally, the step of calculating an air supply time of the indoor unit to the target air supply area according to the temperature adjustment instruction includes:

and calculating the continuous air supply duration of the air deflector and the swinging blade to the target air supply area according to the temperature adjusting instruction.

Optionally, the step of calculating the continuous air supply time of the air deflector and the swing blade to the target air supply area according to the temperature adjustment instruction includes:

determining a row position and a column position corresponding to the target air supply area and respectively taking the row position and the column position as a target row position and a target column position;

determining the corresponding up-down rotation angle of the target line position and using the up-down rotation angle as the target up-down rotation angle, and

determining a left-right swinging angle corresponding to the target column position and taking the left-right swinging angle as a target left-right swinging angle;

and calculating the continuous air supply duration from the air deflector rotating to the target vertical rotation angle and the swinging of the swinging blade to the target horizontal swinging angle according to the temperature adjusting instruction.

Optionally, the step of calculating a continuous air supply time period from the rotation of the air deflector to the target vertical rotation angle and from the swinging of the swing blade to the target horizontal swinging angle according to the temperature adjustment instruction includes:

according to the temperature adjusting instruction, calculating the continuous air supply duration from the air guide plate to the target up-down rotation angle according to the number of the air supply areas at the target row position and the number of the target air supply areas, and

and calculating the continuous air supply duration from the swinging of the swinging blades to the target left-right swinging angle according to the number of the air supply areas of the target row position and the number of the target air supply areas.

Optionally, in the case that the temperature regulation trend corresponding to the temperature regulation instruction is consistent with the heat exchange trend of the air conditioner,

according to

Calculating the continuous air supply time of the air deflector rotating to the target vertical rotation angle and the swinging blade swinging to the target horizontal swinging angle, and

for calculating the continuous air supply time length of the air deflector rotating to the target vertical rotation angle, in the formula, t is the continuous air supply time length of the air deflector rotating to the target vertical rotation angle, num is the number of the air supply areas at the target row position, and num0 is the number of the target air supply areas at the target row position;

for calculating the continuous air supply time length of the swinging blade swinging to the target left-right swinging angle, in the formula, t is the continuous air supply time length of the swinging blade swinging to the target left-right swinging angle, num is the number of the air supply areas at the target row position, and num0 is the number of the target air supply areas at the target row position.

Optionally, in the case that the temperature regulation trend corresponding to the temperature regulation instruction is inconsistent with the heat exchange trend of the air conditioner,

according to

Calculating the continuous air supply time length from the rotation of the air deflector to the target vertical rotation angle and the swinging of the swinging blade to the target horizontal swinging angle, wherein k is an air supply compensation value, T is a standard period time length, and

for calculating the continuous air supply time length of the air deflector rotating to the target vertical rotation angle, in the formula, t is the continuous air supply time length of the air deflector rotating to the target vertical rotation angle, num is the number of the air supply areas at the target row position, and num0 is the number of the target air supply areas at the target row position;

for calculating the continuous air supply time length of the swinging blade swinging to the target left-right swinging angle, in the formula, t is the continuous air supply time length of the swinging blade swinging to the target left-right swinging angle, num is the number of the air supply areas at the target row position, and num0 is the number of the target air supply areas at the target row position.

Optionally, the step of obtaining a plurality of air supply regions pre-divided by an air supply range of an indoor unit of the air conditioner further comprises:

receiving an air supply area acquisition instruction sent by a terminal device and taking the terminal device as a target terminal device, wherein,

and the terminal equipment sends the air supply area acquisition instruction through a code scanning.

According to another aspect of the present invention, there is also provided a control apparatus of an air conditioner, comprising a memory in which a computer program is stored and a processor configured to run the computer program to perform any one of the above-described control methods.

After a plurality of air supply areas pre-divided by the air supply range of an indoor unit of the air conditioner are obtained, at least part of a display interface of a display screen of a target terminal device is divided into a plurality of visual areas, and the visual areas correspond to the air supply areas one to one. Therefore, the user can select the visual area to be adjusted on the mobile terminal, and the user can conveniently adjust the air conditioner.

Further, the method and the device for controlling the temperature of the target terminal device acquire the visual area selected by the user on the target terminal device and take the visual area as the target visual area, and acquire the temperature adjusting instruction which is input by the user on the target terminal device and corresponds to the target visual area. And then determining an air supply area corresponding to the target visible area, taking the air supply area as a target air supply area, and calculating the air supply time of the indoor unit to the target air supply area according to the temperature regulating instruction, so that the air supply intellectualization level of the air conditioner is improved.

The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof, taken in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter, by way of illustration and not limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

fig. 1 is a schematic structural view of an indoor unit of an air conditioner according to an embodiment of the present invention;

fig. 2 is a schematic view of a blowing range of an indoor unit according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a target terminal device according to one embodiment of the present invention;

fig. 4 is a control block diagram of an air conditioner according to an embodiment of the present invention;

fig. 5 is a block diagram of a control apparatus of the air conditioner in fig. 4;

fig. 6 is a schematic flowchart of a control method of an air conditioner according to an embodiment of the present invention.

Detailed Description

Fig. 1 is a schematic structural view of an indoor unit 100 of an air conditioner according to an embodiment of the present invention; fig. 2 is a schematic view of an air blowing range of the indoor unit 100 according to an embodiment of the present invention. Referring to fig. 1 and 2, an indoor unit 100 of an air conditioner includes an air guide plate 110 and a plurality of swing blades 120. The air deflector 110 is transversely disposed at the air outlet 130 of the indoor unit 100, and is configured to rotate up and down along the air outlet 130 of the indoor unit 100 to adjust the longitudinal air supply direction of the indoor unit 100; the plurality of swing blades 120 are longitudinally disposed at the outlet 130 of the indoor unit 100, and configured to swing left and right along the outlet 130 to adjust a lateral air blowing direction of the indoor unit 100. The air blowing range of the indoor unit 100 is divided into a plurality of air blowing regions 400 in advance, and the plurality of air blowing regions 400 are arranged in rows and columns, which are divided into a longitudinal air blowing direction and a lateral air blowing direction.

Specifically, as shown in fig. 2, the air deflector 110 corresponds to a plurality of preset up-down rotation angles, and the swing blade 120 corresponds to a plurality of preset left-right swing angles. The row distribution of the blowing area 400 is set up according to the vertical rotation angle, and the column distribution of the blowing area 400 is set up according to the horizontal swing angle. When the air deflector 110 rotates to different vertical rotation angles, the indoor unit 100 blows air to the air blowing areas 400 in different row positions; when the swing vane 120 rotates to different horizontal swing angles, the indoor unit 100 blows air to the air blowing areas 400 in different row positions.

Fig. 3 is a schematic diagram of a target terminal device 200 according to one embodiment of the present invention. Referring to fig. 3, at least a portion of the interface of the display screen 210 of the destination terminal apparatus 200 is divided into a plurality of visual areas 500, and the plurality of visual areas 500 correspond to the plurality of blowing areas 400 one to one. The target terminal equipment comprises but is not limited to a mobile phone, an iPad and the like. The display screen 210 of the target terminal device 200 may be a touch-enabled display screen 210, and at least a portion of the interface of the display screen 210 of the target terminal may further display keys 220, so that a user may select a visual area 500 to be adjusted and input a corresponding temperature adjustment instruction by touching the display screen 210 of the target terminal.

Fig. 4 is a control block diagram of an air conditioner according to an embodiment of the present invention; fig. 5 is a block diagram of the control apparatus 300 of the air conditioner in fig. 4. Referring to fig. 4 and 5, the control apparatus 300 of the air conditioner includes a memory 320 in which a computer program 321 is stored, and a processor 310 configured to execute the computer program 321 to perform a control method of the air conditioner according to any of the following embodiments.

The control device 300 of the air conditioner may be disposed in a network side device such as a server, a cloud, etc., and is connected to the air conditioner and the terminal device through data to receive an instruction of the terminal device, so that the air conditioner performs corresponding control.

The control device 300 of the air conditioner may also be a part of the air conditioner or a terminal device, and is disposed in the air conditioner or the terminal device to receive an instruction from the terminal device, so that the air conditioner performs corresponding control.

Based on the control apparatus 300 of the air conditioner proposed above, the present invention also proposes a control method of the air conditioner performed by the control apparatus 300 of the air conditioner, and fig. 6 is a schematic flowchart of the control method of the air conditioner according to an embodiment of the present invention. As shown in fig. 6, the method may include at least the following steps:

step S602: a plurality of air blowing regions 400 divided in advance by the air blowing range of the indoor unit 100 of the air conditioner are acquired.

Step S604: at least a part of the display interface of the display screen 210 of the target terminal device 200 is divided into a plurality of visual areas 500, and the plurality of visual areas 500 correspond to the plurality of blowing areas 400 one to one.

Step S606: the visual area 500 selected by the user at the target terminal device 200 is acquired and used as the target visual area, and the temperature adjustment instruction corresponding to the target visual area input by the user at the target terminal device 200 is acquired.

Step S608: and determining an air supply area 400 corresponding to the target visible area, taking the air supply area as a target air supply area, and calculating the air supply time of the indoor unit 100 to the target air supply area according to the temperature regulation instruction.

After acquiring a plurality of air supply areas 400 divided in advance by the air supply range of the indoor unit 100 of the air conditioner, the present invention divides at least part of the display interface of the display screen 210 of the target terminal device 200 into a plurality of visual areas, and the plurality of visual areas correspond to the plurality of air supply areas 400 one to one. Therefore, the user can select the visual area to be adjusted on the mobile terminal, and the user can conveniently adjust the air conditioner. Further, the present invention obtains the visual area 500 selected by the user at the target terminal device 200 and uses it as the target visual area, and obtains the temperature adjustment instruction corresponding to the target visual area input by the user at the target terminal device 200. And then, determining an air supply area 400 corresponding to the target visible area as a target air supply area, and calculating the air supply time of the indoor unit 100 to the target air supply area according to the temperature regulation instruction. Thereby improving the intellectualization level of air supply of the air conditioner.

In some embodiments of the present invention, before step S608 above, the method further comprises: and receiving an air supply area acquisition instruction sent by the terminal device and taking the terminal device as the target terminal device 200, wherein the terminal device sends the air supply area acquisition instruction through code scanning.

In practical applications, the target terminal device 200 may further acquire the plurality of visual areas 500 by logging in a corresponding system through an account password. Compared with an account password login mode, the code scanning mode is particularly suitable for the situation of a large conference, and is more convenient for the operation of participants.

In some embodiments of the present invention, the calculating, according to the temperature adjustment instruction, the air supply duration of the indoor unit 100 to the target air supply area in the step S608 may specifically include: and calculating the continuous air supply duration of the air deflector 110 and the swinging vane 120 to the target air supply area according to the temperature regulation instruction.

Specifically, in calculating the continuous air supply duration of the air deflector 110 and the swing blade 120 to the target air supply area according to the temperature adjustment instruction, first, the row position and the column position corresponding to the target air supply area are determined and are respectively used as the target row position and the target column position. And then determining an up-down rotation angle corresponding to the target row position and taking the up-down rotation angle as a target up-down rotation angle, and determining a left-right swinging angle corresponding to the target column position and taking the left-right swinging angle as a target left-right swinging angle. And then, calculating the continuous air supply time length from the air deflector 110 rotating to the target up-down rotation angle and the swinging of the swinging vane 120 to the target left-right swinging angle according to the temperature adjusting instruction.

Specifically, calculating the continuous air supply time length from the rotation of the air deflector 110 to the target up-down rotation angle and the swinging of the swing vane 120 to the target left-right swinging angle according to the temperature adjustment instruction may include: according to the temperature regulation instruction, the continuous air supply duration from the rotation of the air deflector 110 to the target vertical rotation angle is calculated according to the number of the air supply areas at the target row position and the number of the target air supply areas, and the continuous air supply duration from the swinging of the swinging blade 120 to the target horizontal swinging angle is calculated according to the number of the air supply areas at the target column position and the number of the target air supply areas.

In some embodiments of the present invention, the temperature regulation trend corresponding to the temperature regulation instruction is consistent with the heat exchange trend of the air conditioner according to the temperature regulation instruction

And calculating the continuous air supply time length from the rotation of the air deflector 110 to the target up-down rotation angle and the swinging of the swing blade 120 to the target left-right swinging angle, wherein T is the standard period time length, T can be set according to actual needs, k is an air supply compensation value, and k can be 0.5.

Specifically, for the case where the continuous blowing period until the air deflector 110 rotates to the target vertical rotation angle is calculated, in the above equation, t is the continuous blowing period until the air deflector 110 rotates to the target vertical rotation angle, num is the number of blowing areas at the target row position, and num0 is the number of target blowing areas at the target row position.

In the above equation, t is the duration of the air blowing until the swing blade 120 swings to the target yaw angle, num is the number of air blowing regions at the target row position, and num0 is the number of target air blowing regions at the target row position.

In one example, referring to fig. 2 and 3, the target visible area is a, the temperature regulation trend corresponding to the temperature regulation instruction is temperature rise, and the air conditioner is in a heating mode at this time. Since the number of blowing areas at the target row position where the target blowing area a corresponding to the visible area a is located is 6 and the target blowing area at the target row position is only the target blowing area a, the number of target blowing areas at the target row position is 1. The number of the air supply areas at the target row position and the number of the target air supply areas are substituted into the formula, and the continuous air supply time length of the air deflector 110 rotating to the target vertical rotation angle corresponding to the target row position can be calculated to be 1.67T; the number of blowing areas at the target row position where the target blowing area a is located is 3, and the number of target blowing areas at the target row position is 1. Substituting the number of the air supply areas at the target row position and the number of the target air supply areas into the above formula can calculate that the continuous air supply time length of the swinging blade 120 swinging to the target left-right swinging angle corresponding to the target row position is 1.83T.

Under the condition that the temperature regulation trend corresponding to the temperature regulation instruction is consistent with the heat exchange trend of the air conditioner, the continuous air supply duration from the rotation of the air deflector 110 to the target vertical rotation angle and the swinging of the swinging blade 120 to the target horizontal swinging angle is prolonged. Therefore, the temperature of the target air supply area can be increased or decreased as soon as possible, and the user experience is improved.

In other embodiments of the present invention, under the condition that the temperature regulation trend corresponding to the temperature regulation instruction is not consistent with the heat exchange trend of the air conditioner, according to the following conditions

And calculating the continuous air supply time length from the rotation of the air deflector 110 to the target up-down rotation angle and the swinging of the swing blade 120 to the target left-right swinging angle, wherein k is an air supply compensation value, k can be 0.5, T is the standard period time length, and T can be set according to actual requirements.

Specifically, in the present embodiment, for the case where the continuous blowing time period for the air deflector 110 to rotate to the target up-down rotation angle is calculated, in the above equation, t is the continuous blowing time period for the air deflector 110 to rotate to the target up-down rotation angle, num is the number of blowing areas at the target row position, and num0 is the number of target blowing areas at the target row position.

In the above equation, t is the duration of the air blowing until the swing blade 120 swings to the target yaw angle, num is the number of air blowing regions at the target row position, and num0 is the number of target air blowing regions at the target row position.

Note that, in the present embodiment, in the case where num-num0 is 0, k is equal to 0. That is, when the air supply areas at the target row position or the target column position are both the target air supply areas, the air deflector 110 or the swing blade 120 is enabled to skip the corresponding target row position or target column position.

In one example, still referring to fig. 2 and 3, the target visible area is a, the temperature regulation trend corresponding to the temperature regulation command is temperature rise, and the air conditioner is in the cooling mode at this time. Since the number of blowing areas at the target row position where the target blowing area a corresponding to the visible area a is located is 6 and the target blowing area at the target row position is only the target blowing area a, the number of target blowing areas at the target row position is 1. The number of the air supply areas at the target row position and the number of the target air supply areas are brought into

The continuous air supply time length of the air deflector 110 rotating to the target up-down rotation angle corresponding to the target row position can be calculated to be 1.33T; the number of blowing areas at the target row position where the target blowing area a is located is 3, and the number of target blowing areas at the target row position is 1. The number of the air supply regions of the target row position and the number of the target air supply regions are brought into

The continuous air supply time length of the swinging blade 120 swinging to the target left-right swinging angle corresponding to the target row position can be calculated to be 1.167T.

Under the condition that the temperature regulation trend corresponding to the temperature regulation instruction is inconsistent with the heat exchange trend of the air conditioner, the continuous air supply duration from the rotation of the air deflector 110 to the target vertical rotation angle and the swinging of the swing blade 120 to the target horizontal swinging angle is shortened, so that the temperature rising trend or the temperature falling trend of the target area can be reduced, and the user experience is improved.

In the control method provided by the invention, after a plurality of air supply areas pre-divided by the air supply range of an indoor unit 100 of the air conditioner are acquired, at least part of a display interface of a display screen 210 of a target terminal device 200 is divided into a plurality of visual areas, and the visual areas are in one-to-one correspondence with the air supply areas. Therefore, the user can select the visual area to be adjusted on the mobile terminal, and the user can conveniently adjust the air conditioner.

Further, the present invention obtains the visual area selected by the user at the target terminal device 200 and uses it as the target visual area, and obtains the temperature adjustment instruction corresponding to the target visual area input by the user at the target terminal device 200. And then determining an air supply area corresponding to the target visible area and taking the air supply area as a target air supply area, and calculating the air supply time of the indoor unit 100 to the target air supply area according to the temperature regulating instruction, so that the air supply intellectualization level of the air conditioner is improved.

Furthermore, under the condition that the temperature regulation trend corresponding to the temperature regulation instruction is consistent with the heat exchange trend of the air conditioner, the continuous air supply duration of the air deflector 110 rotating to the target vertical rotation angle and the swinging blade 120 swinging to the target horizontal swinging angle is prolonged; under the condition that the temperature regulation trend corresponding to the temperature regulation instruction is inconsistent with the heat exchange trend of the air conditioner, the continuous air supply time of the air deflector 110 rotating to the target vertical rotation angle and the swinging blade 120 swinging to the target horizontal swinging angle is shortened, so that the user experience can be improved.

Thus, it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been illustrated and described in detail herein, many other variations or modifications consistent with the principles of the invention may be directly determined or derived from the disclosure of the present invention without departing from the spirit and scope of the invention. Accordingly, the scope of the invention should be understood and interpreted to cover all such other variations or modifications.

Claims (10)

1. A control method of an air conditioner, comprising:

acquiring a plurality of air supply areas which are divided in advance by the air supply range of an indoor unit of the air conditioner;

dividing at least part of a display interface of a display screen of target terminal equipment into a plurality of visual areas, wherein the visual areas correspond to the air supply areas one by one;

acquiring a visual area selected by a user on the target terminal equipment, taking the visual area as a target visual area, and acquiring a temperature regulating instruction which is input by the user on the target terminal equipment and corresponds to the target visual area;

and determining an air supply area corresponding to the target visible area, taking the air supply area as a target air supply area, and calculating the air supply time of the indoor unit to the target air supply area according to the temperature regulating instruction.

2. The control method according to claim 1, wherein the indoor unit includes:

the air deflector is transversely arranged at the air outlet of the indoor unit and is configured to rotate up and down along the air outlet so as to adjust the longitudinal air supply direction of the indoor unit; and

a plurality of swing blades longitudinally arranged at the air outlet and configured to swing left and right along the air outlet to adjust the transverse air supply direction of the indoor unit, and

the plurality of air supply areas are respectively divided according to the longitudinal air supply direction and the transverse air supply direction to obtain a plurality of air supply areas arranged in rows and columns.

3. The control method according to claim 2, wherein,

the air deflector corresponds to a plurality of preset vertical rotation angles; and

the swing blades correspond to a plurality of preset left-right swing angles, and

the row distribution of the air supply area is arranged according to the vertical rotation angle, and the column distribution of the air supply area is arranged according to the horizontal swing angle.

4. The control method according to claim 3, wherein the step of calculating the air supply time period of the indoor unit to the target air supply area according to the temperature adjustment instruction includes:

and calculating the continuous air supply duration of the air deflector and the swinging blade to the target air supply area according to the temperature adjusting instruction.

5. The control method according to claim 4, wherein the step of calculating the continuous air supply time of the air deflector and the swing blades to the target air supply area according to the temperature adjustment instruction comprises the following steps:

determining a row position and a column position corresponding to the target air supply area and respectively taking the row position and the column position as a target row position and a target column position;

determining the corresponding up-down rotation angle of the target line position and using the up-down rotation angle as the target up-down rotation angle, and

determining a left-right swinging angle corresponding to the target column position and taking the left-right swinging angle as a target left-right swinging angle;

and calculating the continuous air supply duration from the air deflector rotating to the target vertical rotation angle and the swinging of the swinging blade to the target horizontal swinging angle according to the temperature adjusting instruction.

6. The control method according to claim 5, wherein the step of calculating the continuous air supply time period for the air deflector to rotate to the target up-down rotation angle and the swing blade to swing to the target left-right swing angle according to the temperature regulation instruction comprises the following steps:

according to the temperature adjusting instruction, calculating the continuous air supply duration from the air guide plate to the target up-down rotation angle according to the number of the air supply areas at the target row position and the number of the target air supply areas, and

and calculating the continuous air supply duration from the swinging of the swinging blades to the target left-right swinging angle according to the number of the air supply areas of the target row position and the number of the target air supply areas.

7. The control method according to claim 6, wherein, in the case that the temperature regulation trend corresponding to the temperature regulation instruction is consistent with the heat exchange trend of the air conditioner,

according to

Calculating the continuous air supply time of the air deflector rotating to the target vertical rotation angle and the swinging blade swinging to the target horizontal swinging angle, and

for calculating the continuous air supply time length of the air deflector rotating to the target vertical rotation angle, in the formula, t is the continuous air supply time length of the air deflector rotating to the target vertical rotation angle, num is the number of the air supply areas at the target row position, and num0 is the number of the target air supply areas at the target row position;

for calculating the continuous air supply time length of the swinging blade swinging to the target left-right swinging angle, in the formula, t is the continuous air supply time length of the swinging blade swinging to the target left-right swinging angle, num is the number of the air supply areas at the target row position, and num0 is the number of the target air supply areas at the target row position.

8. The control method according to claim 6, wherein, in the case that the temperature regulation trend corresponding to the temperature regulation instruction is inconsistent with the heat exchange trend of the air conditioner,

according to

Calculating the continuous air supply time length from the rotation of the air deflector to the target vertical rotation angle and the swinging of the swinging blade to the target horizontal swinging angle, wherein k is an air supply compensation value, T is a standard period time length, and

for calculating the continuous air supply time length of the air deflector rotating to the target vertical rotation angle, in the formula, t is the continuous air supply time length of the air deflector rotating to the target vertical rotation angle, num is the number of the air supply areas at the target row position, and num0 is the number of the target air supply areas at the target row position;

for calculating the continuous air supply time length of the swinging blade swinging to the target left-right swinging angle, in the formula, t is the continuous air supply time length of the swinging blade swinging to the target left-right swinging angle, num is the number of the air supply areas at the target row position, and num0 is the number of the target air supply areas at the target row position.

9. The control method according to claim 1, wherein the step of acquiring a plurality of blowing areas divided in advance by a blowing range of an indoor unit of the air conditioner further comprises:

receiving an air supply area acquisition instruction sent by a terminal device and taking the terminal device as a target terminal device, wherein,

and the terminal equipment sends the air supply area acquisition instruction through a code scanning.

10. A control apparatus of an air conditioner comprising a memory having stored therein a computer program and a processor configured to run the computer program to perform the control method of any one of claims 1 to 9.

Images