CN110864442A - Independent control multidirectional air guide device and air delivery equipment - Google Patents

Abstract

The invention provides an independent control multidirectional air guiding device and air conveying equipment, wherein the independent control multidirectional air guiding device is provided with a frame body, a plurality of sets of rotary air guiding mechanisms and a plurality of sets of driving mechanisms, and each set of driving mechanism is provided with an independent controller for independent control; the multi-set rotary air guide mechanism is movably assembled on the frame body respectively, the multi-set drive mechanism is assembled on the frame body, the drive mechanism correspondingly drives the rotary air guide mechanism to rotate relative to the frame body, and at least two sets of rotary air guide mechanisms are driven by two different sets of drive mechanisms. Because the control modes of different controllers are the same or different, and the control time of different controllers is synchronous or asynchronous, the user can obtain different air outlet effects. When different air-out effects are superimposed, can obtain the air-out mode more abundant than prior art. According to the actual use scene, the user can obtain the target air-out effect by sending instructions to different controllers, so that the personalized use requirement of the user is met.

Description

Independent control multidirectional air guide device and air delivery equipment

Technical Field

The invention relates to the technical field of air outlet equipment, in particular to an independent control multidirectional air guide device and air conveying equipment with the same.

Background

In the existing wind transmission equipment products, such as tower fans, the air deflector at the air outlet is controlled by only one set of driving system, and the unidirectional rotation of the air deflector can be realized only. At this moment, the air-out scope is narrow and small, and the air-out scope is restricted by the width of air outlet. To obtain a larger air outlet range, the air outlet can be realized only by enlarging the width of the air outlet. This adjustment is only a very limited means, since the volume of the tower fan cannot be extended infinitely.

Moreover, the aviation baffle can only the unilateral rotation, no matter what kind of expansion angle, sway the angle, sway speed or rotation rate has been set up to the aviation baffle, all can be the air-out under a state like this, and the air-out effect is single, is difficult to satisfy the different demands of blowing of user. If there are many people on room one side, the opposite side is unmanned, when the aviation baffle sways and turns to unmanned one side, extravagant air-out this moment to let the user wait to blow the time and grow, influence user experience.

Therefore, it is necessary to provide an independent control multi-directional wind guiding device and wind conveying equipment to overcome the deficiencies of the prior art.

Disclosure of Invention

The invention aims to avoid the defects of the prior art and provides the independent control multidirectional air guide device, the independent control multidirectional air guide system and the air delivery equipment, which have the characteristics of wide air outlet range, less air outlet waste, high air outlet efficiency and more air outlet effects, so that the use experience of users is improved.

In order to achieve the above object, a first aspect of the present invention provides an independently controlled multi-directional wind guiding device, which comprises a frame, a plurality of sets of rotary wind guiding mechanisms and a plurality of sets of driving mechanisms, wherein each set of driving mechanism is provided with an independent controller for independent control;

the multi-set rotary air guide mechanism is movably assembled on the frame body respectively, the multi-set drive mechanism is assembled on the frame body, the drive mechanism correspondingly drives the rotary air guide mechanism to rotate relative to the frame body, and at least two sets of rotary air guide mechanisms are driven by two different sets of drive mechanisms.

Preferably, the control modes of the different controllers are the same or different; the control times of the different controllers are synchronized or not synchronized.

Preferably, the control parameter for controlling the operation mode of the driving mechanism by the controller is at least one of a rotation direction, a rotation speed and a rotation mode;

the rotation direction comprises clockwise rotation or anticlockwise rotation;

the rotating speed is that the driving mechanism rotates at the rotating speed of R revolutions per minute, wherein R is a positive integer;

the rotation mode is one of swinging, rotating or static.

Preferably, each controller independently controls the corresponding driving mechanism, so that the air outlet from the air duct passing through the independently-controlled multi-directional air guiding device is in at least one of the following working modes: the air conditioner comprises a partial region air outlet mode, a partial region rapid circulation mode, a wide-angle air outlet mode, a multiple-effect air outlet mode and a natural wind simulation mode.

Specifically, the air outlet mode of the partial region specifically includes: the driving mechanisms in partial areas control the corresponding rotary air guide mechanisms to be in a closed state, and the driving mechanisms in other areas work to regulate and control the rotary air guide mechanisms to be in an open state.

Specifically, the partial region fast circulation mode specifically includes: under the condition of the same rotation direction and the same rotation mode, at least two different sets of driving mechanisms rotate at different speeds.

Specifically, the above-mentioned wide angle air-out mode specifically is: under the condition of the same rotating speed and the same rotating mode, at least one set of driving mechanism rotates in a clockwise direction, and the other set of driving mechanism rotates in a counterclockwise direction.

Specifically, the multiple-effect air outlet mode specifically includes: under the condition of the same rotating speed and the same rotating direction, at least one set of driving mechanism is arranged to rotate in a swinging mode, and the other set of driving mechanism is arranged to rotate in a rotating mode.

Specifically, the simulated natural wind mode specifically includes: the swing angles of the air guide mechanisms driven by the driving mechanisms are different, so that the air outlet is scattered, and random natural wind is simulated.

This singly control multidirectional air ducting still is provided with main control chip, and main control chip and every independent controller difference signal of telecommunication are connected, and main control chip is to every controller output control signal.

Preferably, the main control chip controls each independent controller to work, so that air outlet is performed according to any one or more of a target object wind sheltering mode, a target object wind following mode and a target object wind adding mode;

specifically, the target object wind-sheltering mode specifically includes:

when the air passes through the target object position, the air guide mechanism is controlled to swing fast so that the air outlet angle avoids the target object position; or

When the air passes through the target object position, the air guide mechanism is controlled to reversely deviate the air outlet angle or the air guide mechanism is controlled to close the air outlet and not blow air;

specifically, the target object wind following mode specifically includes: controlling the air guide assembly to enable the air outlet direction to move along with the position of the target object;

specifically, the target object wind force adding mode specifically includes:

when the air outlet direction is controlled to reach the position of a target user, the air guide assembly is controlled to perform swinging or increase the air outlet quantity after being decelerated and swung or stopped for T1 time; t1 is more than or equal to 3s and less than or equal to 15 s.

Preferably, each set of the rotary air guide mechanism is provided with an air guide plate and rotating rods fixedly connected with two ends of the air guide plate, and the rotating rods at two ends of the air guide plate are movably assembled with the frame body respectively.

Preferably, the above-mentioned multidirectional air ducting of independent control still is provided with two racks, and the dwang of at least one end of every aviation baffle meshes with corresponding rack, the rack drives the dwang rotation rather than meshing.

Preferably, each set of driving mechanism is provided with a driving motor and a driving gear, the driving motor and the driving gear are fixed on the frame body, the driving motor drives the driving gear to rotate, and the driving gear is meshed with the rack.

Preferably, the single-control multidirectional air guiding device is further provided with a mounting box, and the mounting box is fixed on the frame body; the driving motor and the driving gear are fixed in the mounting box, and the rotating rod at one end of the air deflector is movably assembled in an assembling hole formed in the mounting box.

Preferably, the inner wall of the mounting box is provided with a plurality of pairs of limiting mechanisms, each pair of limiting mechanisms is provided with an upper limiting block and a lower limiting block, and the rack is assembled between each pair of upper limiting block and lower limiting block.

Preferably, the rack body is provided with a through hole for assembling with the rotating rod, and the rotating rod is assembled in the corresponding through hole.

Preferably, every N sets of rotary air guide mechanisms are driven by one set of driving mechanism, and the rotating rods at the corresponding ends of every N sets of rotary air guide mechanisms are meshed with the same rack;

wherein N is a natural number of 1 or more.

Preferably, N is 2 or more and 10 or less.

Preferably, the driving mechanism is disposed at an upper portion, a lower portion or a middle portion of the frame body.

When the independent control multi-directional air guide device is used, when the control modes of at least two different controllers are the same and the control time is synchronous, the air outlet effects of the rotary air guide mechanisms under the control of the independent control multi-directional air guide device are consistent, and the condition is closest to the prior art. When the control modes of the two different controllers are different or the control time is asynchronous, the rotary air guide mechanism under the control of the two different controllers can generate different relative positions, motion states and motion speeds, and at least two different air outlet effects are formed. When different air-out effects are superimposed, can obtain the air-out mode more abundant than prior art. According to the actual use scene, the user can obtain the target air-out effect by sending instructions to different controllers, so that the personalized use requirement of the user is met.

The invention provides a wind conveying device with the independent control multidirectional wind guide device, and the devices can be household wind conveying devices such as fans, air conditioners, air purifiers, humidifiers, fan heaters, infrared radiation heaters and the like. The air delivery equipment using the independent control multidirectional air guide device has the advantages of being wide in air outlet range, less in air outlet waste, high in air outlet efficiency, multiple in air outlet effect and excellent in user experience.

Drawings

Fig. 1 is an exploded perspective view of an embodiment 2 of the independently-controlled multi-directional air guiding device of the present invention;

fig. 2 is an exploded view of a driving mechanism and a rotary air guiding mechanism in embodiment 2 of the individually controlled multi-directional air guiding device of the present invention;

in fig. 1 to 2, the method includes:

an independent control multi-directional air guide device 100, a frame body 200, a mounting box 300,

An upper limit block 410, an upper limit block 420,

A lower limit block 510, a lower limit block 520,

A driving motor 610, a driving motor 620,

A drive gear 710, a drive gear 720,

A rack 810, a rack 820,

Rotating rod 911, rotating rod 912, rotating rod 913, rotating rod 914,

A rotating rod 921, a rotating rod 922, a rotating rod 923, a rotating rod 924,

Air deflector 1011, air deflector 1012, air deflector 1021, air deflector 1022.

Detailed Description

The invention is further illustrated by the following examples.

Example 1.

An independent control multidirectional air guide device is provided with a frame body, a plurality of sets of rotary air guide mechanisms and a plurality of sets of driving mechanisms, wherein each set of driving mechanism is provided with an independent controller for independent control;

the multi-set rotary air guide mechanism is movably assembled on the frame body respectively, the multi-set drive mechanism is assembled on the frame body, the drive mechanism correspondingly drives the rotary air guide mechanism to rotate relative to the frame body, and at least two sets of rotary air guide mechanisms are driven by two different sets of drive mechanisms.

When the air guide mechanism is used, when the control modes of at least two different controllers are the same and the control time is synchronous, the air outlet effects of the rotary air guide mechanism under the control of the controllers are consistent, and the condition is closest to the prior art. When the control modes of the two different controllers are different or the control time is asynchronous, the rotary air guide mechanism under the control of the two different controllers can generate different relative positions, motion states and motion speeds, and at least two different air outlet effects are formed.

The relative position referred in this embodiment refers to the spatial relationship of the planes of the rotary air guiding mechanisms. When the spatial relationship of the planes of the rotary air guiding mechanisms is intersected, the relative positions of the rotary air guiding mechanisms are different. When the spatial relationship of the planes of the rotary air guiding mechanisms is parallel or coincident, the relative positions of the rotary air guiding mechanisms are the same. Setting a group of rotary air guide mechanisms under the control of the same controller, wherein the relative positions of each set of rotary air guide mechanisms in the group are the same; when at least two controllers exist, the control modes or the control time of the controllers are different, the controllers correspondingly control the two groups of rotating wind guide mechanisms, and the relative positions of the wind guide plates between the groups are different.

The motion state referred to in this embodiment refers to any one of the rotary air guiding mechanism being closed, opened at a fixed angle, swinging reciprocally, or rotating reciprocally with respect to the frame body. Any one of the air outlet effects of no air outlet, fixed angle air outlet, swinging air outlet or one-way air sweeping is correspondingly generated.

The movement speed in this embodiment refers to a rotation speed when the rotary air guiding mechanism swings or rotates reciprocally. When one set of rotary air guide mechanism swings to output air, the other set of rotary air guide mechanism sweeps air in a single direction, and the rotating speeds of the two sets of rotary air guide mechanisms are consistent, the waiting time of single-point air blowing is shorter than that of swinging air output in the same time.

In conclusion, when different air-out effects are superposed, more abundant air-out modes than the prior art can be obtained. According to the actual use scene, the user can obtain the target air-out effect by sending instructions to different controllers, so that the personalized use requirement of the user is met.

Example 2.

An independently-controlled multidirectional air guiding device is provided with a frame body 200, two sets of rotary air guiding mechanisms and two sets of driving mechanisms, wherein each set of driving mechanism is provided with an independent controller for independent control, as shown in fig. 1 and 2;

the two sets of rotary air guide mechanisms are respectively and movably assembled on the frame body 200, the two sets of driving mechanisms are assembled on the frame body 200, and the driving mechanisms correspondingly drive the rotary air guide mechanisms to rotate relative to the frame body 200.

Specifically, in the individually controlled multidirectional air guiding device 100, one set of rotary air guiding mechanism is provided with an air guiding plate 1011 and an air guiding plate 1012, a rotary rod 911 and a rotary rod 912 fixedly connected to two ends of the air guiding plate 1011, a rotary rod 913 and a rotary rod 914 fixedly connected to two ends of the air guiding plate 1012, and the rotary rods at two ends of the air guiding plate are movably assembled with the frame body 200 respectively.

The other set of rotary air guiding mechanism is provided with an air guiding plate 1021, an air guiding plate 1022, a rotating rod 921 and a rotating rod 922 which are fixedly connected with two ends of the air guiding plate 1021, a rotating rod 923 and a rotating rod 924 which are fixedly connected with two ends of the air guiding plate 1022, and the rotating rods at two ends of the air guiding plate are respectively movably assembled with the frame body 200.

The independently controlled multi-directional wind guiding device 100 is further provided with two racks, a rack 810 and a rack 820. Dwang 911 and dwang 913 and the meshing of the rack 810 that corresponds, dwang 921 and dwang 923 mesh with the rack 820 that corresponds, the rack drives rather than the dwang rotation of meshing.

One set of driving mechanism of the single-control multi-directional air guiding device 100 is provided with a driving motor 610 and a driving gear 710, the driving motor 610 and the driving gear 710 are fixed on the frame body, the driving motor 610 drives the driving gear 710 to rotate, and the driving gear 710 is meshed with a rack 810.

Another set of actuating mechanism is provided with driving motor 620 and driving gear 720, and driving motor 620 and driving gear 720 are fixed in the support body, driving motor 620 drive driving gear 720 rotates, and driving gear 720 and rack 820 mesh.

The single-control multidirectional air guiding device 100 is further provided with a mounting box 300, and the mounting box 300 is fixed on the frame body 200; the driving motor 610, the driving motor 620, the driving gear 710 and the driving gear 720 are fixed in the mounting box 300, and the air deflector 1011, the air deflector 1012, the air deflector 1021, the rotating rod 911 at one end of the air deflector 1022, the rotating rod 912, the rotating rod 913 and the rotating rod 914 are respectively movably assembled in an assembling hole arranged in the mounting box 300.

This mounting box 300 inner wall is provided with two pairs of stop gear, and a pair of stop gear is equipped with stopper 410 and stopper 510 down, and rack 810 assembles between stopper 410 and stopper 510 down. The other pair of limiting mechanisms is provided with an upper limiting block 420 and a lower limiting block 520, and the rack 820 is assembled between the upper limiting block 420 and the lower limiting block 520.

Specifically, the frame body 200 is provided with a through hole for assembling with the rotating rod, which is assembled in the corresponding through hole.

As shown in fig. 1 and 2, a controller controls the driving motor 610 and the driving gear 710 to move, the driving gear 710 engages with the rack 810, the rack 810 is driven to move between the upper limiting block 410 and the lower limiting block 510, and the rack 810 drives the rotating rod 911 and the rotating rod 913 engaged therewith to rotate.

The other controller controls the driving motor 620 and the driving gear 720 to move, the driving gear 720 engages with the rack 820 to drive the rack 820 to move between the upper limiting block 420 and the lower limiting block 520, and the rack 820 drives the rotating rod 921 and the rotating rod 923 engaged therewith to rotate. Because the two ends of the air deflector are fixedly connected with the rotating rods, the rotating air guide mechanism is a whole, and the rotating rod at one end can rotate to drive the whole rotating air guide mechanism to rotate.

As shown in fig. 1 and 2, as long as the two controllers have different control modes or asynchronous control time, a multi-effect air outlet effect can be obtained.

Example 3.

The structure of the one-control multi-directional air guiding device is the same as that of the embodiment 2, and the difference is that: in the single-control multi-directional air guide device, each set of driving mechanism correspondingly drives 3 sets of rotating air guide mechanisms. The air-out effect that produces like this is more nimble changeable than embodiment 2.

Example 4.

The structure of the one-control multi-directional air guiding device is the same as that of the embodiment 2, and the difference is that: one set of driving mechanism correspondingly drives 3 sets of rotary air guide mechanisms, and the other set of driving mechanism correspondingly drives 10 sets of rotary air guide mechanisms. The air-out effect that produces like this is more nimble changeable than embodiment 3, and user experience is abundanter.

Example 5.

The structure of the one-control multi-directional air guiding device is the same as that of the embodiment 2, and the difference is that: the driving mechanism is disposed at the lower portion of the frame body 200, that is, the rotating rods 912 and 914 are engaged with the corresponding racks 810, and the rotating rods 922 and 924 are engaged with the corresponding racks 820. The advantageous effects of this embodiment are the same as those of embodiment 2.

Example 6.

The structure of the one-control multi-directional air guiding device is the same as that of the embodiment 2, and the difference is that: actuating mechanism sets up in the middle part of support body 200, and the aviation baffle needs to set up one section dwang with aviation baffle fixed connection for support body 200 middle part position this moment, and one set of rotation air guide mechanism is provided with two aviation baffles and 3 sections dwangs promptly, and aviation baffle and dwang are with alternate form fixed connection. The rack is meshed with the rotating rod in the middle. The spatial plane relation of the two air deflectors on each set of rotary air guiding mechanism is coincident, and the beneficial effect is the same as that of the embodiment 2.

Example 7.

The structure of the one-control multi-directional air guiding device is the same as that of the embodiment 6, and the difference is that: the spatial plane relation of two aviation baffles on every set of rotation wind-guiding mechanism is for crossing, and its air-out effect is more nimble changeable than embodiment 6, and user experience is abundanter.

Example 8.

An independent control multi-directional air guide device has the same structure as that of embodiment 2, and an air outlet mode is set as a partial region air outlet mode. The air outlet mode of the partial region is specifically as follows: the driving mechanisms in partial areas control the corresponding rotary air guide mechanisms to be in a closed state, and the driving mechanisms in other areas work to regulate and control the rotary air guide mechanisms to be in an open state.

When the air conditioner is actually used, the left air guide plate and the right air guide plate are arranged, one side with people is set to swing for air outlet, one side without people is set to be fixed for air outlet, and the fixed angle is deviated to one side with people. At the moment, air is only exhausted to the manned region, and air is not exhausted to the unmanned region, so that the effectiveness of air outlet is improved, and waste of air outlet is reduced.

Example 9.

An independent control multi-directional air guide device is the same as the structure of the air guide device in the embodiment 2, and an air outlet mode is set to be a partial area rapid circulation mode. The air outlet mode of the partial region is specifically as follows: the driving mechanisms in partial areas control the corresponding rotary air guide mechanisms to be in a closed state, and the driving mechanisms in other areas work to regulate and control the rotary air guide mechanisms to be in an open state.

When the wind guide plate is actually used, the left and right wind guide plates are arranged, one side with people is set to swing the wind at a low speed, one side without people is set to swing the wind at a high speed, at the moment, the air in the area with people is exhausted more, the air in the area without people is exhausted less, the effectiveness of the wind is improved, and the waste of the wind is reduced. The unmanned area also uses swinging air outlet, so that the air in the room can uniformly circulate with least energy consumption.

Example 10.

An independent control multi-directional air guide device has the same structure as that of the embodiment 2, and an air outlet mode is set to be a simulated natural wind mode. The simulated natural wind mode specifically comprises the following steps: the swing angles of the air guide mechanisms driven by the driving mechanisms are different, so that the air outlet is scattered, and random natural wind is simulated.

When the air conditioner is actually used, the left air guide plate and the right air guide plate can rotate in the same direction, can also rotate in opposite directions, or rotate on one side and do not rotate on the other side, so that different air outlet effects are generated. When the air deflector rotates, different air outlet effects can be generated by adjusting the rotating speed, and the effect of simulating natural wind is achieved.

Example 11.

An air delivery device with an air outlet provided with an independent control multidirectional air guide device as in any one of embodiments 1 to 10 can be common household equipment such as a fan, an air conditioner, an air purifier, a humidifier, a fan heater and an infrared radiation heater, and the independent control multidirectional air guide device is widely applied.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the protection scope of the present invention, and although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims (21)

1. The utility model provides a multidirectional air ducting of independent control which characterized in that: the wind power generation device is provided with a frame body, a plurality of sets of rotary wind guide mechanisms and a plurality of sets of driving mechanisms, wherein each set of driving mechanism is provided with an independent controller for controlling;

the multiple sets of rotary air guide mechanisms are respectively and movably assembled on the frame body, the multiple sets of driving mechanisms are assembled on the frame body, and the driving mechanisms correspondingly drive the rotary air guide mechanisms to rotate relative to the frame body;

at least two sets of rotary air guide mechanisms are driven by two different driving mechanisms.

2. The individually-controlled multidirectional air guiding device as recited in claim 1, wherein: the control modes of different controllers are the same or different; the control times of the different controllers are synchronized or not synchronized.

3. The individually-controlled multidirectional air guiding device as recited in claim 2, wherein:

the control parameter of the controller for controlling the running mode of the driving mechanism is at least one of the rotating direction, the rotating speed and the rotating mode;

the rotation direction comprises clockwise rotation or anticlockwise rotation;

the rotating speed is that the driving mechanism rotates at the rotating speed of R revolutions per minute, wherein R is a positive integer;

the rotation mode is one of swinging, rotating or static.

4. The individually-controlled multidirectional air guiding device as recited in claim 3, wherein: each controller independently controls the corresponding driving mechanism, so that the air outlet of the air duct passing through the independently-controlled multidirectional air guide device is in at least one of the following working modes: the air conditioner comprises a partial region air outlet mode, a partial region rapid circulation mode, a wide-angle air outlet mode, a multiple-effect air outlet mode and a natural wind simulation mode.

5. The individually-controlled multidirectional air guiding device as recited in claim 4, wherein: the air outlet mode of partial region is specifically as follows: the driving mechanisms in partial areas control the corresponding rotary air guide mechanisms to be in a closed state, and the driving mechanisms in other areas work to regulate and control the rotary air guide mechanisms to be in an open state.

6. The individually-controlled multidirectional air guiding device as recited in claim 4, wherein: the partial region rapid circulation mode specifically comprises the following steps: under the condition of the same rotation direction and the same rotation mode, at least two different sets of driving mechanisms rotate at different speeds.

7. The individually-controlled multidirectional air guiding device as recited in claim 4, wherein: the wide-angle air-out mode specifically is: under the condition of the same rotating speed and the same rotating mode, at least one set of driving mechanism rotates in a clockwise direction, and the other set of driving mechanism rotates in a counterclockwise direction.

8. The individually-controlled multidirectional air guiding device as recited in claim 4, wherein: the multiple-effect air outlet mode specifically comprises the following steps: under the condition of the same rotating speed and the same rotating direction, at least one set of driving mechanism is arranged to rotate in a swinging mode, and the other set of driving mechanism is arranged to rotate in a rotating mode.

9. The individually-controlled multidirectional air guiding device as recited in claim 4, wherein: the simulated natural wind mode specifically comprises the following steps: the swing angles of the air guide mechanisms driven by the driving mechanisms are different, so that the air outlet is scattered, and random natural wind is simulated.

10. The individually-controlled multidirectional air guiding device as recited in claim 1, wherein: the intelligent control system is also provided with a main control chip, the main control chip is respectively in electric signal connection with each independent controller, and the main control chip outputs control signals to each controller.

11. The individually-controlled multidirectional air guiding device as recited in claim 10, wherein: the main control chip controls each independent controller to work, so that air outlet is carried out according to any one or more of a target object wind sheltering mode, a target object wind following mode and a target object wind adding mode;

the target object wind-sheltering mode specifically comprises the following steps:

when the air passes through the target object position, the air guide mechanism is controlled to swing fast so that the air outlet angle avoids the target object position; or

When the air passes through the target object position, the air guide mechanism is controlled to reversely deviate the air outlet angle or the air guide mechanism is controlled to close the air outlet and not blow air;

the target object wind following mode specifically comprises the following steps: controlling the air guide assembly to enable the air outlet direction to move along with the position of the target object;

the target object wind power adding mode specifically comprises the following steps:

when the air outlet direction is controlled to reach the position of a target user, the air guide assembly is controlled to perform swinging or increase the air outlet quantity after being decelerated and swung or stopped for T1 time; t1 is more than or equal to 3s and less than or equal to 15 s.

12. The independently-controlled multidirectional air guiding device as recited in any one of claims 1 to 11, wherein: each set of rotary air guide mechanism is provided with an air guide plate and a rotating rod fixedly connected with the two ends of the air guide plate, and the rotating rods at the two ends of the air guide plate are movably assembled with the frame body respectively.

13. The individually-controlled multidirectional air guiding device as recited in claim 12, wherein: the air guide plate is characterized by further comprising two racks, the rotating rod at least one end of each air guide plate is meshed with the corresponding rack, and the rack drives the rotating rod meshed with the rack to rotate.

14. The independently-controlled multidirectional air guiding device as recited in claim 13, wherein: each set of driving mechanism is provided with a driving motor and a driving gear, the driving motor and the driving gear are fixed on the frame body, the driving motor drives the driving gear to rotate, and the driving gear is meshed with the rack.

15. The individually-controlled multidirectional air guiding device as recited in claim 14, wherein: the mounting box is also arranged and fixed on the frame body; the driving motor and the driving gear are fixed in the mounting box, and the rotating rod at one end of the air deflector is movably assembled in an assembling hole formed in the mounting box.

16. The individually-controlled multidirectional air guiding device as recited in claim 15, wherein: the mounting box inner wall is provided with a plurality of pairs of stop gear, and every pair of stop gear is equipped with upper limit piece and lower limit piece, and the rack assembly is between every pair of upper limit piece and lower limit piece.

17. The individually-controlled multidirectional air guiding device as recited in claim 12, wherein: the support body is provided with the through-hole that is used for with the dwang assembly, and the dwang assembly is in the through-hole that corresponds.

18. The independently-controlled multidirectional air guiding device as recited in any one of claims 1 to 11, wherein: every N sets of rotating air guide mechanisms are driven by one set of driving mechanism, and rotating rods at corresponding ends of every N sets of rotating air guide mechanisms are meshed with the same rack;

wherein N is a natural number of 1 or more.

19. The individually-controlled multidirectional air guiding device as recited in claim 18, wherein: n is not less than 2 and not more than 10.

20. The independently-controlled multidirectional air guiding device as recited in any one of claims 1 to 11, wherein: the driving mechanism is arranged at the upper part or the lower part or the middle part of the frame body.

21. A wind delivery apparatus, characterized by: the air guiding device with independent control and multiple directions as claimed in any one of claims 1 to 20.

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