CN110131870B

CN110131870B - Flow-dividing air outlet assembly and air conditioner

Info

Publication number: CN110131870B
Application number: CN201910557551.0A
Authority: CN
Inventors: 李倩文; 古汤汤; 屠璐琼; 陈伟; 李松
Original assignee: Aux Air Conditioning Co Ltd; Ningbo Aux Electric Co Ltd
Current assignee: Aux Air Conditioning Co Ltd; Ningbo Aux Electric Co Ltd
Priority date: 2019-06-25
Filing date: 2019-06-25
Publication date: 2024-06-11
Anticipated expiration: 2039-06-25
Also published as: CN110131870A

Abstract

The invention provides a split air outlet assembly and an air conditioner, and relates to the technical field of air conditioners. Through a plurality of reposition of redundant personnel air duct air-out, avoided directly carrying out the air-out through the air outlet, greatly reduced the air-out area to make the air supply scope littleer, more accurate, guarantee the air supply effect. Meanwhile, the shunt piece is driven to be close to or far away from the air outlet through the propelling movement mechanism, so that the air outlet area of the plurality of shunt air channels is changed, the air outlet speed of the shunt air channels is changed, and the air outlet distance can be adjusted.

Description

Flow-dividing air outlet assembly and air conditioner

Technical Field

The invention relates to the technical field of air conditioners, in particular to a split air outlet assembly and an air conditioner.

Background

With the improvement of living standard of people, the requirement for air supply to the air conditioner is higher and higher. At present, the air outlet of the traditional air conditioner is large, the air supply range is large, but the air supply is not accurate enough, for example, when a user selects the air to blow only the face (or smaller range), the air conditioner is often difficult to do. Meanwhile, the air outlet distance of the air outlet in the prior art is difficult to change, and the requirements of different air outlet distances cannot be met.

Disclosure of Invention

The invention solves the problem of how to improve the air supply accuracy and meet the requirements of different air outlet distances.

In order to solve the problems, the invention adopts the following technical proposal.

In one aspect, the invention provides a split air outlet assembly, which comprises an air outlet shell, a split part and a propelling movement mechanism, wherein the air outlet shell is provided with an air outlet air duct, the split part is arranged in the air outlet air duct and divides the air outlet air duct into a plurality of split air ducts, the plurality of split air ducts are communicated with an air outlet arranged on the outer side of the air outlet shell, and the propelling movement mechanism is connected with the split part and is used for driving the split part to be close to or far from the air outlet so as to change the air outlet area of the plurality of split air ducts.

According to the split air outlet assembly, the split parts are arranged in the air outlet air channels, the air outlet air channels are divided into the split air channels, and the split air channels are converged to the air outlet for air outlet, so that air outlet is prevented from being directly carried out through the air outlet, the air outlet area is greatly reduced, the air supply range is smaller and more accurate, and the air supply effect is ensured. Meanwhile, the shunt piece is driven to be close to or far away from the air outlet through the propelling movement mechanism, so that the air outlet area of the plurality of shunt air channels is changed, the air outlet speed of the shunt air channels is changed, and the air outlet distance is adjusted. Compared with the prior art, the split air outlet assembly provided by the invention has the advantages that the air supply is accurate, the air outlet distance can be adjusted, and different air outlet requirements are met.

Further, the propelling movement mechanism comprises a driving piece and a transmission piece, wherein the driving piece is in transmission connection with the transmission piece, and the transmission piece is connected with the dividing piece.

According to the split air outlet assembly, the driving piece drives the transmission piece to move, and the transmission piece drives the split piece to move, so that the split piece is close to or far away from the air outlet, and the controllability of the split piece is improved.

Further, the transmission piece comprises a driving gear and a driven rack, the driving gear is in transmission connection with the driving piece, the driven rack is meshed with the driving gear, and the driven rack is connected with the shunt piece.

According to the split air outlet assembly, the split piece is driven to move in a driving mode of the gear rack, so that the transmission is stable and reliable, and meanwhile, the driving distance is controlled more accurately.

Further, the driven rack is connected with the bottom of the flow dividing piece, and the driving gear is arranged at the bottom side of the air outlet shell.

According to the split air outlet assembly, the driven rack is connected with the bottom of the split part, and the driving gear is arranged at the bottom side of the air outlet shell, so that the driven rack and the driving gear bear the weight of the split part together, and under the action of gravity, the driven rack and the driving gear are meshed more firmly, and the transmission effect is ensured.

Further, a plurality of screw holes are formed in the driven rack, mounting through holes corresponding to the screw holes one by one are formed in the shunt piece, and the driven rack is connected with the bottom of the shunt piece through the screw holes.

Further, the air-out casing includes wind channel shell and bounding wall, and the setting of bounding wall is in the wind channel shell and has seted up the air outlet in the outside of wind channel shell, and the shunting can be close to or keep away from the bounding wall under the drive of propulsion motion to reduce or increase the air-out area in a plurality of reposition of redundant personnel wind channels.

According to the split air outlet assembly, the coaming is arranged on the outer side of the air duct shell, the air outlet is formed in the coaming, the split air duct sequentially passes through the air duct shell and the coaming and then enters the air outlet, the air outlet direction of the split air duct can deviate towards the center of the air outlet through the stop function of the coaming, direct air blowing is avoided, and meanwhile the air outlet area of the split air duct is conveniently changed by changing the distance between the split piece and the coaming.

Further, the coaming includes first side baffle and second side baffle, and first side baffle and second side baffle set up respectively in the both sides of wind channel shell, all form the reposition of redundant personnel wind channel between first side baffle and the reposition of redundant personnel spare, between second side baffle and the reposition of redundant personnel spare.

Further, the first side baffle is disposed obliquely outward relative to the air duct housing and the second side baffle is disposed obliquely outward relative to the air duct housing.

According to the split air outlet assembly, through the stopping effect of the first side baffle and the second side baffle, the air outlet of the split air channels at two sides can be converged into one strand and sprayed out towards the outer side, so that the air supply accuracy can be ensured.

Further, the first side baffle plate is arranged at a first included angle with the moving direction of the flow dividing piece, the second side baffle plate is arranged at a second included angle with the moving direction of the flow dividing piece, and the first included angle is identical with the second included angle.

According to the split air outlet assembly provided by the invention, the first side baffle plate and the second side baffle plate are oppositely arranged and have the same included angle with the moving direction of the split piece, so that the air outlet directions of the split air channels at two sides are intersected at the central line of the air outlet, and further the split air outlet assembly can be converged into air outlet which is opposite to the air outlet, the control of the air outlet direction can be more convenient, and meanwhile, the air supply accuracy is improved.

In another aspect, the invention provides an air conditioner, comprising a split air outlet assembly, wherein the split air outlet assembly comprises an air outlet shell, a split piece and a propelling movement mechanism, the air outlet shell is provided with an air outlet channel, the split piece is arranged in the air outlet channel and divides the air outlet channel into a plurality of split air channels, the plurality of split air channels are communicated with an air outlet arranged on the outer side of the air outlet shell, and the propelling movement mechanism is connected with the split piece and is used for driving the split piece to be close to or far away from the air outlet so as to change the air outlet area of the plurality of split air channels.

According to the air conditioner provided by the invention, the air outlet air duct is divided into the plurality of split air ducts by arranging the split parts in the air outlet air duct, and the plurality of split air ducts are converged to the air outlet for air outlet, so that air outlet is prevented from being directly carried out through the air outlet, the air outlet area is greatly reduced, the air supply range is smaller and more accurate, and the air supply effect is ensured. Meanwhile, the shunt piece is driven to be close to or far away from the air outlet through the propelling movement mechanism, so that the air outlet area of the plurality of shunt air channels is changed, the air outlet speed of the shunt air channels is changed, and the air outlet distance is adjusted.

Drawings

Fig. 1 is a schematic diagram of an overall structure of an air conditioner according to an embodiment of the present invention;

fig. 2 is a schematic diagram of an internal structure of an air conditioner according to an embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view of an air conditioner according to an embodiment of the present invention;

FIG. 4 is an enlarged schematic view of a portion of IV of FIG. 2;

FIG. 5 is a schematic cross-sectional view of an air conditioner according to a second embodiment of the present invention;

fig. 6 is an enlarged schematic view of a part of vi in fig. 3.

Reference numerals illustrate:

10-an air conditioner; 100-split air outlet components; 110-an air outlet shell; 111-an air duct shell; 113-coaming; 113 a-a first side baffle; 113 b-a second side baffle; 130-a shunt; 131-mounting through holes; 150-a propulsion movement mechanism; 151-driving member; 153-driving member; 155-a drive gear; 157-driven rack; 159-screw holes; 170-a split air duct; 190-an air outlet; 200-an air-conditioning case; 300-fan assembly.

Detailed Description

In order that the above objects, features and advantages of the invention will be readily understood, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

First embodiment

Referring to fig. 1 and 2 in combination, the present embodiment provides an air conditioner 10, which includes a split air outlet assembly 100, an air conditioning case 200, and a fan assembly 300, wherein the fan assembly 300 is disposed inside the air conditioning case 200, the split air outlet assembly 100 is connected with the fan assembly 300, and the fan assembly 300 outputs air through the split air outlet assembly 100. The air conditioner 10 provided by the embodiment is capable of discharging air after being split, so that air supply is more accurate, and meanwhile, the air supply distance is adjustable, so that the use experience of the whole machine is improved.

The air conditioner 10 in the present embodiment is a cabinet air conditioner, however, the cabinet air conditioner is merely taken as an example, and the air conditioner 10 in the present embodiment may be another type of air conditioner 10 such as a hanging machine or a central air conditioner, and is not particularly limited herein. The air conditioner 10 in this embodiment further has the function of up-down air outlet, the split air outlet assembly 100 is arranged on the lower air outlet, so that the air supply of the lower air outlet is more accurate, and the air supply distance of the lower air outlet is adjustable. Of course, the air outlet assembly 100 can also be disposed on the air inlet or on both the air inlet and the air outlet, so as to achieve the purpose of more accurate air supply of the air inlet and adjustable distance.

Referring to fig. 3 to 5 (arrows in the drawings indicate airflow directions), the split air outlet assembly 100 provided in this embodiment includes an air outlet housing 110, a splitter 130 and a propulsion mechanism 150, where the air outlet housing 110 has an air outlet duct, the splitter 130 is disposed in the air outlet duct and divides the air outlet duct into a plurality of split air ducts 170, the plurality of split air ducts 170 are communicated with an air outlet 190 formed outside the air outlet housing 110, and the propulsion mechanism 150 is connected with the splitter 130 and is used to drive the splitter 130 to approach or separate from the air outlet 190 so as to change the air outlet area of the plurality of split air ducts 170.

It should be noted that, the air outlet area mentioned in this embodiment refers to the cross-sectional area of the air outlet opening of the split air duct 170, and the size of the cross-sectional area directly affects the air outlet speed, and by changing the air outlet area of the split air duct 170, the air outlet speed can be changed, so as to change the air supply distance.

In this embodiment, the air outlet housing 110 is connected to the fan volute of the fan assembly 300, and the air conditioner housing 200 is provided with a yielding opening, and the air outlet 190 of the air outlet housing 110 corresponds to the yielding opening, so that the air outlet housing 110 can outlet air through the yielding opening. Meanwhile, the air outlet air duct is divided into the plurality of air distribution air ducts 170 by the aid of the flow distribution pieces 130, the plurality of air distribution air ducts 170 are converged to the air outlet 190 to carry out air outlet, direct air outlet through the air outlet 190 is avoided, the air outlet area is greatly reduced, the air supply range is smaller and more accurate, and the air supply effect is guaranteed. Meanwhile, the pushing movement mechanism 150 drives the flow dividing piece 130 to be close to or far away from the air outlet 190, so that the air outlet area of the plurality of flow dividing air channels 170 is changed, the air outlet speed of the flow dividing air channels 170 is changed, and the air outlet distance is adjusted.

It should be noted that, the pushing movement mechanism 150 can drive the splitter 130 to move back and forth, so that the splitter 130 approaches or departs from the air outlet 190, wherein the front-back direction refers to a connection line direction between the front side and the rear side of the air conditioner 10 after the installation is completed.

In this embodiment, the size of the splitter 130 is larger than the size of the air outlet 190, that is, the size of the splitter 130 in the viewing angle along the moving direction is larger than the size of the air outlet 190, so that the splitter 130 can completely cover the air outlet 190 from inside and completely close the air outlet 190, and when the air conditioner 10 does not need air outlet, the inside of the air outlet housing 110 and the outside of the air conditioner 10 can be isolated, so as to avoid external impurities from entering the air outlet housing 110.

It should be further noted that, in this embodiment, the splitter 130 has a plurality of splitter cambered surfaces and a splitter cambered surface, the splitter cambered surface is located on the outer side surface of the splitter 130 and protrudes outwards, the splitter cambered surfaces extend from the inner side of the splitter 130 to the splitter cambered surface, the splitter cambered surfaces divide the air outlet duct into a plurality of splitter ducts 170, the splitter cambered surfaces correspond to the air outlet 190 and can be covered on the air outlet 190, the propulsion mechanism 150 drives the splitter 130 to move back and forth, and the relative distance between the splitter cambered surfaces and the air outlet 190 can be adjusted, so as to adjust the air outlet area of the splitter ducts 170.

The air outlet shell 110 comprises an air duct shell 111 and a coaming 113, the splitter 130 is accommodated in the air duct shell 111, the coaming 113 is arranged on the outer side of the air duct shell 111 and provided with an air outlet 190, and the splitter 130 can be driven by the propelling movement mechanism 150 to be close to or far away from the coaming 113 so as to reduce or increase the air outlet area of the plurality of splitter air ducts 170.

In this embodiment, the air duct case 111 and the shroud 113 are integrally provided, the shroud 113 extends from the edge of the air duct case 111 toward the center of the air duct case 111, where the center of the air duct case 111 refers to the geometric center of the cross section of the air duct case 111 at the connection with the shroud 113, and the shroud 113 is provided with the air outlet 190, and the splitter 130 can cover the air outlet 190 and abut against the inner side surface of the shroud 113, so as to close the air outlet 190. By adjusting the distance between the splitter 130 and the inner side surface of the shroud 113, the air outlet area of the splitter duct 170 can be adjusted, thereby adjusting the air outlet speed and adjusting the air supply distance. In addition, through the backstop effect of bounding wall 113, can make the air-out direction of branch wind channel 170 to the center skew of air outlet 190, avoid directly blowing out the wind, and because the water conservancy diversion effect of water conservancy diversion cambered surface makes the air current of blowout in a plurality of branch wind channels 170 meet and merge into a high-pressure region at the middle part of water conservancy diversion cambered surface, and the multistrand air current can be integrated into a stream air current and outwards supply air, further improved the air supply precision, the air-out area of branch wind channel 170 is conveniently changed through the distance between change dividing piece 130 and bounding wall 113 simultaneously, thereby change the air supply distance after the confluence.

The shroud 113 includes a first side baffle 113a and a second side baffle 113b, the first side baffle 113a and the second side baffle 113b are respectively disposed at two sides of the duct case 111, and a split duct 170 is formed between the first side baffle 113a and the splitter 130, and between the second side baffle 113b and the splitter 130.

In this embodiment, the number of the split cambered surfaces on the splitter 130 is two, the two split cambered surfaces are respectively located at two sides of the splitter 130, and the two split cambered surfaces divide the air outlet duct into two, and the two air outlet ducts extend between the first side baffle 113a and the splitter 130 and between the second side baffle 113b and the splitter 130 respectively. That is, a part of one of the split air channels 170 is formed between the first side baffle 113a and the diversion cambered surface on the splitter 130, and a part of the other split air channel 170 is formed between the second side baffle 113b and the diversion cambered surface on the splitter 130.

In other preferred embodiments of the present invention, the shroud 113 further includes a third side baffle and a fourth side baffle, the third side baffle and the fourth side baffle are respectively disposed on the upper and lower sides of the air outlet 190, the number of the split cambered surfaces is 4, the 4 split cambered surfaces divide the air outlet duct into 4 split air ducts 170,4, the 4 air outlet ducts extend to the gaps between each side baffle and the splitter 130 respectively, and air outlet is performed in 4 directions from the top, bottom, left and right, so that precise air supply can be achieved, meanwhile, the 4 split air ducts 170 can be converged into a stream of air on the split cambered surfaces and flow to the air outlet, the air outlet area of the 4 split air ducts 170 can be changed by the movement of the splitter 130, the final air supply distance can be changed, and the purposes of precise air supply and adjustable air supply distance can be achieved.

In this embodiment, each of the split air ducts 170 includes an air inlet section and an air outlet section, the air inlet section is formed between the split cambered surface and the inner wall of the air duct shell 111, the air outlet section is formed by the gap between the first side baffle 113a and the split member 130 or the gap between the second side baffle 113b and the split member 130, and the split member 130 is driven to move along the front-back direction by the propulsion movement mechanism 150, so that the cross-sectional area of the air outlet section can be changed, and the air outlet area of the split air duct 170 is further changed.

In the present embodiment, the first side baffle 113a is disposed obliquely outward with respect to the air duct case 111, and the second side baffle 113b is disposed obliquely outward with respect to the air duct case 111. Through the stopping effect of the first side baffle 113a and the second side baffle 113b, the air outlets of the split air channels 170 on two sides can be converged into one strand and sprayed out towards the outer side, so that the air supply accuracy can be further ensured, and meanwhile, the air outlets of the split air channels 170 on two sides are ensured not to be completely counteracted.

In this embodiment, the first side baffle 113a is disposed at a first angle with respect to the moving direction of the splitter 130, and the second side baffle 113b is disposed at a second angle with respect to the moving direction of the splitter 130, and the first angle is the same as the second angle. The first side baffle 113a and the second side baffle 113b are oppositely arranged and have the same included angle with the moving direction of the flow dividing piece 130, so that the air outlet directions of the flow dividing air channels 170 on two sides are intersected at the center line of the air outlet 190, and then the air outlet to the air outlet 190 can be converged, the control of the air outlet directions can be facilitated, and meanwhile, the air supply accuracy is improved.

In other preferred embodiments of the present invention, the first angle is different from the second angle, so that the direction of the air flow converged on the air guiding cambered surface forms a certain angle with the air outlet 190, and the requirement of different air outlet directions or specific air outlet directions can be met.

Referring to fig. 6, the propelling movement mechanism 150 includes a driving member 151 and a transmission member 153, the driving member 151 is in transmission connection with the transmission member 153, and the transmission member 153 is connected with the diverting member 130. The driving piece 151 drives the transmission piece 153 to move, and the transmission piece 153 drives the flow dividing piece 130 to move, so that the flow dividing piece 130 is close to or far away from the air outlet 190, and the controllability of the flow dividing piece 130 is improved.

In the present embodiment, the transmission member 153 includes a driving gear 155 and a driven rack 157, the driving gear 155 is in transmission connection with the driving member 151, the driven rack 157 is engaged with the driving gear 155, and the driven rack 157 is connected with the shunt member 130. Specifically, the driven rack 157 is disposed along the front-rear direction, the driving member 151 is a driving motor, and is disposed below the air duct case 111, and the driving gear 155 is in transmission connection with the driving motor through a speed reducer, so that when the driving motor is started, the driving gear 155 can be driven to rotate, and the driven rack 157 is driven to move along the front-rear direction. The shunt 130 is driven to move in a driving mode of the gear rack, so that the transmission is stable and reliable, and the driving distance is controlled more accurately.

In other preferred embodiments of the present invention, the driving member 151 is an oil cylinder, the driving member 153 is a piston rod disposed along a front-rear direction and extends into the oil cylinder, and the piston rod is connected to the splitter 130, and the piston rod can be driven by the oil cylinder to move along the front-rear direction, so as to drive the splitter 130 to move along the front-rear direction. Of course, other driving forms of the driving member 151 and the driven member are possible, but any driving form capable of driving the flow dividing member 130 to move in the front-rear direction is within the scope of the present invention.

In the present embodiment, the driven rack 157 is connected to the bottom of the splitter 130, and the driving gear 155 is disposed at the bottom side of the air outlet housing 110. The driven rack 157 is connected with the bottom of the shunt 130, and meanwhile, the driving gear 155 is arranged on the bottom side of the air outlet shell 110, so that the driven rack 157 and the driving gear 155 bear the weight of the shunt 130 together, and under the action of gravity, the driven rack 157 is meshed with the driving gear 155 more firmly, and the transmission effect is ensured. Of course, the driven racks 157 may be disposed at two sides or top of the split flow, and the driving gears 155 may be disposed at two sides or top of the air outlet housing 110, so as to achieve the transmission effect.

In this embodiment, a plurality of screw holes 159 are formed in the driven rack 157, and mounting through holes 131 corresponding to the screw holes 159 are formed in the shunt 130, and the driven rack 157 is connected to the bottom of the shunt 130 through the screw holes 159. Through bolted connection's form, it is convenient to dismantle, is convenient for maintain simultaneously. Of course, the driven rack 157 may be engaged with or adhered to the shunt 130, which is not particularly limited herein.

In summary, this embodiment provides an air conditioner 10, through set up the reposition of redundant personnel piece 130 in the air-out wind channel, separate into two reposition of redundant personnel wind channels 170 with the air-out wind channel, under the backstop effect of first side baffle 113a and second side baffle 113b, two reposition of redundant personnel wind channels 170 are along the relative air-out of water conservancy diversion cambered surface, two air currents meet and join at water conservancy diversion cambered surface department simultaneously and form the air current of a forward jet, accurate air supply has been realized, the air-out is carried out through air outlet 190 directly to avoided, greatly reduced the air-out area, thereby make the air supply scope littleer, more accurate, guarantee the air supply effect. Meanwhile, the shunt 130 is driven to be close to or far away from the air outlet 190 through the propelling movement mechanism 150, so that the air outlet area of the plurality of shunt air channels 170 is changed, the air outlet speed of the shunt air channels 170 is changed, the air flow speed after converging is changed, the air outlet distance is adjusted, and the requirements of different air supply distances are met.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the invention, and the scope of the invention should be assessed accordingly to that of the appended claims.

Claims

1. The utility model provides a reposition of redundant personnel air-out subassembly, its characterized in that includes air-out casing (110), reposition of redundant personnel spare (130) and propulsion motion mechanism (150), air-out casing (110) have the air-out wind channel, reposition of redundant personnel spare (130) set up in the air-out wind channel and with the air-out wind channel is divided into a plurality of reposition of redundant personnel wind channels (170), a plurality of reposition of redundant personnel wind channels (170) are with set up air outlet (190) in air-out casing (110) outside, propulsion motion mechanism (150) with reposition of redundant personnel spare (130) are connected, are used for driving reposition of redundant personnel spare (130) are close to or keep away from air outlet (190) in order to change a plurality of the air-out area in reposition of redundant personnel wind channel (170);

the air outlet shell (110) comprises an air duct shell (111) and a surrounding plate (113), the flow dividing piece (130) is accommodated in the air duct shell (111), the surrounding plate (113) is arranged on the outer side of the air duct shell (111) and provided with the air outlet (190), and the flow dividing piece (130) can be driven by the propelling movement mechanism (150) to be close to or far away from the surrounding plate (113); so as to reduce or increase the air outlet area of a plurality of the diversion air channels (170);

The coaming (113) extends from the edge of the air duct shell (111) towards the center of the air duct shell (111), the coaming (113) comprises a first side baffle plate (113 a) and a second side baffle plate (113 b), the first side baffle plate (113 a) and the second side baffle plate (113 b) are respectively arranged on two sides of the air duct shell (111), the split air duct (170) is formed between the first side baffle plate (113 a) and the split air piece (130) and between the second side baffle plate (113 b) and the split air piece (130), and a plurality of split air ducts (170) are converged to the air outlet (190) for air outlet;

The first side baffle plate (113 a) and the moving direction of the flow dividing piece (130) are arranged at a first included angle, the second side baffle plate (113 b) and the moving direction of the flow dividing piece (130) are arranged at a second included angle, and the angles of the first included angle and the second included angle are the same.

2. The split air outlet assembly of claim 1, wherein the propulsion movement mechanism (150) comprises a driving member (151) and a transmission member (153), the driving member (151) is in transmission connection with the transmission member (153), and the transmission member (153) is connected with the split member (130).

3. The split air outlet assembly of claim 2, wherein the transmission member (153) includes a driving gear (155) and a driven rack (157), the driving gear (155) is in driving connection with the driving member (151), the driven rack (157) is meshed with the driving gear (155), and the driven rack (157) is connected with the split member (130).

4. A split air outlet assembly according to claim 3, wherein the driven rack (157) is connected to the bottom of the splitter (130), and the driving gear (155) is disposed at the bottom side of the air outlet housing (110).

5. The split air-out assembly according to claim 4, wherein a plurality of screw holes (159) are formed in the driven rack (157), mounting through holes (131) corresponding to the screw holes (159) one by one are formed in the split piece (130), and the driven rack (157) is connected with the bottom of the split piece (130) through the screw holes (159) in a bolt manner.

6. The split air outlet assembly of claim 1, wherein the first side flap (113 a) is disposed obliquely outward relative to the air duct housing (111) and the second side flap (113 b) is disposed obliquely outward relative to the air duct housing (111).

7. An air conditioner (10) comprising a split air outlet assembly as claimed in any one of claims 1 to 6.