CN218672585U - Shuttle-shaped guiding device, indoor unit and air conditioner - Google Patents

Abstract

The utility model provides a shuttle type guiding device and indoor set, air conditioner, shuttle type guiding device movable mounting is in the air-out wind channel of air conditioning indoor set, shuttle type guiding device encloses wall surface and wind-guiding face as an organic whole from top to bottom including, paste the wall and follow the last air-out wall of air-out wind channel tail end and/or the laminating of air-out wall remove down, and go up the air-out wall with one of them department of air-out wall stretches out down the air-out wind channel to make its half lateral position of air outlet of formation directly extend into indoor space. Through a shuttle type guiding device and indoor set, air conditioner for shuttle type guiding device can replace and cancel conventional air guide plate structure, and then make the air current blow to indoor initial flow path can realize "hot-blast pushing down, the wainscot flow extension air-out effect of blowing on the cold wind" through the air outlet, especially still can not form the backstop to the air current air-out basically, and then still reduce the amount of wind loss by a wide margin.

Description

Shuttle-shaped guiding device, indoor unit and air conditioner

Technical Field

The utility model relates to an air conditioning technology field particularly, relates to a shuttle-shaped guiding device and indoor set, air conditioner.

Background

In the prior art, most of air outlets of a wall-mounted indoor unit are arranged at the bottom of the front side of a casing of the wall-mounted indoor unit, an air deflector is arranged at the air outlet, and an initial flow path of air flow blown to the indoor space through the air outlets is adjusted by adjusting the opening and closing of the air deflector and adjusting the swing angle of the air deflector within a certain range in the operation process of an air conditioner. However, due to the extending direction of the air outlet duct and the swing mounting structure of the air deflector, the swing angle of the air deflector is generally limited, so that the initial flow path of the air flow blown into the room through the air outlet is unsatisfactory, and the air deflector can stop the air flow outlet to a certain extent while guiding the air, thereby causing air loss and possibly generating noise even in a severe case.

SUMMERY OF THE UTILITY MODEL

In view of this, the technical problem to be solved by the utility model is: the first aspect is to provide a shuttle-shaped flow guiding device, so that the shuttle-shaped flow guiding device can replace and cancel a conventional air guiding plate structure, further, the wall-pasting flow of the air flow blowing to the indoor through the air outlet can realize the effect of prolonging the air outlet effect, and especially, the air flow outlet cannot be stopped basically, and further, the air volume loss is reduced greatly.

In order to solve the technical problem of the first aspect, the utility model provides a shuttle guiding device, movable mounting is in the air-out wind channel of machine in the air conditioning, shuttle guiding device includes from top to bottom encloses adherence face and wind-guiding face as an organic whole, paste the wall edge the last air-out wall of air-out wind channel tail end and/or air-out wall laminating removal down, and go up the air-out wall with one of them department of air-out wall is outwards stretched out down air-out wind channel to make its half lateral position of air outlet of formation directly extend into indoor space.

Through shuttle type guiding device, can replace and cancel conventional air guide plate structure, and then make the air current blow to indoor initial flow path can realize "hot-blast pushing down, the wainscot flow extension air-out effect that blows on the cold wind", especially still can not form the backstop to the air current air-out basically, and then still reduce the amount of wind loss by a wide margin. Because the wall-attached surface only extends out of the air outlet duct at one of the upper air outlet wall and the lower air outlet wall, the wall-attached flow design of only prolonging the half-side air outlet wall can be ensured even if the shuttle-shaped flow guide device comprises two flow guide shuttles.

Preferably, the shuttle-type guiding device includes one or two guiding shuttles, wherein a first guiding shuttle of the two guiding shuttles only moves along the upper air outlet wall in a fitting manner, and a second guiding shuttle only moves along the lower air outlet wall in a fitting manner.

The shuttle-type diversion device can be provided with only one diversion shuttle to move along the upper air outlet wall and/or the lower air outlet wall in a fitting manner, and the air outlet is prolonged at one of the upper air outlet wall and the lower air outlet wall according to the selection of the operation mode of the air conditioner. Certainly, the shuttle-shaped diversion device can also be provided with two diversion shuttles at the same time, so that the first diversion shuttle only moves along the upper air outlet wall in a fitting manner, and the air outlet is only prolonged in the heating mode; and the second diversion shuttle only moves along the lower air outlet wall in a fitting manner and only extends the air outlet in the refrigeration mode.

Preferably, the wall attaching surface and the air guide surface are both convex cambered surfaces, and the upper air outlet wall and the lower air outlet wall are both concave cambered surfaces matched with the wall attaching surface.

The air outlet is favorably matched with the height of the air flow in the set guiding direction during dynamic forming, so that the wall flow of hot air pressing and cold air blowing upwards is enhanced, and the air outlet effect is prolonged.

Preferably, a transmission assembly for driving the diversion shuttle to move is arranged at the left end and/or the right end of the diversion shuttle, which is away from the air outlet.

The transmission assembly is used for driving the diversion shuttle to move, and the transmission assembly deviates from the left end and/or the right end of the air outlet, so that physical layout can be conveniently carried out on the transmission assembly, and the air outlet is avoided. The transmission component can be arranged on the air guide surface or the wall attaching surface of the transmission component.

Preferably, only one flow guide shuttle is arranged and selectively attached and moved along the upper air outlet wall or the lower air outlet wall so as to prolong the air outlet at any position of the upper air outlet wall and the lower air outlet wall.

The air guide surface and the air outlet wall which is opposite to the air guide surface can directly form a half-side extended air outlet device of the air outlet, and further are matched with the set air flow guide direction, so that the wall-sticking flow under the condition of pressing hot air downwards and blowing cold air upwards is enhanced, and the air outlet effect is prolonged.

Preferably, at the left end and/or the right end of the wind guide surface, which faces away from the wind outlet, the transmission assembly comprises: the air guide device comprises a driving connecting rod, a moving gear, a fixed gear and a driven connecting rod, wherein the driven connecting rod is used for driving the air guide shuttle to rotate along the upper air outlet wall and the lower air outlet wall in a diameter-variable fit manner and prolong the air outlet.

When the diversion shuttle rotates along the upper air outlet wall and the lower air outlet wall in a fitting manner and extends the air outlet, the fitting rotation is necessarily variable-diameter rotation. When one end of the driven connecting rod is connected with the air guide surface and the other end of the driven connecting rod is connected with the moving gear in the transmission assembly, the rotating center of the driven connecting rod is changed, and therefore the diversion shuttle can be driven to rotate along the upper air outlet wall and the lower air outlet wall in a diameter-variable fit mode and to prolong air outlet.

Preferably, the left end of moving the gear, the initiative connecting rod carries moving the gear is in do the interior meshing rotation of first direction in the fixed gear the right-hand member of moving the gear, driven connecting rod carries the reducing rotation of water conservancy diversion shuttle on the second direction, wherein the both ends of driven connecting rod are used for connecting respectively moving the gear with the wind-guiding surface, just the second direction with first direction is reverse each other.

When the transmission component is arranged along the left end deviating from the air outlet, if the first direction is anticlockwise, the second direction is clockwise, and after the transmission component rotates in place, the heating mode shown in the figure can be opened so as to blow hot air downwards; on the contrary, if the first direction is clockwise, the second direction is counterclockwise, and the refrigeration mode as shown in the figure can be started after the rotation is in place, so as to blow cold air upwards. Of course, the transmission component can also be arranged along the right end deviating from the air outlet, or arranged at the left end and the right end.

Preferably, guide rails are arranged on the upper air outlet wall and the lower air outlet wall, and guide rods matched with the guide rails are arranged on the wall attaching surfaces.

The wall attaching surface can be ensured to closely attach and rotate along the upper air outlet wall and the lower air outlet wall, and meanwhile, the abrasion of the wall attaching surface can be greatly reduced.

The to-be-solved technical problem of the utility model is still in: the second aspect provides an indoor unit, and/or the third aspect provides an air conditioner for it can cancel conventional air guide plate structure, and then makes the air current blow to indoor initial flow path can realize "hot-blast pushing down, cold wind upblow" the wainscot flow prolongs the air-out effect, especially still can not form the backstop to the air current air-out basically, and then still reduces the amount of wind loss by a wide margin.

In order to solve the technical problem of the second aspect, the utility model provides an indoor unit, have any embodiment of the first aspect the shuttle guiding device.

In order to solve the technical problem of the third aspect, the present invention provides an air conditioner having the shuttle-shaped air guiding device of any one of the embodiments of the first aspect.

Compared with the prior art, a shuttle-shaped guiding device and indoor set, air conditioner have following beneficial effect:

1) The shuttle-shaped flow guide device can replace and cancel a conventional air guide plate structure, so that the wall-pasting flow of air flowing through the air outlet and blowing to the indoor can realize the effect of prolonging the air outlet by the wall-pasting flow of 'pressing down hot air and blowing up cold air', particularly the air outlet of the air flow can not be stopped basically, and the air quantity loss is further reduced greatly;

2) Under the switching of the refrigeration and heating modes, the shuttle-type diversion device can realize the wall-pasting flow prolonging air outlet effect of 'pressing down hot air and blowing up cold air' only by arranging one diversion shuttle without any disassembly and assembly.

Drawings

Some of the figures that make up the present invention are intended to provide a further understanding of the invention, and the illustrative embodiments and descriptions thereof are intended to explain the present invention and not to constitute an undue limitation on the invention. In the drawings:

fig. 1 is a schematic cross-sectional view of a shuttle-shaped deflector according to embodiments 1-2 of the present invention in its pre-assembled configuration;

fig. 2 is a schematic view illustrating an operation structure of one of the shuttle-type air guide devices (only one air guide shuttle is provided) in fig. 1 in a heating and air-conditioning mode;

FIG. 3 is a schematic view of the shuttle-type diversion device shown in FIG. 2 operating in an air conditioning cooling mode;

fig. 4 is a schematic view of an operation structure of another shuttle-type air guide device (provided with two air guide shuttles) in the heating mode of the air conditioner, which is illustrated in fig. 1;

FIG. 5 is a schematic view of the shuttle-type deflector shown in FIG. 4 operating in an air conditioning cooling mode;

FIG. 6 is a simplified block diagram of FIG. 2;

fig. 7 is a first simplified view of the shuttle-type deflector device (only one deflector shuttle is provided) of fig. 2-3 during the start of the cooling mode;

fig. 8 is a second simplified view of the shuttle-type deflector device (only one deflector shuttle is provided) illustrated in fig. 2-3, during the opening of the cooling mode;

fig. 9 is a third simplified view of the shuttle-type deflector device (only one deflector shuttle is provided) illustrated in fig. 2-3, during start-up of the cooling mode;

fig. 10 is a simplified structural schematic diagram of fig. 3.

Description of reference numerals:

1-an air outlet duct, 101-an upper air outlet wall, 102-a lower air outlet wall, 2-a wall sticking surface, 3-an air guide surface, 231-a first presetting structural surface, 232-a second presetting structural surface, 4-a diversion shuttle, 41-a first diversion shuttle, 42-a second diversion shuttle, 5-a transmission component, 51-a first transmission component, 52-a second transmission component, 501-a fixed gear, 502-a moving gear, 503-a driving connecting rod, 504-a driven connecting rod, 6-an air outlet, 7-a guide rail, 8-a guide rod and 9-a stop sealing ring.

Detailed Description

In order to make the above objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail with reference to the accompanying drawings and embodiments. It is to be understood that the specific embodiments of the present invention described herein are only some of the embodiments that constitute the present invention, and are only used for explaining the present invention, and do not constitute limitations to the present invention, and features in embodiments and examples of the present invention may be combined with each other without conflict.

Example 1

Referring to fig. 1-10, the utility model provides a shuttle-shaped guiding device, movable mounting is in the air-out wind channel 1 of machine in the air conditioning, shuttle-shaped guiding device encloses adherence face 2 and wind-guiding face 3 as an organic whole from top to bottom, paste wall 2 edge the last air-out wall 101 and/or the laminating of air-out wall 102 down of air-out wind channel 1 tail end remove, and go up air-out wall 101 with one of them department of air-out wall 102 stretches out outward air-out wind channel 1 down to make its half lateral position of air outlet 6 that forms directly extend into the indoor space.

Specifically, the shuttle-shaped flow guiding device comprises an adherence surface 2 and an air guiding surface 3 which are integrated by enclosing from top to bottom, the space enclosed by the interior of the device can be a hollow structure or a solid structure, and the structure forms a flow guiding shuttle 4 as shown in fig. 1. In the refrigeration mode, the wall-attached surface 2 of the flow guide shuttle 4 can move along the lower air outlet wall 102 in an attaching manner, and the air outlet duct 1 extends outwards from the lower air outlet wall 102, so that the wall-attached flow design for prolonging the air outlet of the lower air outlet wall 102 is realized. At this time, when the air flow is blown to the indoor through the air outlet 6, the wall-facing flow of the upward blowing of the cold air is realized to prolong the air outlet effect, and the air volume loss is reduced.

In the heating mode, the wall-attached surface 2 of the flow guide shuttle 4 can move along the upper air outlet wall 101 in a fitting manner, and the air outlet duct 1 extends outwards from the upper air outlet wall 101, so that the wall-attached flow design for prolonging the air outlet of the upper air outlet wall 101 is realized. At this time, when the air current blows to the indoor through the air outlet 6, the wall-pasting flow of the hot air downward blowing can be realized to prolong the air outlet effect, and the air volume loss is reduced.

From this, through shuttle type guiding device, can replace and cancel conventional air guide plate structure, and then make the air current blow through air outlet 6 and can realize "hot-blast pushing down to indoor initial flow path, the wainscot flow extension air-out effect that blows on the cold wind", especially still can not form the backstop to the air current air-out basically, and then still reduce the amount of wind loss by a wide margin. Since the wall-attached surface 2 extends outward from the outlet duct 1 only at one of the upper outlet wall 101 and the lower outlet wall 102, even if the shuttle-shaped guiding device includes two guiding shuttles 4, the wall-attached design of extending only the half-side outlet wall can be ensured.

Of course, it can be understood by those skilled in the art that the shuttle-type guiding device of the present invention only needs to be provided with one guiding shuttle 4 for the single-cold machine, and only extends the outlet air along the lower outlet air wall 102; for the single heater, only one diversion shuttle 4 is needed to be arranged, and the air outlet is only prolonged along the upper air outlet wall 101; for the air conditioner for both cooling and heating purposes, the shuttle-type guiding device comprises one or two guiding shuttles 4, wherein the guiding shuttles 4 can be detachably mounted on the upper air outlet wall 101 or the lower air outlet wall 102.

Preferably, the shuttle-type guiding device includes one or two guiding shuttles 4, wherein the first guiding shuttle 41 of the two guiding shuttles 4 only moves along the upper air outlet wall 101 in a fitting manner, and the second guiding shuttle 42 only moves along the lower air outlet wall 102 in a fitting manner.

Specifically, the shuttle-type guiding device may be provided with only one guiding shuttle 4 to move along the upper air outlet wall 101 and/or the lower air outlet wall 102 in a fitting manner, and the air outlet is extended at one of the upper air outlet wall 101 and the lower air outlet wall 102 according to the selection of the air conditioner operation mode. Certainly, the shuttle-shaped diversion device can also be provided with two diversion shuttles 4 at the same time, so that the first diversion shuttle 41 only moves along the upper air outlet wall 101 in a fitting manner, and the air outlet is only prolonged in the heating mode; the second guiding shuttle 42 only moves along the lower air outlet wall 102 and extends the air outlet only in the cooling mode.

Preferably, the wall attaching surface 2 and the air guiding surface 3 are both convex arc surfaces, and the upper air outlet wall 101 and the lower air outlet wall 102 are both concave arc surfaces adapted to the wall attaching surface 2.

Specifically, when the guiding shuttle 4 extends to discharge air at one of the upper air-discharge wall 101 and the lower air-discharge wall 102, no matter the shuttle-shaped guiding device includes one or two guiding shuttles 4, the above arrangement will facilitate the air outlet 6 to be matched with the height of the air flow in the predetermined guiding direction during the dynamic forming, so as to enhance the wall flow extending air-discharge effect under the condition of "hot air pressing down and cold air blowing up".

Preferably, a transmission assembly 5 for driving the diversion shuttle 4 to move is arranged at the left end and/or the right end of the diversion shuttle 4, which is away from the air outlet 6.

Specifically, the transmission assembly 5 may be, for example, a crank rocker mechanism or a double-rocker mechanism, so that the rocker is fixedly connected to the air guide surface 3, and then under the driving action of the motor and the gear, the transmission assembly 5 may drive the wall-adhering surface 2 of the flow guide shuttle 4 to move along the upper air outlet wall 101 in a fitting manner and extend the air outlet, or move along the lower air outlet wall 102 in a fitting manner and extend the air outlet.

Certainly, the transmission component 5 may also be, for example, an arc-shaped rack fixedly connected to the wall-adhering surface 2 through a connecting rod and disposed on the opposite side of the guiding shuttle 4, and in the case of the air-out wall 101, the connecting rod of the arc-shaped rack slides in a gap formed in the upper air-out wall 101 under the driving action of the motor and the gear, so as to drive the wall-adhering surface 2 of the guiding shuttle 4 to move along the upper air-out wall 101 in an adhering manner and prolong the air-out.

Of course, when the shuttle-type deflector comprises two deflectors 4, the first transmission element 51 can be disposed on the first deflector 41, and the second transmission element 52 can be disposed on the second deflector 42, so that: in the refrigeration mode, only the second diversion shuttle 42 extends out of the air outlet duct 1 to support the wall flow of the cold air blown upwards to prolong the air outlet; in the heating mode, only the first diversion shuttle 41 extends out of the air outlet duct 1 to support the wall flow of the hot air blowing downwards to prolong the air outlet.

Wherein, drive assembly 5 deviates from the left end and/or the right-hand member setting in air outlet 6, can be convenient for carry out the physics overall arrangement to drive assembly 5 to form dodging to air outlet 6.

Example 2

Preferably, as shown in fig. 6 to 10, only one of the flow guide shuttles 4 is provided, and the flow guide shuttle selectively moves along the upper air outlet wall 101 or the lower air outlet wall 102 in a fitting manner, so as to extend the air outlet at any position of the upper air outlet wall 101 and the lower air outlet wall 102.

Specifically, when only one guiding shuttle 4 is provided, the whole set of shuttle-type guiding device will also only include one wall-attached surface 2 and one air guiding surface 3, and the corresponding transmission component 5 will also only have one set, at this time, the wall-attached surface 2 can move along the similar elliptical space enclosed by the upper air-out wall 101 and the lower air-out wall 102 in a fitting manner, wherein at the transition position of the upper air-out wall 101 and the lower air-out wall 102 inside the air-out duct 1, the transmission component 5 needs to ensure the smooth transition of the guiding shuttle 4 at the position, so that the number and the cost of the arrangement of the guiding shuttle 4 can be reduced, and the half-side extended air-out arrangement of the air outlet 6 can be directly formed between the air-out wall 3 and the air-out wall (other than the other air-out wall 3) at the opposite side of the guiding surface 3, and further the set guiding direction of the air flow is more matched, so as to enhance the wall-attached air-out effect of the "hot air pressing down and cold air blowing up" can be extended.

Preferably, at the left end and/or the right end of the air guide surface 3 facing away from the air outlet 6, the transmission assembly 5 includes: the air guide device comprises a driving connecting rod 503, a moving gear 502, a fixed gear 501 and a driven connecting rod 504, wherein the driven connecting rod 504 is used for driving the air guide shuttle 4 to rotate along the upper air outlet wall 101 and the lower air outlet wall 102 in a diameter-variable attaching mode and prolong air outlet.

Specifically, when the guiding shuttle 4 rotates along the upper air outlet wall 101 and the lower air outlet wall 102 in a fitting manner and extends the air outlet, the fitting rotation is necessarily variable-diameter rotation. When one end of the driven connecting rod 504 is connected with the air guide surface 3 and the other end is connected with the moving gear 502 in the transmission assembly 5, the rotation center of the driven connecting rod 504 is changed, so that the guiding shuttle 4 can be driven to perform reducing joint rotation and prolong air outlet along the upper air outlet wall 101 and the lower air outlet wall 102.

Preferably, at the left end of the moving gear 502, the driving link 503 carries the moving gear 502 to perform inner meshing rotation in the fixed gear 501 in a first direction, and at the right end of the moving gear 502, the driven link 504 carries the air guiding shuttle 4 to perform variable diameter rotation in a second direction, wherein two ends of the driven link 504 are respectively used for connecting the moving gear 502 and the air guiding surface 3, and the second direction and the first direction are opposite to each other.

Specifically, when the transmission assembly 5 is disposed along the left end away from the air outlet 6, at the left end of the moving gear 502, the driving link 503 (corresponding to a two-point connecting line AB in the drawing) carries the moving gear 502 to perform inner meshing rotation in the fixed gear 501 in a first direction, at the right end of the moving gear 502, the driven link 504 (corresponding to a two-point connecting line CD in the drawing) carries the diversion shuttle 4 to perform variable diameter rotation in a second direction, wherein the point B and the point C can be concentrically disposed in the projection plane. Thereby:

if the first direction is counterclockwise, the second direction is clockwise, and after the first direction is rotated to the right position, the heating mode shown in fig. 6 can be opened to blow the hot air downwards; on the contrary, if the first direction is clockwise, the second direction is counterclockwise, and the cooling mode shown in fig. 10 is turned on after the first direction is rotated to the right position, so as to blow up the cool wind.

Of course, the transmission assembly 5 may also be disposed along the right end away from the air outlet 6, or disposed at both the left and right ends, but all of the transmission assemblies 5 may be regarded as only one set, and will not be described herein.

Preferably, the wall-facing surface 2 is a deformable first pre-shaped structure surface 231.

Specifically, when the wall-adhering surface 2 is the deformable first pre-shaping structural surface 231, the guiding shuttle 4 is favorably configured to perform smooth diameter changing and fitting rotation at the transition position between the upper air outlet wall 101 and the lower air outlet wall 102. Taking the counterclockwise diameter changing and the attaching rotation of the guiding shuttle 4 as an example, that is, when the front end of the wall attaching surface 2 is about to be separated from the upper air outlet wall 101, due to the deformation of the first presetting structural surface 231, the rear end of the wall attaching surface 2 can drop onto the lower air outlet wall 102, thereby ensuring the smooth transition to the lower air outlet wall 102, and continuing to perform the counterclockwise diameter changing rotation along the lower air outlet wall 102. The wind guide surface 3 may be the first pre-shaping structure surface 231 or the rigid second pre-shaping structure surface 232.

Preferably, guide rails 7 are respectively arranged on the upper air outlet wall 101 and the lower air outlet wall 102, and a guide rod 8 adapted to the guide rails 7 is arranged on the wall attaching surface 2.

Specifically, when the wall-adhering surface 2 is the deformable first pre-shaping structural surface 231, the arrangement of the guide rail 7 and the guide rod 8 can greatly reduce the abrasion of the wall-adhering surface 2 while ensuring that the wall-adhering surface 2 is tightly attached and rotated along the upper air outlet wall 101 and the lower air outlet wall 102.

Preferably, the tail ends of the upper air outlet wall 101 and the lower air outlet wall 102 are both provided with a stop seal ring 9 for preventing the guide rod 8 from falling off.

Specifically, when the guiding shuttle 4 rotates along the upper air outlet wall 101 and the lower air outlet wall 102 in a diameter-variable manner and extends the air outlet, the requirement on the precision of the transmission assembly 5 is high, and the guiding shuttle 4 has a risk of falling off under the action of the gravity of the guiding shuttle 4. And the setting of backstop seal ring 9, even its precision of drive assembly 5 after repetitious usage descends in the later stage, also can effectively avoid the risk that drops of water conservancy diversion shuttle 4.

Example 3

Referring to fig. 1-10, the present invention further provides an indoor unit having the shuttle-type deflector of any one of embodiments 1-2.

The utility model also provides an air conditioner, have embodiment 1-2 any embodiment the shuttle guiding device.

Specifically, it can be understood by those skilled in the art that, when the indoor unit and/or the air conditioner provided in embodiment 3 has the shuttle-type airflow guiding device described in any one of embodiments 1 to 2, the solution of the corresponding technical problem and the achievement of the technical effect thereof can be found in the description of the shuttle-type airflow guiding device in embodiments 1 to 2, and are not described in detail herein.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one of ordinary skill in the pertinent art without departing from the scope or spirit of the present invention, and the scope of the present invention is defined by the appended claims.

Claims (10)

1. The shuttle-shaped flow guide device is characterized by being movably installed in an air outlet duct (1) of an indoor unit of an air conditioner, the shuttle-shaped flow guide device comprises an attachment surface (2) and an air guide surface (3) which are integrated by enclosing from top to bottom, the attachment surface (2) moves along an upper air outlet wall (101) and/or a lower air outlet wall (102) at the tail end of the air outlet duct (1) in an attachment mode, and the air outlet duct (1) extends outwards from one of the upper air outlet wall (101) and the lower air outlet wall (102) so that a half lateral position of a formed air outlet (6) directly extends into an indoor space.

2. The shuttle-type deflector device according to claim 1, characterized in that the shuttle-type deflector device comprises one or two deflectors (4), wherein the first deflector (41) of the two deflectors (4) moves snugly only along the upper outlet wall (101) and the second deflector (42) moves snugly only along the lower outlet wall (102).

3. The shuttle-type flow guiding device as claimed in claim 2, wherein the wall-attaching surface (2) and the air guiding surface (3) are both convex cambered surfaces, and the upper air outlet wall (101) and the lower air outlet wall (102) are both concave cambered surfaces adapted to the wall-attaching surface (2).

4. Shuttle shaped air guiding device according to claim 2 or 3, characterized in that a transmission assembly (5) is arranged at the left and/or right end of the air guiding shuttle (4) facing away from the air outlet (6) for driving the air guiding shuttle (4) to move.

5. The shuttle-type guiding device as claimed in claim 4, wherein the guiding shuttle (4) is provided with only one and performs an alternative engaging movement along the upper outlet wall (101) or the lower outlet wall (102) to extend the outlet air at any position of the upper outlet wall (101) and the lower outlet wall (102).

6. Shuttle-shaped air guiding device according to claim 5, characterized in that the transmission assembly (5) comprises, at the left and/or right end of the air guiding surface (3) facing away from the air outlet opening (6): the air guide device comprises a driving connecting rod (503), a moving gear (502), a fixed gear (501) and a driven connecting rod (504), wherein the driven connecting rod (504) is used for driving the air guide shuttle (4) to rotate along the upper air outlet wall (101) and the lower air outlet wall (102) in a diameter-variable fit mode and prolong air outlet.

7. The shuttle-type diversion device as claimed in claim 6, wherein at the left end of said moving gear (502), said driving link (503) carries said moving gear (502) to make inner gearing rotation in said fixed gear (501) in a first direction, and at the right end of said moving gear (502), said driven link (504) carries said diversion shuttle (4) to make variable diameter rotation in a second direction, wherein both ends of said driven link (504) are respectively used for connecting said moving gear (502) and said air guiding surface (3), and said second direction and said first direction are opposite to each other.

8. The shuttle-type guiding device as claimed in any one of claims 5 to 7, wherein the upper outlet wall (101) and the lower outlet wall (102) are both provided with guide rails (7), and the close wall surface (2) is provided with guide rods (8) adapted to the guide rails (7).

9. An indoor unit, characterized in that the indoor unit has a shuttle guide device according to any one of claims 1 to 8.

10. An air conditioner characterized in that the air conditioner has a shuttle type deflector of any one of claims 1 to 8.

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