CN216231595U - Air conditioner air outlet assembly and air deflector synchronous rotation control mechanism - Google Patents

Abstract

The utility model relates to an air outlet assembly of an air conditioner and a synchronous rotation control mechanism of an air deflector, which comprises an outer shell, a functional component, an air direction regulating piece and a synchronous mechanism, wherein the functional component is arranged in the outer shell and distinguishes an air channel space inside the outer shell, and the air channel space comprises a first air outlet channel, a second air outlet channel and an air inlet channel; the air inlet channel can be communicated with at least one air outlet channel of the first air outlet channel and the second air outlet channel through the air direction adjusting piece; the wind direction adjusting piece comprises a plurality of wind deflectors which are arranged in the wind inlet channel and can synchronously rotate; the synchronous mechanism is arranged on the outer side wall of the outer shell and comprises a plurality of crank pieces and a linkage piece; each crank piece penetrates through the outer side wall of the outer shell and is fixedly connected with one air deflector; the linkage piece is simultaneously connected with each crank piece, and when the linkage piece moves, each crank piece is driven to synchronously rotate. The synchronous mechanism is arranged on the outer side wall of the outer shell, so that the defects that parts with functions similar to those of the synchronous mechanism are arranged in the outer shell to block the wind direction and the wind quantity in the air outlet and the like can be avoided.

Description

Air conditioner air outlet assembly and air deflector synchronous rotation control mechanism

Technical Field

The utility model relates to the field of air conditioner air outlets, in particular to an air conditioner air outlet assembly and an air deflector synchronous rotation control mechanism.

Background

The automobile air conditioner air outlet refers to an air conditioning device arranged on an automobile, and can refrigerate, heat, ventilate and purify air in the automobile, so as to provide a comfortable riding environment for passengers. With the development of the automobile industry and the improvement of the living standard of people, the requirement of people on the aesthetic property is higher and higher under the condition that the parts in the automobile meet the functionality. The traditional air port is large in opening area, multiple in blades and large in influence on the overall shape of an instrument board, and the hidden air outlet becomes a new trend from the development trend of automotive interior.

The upper and lower air-out of traditional air outlet is adjusted through the adjustment of the visible outer blade direction, but the hidden air outlet does not have outer blades, so need new structure to reach the upper and lower air-out regulatory function.

Disclosure of Invention

In order to avoid the defects of the background art, the utility model provides an air outlet assembly of an air conditioner and a synchronous rotation control mechanism of an air deflector, which can realize the control and adjustment of air outlet up and down.

The utility model provides an air outlet assembly of an air conditioner, which comprises an outer shell, a functional component, an air direction adjusting piece and a synchronizing mechanism, wherein the functional component is arranged in the outer shell and distinguishes an air channel space inside the outer shell, and the air channel space comprises a first air outlet channel, a second air outlet channel and an air inlet channel; the air inlet channel can be communicated with at least one air outlet channel of the first air outlet channel and the second air outlet channel through the air direction adjusting piece; the wind direction adjusting piece comprises a plurality of wind deflectors which are arranged in the wind inlet channel and can synchronously rotate; the synchronous mechanism is arranged on the outer side wall of the outer shell and comprises a plurality of crank pieces and linkage pieces, the number of the crank pieces corresponds to that of the air deflectors; each crank piece penetrates through the outer side wall of the outer shell and is fixedly connected with one air deflector; the linkage piece is simultaneously connected with each crank piece, and when the linkage piece moves or rotates, each crank piece is driven to synchronously rotate.

Furthermore, the linkage piece comprises a sliding groove part and a connecting part, and the linkage piece is movably arranged on the outer side wall of the outer shell through the connecting part; the crank member includes a slide shaft slidable in the slide groove portion; when the linkage piece moves or rotates, the crank piece is driven to rotate through the matching of the sliding groove part and the groove shaft between the sliding shafts.

Preferably, the number of the air deflector and the crank piece is two; the connecting part is a connecting column, and the linkage piece is rotatably arranged on the outer side wall of the outer shell through the connecting column; the connecting post is located intermediate the two crank members.

Preferably, the connecting part is a rectangular through groove, and the outer side wall of the outer shell is provided with a rectangular lug matched with the rectangular through groove; the linkage piece moves along the length direction of the rectangular through groove.

Furthermore, the number of the rectangular through grooves is at least two, and the rectangular through grooves are distributed on the left side and the right side of a straight line formed by the crank pieces.

Furthermore, the top end of the rectangular bump is also provided with a buckling part, and the buckling part passes through the rectangular through groove and buckles the linkage part to prevent the linkage part from being separated.

Further, the device also comprises a toggle component, a rotating shaft component and a connecting rod component which are connected in sequence; one end of the connecting rod piece is connected with the linkage piece; the toggle component can drive the rotating shaft component to synchronously rotate when being toggled by external force, the rotating shaft component drives the connecting rod component to move while rotating, and the connecting rod component drives the linkage component to move or rotate while moving.

The utility model also provides a synchronous rotation control mechanism of the air deflector, which is arranged on the outer side wall of the air outlet outer shell and comprises a plurality of crank pieces and linkage pieces, wherein the number of the crank pieces corresponds to that of the air deflectors in the air outlet outer shell; each crank piece penetrates through the outer side wall of the outer shell and is fixedly connected with one air deflector; the linkage piece is simultaneously connected with each crank piece, and when the linkage piece moves, each crank piece is driven to synchronously rotate.

Furthermore, the linkage piece comprises a sliding groove part and a connecting part, and the linkage piece is movably arranged on the outer side wall of the outer shell through the connecting part; the crank member includes a slide shaft slidable in the slide groove portion; when the linkage piece moves, the crank piece is driven to rotate through the matching of the sliding groove part and the groove shaft between the sliding shafts.

The synchronous mechanism can control all the air deflectors in the air direction adjusting piece to synchronously rotate, and the air flow ratio between the first air outlet channel and the second air outlet channel is changed, so that the upper and lower air outlet directions of the air outlet of the air conditioner are changed; meanwhile, the synchronous mechanism is arranged on the outer side wall of the outer shell, so that the defects that parts with functions similar to those of the synchronous mechanism are arranged inside the outer shell to block the wind direction and the wind quantity inside the air outlet and the like can be avoided.

Drawings

Fig. 1 is a schematic perspective view of an air outlet assembly of an embodiment of the present disclosure.

Fig. 2 is a schematic perspective sectional view of an air outlet assembly of an embodiment.

Fig. 3 is a schematic view illustrating a flow direction of air discharged horizontally from the air outlet assembly of the embodiment.

Fig. 4 is a schematic view illustrating a flow direction of air flowing out upward from the air outlet assembly of the embodiment.

Fig. 5 is a schematic view illustrating a flow direction of air discharged downward from the air outlet assembly of the embodiment.

Fig. 6 is a schematic structural diagram of an air outlet assembly control mechanism in an embodiment.

FIG. 7 is an exploded schematic view of one embodiment of a linkage in the examples.

Fig. 8 is a schematic perspective view of a linkage member of another embodiment of an air outlet assembly of an air conditioner according to an embodiment of the present invention.

Fig. 9 is an exploded view of the linkage of fig. 8.

The reference numbers are as follows: 10-an outer shell; 11-a first air outlet channel; 12-a second air outlet channel; 13-air inlet channel; 14-rectangular bumps; 141-a latch portion; 20-a functional component; 30-a wind direction adjustment member; 31-a first air deflector; 32-a second air deflector; 33-a sealing strip; 40-a synchronization mechanism; 41-a first crank; 411-a first sliding shaft; 42-a second crank; 421-a second sliding shaft; 43-a linkage; 431-sliding groove; 432-connecting column; 433-a rectangular through groove; 50-a toggle assembly; 60-a spindle assembly; 70-connecting rod.

Detailed Description

The utility model is further described below with reference to the accompanying drawings and specific examples.

In the embodiment, referring to fig. 1 to 9, an air outlet assembly of an air conditioner includes an outer shell 10, a functional component 20, and a wind direction adjusting member 30, where the functional component 20 is disposed in the outer shell 10 and distinguishes a wind channel space inside the outer shell 10, and the wind channel space includes a first wind outlet channel 11, a second wind outlet channel 12, and a wind inlet channel 13; the air inlet channel 13 can be communicated with at least one air outlet channel of the first air outlet channel 11 and the second air outlet channel 12 through the wind direction adjusting piece 30; the wind direction adjusting piece 30 is rotatably arranged in the air inlet channel 13 and comprises a first air deflector 31 and a second air deflector 32 which rotate synchronously and are arranged in parallel, sealing strips 33 are fixed at two end parts of the first air deflector 31 and the second air deflector 32, each sealing strip 33 comprises a contact part which is used for contacting with the inner wall of the outer shell 10 or the outer wall of the functional component 20, and the outer contour of the contact part is arc-shaped; the sealing strip 33 is preferably made of soft rubber; the first air deflector 31 can isolate the air inlet channel 13 from the first air outlet channel 11 when rotating to a first angle, the second air deflector 32 can isolate the air inlet channel 13 from the second air outlet channel 12 when rotating to a second angle, and the existence of the sealing strip 33 effectively improves the isolation and sealing effect; the air flow ratio between the first air outlet channel 11 and the second air outlet channel 12 is adjusted according to the rotation angles of the first air deflector 31 and the second air deflector 32.

The upper and lower air-out control principle of this embodiment air-conditioning outlet assembly:

when the wind direction adjusting member 30 is located at the position shown in fig. 3, the air enters the air inlet channel 13 from the air inlet of the air outlet assembly of the air conditioner, and the first air guiding plate 31 and the second air guiding plate 32 are located in the horizontal direction, so that the first air outlet channel 11, the second air outlet channel 12 and the air inlet channel 13 are communicated; the air is shunted, half of the air enters the first air outlet channel 11, the other half of the air enters the second air outlet channel 12, the air direction of the outlet of the first air outlet channel 11 faces downwards, the air direction of the outlet of the second air outlet channel 12 faces upwards, and the air outlet direction of the air-conditioning air outlet assembly after two equivalent air are integrated is horizontal air outlet.

When the wind direction adjusting member 30 is located at the position shown in fig. 4, the air enters the air inlet channel 13 from the air inlet of the air outlet assembly of the air conditioner, and at this time, the first air deflector 31 rotates to the first angle to just seal the air vent between the air inlet channel 13 and the first air outlet channel 11, and only the second air outlet channel 12 is communicated with the air inlet channel 13; the air is divided, a small amount of air or no air enters the first air outlet channel 11, most of air or all of air enters the second air outlet channel 12, the air direction of the outlet of the first air outlet channel 11 faces downwards, the air direction of the outlet of the second air outlet channel 12 faces upwards, the air outlet direction of the air outlet assembly of the air conditioner after integration is upward air outlet, and the air outlet direction is more inclined to horizontal air outlet along with the increase of the proportion of air flowing into the first air outlet channel 11.

When the wind direction adjusting member 30 is located at the position shown in fig. 5, the air enters the air inlet channel 13 from the air inlet of the air outlet assembly of the air conditioner, and at this time, the second air deflector 32 rotates to the second angle to just seal the vent between the air inlet channel 13 and the second air outlet channel 12, and only the first air outlet channel 11 is communicated with the air inlet channel 13; the air is divided, a small amount of air or no air enters the second air outlet channel 12, most of air or all of air enters the first air outlet channel 11, the air direction of the outlet of the first air outlet channel 11 faces downwards, the air direction of the outlet of the second air outlet channel 12 faces upwards, the air outlet direction of the air outlet assembly of the air conditioner after integration is downward air outlet, and the air outlet direction is more inclined to horizontal air outlet along with the increase of the proportion of air flowing into the second air outlet channel 12.

The wind direction adjusting member 30 in the air outlet assembly of this embodiment can be controlled by the rotation angle, the angle changes of the first wind deflector 31 and the second wind deflector 32 in the wind direction adjusting member 30 can respectively cause the communication areas of the first wind outlet channel 11 and the wind inlet channel 13, and the second wind outlet channel 12 and the wind inlet channel 13 to simultaneously change, thereby causing the wind flow rate of the wind outlet channel and the wind inlet channel 13 to change, further causing the wind flow rate ratio between the first wind outlet channel 11 and the second wind outlet channel 12 to change, and finally causing the up-down wind outlet direction of the air outlet to change.

The air-conditioning air outlet assembly of the embodiment further comprises a toggle component 50, a rotating shaft component 60, a connecting rod 70 and a synchronizing mechanism 40 which are sequentially connected, wherein the toggle component 50 can drive the rotating shaft component 60 to synchronously rotate when being toggled by an external force, the rotating shaft component 60 drives the connecting rod 70 to move when rotating, and the connecting rod 70 drives the synchronizing mechanism 40 to move when moving; the synchronous mechanism 40 is arranged on the outer side wall of the outer shell 10 and used for controlling the wind direction adjusting piece 30 to rotate; the synchronization mechanism 40 includes a first crank 41, a second crank 42, and a link 43; the first crank 41 and the second crank 42 respectively penetrate through the outer side wall of the outer shell 10 and are fixedly connected with the first air deflector 31 and the second air deflector 32, and the first crank 41 and the second crank 42 can respectively drive the first air deflector 31 and the second air deflector 32 to rotate while rotating; the link 43 includes a sliding groove 431, the first crank 41 includes a first sliding shaft 411 slidable in the sliding groove 431, and the second crank 42 includes a second sliding shaft 421 slidable in the sliding groove 431; the synchronous mechanism 40 is arranged on the outer side wall of the outer shell, so that the defects that parts with functions similar to those of the synchronous mechanism are arranged in the outer shell to block the wind direction and the wind quantity in the air outlet and the like can be avoided;

in a specific embodiment of this embodiment, the linkage 43 includes a connection post 432, and the linkage 43 is rotatably disposed on the outer sidewall of the outer casing 10 through the connection post 432; when the link 43 rotates, the first crank 41 is driven to rotate by the shaft-slot fit between the sliding slot 431 and the first sliding shaft 411, and the second crank 42 is driven to rotate by the shaft-slot fit between the sliding slot 431 and the second sliding shaft 421.

In another specific embodiment of this embodiment, the linkage 43 includes three rectangular through slots 433 distributed on the left and right sides of the straight line formed by the first crank 41 and the second crank 42; the outer side wall of the outer shell 10 is provided with rectangular projections 14 which are matched with the rectangular through grooves 433 and are in the same number, wherein the top ends of the two rectangular projections 14 are also provided with buckling parts 141, and the buckling parts 141 buckle the linkage 43 after passing through the rectangular through grooves 433 to prevent the linkage 43 from being separated; the link 43 moves along the length direction of the rectangular through groove 433, and when the link 43 moves, the first crank 41 is driven to rotate by the matching of the sliding groove 431 and the groove shaft between the first sliding shafts 411, and the second crank 42 is driven to rotate by the matching of the sliding groove 431 and the groove shaft between the second sliding shafts 421.

Although the present invention has been described with reference to preferred embodiments, it will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and various changes in form and details may be made within the scope of the appended claims.

Claims (9)

1. An air-conditioning outlet assembly, its characterized in that: the wind power generation device comprises an outer shell, a functional component, a wind direction adjusting piece and a synchronizing mechanism, wherein the functional component is arranged in the outer shell and distinguishes a wind channel space inside the outer shell, and the wind channel space comprises a first wind outlet channel, a second wind outlet channel and a wind inlet channel;

the air inlet channel can be communicated with at least one air outlet channel of the first air outlet channel and the second air outlet channel through the wind direction adjusting piece; the wind direction adjusting piece comprises a plurality of wind deflectors which are arranged in the wind inlet channel and can synchronously rotate;

the synchronous mechanism is arranged on the outer side wall of the outer shell and comprises a plurality of crank pieces and linkage pieces, the number of the crank pieces corresponds to that of the air deflectors; each crank piece penetrates through the outer side wall of the outer shell body and is fixedly connected with one air deflector; the linkage piece is simultaneously connected with the crank pieces, and when the linkage piece moves or rotates, the linkage piece drives the crank pieces to synchronously rotate.

2. The air outlet assembly of claim 1, wherein: the linkage piece comprises a sliding groove part and a connecting part, and is movably arranged on the outer side wall of the outer shell through the connecting part; the crank member includes a slide shaft slidable in a slide groove portion; when the linkage piece moves or rotates, the crank piece is driven to rotate through the matching of the sliding groove part and the groove shaft between the sliding shafts.

3. An air outlet assembly according to claim 2, wherein: the number of the air deflectors and the number of the crank pieces are two; the connecting part is a connecting column, and the linkage piece is rotatably arranged on the outer side wall of the outer shell through the connecting column; the connecting column is located intermediate the two crank members.

4. An air outlet assembly according to claim 2, wherein: the connecting part is a rectangular through groove, and a rectangular lug matched with the rectangular through groove is arranged on the outer side wall of the outer shell; the linkage piece moves along the length direction of the rectangular through groove.

5. The air outlet assembly of claim 4, wherein: the number of the rectangular through grooves is at least two, and the rectangular through grooves are distributed on the left side and the right side of a straight line formed by the crank pieces.

6. The air outlet assembly of claim 4, wherein: the top end of the rectangular bump is also provided with a buckling part which passes through the rectangular through groove and buckles the linkage part to prevent the linkage part from being separated.

7. The air outlet assembly of claim 1, wherein: the device also comprises a toggle component, a rotating shaft component and a connecting rod component which are connected in sequence; one end of the connecting rod piece is connected with the linkage piece; the toggle component can drive the rotating shaft component to synchronously rotate when being toggled by external force, the rotating shaft component drives the connecting rod component to move while rotating, and the connecting rod component drives the linkage component to move or rotate while moving.

8. The utility model provides an aviation baffle synchro rotation control mechanism which characterized in that: the crank pieces and the linkage pieces are arranged on the outer side wall of the air outlet outer shell and correspond to the air deflectors in the air outlet outer shell in number; each crank piece penetrates through the outer side wall of the outer shell body and is fixedly connected with one air deflector; the linkage piece is simultaneously connected with the crank pieces, and when the linkage piece moves, the linkage piece drives the crank pieces to synchronously rotate.

9. The synchronous rotation control mechanism of claim 8, wherein: the linkage piece comprises a sliding groove part and a connecting part, and is movably arranged on the outer side wall of the outer shell through the connecting part; the crank member includes a slide shaft slidable in a slide groove portion; when the linkage piece moves, the crank piece is driven to rotate through the matching of the sliding groove part and the groove shaft between the sliding shafts.

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