CN114074529B - Air port structure, air conditioning assembly and vehicle - Google Patents

Abstract

The embodiment of the application provides an air port structure, an air conditioner assembly and a vehicle, and relates to the technical field of vehicles. The tuyere structure includes: the shell is provided with an air duct which is communicated with the air inlet and the air outlet; the wind guide assembly is detachably arranged in the air duct and comprises a guide rod and a plurality of wind guide blades, the first ends of the wind guide blades are detachably connected to the shell, the second ends of the wind guide blades are detachably connected to the guide rod, the wind guide blades are arranged at intervals parallel to each other along the length direction of the guide rod, the guide rod is slidably connected to the shell, and the guide rod slidably drives the wind guide blades to rotate by taking the first ends of the wind guide blades as shafts so as to adjust the ventilation quantity and the ventilation direction of the air duct. According to the embodiment of the application, the ventilation quantity of the air port structure can be adjusted by increasing or decreasing the number of the air guide blades, the air port structure is simple and convenient, the operability is high, and in addition, the manual operation capability can be improved in the process of disassembling and installing the air guide blades by a user.

Description

Air port structure, air conditioning assembly and vehicle

Technical Field

The application relates to the technical field of vehicles, in particular to an air port structure, an air conditioner assembly and a vehicle.

Background

With the development of vehicle technology, users have increasingly demanded more comfort from the vehicle. Currently, an air outlet of an air conditioner on a vehicle is generally fixedly arranged on an instrument desk. In order to improve the comfort of the user, the air outlet blades in the air outlet can be regulated, so that the air outlet has the function of regulating the air outlet direction.

However, in the prior art, the air outlet is usually formed by an injection molding process, so that the air outlet blade in the air outlet is difficult to disassemble, and the air outlet volume of the air outlet cannot be adjusted according to the requirement of a user. Once the user needs to adjust the air outlet quantity of the air outlet, the air outlet needs to be replaced by a professional, so that the user experience is poor.

Disclosure of Invention

In view of the foregoing, embodiments of the present invention have been made in order to provide a tuyere structure, an air conditioning assembly and a vehicle that overcome or at least partially solve the foregoing problems.

In a first aspect, the present invention discloses a tuyere structure comprising:

the shell is provided with an air duct which is communicated with the air inlet and the air outlet;

the air guide assembly is detachably arranged in the air duct and comprises a guide rod and a plurality of air guide blades, the first ends of the air guide blades are detachably connected with the shell, the second ends of the air guide blades are detachably connected with the guide rod, the plurality of air guide blades are arranged in parallel and at intervals along the length direction of the guide rod, and the guide rod is slidably connected with the shell;

In the sliding process of the guide rod, the included angle between the wind guide blade and the plane where the air inlet is located is changed.

In a second aspect, the present application also discloses an air conditioning assembly, which includes: an air conditioner and the air port structure;

the air inlet of the air port structure is communicated with the air outlet of the air conditioner.

In a third aspect, the present application also discloses a vehicle, comprising: the air conditioning assembly.

In the embodiment of the application, since the air guide assembly is detachably arranged in the air duct, the air guide assembly comprises a guide rod and a plurality of air guide blades, the first ends of the air guide blades are detachably connected with the shell, the second ends of the air guide blades are detachably connected with the guide rod, the plurality of air guide blades are mutually parallel and spaced along the length direction of the guide rod, the guide rod is slidably connected with the shell, and the guide rod slidably drives the air guide blades to rotate by taking the first ends of the air guide blades as shafts so as to adjust the ventilation quantity and the ventilation direction of the air duct. Therefore, in practical application, can be through dismantling the wind-guiding subassembly by in the wind channel, and then to wind-guiding blade in the wind-guiding subassembly is dismantled and is changed, through increasing and decreasing the quantity of wind-guiding blade to can adjust the ventilation volume of wind gap structure, simple and convenient, the maneuverability is high, moreover, the user can promote manual operation ability in the dismantlement and the installation of wind-guiding blade, and then promotes user experience.

Drawings

FIG. 1 is a schematic view of a tuyere structure according to an embodiment of the present application;

FIG. 2 is an exploded view of the tuyere structure shown in FIG. 1;

FIG. 3 is a schematic view of a wind guiding vane according to an embodiment of the present application;

FIG. 4 is a schematic view of a guide bar according to an embodiment of the present application;

FIG. 5 is a schematic structural diagram of a first fixed card and a second fixed card according to an embodiment of the application;

FIG. 6 is a schematic view of the structure of a first support member according to an embodiment of the present application;

FIG. 7 is a schematic structural diagram of a third fixed card and a fourth fixed card according to an embodiment of the present application;

FIG. 8 is a schematic view of a fifth card holder according to an embodiment of the application;

FIG. 9 is one of the partial schematic views of the tuyere structure of the embodiment of the present application;

FIG. 10 is a partial exploded view of FIG. 9;

FIG. 11 is a second schematic view of a part of a tuyere structure according to an embodiment of the present application;

FIG. 12 is a partial exploded view of FIG. 11;

FIG. 13 is a third schematic view of a portion of a tuyere structure according to an embodiment of the present application;

FIG. 14 is a schematic view of a portion of a tuyere structure according to an embodiment of the present application;

FIG. 15 is a cross-sectional view taken along the line A-A in FIG. 14;

FIG. 16 is a schematic view showing a part of a tuyere structure in accordance with an embodiment of the present application;

fig. 17 is a schematic structural view of an elastic rubber ring according to an embodiment of the present application.

Reference numerals illustrate:

10: a housing; 11: an air duct; 111: an air inlet; 112: an air outlet; 101: a second cover plate; 102: a first cover plate; 103: a first side plate; 104: a second side plate; 20: an air guide assembly; 201: a guide rod; 202: wind guiding blades; 2021: a first rotating shaft; 2121: a first embedded groove; 2022: a second rotating shaft; 2122: a second end; 2023: a third rotating shaft; 2011: a third rotation shaft hole; 203: a first fixed card; 2031: a first fixing hole; 2032: a second fixing hole; 204: a second fixed card; 2041: a second fixing protrusion; 205: a third fixed card; 2051: a third fixing hole; 206: a fourth fixed card; 2061: a fourth fixing protrusion; 2052: a fourth fixing hole; 30: a first support; 301: a first support hole; 31: a first support portion; 1011: a first support groove; 40: a fifth fixed card; 401: a first clamping groove; 402: a second clamping groove; 403: a third clamping groove; 21: a first turntable; 22: and (3) a crank: 23: a connecting rod; 211: an embedding part; 1012: a first through hole; a second rotation shaft hole: 1014;50: a shunt assembly; 501: a diverter plate; 502: a deflector; 503: a diverter rod; 504: a second turntable; 5031: a gear structure; 5011: a rack structure; 60: a second support; 61: a second supporting part; 601: a second support hole; 602: a second chute; 1013: a second support groove; 611: a second groove; 1031: a second through hole; 221: embedding holes; 2111: a first ring groove; 1021: a third through hole; 113: a first mounting projection; 114: a second mounting projection; 115: a first mounting hole; 116: a second mounting hole; 512: a third mounting projection; 117: a third mounting hole; 1022: a second embedded groove; 70: an elastic rubber ring.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to the appended drawings and appended detailed description.

The air outlet structure according to the embodiment of the application includes, but is not limited to, an air outlet of an air conditioner, and may also be applied to an air outlet of other fans or an air guiding structure.

Referring to fig. 1, a schematic view of a tuyere structure according to an embodiment of the present application is shown. Referring to fig. 2, an exploded view of the tuyere structure shown in fig. 1 is shown. The tuyere structure may specifically include: the shell 10, the shell 10 is provided with an air duct 11 which is communicated with an air inlet 111 and an air outlet 112; the wind guide assembly 20, wind guide assembly 20 detachable sets up in wind channel 11, wind guide assembly 20 includes guide arm 201 and a plurality of wind guide blade 202, wind guide blade 202's first end detachably connects in casing 10, wind guide blade 202's second end detachably connects in guide arm 201, and a plurality of wind guide blade 202 are parallel to each other the interval setting along guide arm 201's length direction, guide arm 201 slidably connects in casing 10, guide arm 201 slides and drives wind guide blade 202 and rotate with wind guide blade 202's first end as the axle, in order to adjust wind channel 11's ventilation volume and ventilation direction.

The tuyere structure provided by the embodiment of the application can be arranged on an instrument board of a vehicle and can be conveniently and integrally detached from the instrument board.

In the embodiment of the present application, since the air guiding assembly 20 is detachably disposed in the air duct 11, a user can conveniently detach the air guiding assembly 20 from the air duct 11, and then maintain or replace the air guiding blades 202 in the air guiding assembly 20.

In practical application, since the first end of the air guiding blade 202 is detachably connected to the housing 10, the second end of the air guiding blade 202 is detachably connected to the guide rod 201, and the plurality of air guiding blades 202 are arranged in parallel and spaced along the length direction of the guide rod 201, the guide rod 201 is slidably connected to the housing 10, and the guide rod 201 slides to drive the air guiding blade 202 to rotate with the first end of the air guiding blade 202 as an axis, so that the included angle between the air guiding blade 202 and the air inlet 111 is changed, and the ventilation amount and the ventilation direction of the air duct 111 are adjusted by the air guiding blade 202. Therefore, the included angle formed by the air guide blade 202 and the plane of the air inlet 111 is changed by the sliding of the guide rod 201, on one hand, the air guide blade 202 can guide the air flow entering from the air inlet 111, and on the other hand, the included angle between the air guide blade 202 and the plane of the air inlet 111 can also regulate the ventilation. In addition, according to the air port structure disclosed by the embodiment of the application, the wind resistance of the air port structure can be adjusted by adjusting the number of the air guide blades 202, so that the air volume is adjusted, simplicity, convenience and high operability are realized, and meanwhile, the manual operation capability can be improved in the process of disassembling and installing the air guide blades 202 by a user, and the use experience of the user is further improved.

In the embodiment of the present application, in order to improve the convenience of installation and disassembly of the air guiding assembly 20, one composition mode of the housing 10 may specifically include: opposite first and second cover plates 102, 101, and opposite first and second side plates 103, 104; the first cover plate 102, the first side plate 103, the second cover plate 101 and the second side plate 104 are sequentially connected to form the air duct 11. In practical application, the casing 10 is divided into the first cover plate 102, the second cover plate 101, the first side plate 103 and the second side plate 104, so that the air guide assembly 20 can be conveniently installed and detached on the casing 10, the assembling and disassembling difficulty of the air port structure is effectively reduced, and the manufacturing and maintenance cost of the air port assembly is further reduced.

In practical applications, the first cover plate 102 and the second cover plate 101 may be side wall plates in the length direction of the tuyere structure, and the first side plate 103 and the second side plate 104 may be connection plates on two sides perpendicular to the first cover plate 102 and the second cover plate 101. It will be appreciated by those skilled in the art that the present application may be set according to actual circumstances, and the embodiments of the present application are not limited thereto.

In practical applications, the first end of the wind guiding blade 202 and the second end of the wind guiding blade 202 may be two adjacent sides of the wind guiding blade 202, or the first end of the wind guiding blade 202 and the second end of the wind guiding blade 202 may be two opposite sides of the wind guiding blade 202.

As shown in fig. 3, a schematic structural view of an air guiding blade according to an embodiment of the present application is shown. As shown in fig. 3, the first end of the wind guiding blade 202 and the second end of the wind guiding blade 202 are two sides adjacent to the wind guiding blade 202, specifically, the first end of the wind guiding blade 202 is provided with a first rotating shaft 2021 and a second rotating shaft 2022 opposite to each other, the first rotating shaft 2021 and the second rotating shaft 2022 are located on the same axis and extend in opposite directions, and the wind guiding blade 202 is detachably connected with the casing 10 through the first rotating shaft 2021 and the second rotating shaft 2022; the second end of the wind guiding blade 202 is provided with a third rotating shaft 2023, the third rotating shaft 2023 is parallel to the axes of the first rotating shaft 2021 and the second rotating shaft 2022, the wind guiding blade 202 is detachably connected with the guide rod 201 through the third rotating shaft 2023, and the sliding direction of the guide rod 201 is perpendicular to the axes of the first rotating shaft 2021 and the second rotating shaft 2022. In this way, during the sliding process of the guide rod 201, the guide rod 201 can drive the air guide blade 202 to rotate by using the first rotating shaft 2021 and the second rotating shaft 2022 as rotating shafts through the third rotating shaft 2023, so that the sliding of the guide rod 201 is realized, and the included angle between the plane where the air guide blade 202 is located and the plane of the air inlet 111 is further driven to change. Therefore, the air guiding blade 202 may serve to guide the air flow entering from the air inlet 111. That is, the sliding direction of the guide rod 201 is perpendicular to the center line passing through the first rotation shaft 2021 and the second rotation shaft 2022, so that the sliding of the guide rod 201 can easily drive the wind guiding blade 202 to rotate, thereby enabling the wind guiding blade 202 to realize the wind guiding effect.

In the embodiment of the present application, the guide rod 201 slides to further drive the wind guiding blade 202 to rotate with the first end as the axis, so that the included angle between the wind guiding blade 202 and the air inlet 111 is changed. Therefore, in the embodiment of the present application, the air outlet volume and the air outlet direction of the air inlet structure can be effectively adjusted by adjusting the number of the air guide blades 202 and the included angle between the air guide blades 202 and the air inlet 111. Moreover, in the process of adjusting the wind guide blade 202, the user can further enhance the manual operation capability, and experience the splicing pleasure, so that the user experience is better.

In practical applications, the angle between the plane of the air guiding blade 202 and the plane of the air inlet 111 may vary from 0 ° to 180 °. Of course, in order to avoid that the wind guiding blade 202 forms a large resistance to the airflow, thereby affecting the air output of the air port structure, the above included angle may preferably be in the range of 60 ° -120 °.

In the embodiment of the application, the following specific steps are as follows: the first shaft 2021 is detachably connected to the first cover 102, the second shaft 2022 is detachably connected to the second cover 101, and the third shaft 2023 is detachably connected to the guide rod 201. In practical applications, the first shaft 2021 is detachably connected to the first cover 102 in various manners, the second shaft 2022 is detachably connected to the second cover 101, and the third shaft 2023 is detachably connected to the guide 201 in various manners. The detachable connection of the first shaft 2021, the second shaft 2022, and the third shaft 2023 is explained in detail below.

Referring to FIG. 4, a schematic structural view of a guide bar according to an embodiment of the present application is shown. As shown in fig. 4, a plurality of third rotation shaft holes 2011 are uniformly distributed along the length direction of the guide rod 201, and the third rotation shaft holes 2011 are matched with the third rotation shaft 2023.

It can be appreciated that in practical applications, each third rotating shaft hole 2011 is detachably provided with the third rotating shaft 2023 of one wind guiding vane 202 (the number of the third rotating shaft holes 2011 is equal to that of the installed wind guiding vanes 202), so that the resistance of the wind guiding vanes 202 to the air flow passing through the air duct 11 can be maximized, and the ventilation of the air port structure is minimized. Alternatively, only a part of the third rotation shaft holes may be detachably provided with the third rotation shafts 2023 of the wind guiding blades 202 (the number of the third rotation shaft holes 2011 is larger than the number of the mounted wind guiding blades 202), so that the resistance of the wind guiding blades 202 to the air flow passing through the air duct 11 is small, and the ventilation amount of the air port structure may be increased appropriately. Therefore, in the embodiment of the present application, the maximum ventilation amount and the minimum ventilation amount of the air port structure can be adjusted by adjusting the number of the air guide blades 202, and the air flow direction entering from the air inlet 111 can be effectively guided by adjusting the included angle between the air guide blades 202 and the plane of the air inlet 111.

In the embodiment of the present application, the third shaft 2023 is detachably disposed in the third shaft hole 2011, and in order to prevent the third shaft 2023 from rotating in the third shaft hole 2011, the third shaft 2023 and the third shaft hole 2011 may be fixedly connected by interference fit or adhesion.

In an embodiment of the present application, the air guiding assembly 20 may further include: a first fixed card 203 and a second fixed card 204; the first fixing card 203 is provided with a first fixing hole 2031, the second fixing card 204 is provided with a second fixing protrusion 2041, and the first fixing holes 2031 are in one-to-one correspondence with the second fixing protrusions 2041; in the case where the second fixing protrusions 2041 are embedded in the first fixing holes 2031, a plurality of second fixing holes 2032 are formed between the first fixing card 203 and the second fixing card 204, the second fixing holes 2032 are in one-to-one correspondence with the third rotation shaft holes 2011, and the aperture of the second fixing holes 2032 is smaller than the outer diameter of the third rotation shaft 2023.

Referring to fig. 5, a schematic structural diagram of a first fixed card and a second fixed card according to an embodiment of the application is shown.

In practical application, the third shaft 2023 is detachably disposed in the third shaft hole 2011 and then protrudes out of the third shaft hole 2011 at least partially, so as to avoid the third shaft 2023 rotating in the third shaft hole 2011 in order to improve the connection reliability between the third shaft 2023 and the third shaft hole 2011, the first fixing card 203 and the second fixing card 204 may also be matched, so that the portion of the third shaft 2023 protruding out of the third shaft hole 2011 is embedded in the second fixing hole 2032, and because the aperture of the second fixing hole 2032 is smaller than the outer diameter of the third shaft 2023, interference fit between the second fixing hole 2032 and the third shaft 2023 is provided, thereby avoiding the rotation of the third shaft 2023, avoiding the third shaft 2023 from falling out of the third shaft hole 2011, and improving the connection reliability between the wind guiding blade 202 and the guiding rod 201.

In an embodiment of the present application, the tuyere structure may further include: a first support 30; the first supporting piece 30 is provided with a plurality of first supporting holes 301, the first supporting holes 301 are in one-to-one correspondence with the first rotating shafts 2021, and the aperture of the first supporting holes 301 is larger than the outer diameter of the first rotating shafts 2021; the first supporting member 30 is further provided with at least one first supporting portion 31, the second cover plate 101 is provided with at least one first supporting groove 1011, the first supporting portions 31 are in one-to-one correspondence with the first supporting grooves 1011, and the first supporting portions 31 are disposed in the first supporting grooves 1011.

Referring to fig. 6, a schematic structural view of a first support member according to an embodiment of the present application is shown. In practical applications, the first shaft 2021 of the wind guiding vane 202 may be detachably disposed in the first supporting hole 301, so that the first shaft 2021 may rotate in the first supporting hole 301, and the first supporting member 30 may perform a function of rotatably supporting the wind guiding vane 202.

Optionally, the wind guiding assembly 20 may further include: a third fixed card 205 and a fourth fixed card 206; the third fixing card 205 is provided with a third fixing hole 2051, the fourth fixing card 206 is provided with a fourth fixing protrusion 2061, and the third fixing hole 2051 corresponds to the fourth fixing protrusion 2061 one by one; in the case where the fourth fixing protrusions 2061 are embedded in the third fixing holes 2051, a plurality of fourth fixing holes 2052 are formed between the third fixing card 205 and the fourth fixing card 206, the fourth fixing holes 2052 are in one-to-one correspondence with the first rotation shaft 2021, and the aperture of the fourth fixing holes 2052 is smaller than the outer diameter of the first rotation shaft 2021.

Referring to fig. 7, a schematic structural diagram of a third fixed card and a fourth fixed card according to an embodiment of the application is shown.

In the embodiment of the application, after the first shaft 2021 is detachably disposed in the first supporting hole 301, at least a portion of the first shaft 2021 protrudes out of the first supporting hole 301, and a portion of the first shaft 2021 protruding out of the first supporting hole 301 is provided with a first embedding groove 2121. It is also necessary to provide the first shaft 2021 rotatably in the first supporting hole 301, and since the aperture of the fourth fixing hole 2052 is smaller than the outer diameter of the first shaft 2021, it is also necessary to provide the first fitting groove 2121 with an outer diameter smaller than the aperture of the fourth fixing hole 2052.

In practical applications, in order to avoid the first shaft 2021 from falling off from the first supporting hole 301, the third fixing clip 205 may be further matched with the fourth fixing clip 206, so that the fourth fixing hole 2052 is clamped in the first embedding groove 2121, and since the aperture of the fourth fixing hole 2052 is smaller than the outer diameter of the first shaft 2021, and the outer diameter of the first embedding groove 2121 is smaller than the aperture of the fourth fixing hole 2052, the rotation of the first shaft 2021 in the first supporting hole 301 can be realized, and the risk that the first shaft 2021 falls off from the first supporting hole 301 is avoided.

In the embodiment of the present application, a plurality of second rotating shaft holes 1014 are formed in the second cover 101, the second rotating shaft holes 1014 are in one-to-one correspondence with the second rotating shafts 2022, and the outer diameter of the second rotating shaft 2022 is smaller than the aperture of the second rotating shaft holes 1014. In practical applications, the second shaft 2022 is detachably disposed in the second shaft hole 1014, and since the outer diameter of the second shaft 2022 is smaller than the aperture of the second shaft hole 1014, the rotatable connection of the second shaft 2022 in the second shaft hole 1014 is also achieved, so that the connection of the wind guiding blade 202 and the second cover plate 101 is also achieved.

Referring to fig. 8, a schematic structural diagram of a fifth fixing card according to an embodiment of the present application is shown.

Optionally, the tuyere structure may further include: a fifth fixed card 40; the fifth fixing card 40 is provided with a plurality of first clamping grooves 401 and a plurality of second clamping grooves 402, the first clamping grooves 401 are in one-to-one correspondence with the first supporting parts 31, and the second clamping grooves 402 are in one-to-one correspondence with the second rotating shaft holes 1014; the end of second shaft 2022 is provided with a second end 2122, the outer diameter of second end 2122 being larger than the outer diameter of second shaft 2022; the second clamping groove 402 is matched with the outer diameter of the second rotating shaft 2022; the first supporting portion 31 is embedded in the first clamping groove 401.

In the embodiment of the present application, when the second spindle 2022 is detachably disposed in the second spindle hole 1014, at least a portion of the second spindle 2022 may be disposed to extend out of the housing 10 through the second spindle hole 1014, in order to avoid the second spindle 2022 from falling out of the second spindle hole 1014, the second clamping groove 402 may be smaller than the second end 2122, and a portion of the second spindle 2022 extending out of the housing 10 may be clamped in the second clamping groove 402, so that the second spindle 2022 may be fixed in the second spindle hole 1014 by the fifth fixing card 40, and since the second clamping groove 402 is smaller than the second end 2122, the second spindle 2022 may be firmly fixed in the second spindle hole 1014 by clamping the second spindle 2022 in the second clamping groove 402, and the second spindle 2022 may be prevented from falling out of the second spindle hole 1014. Similarly, when the first supporting portion 31 is embedded in the first supporting slot 1011, at least a portion of the first supporting portion 31 passes through the first supporting slot 1011 and extends out of the housing 10, in order to prevent the first supporting portion 31 from falling out of the first supporting slot 1011, a portion of the first supporting portion 31 extending out of the housing 10 may be clamped in the first clamping slot 401, so that the first supporting portion 31 may be fixed in the first supporting slot 1011 by the fifth fixing clip 40.

In practical application, in order to improve the reliability of the clamping connection of the fifth fixing card 40, a clamping groove protrusion is further provided in the first clamping groove 401, and correspondingly, a supporting hole is provided on the first supporting portion 31, and under the condition that the first supporting portion 31 is embedded in the first clamping groove 401, the clamping groove protrusion is embedded in the supporting hole, so that the first supporting portion 31 is firmly clamped in the first clamping groove 401, and the first supporting portion 31 can be effectively prevented from falling off from the first clamping groove 401.

In the embodiment of the application, the first support 30 and the second rotating shaft 2022 are simultaneously fixed by the fifth fixing card 40, so that the structure is simple and the cost is low. Of course, those skilled in the art may also separately fix the first support 30 and the second rotation shaft 2022 according to practical situations, and only one schematic description is given in the embodiment of the present application.

Optionally, the wind guiding assembly 20 may further include: a crank-link mechanism; the guide 201 is slidably connected to the housing 10 by a crank linkage.

In the embodiment of the present application, the guide rod 201 may be slidably connected to the housing 10 in a variety of manners, for example, a sliding groove is provided on the housing 10, and the guide rod 201 is movably disposed in the sliding groove, so as to realize the slidable connection of the guide rod 201 to the housing 10. Alternatively, the guide 201 may be slidably connected to the housing 10 by a crank-link mechanism, which may include: a first turntable 21, a crank 22 and a connecting rod 23; the second cover plate 101 is provided with a first through hole 1012; the first rotary table 21 is arranged outside the air duct 11, an embedded part 211 is arranged on the first rotary table 21, the embedded part 211 is fixedly connected with one end of a crank 22 through a first through hole 1012, the other end of the crank 22 is hinged with one end of a connecting rod 23, and the other end of the connecting rod 23 is rotatably connected with one end of a guide rod 201. Thus, by rotating the first rotating disc 21, the crank 22 is driven by the embedded portion 211, the crank 22 drives the connecting rod 23, and the connecting rod 23 drives the guide rod 201 to slide along the direction parallel to the air inlet 111. In practical application, the crank connecting rod has a simple structure and high reliability, so that the sliding of the guide rod 201 realized by the crank connecting rod also has the advantages of simple structure and high reliability.

In practical applications, the crank 22 and the connecting rod 23 in the crank-connecting rod mechanism are usually connected with the guide rod 201 and arranged in an integrated structure, so that the assembly steps are reduced, and the assembly efficiency is improved.

Optionally, the tuyere structure may further include: a shunt assembly 50; the flow dividing assembly 50 is detachably disposed on a side of the air guiding blade 202 near the air outlet 112, and the flow dividing assembly 50 is used for dividing the air flow entering from the air inlet 111 into at least two parts.

In the embodiment of the application, the air flow passing through the air guide blade 202 is split by the splitting assembly 50 and then is separated into at least two parts to be blown out from the air outlet 112, so that on one hand, the air flow can be guided, on the other hand, the air blown out from the air outlet 112 can be more uniform and softer, and the use comfort of a user can be effectively improved.

Alternatively, the flow splitting assembly 50 may include: a diverter plate 501 and a diverter plate 502; the splitter plate 501 is slidably connected to the housing 10, and the splitter plate 501 is close to the air guiding blade 202 and parallel to a first section of the air duct 11, where the first section is a section of the air duct 11 at a first end of the air guiding blade 202; one end of the deflector 502 is perpendicular to the flow dividing plate 501, and the other end extends toward the air outlet 112.

In the embodiment of the application, the splitter plate 501 is arranged close to the air guide blade 202, so that the air flow led in by the air guide blade 202 is separated into at least two parts through the splitter plate 501, and because one end of the splitter plate 502 is perpendicular to the splitter plate 501 and the other end extends towards the direction of the air outlet 112, the air flow split through the splitter plate 501 can be led out to the air outlet 112 for blowing out through the splitter plate 502, and the air flow can be reduced by the guiding effect of the splitter plate 502 on the air flow, so that the air volume of the air outlet 112 is stronger, and on the other hand, the air flow separated by the splitter plate 501 is prevented from being converged together, and the air flow is separated into at least two parts for blowing out, so that the blown air is softer.

In the embodiment of the present application, the extending track of the air duct 11 may be an irregular line. For example, the extending track of the air duct 11 may be a wavy line. In the embodiment of the present application, since the air inlet 111 and the air outlet 112 are located at two adjacent sides of the housing, the air duct 11 may be regarded as an L-shaped air duct.

In the embodiment of the present application, since the extending track of the air duct 11 may be an irregular line, in order to make the splitting effect of the splitter plate 501 better, a first section of the splitter plate 501 parallel to the air duct 11 may be provided, where the first section is a cross section of the air duct 11 at the first end of the air guiding blade 202. That is, the splitter plate 501 is located in the cross-section of the duct 11 through the first end of the wind guiding blade 202. In the embodiment of the present application, the splitter plate 501 moves in parallel on the cross section of the air duct 11, so that the splitter plate 501 divides the air duct 11 into two parts, and because one end of the splitter plate 502 is perpendicular to the splitter plate 501 and the other end extends towards the air outlet 112, the air flow in the air duct 11 is divided into at least two parts by the splitter plate 501, and then is led to the air outlet 112 along the extending direction of the splitter plate 502 for blowing.

In the embodiment of the present application, the deflector 502 has a curved surface structure matching with the shape of the air duct 11, so that the extension of the deflector 502 matches with the internal shape of the air duct 11, the resistance of the deflector 502 to the air flow is reduced, and the deflector 502 has a deflector effect.

In practical applications, the number of the flow dividing plates 501 and the number of the flow guiding plates 502 may be limited according to practical situations, and in theory, the number of the flow dividing plates 501 and the number of the flow guiding plates 502 cannot be too large, otherwise, wind resistance is too large. The embodiment of the present application is schematically illustrated and described by taking the case of one flow dividing plate 501 and one flow dividing plate 502 as an example, and other references should be made. The baffle 502 may be configured by those skilled in the art according to actual needs, which is not limited in this embodiment of the present application.

In the embodiment of the present application, there are various sliding manners of the splitter plate 501, for example, a guide groove is provided on the housing 10, and two ends of the splitter plate 501 are movably embedded in the guide groove, so that the splitter plate 501 can be slidably connected with the housing 10 by sliding the splitter plate 501 in the guide groove.

In another embodiment of the present application, the sliding manner of the splitter plate 501 may be further configured as follows, and specifically, the splitter assembly 50 may further include: a diverter lever 503; the diversion rod 503 is rotatably connected with the shell 10, and the diversion rod 503 is provided with a gear structure 5031; the flow dividing plate 501 is provided with a rack structure 5011 engaged with the gear structure 5031, and the rack structure 5011 extends in the width direction of the flow dividing plate 501. In the embodiment of the application, the split plate 501 can be driven to slide by rotating the split rod 503 in a mode of meshing and connecting the gear structure 5031 with the rack structure 5011, so that the structure is simple, the precision is high and the reliability is high.

There are also various sliding connection modes of the splitter plate 501 in the embodiment of the present application, and the embodiment of the present application only gives a schematic illustration, and other embodiments can be set by those skilled in the art.

Optionally, the wind guiding assembly 20 may further include: a second support 60; the second supporting piece 60 is provided with a second supporting hole 601 and a second sliding groove 602, the flow dividing rod 503 is rotatably arranged in the second supporting hole 601, the second sliding groove 602 extends along the width direction of the flow dividing plate 501, and the flow dividing plate 501 is movably arranged in the second sliding groove 602; the second cover plate 101 is provided with a second supporting groove 1013, the second supporting member 60 is provided with a second supporting portion 61, the second supporting portion 61 is embedded in the second supporting groove 1013, and at least part of the second supporting portion 61 passes through the second supporting groove 1013 and extends out of the housing 10.

In practical applications, the second supporting hole 601 is generally disposed along the central position of the length of the second sliding chute 602, so that the flow dividing plate 501 can be driven to slide in the second sliding chute 602 by rotating the flow dividing rod 503 in the second supporting hole 601, and the flow dividing plate 501 can achieve symmetrical flow dividing effect due to the arrangement of the second supporting hole 601 along the central position of the length of the second sliding chute 602.

In the embodiment of the present application, the second supporting portion 61 is embedded in the second supporting groove 1013, so that the connection between the second supporting member 60 and the second cover plate 101 can be achieved.

Optionally, a third slot 403 may be further provided on the fifth fixed card 40; the second supporting portion 61 is provided with a second groove 611 at a portion extending out of the housing 10; the third clamping groove 403 is embedded with the second groove 611.

In practical applications, in order to avoid the second supporting portion 61 from disengaging from the second supporting groove 1013, the third clamping groove 403 may be further configured to be engaged with the second groove 611, so that the second supporting portion 61 and the housing 10 may be more reliably connected.

In the embodiment of the present application, the first fixing card 203, the second fixing card 204, the third fixing card 205, the fourth fixing card 206 and the fifth fixing card 40 may be plastic cards, and the plastic cards have the advantages of good toughness, high plasticity, low cost, etc., so the fixing cards formed by the plastic cards also have the advantages. Further, the first fixing card 203, the second fixing card 204, the third fixing card 205, the fourth fixing card 206 and the fifth fixing card 40 may be manufactured by injection molding or machining. Especially, under the condition that the card is provided with a plurality of holes and clamping grooves, the precision of the special-shaped holes or the clamping grooves can be improved due to the injection molding integrated forming, so that the fixed card formed through the injection molding integrated forming also has the corresponding advantages of high precision and low processing cost.

Optionally, the shunt assembly 50 may further include: a second turntable 504; the housing 10 is provided with a second through hole 1031; the second turntable 504 is disposed outside the housing 10; one end of the diversion lever 503 is fixedly connected with the second turntable 504 through the second through hole 1031.

In the embodiment of the application, the second turntable 504 drives the diversion rod 503 to rotate, so that the structure is simple and the cost is low. In addition, since the second turntable 504 is disposed outside the housing 10, the second turntable 504 does not occupy the space in the air duct 11, and the second turntable 504 does not increase the wind resistance or affect the air volume.

Optionally, the number of the air guiding assemblies 20 is two, and the two air guiding assemblies 20 are symmetrically arranged in the air duct 11.

In the embodiment of the present application, the number of the air guiding assemblies 20 may be two, and the two air guiding assemblies 20 are symmetrically arranged in the air duct 11, so that the air guiding blades 202 in each air guiding assembly 20 can be respectively adjusted, thereby realizing the adjustment of the air quantity and the air outlet direction in the air port structure. For example, the air outlet directions of the two air guiding assemblies 20 can be adjusted to be opposite, so that the air directions blown out through the air outlets 112 are different, and the user experience is better.

In the embodiment of the application, the assembly sequence of the tuyere structure can be as follows: referring to FIG. 9, one of the partial schematic views of the tuyere structure of the embodiment of the present application is shown; referring to fig. 10, a partial exploded view of fig. 9 is shown. Step one, disposing the third rotating shaft 2023 of the wind guiding blade 202 in the third rotating shaft hole 2011 of the guide rod 201, and then matching the first fixing card 203 with the second fixing card 204, so that the portion of the third rotating shaft 2023 protruding out of the third rotating shaft hole 2011 is clamped in the second fixing hole 2032, so that the wind guiding blade 202 can be connected with the guide rod 201; step two, arranging the first rotating shaft 2021 of the wind guiding blade 202 in the first supporting hole 301 of the first supporting member 30, matching the third fixing card 205 with the fourth fixing card 206 to form a fourth fixing hole 2052, and clamping the embedded groove of the first rotating shaft 2021 in the fourth fixing hole 2052, thus completing the connection between the wind guiding blade 202 and the first supporting member 30; it will be appreciated that in the first and second steps, the crank 22 and the connecting rod 23 may be integrally provided directly with the guide rod 201, thereby reducing the number of connection steps. In the embodiment of the present application, a partial schematic view of the tuyere structure formed through the first and second steps is shown in fig. 9.

Referring to FIG. 11, there is shown a second partial schematic view of a tuyere structure according to an embodiment of the present application. Referring to fig. 12, a partial exploded view of fig. 11 is shown. As shown in the figure, step three, disposing the second rotation shaft 2022 of the wind guiding vane 202 in the second rotation shaft hole 1014 of the second cover plate 101, and disposing the first supporting portion 31 of the first supporting member 30 in the first supporting groove 1011; meanwhile, the diverting rod 503 is disposed in the second supporting hole 601 of the second supporting member 60, the diverting plate 501 is disposed in the second sliding groove 602 of the second supporting member 60, and then the second supporting portion 61 of the second supporting member 60 is disposed in the second supporting groove 1013; finally, the first clamping groove 401 of the fifth fixing card 40 is clamped with the first supporting portion 31, the second clamping groove 402 of the fifth fixing card 40 is clamped with the second rotating shaft 2022, and the third clamping groove 403 of the fifth fixing card 40 is clamped with the second groove 611 of the second supporting portion 61, so that the first supporting member 30, the second supporting member 60 and the second rotating shaft 2022 are reliably connected with the second cover plate 101. Specifically, referring to fig. 13, there is shown a third partial schematic view of the tuyere structure according to an embodiment of the present application. As shown in fig. 13, the first support 30, the second support 60, and the second shaft 2022 are fixed to the second cover 101 by the fifth fixing clip 40, respectively, so that the structure is simple and the reliability is high.

Referring to fig. 14, there is shown a schematic view of a part of a tuyere structure according to an embodiment of the present application. Referring to fig. 15, a cross-sectional view along A-A in fig. 14 is shown. The embodiment of the present application further includes a fourth step of connecting the embedded portion 211 of the first turntable 21 to one end of the crank 22 through the first through hole 1012. In practical applications, an insertion hole 221 is usually formed at one end of the crank 22, the insertion portion 211 is inserted into the insertion hole 221, and at least part of the insertion portion 211 protrudes from the insertion hole 221. In order to prevent the embedded portion 211 from falling out of the embedded hole 221, a first ring groove 2111 is further provided at a portion of the embedded portion 211 extending out of the embedded hole 221, and when the embedded portion 211 is embedded in the embedded hole 221 and at least a portion of the embedded portion 211 extends out of the embedded hole 221, the embedded portion 211 may be elastically clamped in the first ring groove 2111 by the elastic rubber ring 70, so that the embedded portion 211 is firmly fixed in the embedded hole 221 by the elastic rubber ring 70. Further, the elastic rubber ring 70 is provided in the first ring groove 2111, so that the elastic rubber ring 70 can be effectively prevented from falling off.

In the embodiment of the application, compared with other fixing modes, the elastic rubber ring 70 has simple structure and low cost, and does not need tools during maintenance and replacement, so that the installation and maintenance are more convenient.

Referring to fig. 16, there is shown a schematic view of a part of a tuyere structure according to an embodiment of the present application.

The embodiment of the application also comprises the following steps: step five, the first cover plate 102, the first side plate 103 and the second side plate 104 are assembled with the components in step four, specifically: a third through hole 1021 matched with the first support 30 is arranged on the first cover plate 102 so as to facilitate the first support 30 to be embedded in the third through hole 1021; further, the first mounting protrusions 113 are respectively disposed at two ends of the first cover plate 102, the second mounting protrusions 114 are respectively disposed at two ends of the second cover plate 101, the first mounting holes 115 matched with the first mounting protrusions 113 and the second mounting holes 116 matched with the second mounting protrusions 114 are respectively disposed on the first side plate 103 and the second side plate 104, and the first mounting protrusions 113 are embedded in the first mounting holes 115, and the second mounting protrusions 114 are embedded in the second mounting holes 116, so that connection between the second cover plate 101 and the first cover plate 102 and connection between the first side plate 103 and the second side plate 104 are achieved.

In the embodiment of the present application, in order to improve the structural stability of the second support member 60, a second embedded groove 1022 may be further provided on the first cover plate 102, and the other end of the second support member 60 is embedded in the second embedded groove 1022 and at least partially extends out of the second embedded groove 1022, and further, the portion of the second support member 60 extending out of the housing 10 may be further fixed by the elastic rubber ring 70.

It can be understood that, in the fifth step, in order to avoid the first mounting protrusion 113 from falling out of the first mounting hole 115 and to avoid the second mounting protrusion 114 from falling out of the second mounting hole 116, in the fourth step, the portion of the first mounting protrusion 113 extending out of the first mounting hole 115 may be elastically clamped by the elastic rubber ring 70, and the portion of the second mounting protrusion 114 extending out of the second mounting hole 116 may be elastically clamped by the elastic rubber ring 70. It will be appreciated that the portion of the first mounting protrusion 113 extending out of the first mounting hole 115 may further be provided with a second annular groove (the second annular groove is similar to the first annular groove 2111 in shape, the structure is referred to the first annular groove 2111, the second annular groove is not specifically shown in the drawing), and the portion of the second mounting protrusion 114 extending out of the second mounting hole 116 may also be provided with a third annular groove (the third annular groove is similar to the first annular groove 2111 in shape, the structure is referred to the first annular groove 2111, the third annular groove is not specifically shown in the drawing), so that the elastic rubber ring 70 is respectively disposed in the second annular groove and the third annular groove, thereby effectively preventing the elastic rubber ring 70 from falling off.

Referring to fig. 17, a schematic structural view of an elastic rubber ring 70 according to an embodiment of the present application is shown. In the embodiment of the present application, the elastic rubber ring 70 may be applied to the detachable connection portions of the embodiments of the present application, for example, the detachable connection of the baffle 502 on the first side plate 103 and the second side plate 104, the connection of the second support 60 on the first cover plate 102, and the like, may be all fixed by using the elastic rubber ring 70, and since the elastic rubber ring 70 is simple in structure and low in cost compared with other fixing methods, and no tool is required during maintenance and replacement, so that the installation and maintenance are more convenient.

In practical applications, the size of the elastic rubber ring 70 may be various to match with different sizes of components, or the size of the elastic rubber ring 70 may be only one, and in practical applications, the elastic rubber ring 70 may be wound multiple times by using the elasticity of the elastic rubber ring 70 to realize winding fixation. Therefore, in the embodiment of the present application, the size of the elastic rubber ring 70 is not particularly limited, and may be set by those skilled in the art according to the actual situation.

In practical applications, in order to improve the connection stability between the baffle 502 and the housing 10, third mounting protrusions 512 may be further disposed at two ends of the baffle 502, and third mounting holes 117 are disposed on the first side plate 103 and the second side plate 104, and in the fifth step, the third mounting protrusions 512 are disposed in the third mounting holes 117 synchronously, so that the baffle 502 is connected to the first side plate 103 and the second side plate 104 respectively. It is understood that the fitting connection between the third mounting protrusion 512 and the third mounting hole 117 may be the same as the fitting structure between the second mounting protrusion 114 and the second mounting hole 116, which is described above, and will be omitted herein for brevity.

In an embodiment of the present application, in order to further improve the stability of the baffle 502, the number of the third mounting protrusions 512 may be plural, and the plural third mounting protrusions 512 are disposed opposite to each other at two ends of the baffle 502. In practical application, the shape and the size of the third installation protrusions 512 can be the same, so that the processing difficulty of the baffle 502 can be effectively reduced, or the shape and the size of the third installation protrusions 512 can be different, so that the third installation protrusions 512 can be better matched with the shape of the baffle 502, the stability of the baffle 502 is improved, and noise generation caused by unstable fixing of the baffle 502 is avoided.

In practical application, in order to improve stability of the diverter rod 503, fourth mounting holes (not shown in the drawings) may be further disposed on the first side plate 103 and the second side plate 104, and meanwhile, the diverter rod 503 is extended from the second supporting hole 601 on the second supporting member 60 and is embedded in the fourth mounting hole, so that structural stability of the diverter rod 503 may be improved, and structural stability of the second supporting member 60 may be improved.

Step six, installing a second turntable 504; in practical application, after the first side plate 103 and the second side plate 104 are respectively installed, the second turntable 504 connected with the diversion rod can be installed, and since the second turntable 504 is arranged outside the casing 10, the second turntable 504 can be installed at last, so that the diversion rod can be easily driven to rotate by rotating the second turntable 504.

It can be understood that the above-mentioned installation step is only one assembly form of the tuyere structure according to the embodiment of the present application, and a user can adjust the installation sequence in the above-mentioned step according to the situation during the installation process, so that the user experiences more assembly fun.

In the embodiment of the application, each part of the tuyere structure can be a plastic part, and is processed through an injection molding integrated structure, and because the plastic part can be processed into more complex and precise parts through injection molding, the shape of the shell 10 of the tuyere structure and the air duct 11 of the shell 10 can be designed into a special-shaped structure, thereby being more beneficial to the reasonable utilization of the vehicle space.

In summary, the tuyere structure according to the embodiment of the present application at least includes the following advantages:

in the embodiment of the application, since the air guide assembly is detachably arranged in the air duct, the air guide assembly comprises a guide rod and a plurality of air guide blades, the first ends of the air guide blades are detachably connected with the shell, the second ends of the air guide blades are detachably connected with the guide rod, the plurality of air guide blades are mutually parallel and spaced along the length direction of the guide rod, the guide rod is slidably connected with the shell, and the guide rod slidably drives the air guide blades to rotate by taking the first ends of the air guide blades as shafts so as to adjust the ventilation quantity and the ventilation direction of the air duct. Therefore, in practical application, can be through dismantling the wind-guiding subassembly by in the wind channel, and then to wind-guiding blade in the wind-guiding subassembly is dismantled and is changed, through increasing and decreasing the quantity of wind-guiding blade to can adjust the ventilation volume of wind gap structure, simple and convenient, the maneuverability is high, moreover, the user can promote manual operation ability in the dismantlement and the installation of wind-guiding blade, and then promotes user experience.

The application also provides an air conditioner component, which specifically comprises: an air conditioner and the air port structure; the air inlet of the air port structure is communicated with the air outlet of the air conditioner.

In the embodiment of the application, the air inlet of the air inlet structure is communicated with the air outlet of the air conditioner, so that the air blown out from the air outlet of the air conditioner can enter through the air inlet of the air inlet structure, and can be blown out from the air outlet of the air inlet structure after passing through the air guide component and the flow dividing component of the air inlet structure. Therefore, on one hand, the air outlet direction of the air conditioner can be adjusted through the air port structure, and on the other hand, the air outlet of the air conditioner can be guided, so that the comfort of a user in using the air conditioner is improved. And in practical application, can be through with wind-guiding subassembly by dismantle in the wind channel, and then to wind-guiding blade in the wind-guiding subassembly is dismantled and is changed, through increasing and decreasing the quantity of wind-guiding blade to can adjust the ventilation volume of wind gap structure, simple and convenient, the maneuverability is high, moreover, the user can promote manual operation ability in the dismantlement and the installation of wind-guiding blade, and then promotes user's use experience.

The embodiment of the application also provides a vehicle, which can specifically comprise the air conditioner assembly.

In practical application, because the wind gap structure of air conditioning unit is the position of demountable installation at the instrument board of vehicle, consequently, when the user wants to adjust the air output, through dismantling wind gap structure to adjust the quantity of wind-guiding blade, thereby can satisfy the demand of user to the air output on the one hand, promote the comfort level that the user used, on the other hand can also increase the concatenation enjoyment for the user in the way of driving traveling with the dismantlement and the assembly process of above-mentioned wind gap structure, promote user's use experience.

Finally, it is further noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or terminal that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or terminal. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article or terminal device comprising the element.

The above detailed description of the tuyere structure, the air conditioning assembly and the vehicle provided by the invention applies specific examples to illustrate the principle and the implementation of the invention, and the above examples are only used for helping to understand the method and the core idea of the invention; meanwhile, as those skilled in the art will have variations in the specific embodiments and application scope in accordance with the ideas of the present invention, the present description should not be construed as limiting the present invention in view of the above.

Claims (9)

1. A tuyere structure, characterized in that the tuyere structure comprises:

the shell is provided with an air duct which is communicated with the air inlet and the air outlet;

the air guide assembly is detachably arranged in the air duct and comprises a guide rod and a plurality of air guide blades, the first ends of the air guide blades are detachably connected with the shell, the second ends of the air guide blades are detachably connected with the guide rod, the plurality of air guide blades are arranged at intervals in parallel along the length direction of the guide rod, the guide rod is slidably connected with the shell, and the guide rod slidably drives the air guide blades to rotate by taking the first ends of the air guide blades as shafts so as to adjust the ventilation quantity and the ventilation direction of the air duct;

The tuyere structure further comprises: a shunt assembly;

the flow dividing assembly is used for dividing the air flow entering from the air inlet into at least two parts;

the flow splitting assembly includes: a diverter plate, diverter rod, and diverter plate; the splitter plate is slidably connected to the housing; the separated air flow is guided out to the air outlet through the guide plate and is blown out;

the shunt rod is rotatably connected with the shell, and a gear structure is arranged on the shunt rod;

the splitter plate is provided with a rack structure meshed with the gear structure, and the rack structure extends along the width direction of the splitter plate.

2. The tuyere structure of claim 1, wherein the first end of the wind guiding vane is provided with a first rotating shaft and a second rotating shaft which are opposite, the first rotating shaft and the second rotating shaft are positioned on the same axis and extend in opposite directions;

the wind guide blade is detachably connected with the shell through the first rotating shaft and the second rotating shaft;

the second end of the wind guide blade is provided with a third rotating shaft, the third rotating shaft is parallel to the axis where the first rotating shaft and the second rotating shaft are located, the wind guide blade is detachably connected with the guide rod through the third rotating shaft, and the sliding direction of the guide rod is perpendicular to the axis where the first rotating shaft and the second rotating shaft are located.

3. The tuyere structure of claim 2, wherein the housing includes: opposite first and second cover plates, and opposite first and second side plates;

the first cover plate, the first side plate, the second cover plate and the second side plate are sequentially connected to form the air duct;

the first rotating shaft is detachably connected with the first cover plate, and the second rotating shaft is detachably connected with the second cover plate.

4. The tuyere structure of claim 1, wherein the wind guiding assembly further comprises: a crank-link mechanism;

the guide rod is slidably connected to the housing through the crank linkage.

5. The tuyere structure of claim 1, wherein the diverting assembly is detachably disposed at a side of the wind guiding blade close to the air outlet.

6. The tuyere structure of claim 5, wherein the flow dividing plate is adjacent to the wind guiding vane and parallel to a first section of the wind channel, the first section being a section of the wind channel at a first end of the wind guiding vane;

one end of the guide plate is perpendicular to the flow dividing plate, and the other end extends towards the direction of the air outlet.

7. The tuyere structure of claim 1, wherein the number of the wind guiding assemblies is two, and the two wind guiding assemblies are symmetrically arranged in the air duct.

8. An air conditioning assembly, the air conditioning assembly comprising: air conditioner and tuyere structure according to any one of the preceding claims 1 to 7;

the air inlet of the air port structure is communicated with the air outlet of the air conditioner.

9. A vehicle, characterized in that the vehicle comprises: an air conditioning assembly as claimed in claim 8.