CN215675738U - Air guide component and air conditioner with same - Google Patents

Abstract

The utility model discloses an air guide component and an air conditioner with the same, wherein the air guide component comprises: air guide grid, tripe subassembly and wind guide drive assembly, air guide grid includes the air guide rib along air guide grid's longitudinal extension, air guide rib is a plurality of and sets up along air guide grid's horizontal interval, air guide grid has the first pivot axis along air guide grid's longitudinal extension, tripe subassembly includes a plurality of tripes along air guide grid's longitudinal separation, tripe pivotal connection to air guide grid, and have the second pivot axis along air guide grid's horizontal extension, wind guide drive assembly includes first actuating mechanism and second actuating mechanism, first actuating mechanism links to each other with air guide grid, and be used for driving air guide grid and rotate around first pivot axis, second actuating mechanism links to each other with tripe subassembly, and be used for driving the relative air guide grid of tripe and rotate around the second pivot axis. According to the air guide part disclosed by the utility model, the air outlet angle can be adjusted in a wider range, and the whole assembly and disassembly are facilitated.

Description

Air guide component and air conditioner with same

Technical Field

The utility model relates to the technical field of air outlet adjustment, in particular to an air guide component and an air conditioner with the same.

Background

In the air conditioner in the related art, in order to realize air guide adjustment, a transverse louver component for swinging air up and down and a vertical louver component for swinging air left and right are arranged at an air outlet, the transverse louver component and the vertical louver component are respectively and independently installed on an air outlet frame, the assembly is complex, and the air guide range is limited.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the utility model provides the air guide component which can realize air outlet angle adjustment in a wider range, has a simple structure and is beneficial to integral disassembly and assembly.

The utility model also provides an air conditioner with the air guide component.

According to an embodiment of the first aspect of the present invention, the wind guide member includes: the air guide grid comprises a plurality of air guide ribs extending along the longitudinal direction of the air guide grid, the air guide ribs are arranged at intervals along the transverse direction of the air guide grid, and the air guide grid is provided with a first pivot axis extending along the longitudinal direction of the air guide grid; a louver assembly including a plurality of louvers spaced apart along a longitudinal direction of the air deflection grille, the louvers being pivotally connected to the air deflection grille and having a second pivot axis extending along a transverse direction of the air deflection grille; wind guide drive assembly, wind guide drive assembly includes first actuating mechanism and second actuating mechanism, first actuating mechanism with the wind-guiding grid links to each other, and is used for the drive the wind-guiding grid winds first pivot axis rotates, second actuating mechanism with the tripe subassembly links to each other, and is used for the drive the tripe is relative the wind-guiding grid winds the second pivot axis rotates.

According to the air guide component provided by the embodiment of the utility model, the air outlet angle can be adjusted in a wider range, and the integral assembly and disassembly are facilitated.

In some embodiments, the first drive mechanism cooperates directly or indirectly with the second drive mechanism to integrate the wind directing drive assembly into one module.

In some embodiments, the wind guide driving assembly comprises a driving box, and the first driving mechanism and the second driving mechanism are both received in the driving box, so that the wind guide driving assembly is integrated into a module.

In some embodiments, the wind guide driving assembly includes a first driving motor and a second driving motor, the first driving motor drives the first driving mechanism, the second driving motor drives the second driving mechanism, and the first driving motor and the second driving motor are both installed outside the driving box.

In some embodiments, the wind guide driving assembly is arranged at one longitudinal end of the wind guide grid.

In some embodiments, the wind guide grid is provided with mounting plates at both ends in the longitudinal direction, at least one of the mounting plates is provided with a first connecting shaft portion, the first driving mechanism comprises a driving gear and a driven gear which are in meshing transmission, the driven gear comprises a gear portion and a second connecting shaft portion which are arranged along the axial direction, and the second connecting shaft portion is in transmission fit with the first connecting shaft portion.

In some embodiments, one of the first connecting shaft portion and the second connecting shaft portion is a connecting shaft, and the other one of the first connecting shaft portion and the second connecting shaft portion is a connecting hole, and the connecting shaft is inserted into the connecting hole and transmits torque through non-circular surface fitting.

In some embodiments, the wind guide driving assembly further comprises a driving case including a supporting shaft hole, the driven gear includes a supporting shaft portion located between the gear portion and the second coupling shaft portion, the supporting shaft portion is rotatably supported in the supporting shaft hole, the gear portion is located inside the driving case, and the second coupling shaft portion is located outside the driving case.

In some embodiments, the driven gear has a through hole penetrating in the axial direction, the louver assembly further includes a connecting rod extending in the longitudinal direction of the air guide grille, the connecting rod is pivotally connected to each louver, the air guide driving assembly includes a pushing shaft connecting the second driving mechanism and the connecting rod, and the pushing shaft is disposed through the through hole to reciprocate in the axial direction of the through hole so as to push the connecting rod to reciprocate in the longitudinal direction of the air guide grille.

In some embodiments, the second driving mechanism comprises a meshing transmission driving gear and a meshing rack, and the meshing rack is connected with the push shaft.

In some embodiments, a connector is arranged at one end of the connecting rod, the push shaft comprises a connecting section extending into the connector, and the connector and the connecting section are in limit fit through a limit structure so as to limit the connecting section to be separated from the connector along the longitudinal direction of the air guide grid.

In some embodiments, the air guide grille is a grid-shaped arc panel, and the first pivot axis passes through an arc center of the air guide grille.

An air conditioner according to an embodiment of a second aspect of the present invention includes: a housing component having an air outlet therein; the air guide component is arranged at the air outlet and is the air guide component according to the embodiment of the first aspect of the utility model.

According to the air conditioner provided by the embodiment of the utility model, the air guide component in the embodiment of the first aspect is arranged, so that the air outlet angle can be adjusted in a wider range, and the air guide component is beneficial to the overall assembly and disassembly.

An air conditioner according to an embodiment of a third aspect of the present invention includes: the air outlet is formed in the shell part, and a first mounting seat and a second mounting seat which are respectively positioned on two sides of the length of the air outlet are arranged in the shell part; the air guide component is arranged at the air outlet and is the air guide component according to the embodiment of the first aspect of the utility model, and the air guide driving assembly is arranged on the first mounting seat; the door opening and closing component comprises an opening and closing door and an opening and closing door driving component, the opening and closing door driving component is installed on the second installation seat and drives the opening and closing door to rotate at the air outlet to open and close the air outlet.

According to the air conditioner provided by the embodiment of the utility model, the air guide component in the embodiment of the first aspect is arranged, so that the air outlet angle can be adjusted in a wider range, and the air guide component is beneficial to the overall assembly and disassembly.

In some embodiments, the length direction of the switch door and the length direction of the air guide grid are both the same as the length direction of the air outlet, a first mounting plate and a second mounting plate are respectively arranged at two ends of the length of the air guide grid, a first mounting lug and a second mounting lug are respectively arranged at two ends of the length of the switch door, the first mounting lug is located between the first mounting plate and the first mounting seat, the second mounting lug is located between the second mounting plate and the second mounting seat, a first via hole is arranged on the first mounting seat, a first supporting hole is formed on the first mounting lug, a first connecting shaft portion is arranged on the first mounting plate, the air guide driving component comprises a first supporting shaft and a second connecting shaft portion, the air guide driving component is accommodated in the first mounting seat, the second connecting shaft portion is located outside the first mounting seat and is in transmission fit with the first connecting shaft portion, the first support shaft penetrates through the first via hole and the first support hole; be equipped with the second via hole on the second mount pad, be equipped with the second supported hole on the second mounting panel, be equipped with second back shaft and third even axial region on the second installation ear, switch door drive assembly accomodate in the second mount pad just includes the fourth even axial region, the third is even axial region and is worn to locate the second via hole and with the fourth is even axial region transmission cooperation, the second back shaft is worn to locate the second supported hole.

Additional aspects and advantages of the utility model will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

Figure 1 is an exploded view of a wind-directing component according to one embodiment of the present invention;

FIG. 2 is an assembly view of the wind-directing component shown in FIG. 1;

FIG. 3 is an exploded view of the wind-directing component shown in FIG. 2;

FIG. 4 is an exploded view of the wind guide drive assembly shown in FIG. 3;

FIG. 5 is an assembled cross-sectional view of the wind directing drive assembly shown in FIG. 4;

FIG. 6 is an exploded view of the wind guide drive assembly shown in FIG. 4;

FIG. 7 is an enlarged view of portion A shown in FIG. 1;

fig. 8 is an assembly view of an air conditioner according to an embodiment of the present invention;

FIG. 9 is an assembly view of the outlet frame, door opening and closing member, and air guide member shown in FIG. 8;

FIG. 10 is an exploded view of the air outlet frame, door opening and closing member and air guide member shown in FIG. 9;

FIG. 11 is an exploded view of the air outlet frame, door opening and closing member, and air guide member shown in FIG. 9 at another angle;

FIG. 12 is an assembled sectional view of the air outlet frame, the door opening and closing member and the air guide member shown in FIG. 9;

FIG. 13 is an angled perspective view of the outlet frame, door opening and closing member, and air guide member shown in FIG. 9;

FIG. 14 is a perspective view of the outlet frame, door opening and closing member, and air guide member shown in FIG. 9 at another angle;

fig. 15 is an exploded view of the air conditioner shown in fig. 8;

fig. 16 is a sectional view of the air conditioner shown in fig. 8.

Reference numerals:

an air conditioner 1000;

a wind guide member 100;

longitudinal direction F1; transverse direction F2;

the first pivot axis L1; the second pivot axis L2; the third pivot axis L3;

an air guide grid 1; a mounting plate 11; a first mounting plate 11 a; a second mounting plate 11 b;

a first link portion 111; the second support hole 112;

air guide ribs 12; support ribs 13; a pivot hole 14;

a louver assembly 2; a louver 21; a pivot shaft 211; a connecting rod 22;

a connector 23; a cartridge holder 231; a box cover 232; a limit rib 233;

an air guide driving assembly 9;

a push shaft 3; a circular shaft section 31; a connecting section 32; a stopper groove 33;

a first drive mechanism 4; a drive gear 41; a driven gear 42;

a gear portion 421; a second connecting shaft portion 422;

a support shaft portion 423; perforations 424;

a second drive mechanism 5; a drive gear 51; a meshing rack 52;

a drive cassette 6; a support shaft hole 61; a first cassette part 62;

a second box portion 63; a first support shaft 64;

a first drive motor 7; a second drive motor 8;

a housing member 200; an air outlet 201; a face frame 202;

a first mount 203; a first via 2031;

a second mount 204; a second via 2041;

a lower panel 205; a top cover 206; a base 207;

a rear box 208; an air inlet 2081;

a door opening and closing part 300; opening and closing the door 301;

a first mounting ear 301 a; the first support hole 3011;

a second mounting ear 301 b; a second support shaft 3012; a third link shaft portion 3013;

a switch door drive assembly 302; a fourth coupling portion 3021;

a heat exchange part 400; a ventilation component 500.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

The following disclosure provides many different embodiments, or examples, for implementing different features of the utility model. To simplify the disclosure of the present invention, the components and arrangements of specific examples are described below. Of course, they are merely examples and are not intended to limit the present invention. Furthermore, the present invention may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed. In addition, the present invention provides examples of various specific processes and materials, but one of ordinary skill in the art may recognize the applicability of other processes and/or the use of other materials.

Next, a wind scooping part 100 according to an embodiment of the first aspect of the present invention will be described with reference to the accompanying drawings.

As shown in fig. 1 to 3, the wind guide part 100 may include: the air guide grille comprises an air guide grille 1, a louver component 2 and an air guide driving component 9. The air guide grille 1 comprises a plurality of air guide ribs 12 extending along the longitudinal direction F1 of the air guide grille 1, and the air guide ribs 12 are arranged at intervals along the transverse direction F2 of the air guide grille 1. That is, the air guide grille 1 comprises a plurality of air guide ribs 12 arranged at intervals in the transverse direction F2 of the air guide grille 1, and each air guide rib 12 extends in the longitudinal direction F1 of the air guide grille 1. This allows ventilation gaps to be formed between adjacent air guide ribs 12, so that an air flow can pass through them. It can be understood that the air guiding ribs 12 have a certain width along the airflow flowing direction, and when the air guiding grille 1 rotates, so that the width extending direction and the air outlet direction present different included angles, the air outlet direction can be changed. For example, the wind outlet direction is horizontal wind outlet, when the width direction F2 of the wind guiding rib 12 forms an upward included angle with the horizontal direction, wind is guided upwards, when the width direction F2 of the wind guiding rib 12 forms a downward included angle with the horizontal direction, wind is guided downwards,

note that the "longitudinal direction F1 of the air guide grille 1" includes: similarly, the "transverse direction F2" of the air guide grille 1 includes: the width direction F2 of the air guide grille 1 and the direction close to the width direction F2 of the air guide grille 1 (that is, the angle between the direction and the width direction F2 of the air guide grille 1 is smaller than the angle between the direction and the length direction of the air guide grille 1).

It should also be noted that, although each air guiding rib 12 extends in the longitudinal direction F1 of the air guiding grille 1, the plurality of air guiding ribs 12 may be parallel (i.e. the plurality of air guiding ribs 12 may extend in the same longitudinal direction F1, for example, each air guiding rib 12 extends in the longitudinal direction of the air guiding grille 1), the plurality of air guiding ribs 12 may also be non-parallel (i.e. the plurality of air guiding ribs 12 may extend in different longitudinal directions F1, for example, some of the plurality of air guiding ribs 12 extend in the longitudinal direction of the air guiding grille 1, and others extend in the direction close to the longitudinal direction of the air guiding grille 1), and so on.

As shown in fig. 1 to 3, the air guide grille 1 has a first pivot axis L1 extending in the longitudinal direction F1 of the air guide grille 1, so that when the air guide grille 1 moves about the first pivot axis L1, the inclination angle of the air guide ribs 12 changes, and thus the air guide direction in the transverse direction F2 of the air guide grille 1 changes. For example, the longitudinal direction F1 of the air guide grille 1 is the left-right direction, the transverse direction F2 of the air guide grille 1 is the up-down direction, and the tilt angle between the air guide ribs 12 and the horizontal plane can be changed by the up-down rotation of the air guide grille 1 about the first pivot axis L1 extending in the left-right direction, so that the air guide angle of the air guide ribs 12 in the up-down direction can be changed, and the air guide outlet direction of the air guide grille 1 in the up-down direction can be changed. For example, if the air guide grille 1 is rotated upward about the first pivot axis L1, the air guide ribs 12 will guide the air upward, whereas if the air guide grille 1 is rotated downward about the first pivot axis L1, the air guide ribs 12 will guide the air downward, and so on.

It should also be mentioned that, although the air guiding ribs 12 extend in the longitudinal direction F1 of the air guiding grille 1 and the first pivot axis L1 also extends in the longitudinal direction F1 of the air guiding grille 1, the air guiding ribs 12 and the first pivot axis L1 may be parallel (i.e. the air guiding ribs 12 and the first pivot axis L1 may extend in the same longitudinal direction F1, for example both the air guiding ribs 12 and the first pivot axis L1 extend in the length direction of the air guiding grille 1), the air guiding ribs 12 and the first pivot axis L1 may also be non-parallel (i.e. the air guiding ribs 12 and the first pivot axis L1 may extend in different longitudinal directions F1, for example one of the air guiding ribs 12 and the first pivot axis L1 extends in the length direction of the air guiding grille 1 and the other extends in a direction close to the length direction of the air guiding grille 1), and so on.

As shown in fig. 1 to 3, the louver assembly 2 comprises a plurality of louvers 21 arranged at intervals along the longitudinal direction F1 of the air guide grille 1, the louvers 21 being pivotally connected to the air guide grille 1 and having a second pivot axis L2 extending along the transverse direction F2 of the air guide grille 1. Therefore, when the louver 21 moves around the second pivot axis L2, the pivot angle of the louver 21 changes, and the wind guiding wind direction in the longitudinal direction F1 of the wind guiding grille 1 changes accordingly. For example, the longitudinal direction F1 of the air guide grille 1 is the left-right direction, the transverse direction F2 of the air guide grille 1 is the up-down direction, and the tilt angle between the louver 21 and the vertical surface can be changed by the left-right rotation of the louver 21 around the two pivot axes extending in the up-down direction, so that the air guide angle of the louver 21 in the left-right direction can be changed, and the air guide wind outlet direction of the louver assembly 2 in the left-right direction can be changed. For example, if the louver 21 is rotated to the left about the second pivot axis L2, the louver 21 will wind to the left, and if the louver 21 is rotated to the right about the second pivot axis L2, the wind-guiding ribs 12 will wind to the right, and so on.

As shown in fig. 1 to 3, the air guiding driving assembly 9 is connected to the air guiding grille 1 and the louver assembly 2 respectively, and is used for driving the air guiding grille 1 to rotate around the first pivot axis L1, and driving the louver 21 to rotate around the second pivot axis L2 relative to the air guiding grille 1. That is, the air guiding driving assembly 9 is not only connected with the air guiding grille 1 for driving the air guiding grille 1 to rotate around the first pivot axis L1, but also the air guiding driving assembly 9 is connected with the louver assembly 2, and the air guiding louver 21 is driven to rotate around the second pivot axis L2 relative to the air guiding grille 1. Specifically, referring to fig. 4, the air guiding driving assembly 9 may include a first driving mechanism 4 and a second driving mechanism 5, the first driving mechanism 4 is connected to the air guiding grille 1 and is used for driving the air guiding grille 1 to rotate around the first pivot axis L1, and the second driving mechanism 5 is connected to the louver assembly 2 and is used for driving the louvers 21 to rotate around the second pivot axis L2 relative to the air guiding grille 1.

Thereby, the first drive mechanism 4 can be used to drive the air guide grille 1 to rotate about the first pivot axis L1, so that air guide adjustment in the transverse direction F2 of the air guide grille 1 is achieved, and the second drive mechanism 5 can be used to drive the louvers 21 to rotate about the second pivot axis L2, so that air guide adjustment in the longitudinal direction F1 of the air guide grille 1 is achieved. For example, the longitudinal direction F1 of the air guide grille 1 is the left-right direction, the transverse direction F2 of the air guide grille 1 is the up-down direction, the air guide driving assembly 9 can be used to drive the air guide grille 1 to rotate up and down around the first pivot axis L1, so that air guide adjustment in the up-down direction can be realized, and the air guide driving assembly 9 can be used to drive the louvers 21 to rotate left and right around the second pivot axis L2, so that air guide adjustment in the left-right direction can be realized.

As shown in fig. 1 to 3, "the louver 21 is pivotally connected to the air guiding grille 1" means that the louver 21 is directly or indirectly connected to the air guiding grille 1, and the louver 21 is rotatable relative to the air guiding grille 1. For example, pivot holes 14 are respectively formed in two sides of the air guide grille 1 in the transverse direction F2, pivot shafts 211 are respectively formed at two ends of the louver 21 in the transverse direction F2 of the air guide grille 1, and the pivot shaft 211 on the corresponding side is inserted into the pivot hole 14 on the corresponding side, so that the louver 21 and the air guide grille 1 are pivotally connected, and meanwhile, the louver 21 can rotate around a second pivot axis L2 extending in the transverse direction F2 of the air guide grille 1 relative to the air guide grille 1. Of course, the present invention is not limited to this, for example, the positions of the pivot shaft 211 and the pivot hole 14 may be interchanged, or the pivot shaft 211 and the pivot hole 14 may be indirectly connected through a rotating bearing, etc., and the details are not described herein.

Therefore, the louver 21 is pivotally connected to the air guide grille 1, so that in the process that the air guide grille 1 rotates around the first pivot axis L1, the louver 21 is driven to rotate around the first pivot axis L1, and thus, the rotation of the air guide grille 1 around the first pivot axis L1 is well adjusted, and on the basis of the air guide angle on the transverse F2 of the air guide grille 1, the louver 21 is further rotated around the second pivot axis L2 to adjust the longitudinal F1 air outlet angle in the current transverse F2 air outlet range, so that a wider range and more accurate air outlet angle adjustment can be presented, and the user requirements are better met. For example, the vertical F1 of wind guide grille 1 is the left and right direction, the horizontal F2 of wind guide grille 1 is the upper and lower direction, on the basis of utilizing wind guide grille 1 to adjust the wind guide angle in the upper and lower direction around the upper and lower rotation of first pivot axis L1, further utilize the tripe 21 to rotate around the left and right sides of second pivot axis L2, adjust the air outlet angle about in current air outlet height range from top to bottom, thereby can realize more extensively, and more accurate air outlet angle adjusts, satisfy user's demand better. In addition, as the louvers 21 are connected with the air guide grille 1, the louvers and the air guide grille can be integrated into a whole, so that the integral assembly and disassembly are convenient, for example, the two louvers do not need to be separately and respectively installed on an equipment carrier (such as an air outlet frame of the air conditioner 1000), the integral assembly and disassembly are simplified, and the design and the processing of the installation structure of the equipment carrier (such as the air outlet frame of the air conditioner 1000) are simplified. And, because the louver 21 is integrated with the air guide grid 1 into a whole, the structural reliability of the whole module is better.

In some embodiments of the present invention, as shown in fig. 1, the air guiding grille 1 may include a plurality of supporting ribs 13 extending along a transverse direction F2 of the air guiding grille 1, and the supporting ribs 13 are arranged at intervals along a longitudinal direction F1 of the air guiding grille 1. Thereby, the air guiding ribs 12 and the supporting ribs 13 can be arranged crosswise to divide the ventilation gap into a plurality of ventilation holes for the air flow to pass through. Therefore, the overall structural strength and reliability of the air guide grille 1 can be improved, and the deformation problem of the air guide ribs 12 can be improved by the connection between the air guide ribs 12 and the support ribs 13, thereby improving the air guide reliability of the air guide ribs 12. It should be noted that, although each of the supporting ribs 13 extends along the transverse direction F2 of the air guiding grille 1, the plurality of supporting ribs 13 may be parallel (i.e. the plurality of supporting ribs 13 may extend along the same transverse direction F2, for example, each of the supporting ribs 13 extends along the width direction F2 of the air guiding grille 1), the plurality of supporting ribs 13 may also be non-parallel (i.e. the plurality of supporting ribs 13 may extend along different transverse directions F2, for example, some of the plurality of supporting ribs 13 extend along the width direction F2 of the air guiding grille 1, and others extend along a direction approaching the width direction F2 of the air guiding grille 1), and so on.

In some embodiments of the present invention, as shown in fig. 3 and 4, the first driving mechanism 4 is directly or indirectly engaged with the second driving mechanism 5, so that the wind guide driving assembly 9 is integrated into one module. The term "the first driving mechanism 4 and the second driving mechanism 5 are directly or indirectly engaged" is to be understood in a broad sense, for example, a part of the first driving mechanism 4 may have an engaging relationship with the second driving mechanism 5, a part of the second driving mechanism 5 may have an engaging relationship with the first driving mechanism 4, a component connected with the first driving mechanism 4 may have an engaging relationship with the second driving mechanism 5, a forest member connected with the second driving mechanism 5 may have an engaging relationship with the first driving mechanism 4, and so on, for example, in the example described later, the push shaft 3 connected with the second driving mechanism 5 is inserted and guided to engage with the driven gear 42 of the first driving mechanism 4. Therefore, as the air guide driving assembly 9 is integrated into a module, the air guide driving assembly 9 can realize the modularized integral installation and disassembly, the assembly efficiency is better, the structural reliability of the air guide driving assembly 9 is better, the structure is more compact, the installation space is more saved, and the air guide part 100 is simpler in structure and more compact in integral structure.

In some embodiments of the present invention, as shown in fig. 3 to 6, the wind guide driving assembly 9 includes a driving case 6, and the first driving mechanism 4 and the second driving mechanism 5 are both accommodated in the driving case 6, so that the wind guide driving assembly 9 is integrated into one module. From this, accomodate first actuating mechanism 4 and second actuating mechanism 5 through setting up drive box 6, can utilize drive box 6 to protect first actuating mechanism 4 and second actuating mechanism 5 to can improve first actuating mechanism 4 and second actuating mechanism 5's operational reliability, and make wind-guiding drive assembly 9 this whole module's whole shock resistance, anti external force nature better, operational reliability is higher. Moreover, as the wind guide driving assembly 9 is integrated into a module, the wind guide driving assembly 9 can realize modularized integral installation and disassembly, the assembly efficiency is better, the structural reliability of the wind guide driving assembly 9 is better, the structure is more compact, the installation space is saved, and the wind guide part 100 is simpler in structure and more compact in integral structure.

Further, the air guide driving assembly 9 comprises a first driving motor 7 and a second driving motor 8, the first driving motor 7 drives the first driving mechanism 4, the second driving motor 8 drives the second driving mechanism 5, and the first driving motor 7 and the second driving motor 8 are both installed outside the driving box 6. From this, can realize automatic control through motor drive, avoid manually operation, moreover, all install first driving motor 7 and second driving motor 8 outside drive box 6, be favorable to the heat dissipation, and can improve wind guide drive assembly 9's compact structure nature. Of course, the present invention is not limited thereto, and in other embodiments of the present invention, at least one of the first driving motor 7 and the second driving motor 8 may be omitted, and the driving may be performed manually, which is not described herein.

When both the first drive mechanism 4 and the second drive mechanism 5 are housed in the drive cassette 6, the first drive mechanism 4 and the second drive mechanism 5 may or may not have a fitting relationship with each other. When the first driving mechanism 4 and the second driving mechanism 5 are engaged with each other, both the first driving mechanism 4 and the second driving mechanism 5 may be accommodated in the drive cassette 6, one of them may be accommodated in the drive cassette 6, or neither of them may be accommodated in the drive cassette 6. However, in these methods, the air guide driving assembly 9 may be integrated into one module.

Alternatively, when the air guide driving assembly 9 is integrated into a module, for example, the first driving mechanism 4 and the second driving mechanism 5 are matched with each other, and/or when the first driving mechanism 4 and the second driving mechanism 5 are both accommodated in the driving box 6, the air guide driving assembly 9 may be disposed at one end of the air guide grille 1 in the longitudinal direction F1, for example, the longitudinal direction F1 of the grille is the left-right direction, and the air guide driving assembly 9 may be disposed at the left end or the right end of the air guide grille 1. Therefore, compared with the arrangement of the air guide driving component 9 in the middle of the longitudinal F1 of the air guide grille 1, the air guide driving component 9 can be prevented from blocking ventilation to the greatest extent, the ventilation quantity and the ventilation effect are influenced, and the arrangement of the air guide driving component 9 at the end part of the longitudinal F1 is more convenient for the connection of the air guide driving component 9 with the louver component 2 and the air guide grille 1. In addition, the air guide driving assembly 9 can be located at one end of the air guide grille 1 in the longitudinal direction F1, so that a space can be reserved at the other end of the air guide grille 1 in the longitudinal direction F1, and other assemblies, such as a door opening and closing driving assembly 302 and the like, can be arranged, and the overall structure of an equipment carrier (such as an air conditioner 1000) applied by the air guide component 100 is more compact.

In some embodiments of the present invention, as shown in fig. 1, the two ends of the air guiding grille 1 in the longitudinal direction F1 are respectively provided with a mounting plate 11, at least one mounting plate 11 is formed with a first connecting shaft portion 111, and in combination with fig. 4, the first driving mechanism 4 includes a driving gear 41 and a driven gear 42 which are in meshing transmission, the driven gear 42 includes a gear portion 421 and a second connecting shaft portion 422 which are arranged along the axial direction, that is, the gear portion 421 and the second connecting shaft portion 422 are arranged along the axial direction, and the second connecting shaft portion 422 is in transmission fit with the first connecting shaft portion 111. That is, the driven gear 42 includes a gear portion 421 engaged with the driving gear 41, and a second connecting shaft portion 422 in transmission connection with the first connecting shaft portion 111, when the driving gear 41 drives the gear portion 421 of the driven gear 42 to rotate, the gear portion 421 of the driven gear 42 drives the second connecting shaft portion 422 to rotate, and during the rotation of the second connecting shaft portion 422, the gear portion is transmitted to the first connecting shaft portion 111 to drive the wind guide grille 1 to rotate around the first pivot axis L1. Thus, the first driving mechanism 4 has a simple and compact structure, and can simply and efficiently drive the air guide grille 1 to rotate.

Alternatively, the gear portion 421 and the second connecting shaft portion 422 may be coaxially disposed, so that the rotation axis of the gear portion 421 is the first pivot axis L1 of the air guide grille 1, thereby simplifying the design and reducing the rotation space required for the air guide grille 1.

Optionally, as shown in fig. 4, the air guiding driving assembly 9 may further include a first driving motor 7, the first driving motor 7 may be configured to drive the driving gear 41 to rotate, and when the first driving motor 7 is directly or indirectly fixedly mounted on the equipment carrier (e.g., the air outlet frame of the air conditioner 1000), the first driving motor 7 operates to drive the air guiding grille 1 to rotate around the first pivot axis L1 relative to the equipment carrier (e.g., the air outlet frame of the air conditioner 1000) through cooperation of the driving gear 41 and the driven gear 42. Therefore, motor driving can be realized, manual adjustment is not needed, and automation is stronger.

In some embodiments of the present invention, as shown in fig. 1, one of the first connecting shaft portion 111 and the second connecting shaft portion 422 is a connecting shaft, and the other is a connecting hole, and the connecting shaft is inserted into the connecting hole and transmits torque through a non-circular surface fit. That is to say, the cross section of the connecting shaft is a non-circular surface, such as a polygon, or an ellipse, or a special shape, etc., and the cross section of the connecting hole is matched with the cross section of the connecting shaft, so that the connecting shaft can be inserted into the connecting hole, and the non-circular surface is matched with the connecting hole to transmit torque, so that the driven gear 42 can drive the air guide grille 1 to synchronously rotate. Therefore, the driven gear 42 and the air guide grid 1 are relatively simple in structure, convenient to process and assemble, few in parts and low in cost. Of course, the present invention is not limited to this, and in other embodiments of the present invention, the driven gear 42 and the air guiding grille 1 may be connected by another device such as a coupler, so as to realize transmission of the rotation torque, which is not described herein again.

For example, in the specific example shown in fig. 3 and 4, the first connecting shaft portion 111 on the air guide grille 1 is a polygonal connecting hole, the second connecting shaft portion 422 on the driven gear 42 is a prismatic connecting shaft, and the second connecting shaft portion 422 is in transmission fit with the first connecting shaft portion 111 through matching insertion of a prismatic surface and the polygonal hole, so that the first driving motor 7 is realized, and the air guide grille 1 is driven to rotate through the fit of the driving gear 41 and the driven gear 42.

In some embodiments of the present invention, as shown in fig. 4 to 6, the wind guide driving assembly 9 further includes a driving case 6, the driving case 6 includes a supporting shaft hole 61, the driven gear 42 includes a supporting shaft portion 423, the supporting shaft portion 423 is located between the gear portion 421 and the second connecting shaft portion 422, the supporting shaft portion 423 is rotatably supported in the supporting shaft hole 61, the gear portion 421 is located in the driving case 6, and the second connecting shaft portion 422 is located outside the driving case 6. Therefore, the gear portion 421 of the driven gear 42 can be protected by the driving box 6, the driven gear 42 is supported to stably rotate, the working stability and reliability of the first driving mechanism 4 are improved, the supporting shaft portion 423 is arranged between the gear portion 421 and the second connecting shaft portion 422, and the second connecting shaft portion 422 can be positioned outside the driving box 6 on the premise that the gear portion 421 is positioned in the driving box 6, so that the second connecting shaft portion 422 can be conveniently connected with the first connecting shaft portion 111 on the air guide grille 1.

Further, the driving gear 41 may be provided in the drive case 6, so that the operational stability and reliability of the first driving mechanism 4 can be further improved. In addition, at least a part of the second driving mechanism 5, for example, at least a part of the drive gear 51, the meshing rack 52, and the push shaft 3 described later may be provided in the drive cassette 6, so that the operational stability and reliability of the second driving mechanism 5 can be improved. Alternatively, to facilitate assembly of the drive cartridge 6 with its internal components, the drive cartridge 6 may be provided in an openable form, for example, in the example shown in fig. 4, the drive cartridge 6 may include a first cartridge part 62 and a second cartridge part 63, the first cartridge part 62 and the second cartridge part 63 being detachably connected and together defining a receiving cavity, thereby facilitating assembly and design.

In some embodiments of the present invention, as shown in fig. 3 and 4, the driven gear 42 has a through hole 424 penetrating in an axial direction, so that the through hole 424 may penetrate through the gear portion 421 and the second connecting shaft portion 422, the louver assembly 2 further includes a connecting rod 22 extending in the longitudinal direction F1 of the air guide grille 1, the connecting rod 22 is pivotally connected to each louver 21, the air guide driving assembly 9 includes a pushing shaft 3 connecting the second driving mechanism 5 and the connecting rod 22, the pushing shaft 3 is disposed through the through hole 424 to reciprocate in the axial direction of the through hole 424 to push the connecting rod 22 to reciprocate in the longitudinal direction F1 of the air guide grille 1, so that the pushing shaft 3 is moved by pushing the connecting rod 22, so that the connecting rod 22 can pull each louver 21 to rotate around the second pivot axis L2 relative to the air guide grille 1. From this, can utilize driven gear 42 to play the effect of direction to the push rod, guarantee the motion stability of push shaft 3 to, through being connected of push rod and driven gear 42, make first actuating mechanism 4 and the indirect cooperation of second actuating mechanism 5, so that wind-guiding drive assembly 9 is integrated as a module, improve wind-guiding drive assembly 9's compact structure nature, simplify overall structure design, reduce cost.

Alternatively, for example, in the specific example shown in fig. 4 and 5, the through hole 424 may be a circular hole, and the push shaft 3 may include a circular shaft section 31, and the circular shaft section 31 is disposed through the circular hole to reciprocate along the axial direction of the circular hole, and the circular shaft section 31 is supported by the circular through hole to perform an effective guiding and supporting function.

Further, as shown in fig. 4 and 5, the second driving mechanism 5 may include a driving gear 51 and a meshing rack 52, the meshing rack 52 is connected to the pushing shaft 3, when the driving gear 51 rotates, the meshing rack 52 may be pushed to reciprocate, the meshing rack 52 is connected to the pushing shaft 3 to drive the pushing shaft 3 to reciprocate, and the pushing shaft 3 drives the connecting rod 22 to reciprocate during the movement process, so as to realize the rotation driving of the louver 21. Thus, the second driving mechanism 5 has a simple structure and high operational reliability. The connection manner of the engaging rack 52 and the pushing shaft 3 is not limited, and may be an assembly connection, an integral molding, or the like. In addition, the structural shape of the engaging rack 52 is not limited, and the cross section may be cylindrical or polygonal, and the like, and may be specifically set according to actual requirements.

Alternatively, as shown in fig. 4, the air guiding driving assembly 9 may further include a second driving motor 8, the second driving motor 8 may be configured to drive the driving gear 51 to rotate, and when the second driving motor 8 is directly or indirectly fixedly mounted on the equipment carrier (e.g., the air outlet frame of the air conditioner 1000), the second driving motor 8 is operated to drive the louver 21 to rotate around the second pivot axis L2 relative to the air guiding grille 1 through cooperation between the driving gear 51 and the engaging rack 52. Therefore, motor driving can be realized, manual adjustment is not needed, and automation is stronger.

In some embodiments, as shown in fig. 1 and 7, a connector 23 is provided at one end of the length of the connecting rod 22, the pushing shaft 3 includes a connecting section 32 extending into the connector 23, a connecting cavity is formed in the connector 23, the pushing shaft 3 includes the connecting section 32 extending into the connecting cavity, and the connector 23 and the connecting section 32 are in limit fit through a limit structure so as to limit the connecting section 32 from coming out of the connector 23 along the longitudinal direction F1 of the air guide grille 1. Thereby, the connection of the push shaft 3 and the link 22 can be simply and efficiently achieved.

It should be noted that the specific structure of the limiting structure is not limited, for example, in some specific examples, as shown in fig. 1 and 7, one of the connecting cavity and the connecting section 32 is formed with a limiting rib 233, the other is formed with a limiting groove 33, and the limiting rib 233 is in limiting fit with the limiting groove 33, so as to limit the connecting section 32 from coming out of the connecting cavity. Therefore, the limiting mode is simple, and the limiting structure is easy to process. For example, the connecting section 32 of the push shaft 3 may be provided as a stepped shaft formed with a stopper groove 33, in particular, thereby facilitating processing and manufacturing. In addition, in order to conveniently extend the connecting section 32 into the connector 23, the connector 23 may be configured to include a box cover 232 and a box base 231, a connecting cavity and a limiting rib 233 are processed in the box base 231, the box cover 232 is used for opening and closing the box base 231, so that the processing and the assembly are convenient, and in addition, the limiting rib 233 may also be processed on the box cover 232, so that the limiting reliability is improved.

An air conditioner 1000 according to an embodiment of the second aspect of the present invention is described below with reference to the accompanying drawings.

As shown in fig. 8, the air conditioner 1000 may include: the casing member 200 has an air outlet 201, and the air guiding member 100 is disposed at the air outlet 201 and is the air guiding member 100 according to the embodiment of the first aspect of the present invention. Thus, the air guide member 100 can adjust the air outlet direction at the air outlet 201. For example, the length direction of the outlet 201 is the left-right direction, the width direction F2 is the up-down direction, the longitudinal direction F1 of the air guide grille 1 is the left-right direction, and the lateral direction F2 is the up-down direction, so that the air guide grille 1 can be driven by the first drive mechanism 4 to rotate up and down about the first pivot axis L1, thereby achieving air guide adjustment in the up-down direction of the air guide grille 1, and the louvers 21 can be driven by the second drive mechanism 5 to rotate left and right about the second pivot axis L2, thereby achieving air guide adjustment in the left-right direction of the air guide grille 1.

Thus, by providing the air guide member 100, since the louver 21 is pivotally connected to the air guide grille 1, the louver 21 is driven to rotate around the first pivot axis L1 during the rotation of the air guide grille 1 around the first pivot axis L1, so that the air guide grille 1 is adjusted by the rotation around the first pivot axis L1, and on the basis of the air guide angle on the transverse F2 of the air guide grille 1, the air conditioner 1000 according to the embodiment of the second aspect of the present invention further adjusts the air outlet angle in the longitudinal direction F1 within the air outlet range of the current transverse direction F2 by the rotation around the second pivot axis L2, so that a wider range and more accurate air outlet angle adjustment can be presented, and user requirements can be better met. For example, the vertical F1 of wind guide grille 1 is the left and right direction, the horizontal F2 of wind guide grille 1 is the upper and lower direction, on the basis of utilizing wind guide grille 1 to adjust the wind guide angle in the upper and lower direction around the upper and lower rotation of first pivot axis L1, further utilize the tripe 21 to rotate around the left and right sides of second pivot axis L2, adjust the air outlet angle about in current air outlet height range from top to bottom, thereby can realize more extensively, and more accurate air outlet angle adjusts, satisfy user's demand better. In addition, as the louvers 21 are connected with the air guide grille 1, the louvers and the air guide grille can be integrated into a whole, so that the integral assembly and disassembly are convenient, for example, the two louvers do not need to be separately and respectively installed on an equipment carrier (such as an air outlet frame of the air conditioner 1000), the integral assembly and disassembly are simplified, and the design and the processing of the installation structure of the equipment carrier (such as the air outlet frame of the air conditioner 1000) are simplified. And, because the louver 21 is integrated with the air guide grid 1 into a whole, the structural reliability of the whole module is better.

It should be noted that the number of the air outlets 201 is not limited, for example, the number of the air outlets 201 is one or more, and when the number of the air outlets 201 is multiple, one air guiding component 100 may be respectively disposed at each air outlet 201. For example, in the example shown in fig. 8, the length direction of the air outlet 201 is a left-right direction, the width direction F2 is an up-down direction, two air outlets 201 are provided at the upper part of the front surface of the housing member 200, the two air outlets 201 are arranged at intervals along the up-down direction, and one air guiding member 100 is provided at each air outlet 201 to adjust the air outlet direction of each air outlet 201, for example, both air outlets 201 may be towards the front air outlet 201, or both air outlets may be towards the down direction, or both air outlets may be towards the up direction; for another example, the air outlet 201 on the upper side can be used for discharging air downwards, and the air outlet 201 on the lower side can be used for discharging air upwards; for example, the upper air outlet 201 may be used to discharge air upwards, and the lower air outlet 201 may be used to discharge air downwards, and so on, which are not described herein again.

Of course, the present invention is not limited thereto, and the wind guide component 100 according to the embodiment of the present invention is not limited to be applied to the air conditioner 1000, for example, other devices with a wind blowing function may also be provided, such as an air purifier, a humidifier, and the like, which are not described herein again.

In some embodiments of the present invention, as shown in fig. 9 and 10, the air conditioner 1000 further includes a door opening and closing component 300, the door opening and closing component 300 includes a door opening and closing 301 and a door opening and closing driving component 302, the door opening and closing driving component 302 drives the door opening and closing 301 to rotate at the air outlet 201 to open and close the air outlet 201, a first mounting seat 203 and a second mounting seat 204 are respectively arranged in the housing component 200 at two sides of the length of the air outlet 201, when the air guiding driving component 9 is arranged at one end of the air guiding grille 1 in the longitudinal direction F1, the air guiding driving component 9 is mounted on the first mounting seat 203, and the door opening and closing driving component 302 is mounted on the second mounting seat 204. Therefore, the overall structure layout is more compact, and the assembly is more convenient and simpler.

In the specific example shown in fig. 9 to 11, for example, the air guide grille 1 can be a grille-like curved panel on the one hand and the first pivot axis L1 passes through the center of the arc of the air guide grille 1, so that the form of construction of the air guide grille 1 requires less space when it is rotated. The first pivot axis L1 may be located in the housing member 200, so that the air guide grille 1 may be integrally received in the housing member 200 to rotate. On the other hand, the length direction of the switch door 301 is the same as the length direction of the air outlet 201, the switch door 301 is an arc panel and has a third pivot axis L3, the third pivot axis L3 passes through the arc center of the switch door 301, the third pivot axis L3 is located in the housing member 200, so that the switch door 301 opens the air outlet 201 by rotating towards the inside of the housing member 200 (for example, the state shown in fig. 8), and when the switch door 301 closes the air outlet 201, the switch door 301 is located outside the air guiding grille 1 (for example, the state shown in fig. 9). The door 301 is thus constructed in such a way that it requires less space when it is rotated.

Optionally, the housing member 200 includes a face frame 202, the air outlet 201 is formed on the face frame 202, and the inside of the face frame 202 is provided with a first mounting seat 203 and a second mounting seat 204 respectively located at both sides of the length of the air outlet 201. Thus, the housing member 200 has a simple structure and is easy to process.

In some embodiments of the present invention, the length direction of the switch door 301 and the length direction of the air guiding grille 1 are both the same as the length direction of the air outlet 201, for example, both the left and right directions, as shown in fig. 11, a first mounting plate 11a and a second mounting plate 11b are respectively disposed at both ends of the length of the air guiding grille 1, a first mounting lug 301a and a second mounting lug 301b are respectively disposed at both ends of the length of the switch door 301, and referring to fig. 12, the first mounting lug 301a is located between the first mounting plate 11a and the first mounting seat 203, and the second mounting lug 301b is located between the second mounting plate 11b and the second mounting seat 204.

As shown in fig. 11 and 12, a first through hole 2031 is provided on the first mounting base 203, a first support hole 3011 is formed on the first mounting lug 301a, a first axle portion 111 is provided on the first mounting plate 11a, the wind guide driving component 9 includes a first support shaft 64 and a second axle portion 422, the wind guide driving component 9 is accommodated in the first mounting base 203 (as shown in fig. 13), the second axle portion 422 is located outside the first mounting base 203 and is in transmission fit with the first axle portion 111, the first support shaft 64 penetrates through the first through hole 2031 and the first support hole 3011, thereby the first mounting lug 301a on the switch door 301 can be rotated by being sleeved on the first support shaft 64 of the wind guide driving component 9 through the first support hole 3011.

Alternatively, referring to fig. 4, when the wind guide driving assembly 9 includes the above-described driving case 6, the first support shaft 64 may be formed on the driving case 6, thereby facilitating the processing, and in addition, when the driving case 6 includes the above-described support shaft hole, the support shaft hole may penetrate the first support shaft 64, thereby simplifying the structure and the assembly. In addition, the manner of the transmission fit between the second connecting shaft portion 422 and the first connecting shaft portion 111 can refer to the above description, and is not described herein again.

As shown in fig. 11 and 12, a second through hole 2041 is formed in the second mounting plate 204, a second support hole 112 is formed in the second mounting plate 11b, a second support shaft 3012 and a third connecting shaft 3013 are formed in the second mounting lug 301b, the door opening/closing driving assembly 302 is received in the second mounting plate 204 (see fig. 14), the door opening/closing driving assembly 302 includes a fourth connecting shaft 3021, the third connecting shaft 3013 is inserted into the second through hole 2041 and is in transmission fit with the fourth connecting shaft 3021, and the second support shaft 3012 is inserted into the second support hole 112, so that the second mounting plate 11b on the air guide grille 1 can be sleeved on the second support shaft 3012 on the door opening/closing 301 through the second support hole 112 to rotate.

Thus, one end (e.g., the right end shown in fig. 12) of the air guide grille 1 corresponding to the first mounting seat 203 is driven by the air guide driving component 9 mounted on the first mounting seat 203, one end (e.g., the left end shown in fig. 12) of the air guide grille 1 corresponding to the second mounting seat 204 is rotatably supported by the second support shaft 3012 on the opening/closing door 301, one end (e.g., the left end shown in fig. 12) of the opening/closing door 301 corresponding to the second mounting seat 204 is driven by the opening/closing door driving component 302 mounted on the second mounting seat 204, and one end (e.g., the right end shown in fig. 12) of the opening/closing door 301 corresponding to the first mounting seat 203 is rotatably supported by the first support shaft 64 on the air guide driving component 9, which is very skillful and compact in design.

Of course, the present invention is not limited thereto, for example, in other embodiments of the present invention, an end of the switch door 301 corresponding to the first mounting seat 203 may not be rotatably supported on the first supporting shaft 64 on the wind guide driving assembly 9, for example, a hollow shaft or other first supporting holes 3011 for supporting the switch door 301 may be disposed on the wind outlet frame, and so on, which are not described herein again.

An air conditioner 1000 according to an embodiment of the present invention will be described with reference to fig. 1 to 16.

The air conditioner 1000 is a split floor type air conditioner, and includes a case member 200, an air guide member 100, a door opening and closing member 300, a heat exchange member 400, and a ventilation member 500. The housing part 200 may include: air-out frame, lower panel 205, top cap 206, base 207, back box 208. The air-out frame and the lower panel 205 are both arranged on the front side of the rear box body 208, the top cover 206 is arranged on the top of the rear box body 208, the base 207 is arranged at the bottom of the rear box body 208, the air-out frame is arranged above the lower panel 205, two air outlets 201 are formed in the air-out frame and are arranged at intervals up and down, the length direction of each air outlet 201 is the left-right direction, and air inlets 2081 are respectively arranged on the left side and the right side of the lower portion of the rear box body 208. The heat exchange part 400 and the ventilation part 500 are arranged in the rear box body 208, the heat exchange part 400 is located above the ventilation part 500, the heat exchange part 400 comprises a heat exchanger, the ventilation part 500 comprises a centrifugal fan, the heat exchanger extends forwards from top to bottom in an inclined mode, the centrifugal fan supplies air from air inlets 2081 on the left side and the right side and supplies air upwards to the rear side of the heat exchanger, and air flow forwards penetrates through the heat exchanger and forwards flows out from an air outlet 201 on an air outlet frame.

Every air outlet 201 punishment is equipped with a wind-guiding part 100 and a switch door part 300 respectively, and switch door part 300 includes switch door 301, and wind-guiding part 100 includes air guide grid 1, and the length direction of switch door 301, the length direction of air guide grid 1 all are the same with the length direction of air outlet 201, and all are left right direction. The wind guide member 100 includes: air guide grid 1, shutter assembly 2 and wind guide drive assembly 9, air guide grid 1 includes the wind guide rib 12 that extends along the vertical F1 of air guide grid 1, wind guide rib 12 is a plurality of and sets up along the horizontal F2 interval of air guide grid 1, air guide grid 1 has the first pivot axis L1 that extends along the vertical F1 of air guide grid 1, air guide grid 1 is grid form arc panel, and the arc centre of a circle of air guide grid 1 is crossed to first pivot axis L1. The louver assembly 2 comprises a plurality of louvers 21 spaced along a longitudinal direction F1 of the air guide grille 1, the louvers 21 are pivotally connected to the air guide grille 1 and have a second pivot axis L2 extending along a transverse direction F2 of the air guide grille 1, the air guide driving assembly 9 comprises a first driving mechanism 4 and a second driving mechanism 5, the first driving mechanism 4 is connected with the air guide grille 1 and is used for driving the air guide grille 1 to rotate around a first pivot axis L1, and the second driving mechanism 5 is connected with the louver assembly 2 and is used for driving the louvers 21 to rotate around a second pivot axis L2 relative to the air guide grille 1.

The air guide driving component 9 is integrated into a module and is arranged at one end of the air guide grid 1 in the longitudinal direction F1. Wind-guiding drive assembly 9 includes drive box 6, push away axle 3, first driving motor 7 and second driving motor 8, first actuating mechanism 4 and second actuating mechanism 5 are all accomodate in drive box 6, first actuating mechanism 4 and second actuating mechanism 5 are through pushing away the cooperation of axle 3, first driving motor 7 drives first actuating mechanism 4, second driving motor 8 drives second actuating mechanism 5, first driving motor 7 and second driving motor 8 are all installed outside drive box 6.

The vertical F1 both ends of air guide grid 1 are equipped with these two mounting panels 11 of first mounting panel 11a and second mounting panel 11b respectively, be formed with first axle part 111 on the first mounting panel 11a, first axle part 111 is the connecting hole, first actuating mechanism 4 is including meshing driven driving gear 41 and driven gear 42, driven gear 42 is including linking axle part 422 along gear portion 421 and the second of axial setting, axle part 422 is the connecting axle even to the second, the connecting axle is inserted and is joined in marriage in the connecting hole, and through the non-circular face cooperation transmission moment of torsion, in order to realize that second links axle part 422 and first axle part 111 transmission cooperation. The drive case 6 includes a support shaft hole 61, the driven gear 42 includes a support shaft portion 423, the support shaft portion 423 is located between the gear portion 421 and the second coupling shaft portion 422, the support shaft portion 423 is rotatably supported in the support shaft hole 61, the gear portion 421 is located in the drive case 6, and the second coupling shaft portion 422 is located outside the drive case 6.

The driven gear 42 is provided with a through hole 424 penetrating along the axial direction, the louver assembly 2 further comprises a connecting rod 22 extending along the longitudinal direction F1 of the air guide grille 1, the connecting rod 22 is pivotally connected with each louver 21, the air guide driving assembly 9 comprises a pushing shaft 3 connecting the second driving mechanism 5 and the connecting rod 22, and the pushing shaft 3 is arranged through the through hole 424 to reciprocate along the axial direction of the through hole 424 so as to push the connecting rod 22 to reciprocate along the longitudinal direction F1 of the air guide grille 1. The second driving mechanism 5 comprises a driving gear 51 and a meshing rack 52 which are in meshing transmission, and the meshing rack 52 is connected with the push shaft 3. The connecting rod 22 is provided with a connector 23 at one end of the length thereof, the push shaft 3 comprises a connecting section 32 extending into the connector 23, and the connector 23 is in limit fit with the connecting section 32 through a limit structure so as to limit the connecting section 32 to be pulled out of the connector 23 along the longitudinal direction F1 of the air guide grille 1.

The door opening and closing part 300 includes an opening and closing door 301 and an opening and closing door driving assembly 302, and the opening and closing door driving assembly 302 drives the opening and closing door 301 to rotate at the outlet 201 to open and close the outlet 201. The switch door 301 is an arc panel and has a third pivot axis L3, the third pivot axis L3 passes through the arc center of the switch door 301, the third pivot axis L3 is located in the housing component 200, so that the switch door 301 opens the air outlet 201 by rotating towards the inside of the housing component 200, and when the switch door 301 closes the air outlet 201, the switch door 301 is located at the outer side of the air guiding grille 1.

The inner side of the air outlet frame is provided with a first mounting seat 203 and a second mounting seat 204 which are respectively positioned at the left side and the right side of the air outlet 201, the air guide driving assembly 9 is installed on the first mounting seat 203, and the door opening and closing driving assembly 302 is installed on the second mounting seat 204. Specifically, a first mounting plate 11a and a second mounting plate 11b are respectively arranged at two ends of the length of the air guide grille 1, a first mounting lug 301a and a second mounting lug 301b are respectively arranged at two ends of the length of the switch door 301, the first mounting lug 301a is located between the first mounting plate 11a and the first mounting seat 203, the second mounting lug 301b is located between the second mounting plate 11b and the second mounting seat 204, a first through hole 2031 is arranged on the first mounting seat 203, a first support hole 3011 is formed on the first mounting lug 301a, a first connecting shaft 111 is arranged on the first mounting plate 11a, the drive box 6 of the air guide drive assembly 9 further comprises a first support shaft 64, the support shaft hole 61 penetrates through the first support shaft 64, the air guide drive assembly 9 is accommodated in the first mounting seat 203, the first connecting shaft 111 is located outside the mounting seat and is in transmission fit with the second connecting shaft 422, the first support shaft 64 penetrates through the first through hole 2031 and the first support hole 3011, the second mounting seat 204 is provided with a second via hole 2041, the second mounting lug 301b is provided with a door opening/closing driving component 302 and a second support shaft 3012, the second mounting plate 11b is provided with a second support hole 112, the door opening/closing driving component 302 is accommodated in the second mounting seat 204, and the second support shaft 3012 penetrates through the second support hole 112.

The above-mentioned split floor type air conditioner will be further detailed and schematically described below.

The split floor type air conditioner 1000 comprises a shell part 200, a heat exchange part 400 is arranged in a rear box 208 of the shell part 200 and is positioned at the upper part in the shell part 200, a ventilation part 500 is also arranged in the rear box 208 and is positioned below the heat exchange part 400, air duct air inlets 2081 are respectively arranged on the left side surface and the right side surface of the ventilation part 500 and are arranged corresponding to the air inlets 2081 on the left side surface and the right side surface of the ventilation part 500, and air inlet grids are respectively arranged at the air inlets 2081 on the left side surface and the right side surface of the rear box 208. The lower panel 205 and the air outlet frame of the casing member 200 are both installed on the front side of the rear box 208, the air outlet frame is provided with an air outlet 201, the air outlet 201 is provided with a switch door 301 for opening or closing the air outlet 201, an air guiding member 100 is further arranged at a position corresponding to the air outlet 201, the switch door 301 and the air guiding member 100 are both installed on the air outlet frame, the air outlet frame can be provided with an upper panel or be an integrated piece with the upper panel, and air after heat exchange of the heat exchange member 400 changes the wind direction through the air guiding member 100 and is blown into a room. The top cover 206 is positioned on the top of the rear cabinet 208 to enclose the upper portion of the split floor type air conditioner 1000, and the base 207 is positioned on the bottom of the rear cabinet 208 to support the split floor type air conditioner 1000.

The left and right sides of air outlet 201 in the air-out frame is provided with first mount pad 203 and second mount pad 204 respectively, defines drive assembly's holding chamber, and second mount pad 204 is used for holding the rotatory switch door drive assembly 302 of drive switch door 301, and second mount pad 204 is used for holding the rotatory and drive tripe 21 wobbling wind guide drive assembly 9 of drive wind-guiding grid 1. The opening and closing door 301 is driven to rotate by the opening and closing door driving component 302, so as to open and close the air outlet 201. The air guiding component 100 comprises an air guiding grille 1, louver assemblies 2 and an air guiding driving assembly 9, wherein the air guiding grille 1 can rotate around a first pivot axis L1 extending along the left-right direction under the driving of the air guiding driving assembly 9 to realize up-down air guiding, the louver assemblies 2 are assembled on the air guiding grille 1 and rotate up and down around a first pivot axis L1 together with the air guiding grille 1, the louver 21 is provided with a second pivot axis L2 extending along the up-down direction, the louver 21 can rotate left and right around a second pivot axis L2 to realize left-right swinging air guiding, and the plurality of louvers 21 are connected through connecting rods 22 to realize linkage.

The air guide driving assembly 9 comprises a driving box 6, a first driving mechanism 4, a second driving mechanism 5, a first driving motor 7, a second driving motor 8 and a pushing shaft 3, wherein the first driving mechanism 4 comprises a driving gear 41 and a driven gear 42, and the second driving mechanism 5 comprises a driving gear 51 and a meshing rack 52. Wherein the driving gear 41, the driven gear 42, the driving gear 51 and the meshing rack 52 are all assembled in the driving box 6, and the first driving motor 7 and the second driving motor 8 are all assembled outside the driving box 6. The first driving motor 7 drives the driving gear 41 to rotate, so as to drive the driven gear 42 to rotate, one end of the driven gear 42 comprises a gear part 421, the other end of the driven gear 42 comprises a second connecting shaft part 422 with a prism structure, the prism surface of the second connecting shaft part 422 is in transmission fit with the first connecting shaft part 111 in the form of a corresponding polygon hole arranged on the wind guide grid 1, so as to drive the wind guide grid 1 to rotate, a supporting shaft part 423 with a cylindrical structure is arranged between the gear part 421 and the second connecting shaft part 422, so as to connect the gear part 421 and the second connecting shaft part 422, and the supporting shaft part 423 with the cylindrical structure is assembled at the supporting shaft hole 61 on the driving box 6.

The second drive motor 8 drives the drive gear 51 to rotate, so that the drive gear 51 drives the meshing rack 52 to move in the axial direction. The one end of meshing rack 52 is connected for pushing away axle 3, it includes circle axle section 31 and linkage segment 32 to push away axle 3, circle axle section 31 is connected between linkage segment 32 and meshing rack 52, linkage segment 32 is the step shaft structure, connecting rod 22 one end is passed through connector 23 and is connected with the linkage segment 32 of step shaft structure, spacing muscle 233 screens epaxial spacing groove 33 of ladder through in the connector 23, when meshing rack 52 along axis reciprocating motion, drive connecting rod 22 through pushing away axle 3 and connector 23 and remove, thereby drive a plurality of tripe 21 synchronous oscillation, realize controlling the wind-guiding. The connector 23 comprises a box seat 231 and a box cover 232, the box seat 231 and the box cover 232 are both provided with limiting ribs 233, a stepped shaft of the push shaft 3 extends into the box seat 231, a limiting groove 33 on the stepped shaft is clamped by the limiting ribs 233 on the box seat 231 and the box cover 232, and the meshing rack 52 can drive the connector 23 to move when moving along the axis. The opening and closing door 301 has one end connected to the opening and closing door driving assembly 302 and the other end rotatably supported on the first support shaft 64 of the driving box 6, and the circular shaft section 31 of the push shaft 3 passes through the circular through hole 424 of the driven gear 42 to be supported by the circular through hole 424 and can move in the axial direction of the through hole 424.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

While embodiments of the utility model have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the utility model, the scope of which is defined by the claims and their equivalents.

Claims (15)

1. A wind-directing component, comprising:

the air guide grid comprises a plurality of air guide ribs extending along the longitudinal direction of the air guide grid, the air guide ribs are arranged at intervals along the transverse direction of the air guide grid, and the air guide grid is provided with a first pivot axis extending along the longitudinal direction of the air guide grid;

a louver assembly including a plurality of louvers spaced apart along a longitudinal direction of the air deflection grille, the louvers being pivotally connected to the air deflection grille and having a second pivot axis extending along a transverse direction of the air deflection grille;

wind guide drive assembly, wind guide drive assembly includes first actuating mechanism and second actuating mechanism, first actuating mechanism with the wind-guiding grid links to each other, and is used for the drive the wind-guiding grid winds first pivot axis rotates, second actuating mechanism with the tripe subassembly links to each other, and is used for the drive the tripe is relative the wind-guiding grid winds the second pivot axis rotates.

2. The wind scooper of claim 1, wherein the first drive mechanism and the second drive mechanism cooperate directly or indirectly to integrate the wind directing drive assembly into a module.

3. The wind guide component of claim 1, wherein the wind guide driving assembly comprises a driving box, and the first driving mechanism and the second driving mechanism are received in the driving box, so that the wind guide driving assembly is integrated into a module.

4. The wind guide component of claim 3, wherein the wind guide driving assembly comprises a first driving motor and a second driving motor, the first driving motor drives the first driving mechanism, the second driving motor drives the second driving mechanism, and the first driving motor and the second driving motor are both mounted outside the drive box.

5. The wind guide component according to any one of claims 1 to 4, wherein the wind guide driving assembly is provided at one longitudinal end of the wind guide grille.

6. The wind guide component according to claim 1, wherein mounting plates are respectively disposed at two longitudinal ends of the wind guide grille, a first connecting shaft portion is formed on at least one of the mounting plates, the first driving mechanism comprises a driving gear and a driven gear which are in meshing transmission, the driven gear comprises a gear portion and a second connecting shaft portion which are axially disposed, and the second connecting shaft portion is in transmission fit with the first connecting shaft portion.

7. The wind guide component of claim 6, wherein one of the first connecting shaft portion and the second connecting shaft portion is a connecting shaft, the other one of the first connecting shaft portion and the second connecting shaft portion is a connecting hole, and the connecting shaft is inserted into the connecting hole and is matched with the connecting hole through a non-circular surface to transmit torque.

8. The wind guide assembly of claim 6 further comprising a drive cassette including a support shaft hole, the driven gear including a support shaft portion between the gear portion and the second coupling portion, the support shaft portion being rotatably supported within the support shaft hole, the gear portion being located within the drive cassette, the second coupling portion being located outside the drive cassette.

9. The wind guide component according to claim 6, wherein the driven gear has a through hole extending therethrough in an axial direction, the louver assembly further includes a connecting rod extending in a longitudinal direction of the wind guide grille, the connecting rod is pivotally connected to each louver, the wind guide driving assembly includes a pushing shaft connecting the second driving mechanism and the connecting rod, and the pushing shaft is inserted through the through hole to reciprocate in the axial direction of the through hole so as to push the connecting rod to reciprocate in the longitudinal direction of the wind guide grille.

10. The wind guide component of claim 9, wherein the second drive mechanism comprises a drive gear and a rack gear, and the rack gear is in meshing transmission with the push shaft.

11. The wind guide component of claim 9, wherein a connector is disposed at one end of the connecting rod, the push shaft comprises a connecting section extending into the connector, and the connector and the connecting section are in limit fit through a limit structure to limit the connecting section from being removed from the connector along the longitudinal direction of the wind guide grid.

12. The wind guide component of claim 1, wherein the wind guide grille is a grille-shaped cambered panel, and the first pivot axis passes through a center of a cambered circle of the wind guide grille.

13. An air conditioner, comprising:

a housing component having an air outlet therein;

the air guide component is arranged at the air outlet and is according to any one of claims 1 to 12.

14. An air conditioner, comprising:

the air outlet is formed in the shell part, and a first mounting seat and a second mounting seat which are respectively positioned on two sides of the length of the air outlet are arranged in the shell part;

the air guide component is arranged at the air outlet and is the air guide component according to claim 5, and the air guide driving assembly is mounted on the first mounting seat;

the door opening and closing component comprises an opening and closing door and an opening and closing door driving component, the opening and closing door driving component is installed on the second installation seat and drives the opening and closing door to rotate at the air outlet to open and close the air outlet.

15. The air conditioner as claimed in claim 14, wherein the length direction of the switch door and the length direction of the air guide grille are both the same as the length direction of the air outlet, a first mounting plate and a second mounting plate are respectively provided at both ends of the length of the air guide grille, a first mounting lug and a second mounting lug are respectively provided at both ends of the length of the switch door, the first mounting lug is located between the first mounting plate and the first mounting seat, the second mounting lug is located between the second mounting plate and the second mounting seat,

the first mounting seat is provided with a first through hole, a first supporting hole is formed in the first mounting lug, a first connecting shaft part is arranged on the first mounting plate, the wind guide driving assembly comprises a first supporting shaft and a second connecting shaft part, the wind guide driving assembly is accommodated in the first mounting seat, the second connecting shaft part is positioned outside the first mounting seat and is in transmission fit with the first connecting shaft part, and the first supporting shaft penetrates through the first through hole and the first supporting hole;

be equipped with the second via hole on the second mount pad, be equipped with the second supported hole on the second mounting panel, be equipped with second back shaft and third even axial region on the second installation ear, switch door drive assembly accomodate in the second mount pad just includes the fourth even axial region, the third is even axial region and is worn to locate the second via hole and with the fourth is even axial region transmission cooperation, the second back shaft is worn to locate the second supported hole.

Images