CN114135936A - Air conditioner - Google Patents

Abstract

The invention provides an air conditioner, which comprises a shell, a heat exchanger arranged in the shell, a cross-flow fan blade assembly and a flow guide mechanism, wherein the cross-flow fan blade assembly is arranged in the shell; a front air outlet is formed in one end of the shell in the width direction; the heat exchanger is positioned on one side of the cross-flow fan blade assembly, which is deviated from the front air outlet; the end part of the shell in the length direction is provided with a side air outlet, and the flow guide mechanism is arranged at an air duct fork joint between the side air outlet and the front air outlet and is suitable for opening or closing the side air outlet. The air conditioner of the invention enriches the air outlet mode and direction of the air conditioner by arranging the front air outlet and the side air outlet, so that the air conditioner can supply air in multiple directions and wide areas; and, set up the water conservancy diversion mechanism through wind channel fork department between side air outlet and preceding air outlet for the multidirectional air-out of air conditioner has selectivity, controllability, has promoted user and has used experience.

Description

Air conditioner

Technical Field

The invention relates to the technical field of air conditioners, in particular to an air conditioner.

Background

At present, a wide-area air supply type air conditioner is provided with a front air outlet at the front end of a shell, and side air outlets are arranged at the left end and the right end of the shell, so that multidirectional air supply and wide-area air supply are realized. However, the side air outlet and the front air outlet of the existing wide area air supply type air conditioner can only be opened or closed at the same time, so that a user cannot select a single air outlet mode or a multi-directional air outlet mode according to needs.

Disclosure of Invention

The invention solves the problems that: how to make the multi-directional air outlet of the air conditioner have selectivity.

In order to solve the problems, the invention provides an air conditioner, which comprises a shell, a heat exchanger arranged in the shell, a cross-flow fan blade assembly and a flow guide mechanism, wherein the cross-flow fan blade assembly is arranged in the shell; a front air outlet is formed in one end of the shell in the width direction; the heat exchanger is positioned on one side of the cross-flow fan blade assembly, which is deviated from the front air outlet; the end part of the shell in the length direction is provided with a side air outlet, and the flow guide mechanism is arranged at an air duct fork joint between the side air outlet and the front air outlet and is suitable for opening or closing the side air outlet.

From this, the air conditioner has richened the air-out mode and the air-out direction of air conditioner through air outlet and side air outlet before setting up, and makes the air supply direction and the angle of air conditioner wider to make the air conditioner can multidirectional, the wide area air supply. And, set up guiding mechanism through the wind channel fork mouth department between side air-out mouth and preceding air outlet to the side air-out of control air conditioner has promoted the convenience that the air conditioner side air-out mouth opened and closed, and has made the multidirectional air-out of air conditioner have selectivity, controllability, makes the user can select single air-out mode or multidirectional air-out mode as required, has promoted user's use experience.

Optionally, an upper air inlet and a lower air inlet are respectively arranged at two ends of the shell in the vertical direction, and the heat exchanger is located between the upper air inlet and the lower air inlet.

Therefore, the shell of the air conditioner is provided with an upper air inlet and a lower air inlet, and the heat exchanger is arranged between the upper air inlet and the lower air inlet; so, increased the air inlet area of air conditioner for the air conditioner can have bigger intake, in order to promote the heat transfer effect of the heat exchanger of air conditioner, and guaranteed the air output of air conditioner.

Optionally, the cross-flow fan assembly includes a first cross-flow fan, a second cross-flow fan, and a fan motor, the fan motor is disposed between the first cross-flow fan and the second cross-flow fan, and the fan motor, the first cross-flow fan, and the second cross-flow fan are coaxially disposed.

Therefore, the fan blade motor, the first cross-flow fan blade and the second cross-flow fan blade are preferably arranged coaxially, and on one hand, the fan blade motor, the first cross-flow fan blade and the second cross-flow fan blade are used for ensuring uniform air outlet of the air conditioner; on the other hand, when only one fan blade motor for driving the fan blades to rotate is arranged in the air conditioner, the fan blade motor, the first through-flow fan blade and the second through-flow fan blade are coaxially arranged, so that the control of the fan blade motor on the first through-flow fan blade and the second through-flow fan blade is facilitated, and the first through-flow fan blade and the second through-flow fan blade can synchronously rotate.

Optionally, the blade motor is located in the middle of the housing, and the first cross-flow blade and the second cross-flow blade are symmetrically arranged with respect to the blade motor.

Therefore, the first through-flow fan blade and the second through-flow fan blade are symmetrically arranged relative to the fan blade motor, and preferably have the same specification as the first through-flow fan blade and the second through-flow fan blade, so that the air outlet rate or the air outlet volume of the left end and the right end of the front air outlet is ensured to be the same, that is, the air outlet of the front air outlet is ensured to be uniform, the use experience of a user is improved, the first through-flow fan blade or the second through-flow fan blade is convenient to maintain and replace, and the maintenance and replacement cost of the first through-flow fan blade or the second through-flow fan blade is reduced.

Optionally, the air conditioner further includes an air guide mechanism disposed at the front air outlet and/or the side air outlet, and the air guide mechanism is adapted to adjust an air outlet angle of the front air outlet and/or the side air outlet.

From this, wind guiding mechanism sets up air outlet and/or side air outlet department in the front for adjust the air outlet angle of air conditioner air outlet and/or side air outlet department in the front, make the air conditioner be suitable for wind and/or about wind is swept in air outlet department in the front, and/or, wind and/or front and back are swept in wind about side air outlet department from top to bottom, so, the air-out mode of air conditioner has further been richened, and make the air-out mode of air conditioner have hommization, it is intelligent, selectable, controllable advantage, user experience has been promoted.

Optionally, the front air outlet includes a first front air outlet and a second front air outlet, and the positions of the first front air outlet and the second front air outlet correspond to the positions of the first cross-flow fan blade and the second cross-flow fan blade, respectively; air guide mechanism includes first air guide structure and second air guide structure, first air guide structure with second air guide structure sets up respectively first front air outlet with air outlet department before the second.

Therefore, the first front air outlet and the second front air outlet respectively correspond to the first cross-flow fan blade and the second cross-flow fan blade, so that the mutual interference of the air flow blown to the first front air outlet by the first cross-flow fan blade and the air flow blown to the second front air outlet by the second cross-flow fan blade in the shell is avoided, the air duct shunting of the air conditioner is optimized, and various air outlet modes of the air conditioner are facilitated; the first front air outlet and the second front air outlet are respectively provided with a first air guide structure and a second air guide structure so as to respectively control the air outlet angles at the first front air outlet and the second front air outlet, so that the air conditioner has multiple air outlet modes.

Optionally, the air guiding mechanism further comprises a first air guiding motor and a second air guiding motor, the first air guiding motor is suitable for driving the first air guiding structure to rotate so as to adjust the air outlet angle at the first front air outlet, the second air guiding motor is suitable for driving the second air guiding structure to rotate so as to adjust the air outlet angle at the second front air outlet, and the first air guiding motor and the second air guiding motor are arranged in parallel.

From this, first air guide motor and second air guide motor are suitable for independent control to make first aviation baffle and second aviation baffle independent control, further richened the air-out mode of air conditioner, and make the air-out mode of air conditioner have humanized, intelligent, selectable, controllable advantage, promoted user and used experience.

Optionally, the first air guiding structure includes a first air guiding plate and/or a second air guiding plate, the first air guiding plate is adapted to adjust an air outlet angle at the first front air outlet in a vertical direction, and the second air guiding plate is adapted to adjust an air outlet angle at the first front air outlet in a length direction of the first front air outlet.

Therefore, the first air deflector is used for adjusting the air outlet angle of the air conditioner at the first front air outlet in the up-down direction, and the second air deflector is used for adjusting the air outlet angle of the front air outlet in the length direction of the first front air outlet, so that the air outlet mode of the air conditioner is enriched.

Optionally, the diversion mechanism includes a wind shielding assembly and a diversion assembly, the wind shielding assembly is adapted to open or close the side wind outlet, and the diversion assembly is adapted to guide the airflow flowing to the diversion assembly to blow out from the side wind outlet and/or the front wind outlet when the wind shielding assembly opens the side wind outlet.

Therefore, when the side air outlet of the air conditioner is closed, the air flow in the shell is only blown out from the front air outlet; when the side air outlet of air conditioner was opened, the air current in the casing blew off with the side air outlet together in the past, so, made things convenient for the air current to blow off from side air outlet and front air outlet under the water conservancy diversion effect of water conservancy diversion subassembly to realize the initiative air supply of side air outlet, make the function of air conditioner diversified, convenience of customers selects the mode of one-way air-out or multidirectional air supply according to actual need.

Optionally, the wind deflector assembly comprises a wind deflector adapted to be disposed within the housing, the wind deflector having a closed position and an open position, and a motor adapted to drive the wind deflector to switch between the closed position and the open position; the wind deflector is adapted to shield the side outlet when the wind deflector is in the closed position; when the wind deflector is in the open position, the wind deflector is adapted to open the side outlet vents to communicate the side outlet vents with an external space of the air conditioner.

From this, switch between closed position and open position with the drive deep bead through setting up the motor to open or close the side air outlet, make the multidirectional air-out of air conditioner have selectivity, controllability, richened the air-out mode of air conditioner.

Optionally, the wind deflector includes a wind blocking portion and a connecting rod portion, the wind blocking portion is adapted to block the side air outlet, the connecting rod portion is connected to the motor, and the motor is adapted to drive the wind blocking portion to rotate around an axis of the connecting rod portion, so that the wind deflector is located at the closing position or the opening position.

Therefore, the diversion mechanism drives the connecting rod part to rotate through the motor so as to drive the wind shielding part to rotate around the axis of the connecting rod part, so that the side air outlet is closed or opened, and the convenience of opening and closing the side air outlet of the air conditioner is improved.

Optionally, the wind shielding assembly further comprises a shaft sleeve sleeved on the connecting rod portion, a limiting structure is arranged on the shaft sleeve, and the limiting structure is suitable for being matched with the wind shielding portion to limit the rotation angle of the wind shielding plate.

Therefore, the shaft sleeve is used for limiting the wind shielding part and the connecting rod part in the direction perpendicular to the rotating direction of the wind shielding part so as to ensure that the wind shielding part and the connecting rod part can stably rotate between a closed position and an open position; and the shaft sleeve is provided with a limiting structure, and the limiting structure is suitable for being matched with the wind shielding part to limit the rotation angle of the wind shielding plate so as to avoid the situation that the wind shielding part blocks the wind outlet of the front wind outlet or causes the damage of the flow guide mechanism due to excessive rotation.

Optionally, the flow directing assembly comprises a first flow deflector disposed within the housing; one end of the first guide plate is connected with the shaft sleeve, and the other end of the first guide plate extends towards the side air outlet and is connected to the shell; the first deflector is adapted to direct an airflow directed toward the first deflector to exit the side air outlet when the wind deflector is in the open position.

Therefore, the shaft sleeve is arranged on the first guide plate, so that the first guide plate is rotatably connected with the wind shield through the shaft sleeve to ensure that the wind shield can smoothly rotate, and the wind shield is smoothly switched between a closed position and an open position; the other end of the first guide plate is connected with the shell so as to ensure the tightness of the connection of the first guide plate and the shell.

Optionally, the air guide assembly further includes a second air guide plate, one end of the second air guide plate is connected to the shaft sleeve or the first air guide plate, and the other end of the second air guide plate extends toward the front air outlet of the air conditioner and is connected to the housing; the second baffle is adapted to direct airflow flowing toward the second baffle to exit the front air outlet.

Therefore, one end, far away from the end connected with the shell, of the second guide plate is connected with the shaft sleeve or the first guide plate, and therefore when the wind shield is located at the opening position, the wind shield and the side face, facing one side of the side air outlet, of the first guide plate are suitable for guiding air flow flowing to the flow guide mechanism to blow out from the side air outlet; when the wind shield is located at the closed position, the wind shield and the side face, facing one side of the fan blade, of the first wind guide plate are suitable for guiding airflow flowing to the wind guide mechanism to be blown out from the front air outlet. The guide mechanism guides the airflow, and avoids the generation of loud noise caused by the direct collision of the airflow and the inner wall of the shell.

Optionally, the side air outlet includes a left air outlet and a right air outlet respectively disposed at two ends of the housing in the length direction; the two flow guide mechanisms are respectively arranged at an air duct fork between the left air outlet and the front air outlet and an air duct fork between the right air outlet and the front air outlet; and the motors of the two diversion mechanisms are arranged in parallel.

Therefore, the left end of the shell is provided with the left air outlet, and the right end of the shell is provided with the right air outlet, so that the air conditioner can simultaneously perform front air outlet, left air outlet and right air outlet, the air outlet modes of the air conditioner are further enriched, and the air outlet direction and the angle of the air conditioner are wider; the setting of two water conservancy diversion mechanisms to control opening or closing of left air outlet, right air outlet respectively, and the parallelly connected setting of motor of two water conservancy diversion mechanisms, richened the air-out mode of air conditioner, make multidirectional, the wide area air-out of air conditioner have can select, controllable advantage.

Drawings

Fig. 1 is a schematic structural view of a casing of an air conditioner according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of an air conditioner according to an embodiment of the present invention;

FIG. 3 is a schematic view of an air conditioner with the air deflector in an open position according to an embodiment of the present invention;

FIG. 4 is a schematic structural view of an air conditioner with a windshield in a closed position according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of a deflector mechanism disposed in a housing of an air conditioner according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram of a flow guide mechanism according to an embodiment of the present invention.

Description of reference numerals:

1-shell, 11-upper inlet, 12-lower inlet, 13-front outlet, 131-first front outlet, 132-second front outlet, 14-side outlet, 141-left outlet, 142-right outlet; 2-a flow guide mechanism, 21-a wind shielding assembly, 211-a wind shielding plate, 2111-a wind shielding part, 2112-a connecting rod part, 212-a motor, 22-a flow guide assembly, 221-a first flow guide plate, 222-a second flow guide plate and 23-a shaft sleeve; 3-air guiding mechanism, 31-first air guiding structure, 311-first air guiding plate, 312-second air guiding plate, 32-second air guiding structure, 321-third air guiding plate, 322-fourth air guiding plate; 4-cross-flow fan blade assembly, 41-first cross-flow fan blade, 42-second cross-flow fan blade and 43-fan blade motor; 5-heat exchanger.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the description of the present invention, it should be noted that the terms "upper", "lower", "left", "right", "high", "low", and the like indicate directions or positional relationships based on the orientations or positional relationships shown in the drawings, and a coordinate system XYZ is provided herein, in which a forward direction of the X axis represents a forward direction, a reverse direction of the X axis represents a backward direction, a forward direction of the Y axis represents a right direction, a reverse direction of the Y axis represents a left direction, a forward direction of the Z axis represents an upper direction, and a reverse direction of the Z axis represents a lower direction; this is done solely for the purpose of facilitating the description of the invention and simplifying the description, and is not intended to indicate or imply that the apparatus referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be taken as limiting the invention.

Referring to fig. 1 to 4, an embodiment of the present invention provides an air conditioner, including a housing 1, a heat exchanger 5 disposed in the housing 1, a cross-flow fan blade assembly 4, and a flow guide mechanism 2; a front air outlet 13 is arranged at one end of the shell 1 in the width direction; the heat exchanger 5 is positioned on one side of the cross-flow fan blade assembly 4 departing from the front air outlet 13; the end part of the shell 1 in the length direction is provided with a side air outlet 14, and the flow guide mechanism 2 is arranged at an air duct fork between the side air outlet 14 and the front air outlet 13 and is suitable for opening or closing the side air outlet 14.

In this embodiment, a casing 1 of the air conditioner is used for protecting and accommodating components such as a cross-flow fan blade assembly 4, a heat exchanger 5, a flow guide mechanism 2 and the like of the air conditioner, two ends of the casing 1 in the width direction are respectively the front end and the rear end of the casing 1, wherein the width direction of the casing 1 refers to the X-axis direction in fig. 1; the front end of the casing 1 (i.e. the end of the casing 1 located in the positive direction of the X axis in fig. 1) is provided with a front air outlet 13, and the rear end of the casing 1 (i.e. the end of the casing 1 located in the negative direction of the X axis in fig. 1) is adapted to be directly connected with a mounting surface (such as a wall surface) or connected through a bracket, so as to mount the air conditioner on the wall surface. The heat exchanger 5 is arranged between the rear end of the shell 1 and the cross-flow fan blade assembly 4, namely the heat exchanger 5 is in a rear-mounted type in the shell 1 of the air conditioner; the two ends of the housing 1 in the length direction are respectively the left end (i.e. the end of the housing 1 located in the opposite direction of the Y axis in fig. 3) and the right end (i.e. the end of the housing 1 located in the positive direction of the Y axis in fig. 3) of the housing 1, wherein the length direction of the housing 1 refers to the Y axis direction in fig. 1; the left end of the casing 1 (i.e. the end of the casing 1 located in the reverse direction of the Y axis in fig. 1) and/or the right end of the casing 1 (i.e. the end of the casing 1 located in the forward direction of the Y axis in fig. 1) are/is provided with the side air outlet 14, that is, in this embodiment, the side air outlet 14 may be provided at the left end of the casing 1, the side air outlet 14 may be provided at the right end of the casing 1, and the left end and the right end of the casing 1 may both be provided with the side air outlet 14. By arranging the front air outlet 13 and the side air outlets 14, on one hand, the air outlet area of the air conditioner is increased, so that the air conditioner is suitable for providing larger air outlet volume, the heating or refrigerating effect of the air conditioner is improved, and the use experience of a user is improved; on the other hand, the air outlet mode of the air conditioner is enriched, the air outlet direction and the angle of the air conditioner are wider, the air outlet dead angle of the air conditioner is reduced (namely the position where the air flow blown out by the air conditioner cannot directly reach), and the use experience of a user is further improved.

Because different customers have different demands to the air-out direction of air conditioner, for example, some customers only need the front air outlet 13 open can, and at this moment air conditioner side air outlet 14 just need not open when using, and some customers then need front air outlet 13 and side air outlet 14 all to open. Moreover, different customers have different demands to the mounted position of hanging air conditioner, for example, some customers need to be close to the left side wall installation with the left end ann of air conditioner, and at this moment, the air outlet on the left side of air conditioner just need not open when using, and some customers need be close to the right side wall installation with the right-hand member ann of air conditioner, and at this moment, the air outlet on air conditioner right side just need not open when using. However, the side air outlet 14 of the conventional hanging air conditioner capable of supplying air in multiple directions is usually opened or closed together with the front air outlet 13, that is, when the air conditioner is turned on, the side air outlet 14 is opened together with the front air outlet 13, and when the air conditioner is turned off, the side air outlet 14 is closed together with the front air outlet 13, so that the side air outlet 14 of the air conditioner cannot be selectively opened or opened according to actual conditions when the air conditioner is turned on, and thus, the use requirements of different customers cannot be met.

In the embodiment, the diversion mechanism 2 is arranged at the air duct fork between the side air outlet 14 and the front air outlet 13 and is used for controlling the opening or closing of the side air outlet 14; the air duct corresponding to the side air outlet 14 (i.e., the air duct communicated with the side air outlet 14) intersects with the air duct corresponding to the front air outlet 13 (i.e., the air duct communicated with the front air outlet 13), and the air duct intersection between the side air outlet 14 and the front air outlet 13 refers to the position where the two air ducts intersect, that is, the air duct intersection between the left air outlet 141 (described later) and the front air outlet 13 refers to the position where the air duct corresponding to the left air outlet 141 and the air duct corresponding to the front air outlet 13 intersect, and the air duct intersection between the right air outlet 142 (described later) and the front air outlet 13 refers to the position where the air duct corresponding to the right air outlet 142 and the air duct corresponding to the front air outlet 13 intersect. So, set up air duct fork department between preceding air outlet 13 and side air outlet 14 with guiding mechanism 2, rather than setting up in the place plane department of side air outlet 14 for guiding mechanism 2 can also shunt the air current under the effect that realizes that control side air outlet 14 opens or closes, so that the air current blows off from preceding air outlet 13 and/or side air outlet 14 better, has improved the air output and the air-out effect of air conditioner. Specifically, when the side outlet 14 of the air conditioner is closed, the airflow inside the casing 1 is blown out only from the front outlet 13; when the side air outlet 14 of the air conditioner is opened, the air flow in the shell 1 is blown out from the front air outlet 13 and the side air outlet 14 together; therefore, the multi-directional air outlet of the air conditioner has selectivity and controllability, and the air outlet mode of the air conditioner is enriched; the user can select a single air outlet mode or a multi-directional air outlet mode according to the requirement, and the user experience is improved.

Like this, through setting up front air outlet 13 and side air outlet 14, richened the air-out mode and the air-out direction of air conditioner, and made the air-out direction and the angle of air conditioner wider to make the air conditioner can multidirectional, wide area air-out. Moreover, the diversion mechanism is arranged at the air duct turnout between the side air outlet 14 and the front air outlet 13 to control the side air outlet of the air conditioner, so that the opening and closing convenience of the air outlet 14 on the side of the air conditioner is improved, the multi-directional air outlet of the air conditioner is selectable and controllable, a user can select a single air outlet mode or a multi-directional air outlet mode as required, and the user experience is improved.

Optionally, as shown in fig. 2, an upper air inlet 11 and a lower air inlet 12 are respectively disposed at two ends of the housing 1 in the vertical direction, and the heat exchanger 5 is located between the upper air inlet 11 and the lower air inlet 12.

An upper air inlet 11 and a lower air inlet 12 are respectively arranged at two ends of a shell 1 of the air conditioner in the vertical direction (namely two ends of the shell 1 in the Z-axis direction in fig. 2), and a heat exchanger 5 is arranged between the upper air inlet 11 and the lower air inlet 12; therefore, the air inlet area of the air conditioner is increased, so that the air conditioner can have larger air inlet volume to improve the heat exchange effect of the heat exchanger 5 of the air conditioner, thereby improving the heating and refrigerating effects of the air conditioner, and ensuring the air outlet volume of the air conditioner, so as to avoid the air outlet volume of the air conditioner at each air outlet (namely the front air outlet 13 and the side air outlet 14) from being reduced due to too small air inlet volume; moreover, the upper air inlet 11 and the lower air inlet 12 are respectively disposed at the upper end and the lower end of the housing 1 (i.e., the housing 1 is disposed at the two ends in the Z-axis direction in fig. 2), so as to prevent the upper air inlet 11 and the lower air inlet 12 from being disposed too close to each other and interfering with each other.

Optionally, as shown in fig. 3 and 4, the cross-flow fan blade assembly 4 includes a first cross-flow fan blade 41, a second cross-flow fan blade 42, and a fan blade motor 43, where the fan blade motor 43 is disposed between the first cross-flow fan blade 41 and the second cross-flow fan blade 42, and the fan blade motor 43, the first cross-flow fan blade 41, and the second cross-flow fan blade 42 are coaxially disposed.

The fan blade motor 43, the first through-flow fan blade 41 and the second through-flow fan blade 42 are preferably arranged coaxially, and on one hand, the fan blade motor is used for ensuring uniform air outlet of the air conditioner, and avoiding the situation that the air outlet rates or the air outlet volumes of the air conditioner at the left end and the right end of the front air outlet 13 are not consistent when the distances from the first through-flow fan blade 41 and the second through-flow fan blade 42 to the front air outlet 13 are not consistent, so as to ensure the use experience of a user; on the other hand, when only one fan blade motor 43 for driving the fan blades to rotate is arranged in the air conditioner, the fan blade motor 43, the first cross-flow fan blade 41 and the second cross-flow fan blade 42 are coaxially arranged, so that the control of the fan blade motor 43 on the first cross-flow fan blade 41 and the second cross-flow fan blade 42 is facilitated, and the first cross-flow fan blade 41 and the second cross-flow fan blade 42 can synchronously rotate; the blade motor 43 is preferably disposed between the first through-flow blade 41 and the second through-flow blade 42, so that the blade motor 43 is connected to and drives the first through-flow blade 41 and the second through-flow blade 42 at the same time, so as to ensure that the first through-flow blade 41 and the second through-flow blade 42 have the same rotation speed under the driving of the blade motor 43, that is, to ensure that the first through-flow blade 41 and the second through-flow blade 42 can rotate synchronously.

Further, when the first through-flow fan blade 41 and the second through-flow fan blade 42 need to be controlled independently, the air conditioner may be provided with two driving motors, and the two driving motors are respectively used for driving the first through-flow fan blade 41 and the second through-flow fan blade 42 to rotate, so as to further enrich the air outlet mode of the air conditioner.

Optionally, as shown in fig. 3 and 4, the blade motor 43 is located in a middle position in the housing 1, and the first through-flow blade 41 and the second through-flow blade 42 are symmetrically arranged with respect to the blade motor 43.

In this embodiment, the first through-flow fan blade 41 and the second through-flow fan blade 42 are symmetrically arranged relative to the fan blade motor 43, and preferably, the first through-flow fan blade 41 and the second through-flow fan blade 42 have the same specification, so as to ensure that the air outlet rate or the air outlet volume of the left end and the right end of the front air outlet 13 is the same, that is, the air outlet of the front air outlet 13 is uniform, so as to improve the user experience, facilitate the maintenance and replacement of the first through-flow fan blade 41 or the second through-flow fan blade 42, and reduce the maintenance and replacement costs of the first through-flow fan blade 41 or the second through-flow fan blade 42.

Optionally, as shown in fig. 1 to 4, the air conditioner further includes a wind guiding mechanism 3 disposed at the front wind outlet 13 and/or the side wind outlet 14, and the wind guiding mechanism 3 is adapted to adjust a wind outlet angle at the front wind outlet 13 and/or the side wind outlet 14.

In this embodiment, the air guiding mechanism 3 may be only disposed at the front air outlet 13, may be only disposed at the side air outlet 14, and may be disposed at both the front air outlet 13 and the side air outlet 14 of the air guiding mechanism 3. The air guide mechanism 3 of setting in front air outlet 13 department is used for adjusting the air-out angle of air conditioner in front air outlet 13 department for the air conditioner is suitable for in front air outlet 13 department from top to bottom (Z axle direction in figure 1) to sweep the wind and/or about (Y axle direction in figure 1) sweep the wind, so, the air-out mode of air conditioner has further been richened, and make the air-out mode of air conditioner have hommization, intellectuality, can select, controllable advantage, user experience has been promoted. The air guide mechanism 3 arranged at the side air outlet 14 is used for adjusting the air outlet angle of the air conditioner at the side air outlet 14, so that the air conditioner is suitable for sweeping air up and down and/or sweeping air back and forth at the side air outlet 14, the air outlet mode of the air conditioner is further enriched, the air outlet mode of the air conditioner is humanized, intelligent, selectable and controllable, and the user use experience is improved.

Optionally, as shown in fig. 3 and 4, the front air outlet 13 includes a first front air outlet 131 and a second front air outlet 132, and the positions of the first front air outlet 131 and the second front air outlet 132 correspond to the positions of the first cross-flow fan blade 41 and the second cross-flow fan blade 42, respectively; the air guiding mechanism 3 includes a first air guiding structure 31 and a second air guiding structure 32, and the first air guiding structure 31 and the second air guiding structure 32 are respectively disposed at the first front air outlet 131 and the second front air outlet 132.

The first front air outlet 131 and the second front air outlet 132 are respectively located at the front ends of the first through-flow fan blade 41 and the second through-flow fan blade 42 and respectively correspond to the positions of the first through-flow fan blade 41 and the second through-flow fan blade 42, so that the airflow driven by the first through-flow fan blade 41 in the casing 1 is blown to the first front air outlet 131, and the airflow driven by the second through-flow fan blade 42 in the casing 1 is blown to the second front air outlet 132, thereby preventing the airflow blown to the first front air outlet 131 by the first through-flow fan blade 41 in the casing 1 and the airflow blown to the second front air outlet 132 by the second through-flow fan blade 42 from interfering with each other, optimizing air duct flow distribution of the air conditioner, and facilitating realization of multiple air outlet modes of the air conditioner.

Based on the front air outlet 13 including the first front air outlet 131 and the second front air outlet 132, the first front air outlet 131 and the second front air outlet 132 are respectively provided with the first wind guiding structure 31 and the second wind guiding structure 32 to respectively control the air outlet angles at the first front air outlet 131 and the second front air outlet 132. The first air guiding structure 31 and the second air guiding structure 32 may be controlled synchronously (for example, one control motor is provided to control the first air guiding structure 31 and the second air guiding structure 32 simultaneously), or may be controlled independently (for example, two control motors are provided to control the first air guiding structure 31 and the second air guiding structure 32 respectively). Thus, the air outlet angles of the air flow at the first front air outlet 131 and the second front air outlet 132 are adjusted by arranging the first air guiding structure 31 and the second air guiding structure 32, so that the angles of the air flow blown out from the first front air outlet 131 and the second front air outlet 132 can be the same or different, and the air conditioner has multiple air outlet modes.

Optionally, the air guiding mechanism 3 further includes a first air guiding motor and a second air guiding motor, the first air guiding motor is adapted to drive the first air guiding structure 31 to rotate so as to adjust the air outlet angle at the first front air outlet 131, the second air guiding motor is adapted to drive the second air guiding structure 32 to rotate so as to adjust the air outlet angle at the second front air outlet 132, and the first air guiding motor and the second air guiding motor are arranged in parallel.

In this embodiment, the first air guiding structure 31 and the second air guiding structure 32 are controlled and driven by providing the first air guiding motor and the second air guiding motor, respectively; specifically, the first wind guiding motor is connected to the first wind guiding structure 31, the second wind guiding motor is connected to the second wind guiding structure 32, and the first wind guiding motor is adapted to drive the first wind guiding structure 31 to rotate so as to adjust the wind outlet angle of the first front wind outlet 131 in the up-down direction, and the second wind guiding motor is adapted to drive the second wind guiding structure 32 to rotate so as to adjust the wind outlet angle of the second front wind outlet 132 in the length direction of the front wind outlet 13. Moreover, first wind-guiding motor and the parallelly connected setting of second wind-guiding motor, that is to say, first wind-guiding motor is suitable for independent control with second wind-guiding motor to make first wind-guiding structure 31 and second wind-guiding structure 32 independent control, with the air-out mode of further richened air conditioner, and make the air-out mode of air conditioner have humanized, intelligent, can select, controllable advantage, promoted user's use and experienced.

Optionally, as shown in fig. 3 and 4, the first wind guiding structure 31 includes a first wind guiding plate 311 and/or a second wind guiding plate 312, where the first wind guiding plate 311 is adapted to adjust the wind outlet angle at the first front wind outlet 131 in the vertical direction, and the second wind guiding plate 312 is adapted to adjust the wind outlet angle at the first front wind outlet 131 in the length direction of the first front wind outlet 131.

In this embodiment, the air conditioner may be provided with only the first air deflector 311 or the second air deflector 312 at the first front air outlet 131, or may be provided with both the first air deflector 311 and the second air deflector 312. The first air deflector 311 is used for adjusting the air outlet angle of the air conditioner at the first front air outlet 131 in the up-down direction, and the second air deflector 312 is used for adjusting the air outlet angle at the first front air outlet 131 in the length direction (i.e. the left-right direction, i.e. the Y-axis direction in fig. 1) of the front air outlet 13; specifically, the first air deflector 311 includes a first air deflector body and a first air deflector rotating shaft, the first air deflector rotating shaft is parallel to the horizontal plane, and the first air deflector body is connected with the first air deflector rotating shaft and is suitable for rotating around the first air deflector rotating shaft; therefore, after the first air deflector body rotates around the first air deflector rotating shaft, the included angle between the first air deflector body and the horizontal plane changes, so that the air outlet angle of the air conditioner at the first front air outlet 131 in the up-down direction (i.e., the Z-axis direction in fig. 1) changes correspondingly. The second air guiding plate 312 includes a second air guiding plate body and a second air guiding plate rotating shaft, the second air guiding plate rotating shaft is perpendicular to the first air guiding plate rotating shaft, and the second air guiding plate body is connected with the second air guiding plate rotating shaft and is suitable for rotating around the second air guiding plate rotating shaft; thus, after the second air deflector body rotates around the second air deflector rotating shaft, the included angle between the second air deflector body and the XZ plane in fig. 1 changes, so that the air outlet angle of the air conditioner in the left-right direction at the first front air outlet 131 correspondingly changes.

Further, when the air guiding mechanism 3 is disposed at the side outlet 14, the first air guiding plate 311 is used for adjusting the air outlet angle of the air conditioner at the side outlet 14 in the up-down direction, and the second air guiding plate 312 is used for adjusting the air outlet angle of the air conditioner at the side outlet 14 in the front-back direction. When the left end (right end) of the casing 1 is provided with the left air outlet 141 (right air outlet 142) and the second air deflector body is arranged at the left air outlet 141 (right air outlet 142), the second air deflector body is used for adjusting the air outlet angle of the air conditioner in the front-back direction (i.e. the X-axis direction in fig. 1); specifically, after the second air deflector body rotates around the second air deflector rotating shaft, an included angle between the second air deflector body and a YZ plane in fig. 1 is changed, so that an air outlet angle of the side air outlet 14 of the air conditioner in the front-back direction is correspondingly changed.

Further, the second air guiding structure 32 is preferably configured to have the same structure as the first air guiding structure 31. The second wind guiding structure 32 includes a third wind guiding plate 321 and/or a fourth wind guiding plate 322, the third wind guiding plate 321 is adapted to adjust the wind outlet angle at the second front wind outlet 132 in the vertical direction, and the fourth wind guiding plate 322 is adapted to adjust the wind outlet angle at the second front wind outlet 132 in the length direction of the front wind outlet 131. Specifically, the air conditioner may be provided with only the third air deflector 321 or the fourth air deflector 322 at the second front air outlet 132, or may be provided with both the third air deflector 321 and the fourth air deflector 322. The third air deflector 321 is used for adjusting the air outlet angle of the air conditioner at the second front air outlet 132 in the up-down direction, and the fourth air deflector 322 is used for adjusting the air outlet angle at the second front air outlet 132 in the length direction (i.e. the left-right direction, i.e. the Y-axis direction in fig. 1) of the front air outlet 13; the third air guiding plate 321 comprises a third air guiding plate body and a third air guiding plate rotating shaft, the third air guiding plate rotating shaft is parallel to the horizontal plane, and the third air guiding plate body is connected with the third air guiding plate rotating shaft and is suitable for rotating around the third air guiding plate rotating shaft; therefore, after the third air deflector body rotates around the third air deflector rotating shaft, the included angle between the third air deflector body and the horizontal plane is changed, so that the air outlet angle of the air conditioner in the vertical direction (namely the Z-axis direction in fig. 1) is correspondingly changed. The fourth air deflector 322 comprises a fourth air deflector body and a fourth air deflector rotating shaft, the fourth air deflector rotating shaft is perpendicular to the fourth air deflector rotating shaft, and the fourth air deflector body is connected with the fourth air deflector rotating shaft and is suitable for rotating around the fourth air deflector rotating shaft; therefore, after the fourth air deflector body rotates around the fourth air deflector rotating shaft, the included angle between the fourth air deflector body and the XZ plane in the figure 1 is changed, so that the air outlet angle of the air conditioner in the left and right directions is correspondingly changed.

Alternatively, as shown in fig. 3 to 5, the diversion mechanism 2 includes a wind shielding assembly 21 and a diversion assembly 22, the wind shielding assembly 21 is adapted to open or close the side outlet 14, and the diversion assembly 22 is adapted to guide the airflow flowing to the diversion assembly 22 to be blown out from the side outlet 14 and/or the front outlet 13 when the wind shielding assembly 21 opens the side outlet 14.

In the embodiment, by arranging the diversion mechanism 2 at the air duct intersection between the front air outlet 13 and the side air outlet 14, the opening or closing of the side air outlet 14 is controlled by using the wind shielding assembly 21 of the diversion mechanism 2, and when the side air outlet 14 of the air conditioner is closed, the air flow in the housing 1 is only blown out from the front air outlet 13; when the side air outlet 14 of the air conditioner is opened, the air flow in the shell 1 is blown out from the front air outlet 13 and the side air outlet 14 together, so that the air flow is conveniently blown out from the side air outlet 14 and the front air outlet 13 under the flow guide effect of the flow guide assembly 22, active air supply of the side air outlet 14 is realized, and independent air supply is further realized, so that multi-directional air supply of the air conditioner has selectivity and controllability, the functions of the air conditioner are diversified, a user can conveniently select a one-way air outlet or multi-directional air supply mode according to actual needs, and the satisfaction degree of the user is improved; moreover, the diversion mechanism 2 is arranged at the air duct intersection between the front air outlet 13 and the side air outlet 14 instead of the plane of the side air outlet 14, so that the diversion mechanism 2 can also divert the air flow under the effect of controlling the opening or closing of the side air outlet 14, so that the air flow can be better blown out from the front air outlet 13 and/or the side air outlet 14, and the air output effect of the air conditioner are improved.

Optionally, as shown in conjunction with fig. 3-6, the wind deflector assembly 21 comprises a wind deflector 211 adapted to be disposed within the housing 1, the wind deflector 211 having a closed position and an open position, and a motor 212 adapted to drive the wind deflector 211 to switch between the closed position and the open position; when the wind deflector 211 is in the closed position, the wind deflector 211 is adapted to shield the side outlet vents 14; when the wind deflector 211 is in the open position, the wind deflector 211 is adapted to open the side outlet vents 14 to communicate the side outlet vents 14 with the external space of the air conditioner.

In the present embodiment, the motor 212 is provided to drive the wind deflector 211 to switch between the closed position and the open position, thereby opening or closing the side wind outlet 14; when the wind deflector 211 is located at the closed position, the wind deflector 211 is adapted to shield the side outlet 14 of the air conditioner, that is, the side outlet 14 of the air conditioner is closed, and at this time, the air flow in the housing 1 is only blown out from the front outlet 13; when the wind deflector 211 is located at the open position, the wind deflector 211 is adapted to open the side outlet 14 so as to communicate the side outlet 14 with the external space of the air conditioner, that is, the side outlet 14 of the air conditioner is opened, and at this time, the air flow in the housing 1 is blown out from the front outlet 13 and the side outlet 14 together; therefore, the multidirectional air outlet of the air conditioner has selectivity and controllability, and the air outlet mode of the air conditioner is enriched.

Further, the switching of the windshield 211 between the closed position and the open position may be achieved by the motor 212 driving the windshield 211 to move (e.g., rotate, translate, etc.).

Alternatively, as shown in fig. 3 to 6, the wind deflector 211 includes a wind shielding portion 2111 and a link portion 2112, the wind shielding portion 2111 is adapted to shield the side wind outlet 14, the link portion 2112 is connected to the motor 212, and the motor 212 is adapted to drive the wind shielding portion 2111 to rotate around the axis of the link portion 2112, so that the wind deflector 211 is located at the closed position or the open position.

In this embodiment, the wind deflector 211 includes a wind deflector portion 2111 and a link portion 2112, and the diversion mechanism drives the link portion 2112 to rotate through the motor 212 to drive the wind deflector portion 2111 to rotate around the axis of the link portion 2112, so as to close or open the side air outlet 14; specifically, when the wind deflector 211 is located at the closed position, the wind deflector 2111 shields the side wind outlet 14; when the wind deflector 211 is in the open position, the wind deflector 2111 is adapted to open the side outlet 14 to communicate the side outlet 14 with the external space of the air conditioner; therefore, the opening and closing convenience of the side air outlet 14 of the air conditioner is improved.

Optionally, as shown in fig. 6, the wind shielding assembly 21 further includes a shaft sleeve 23 sleeved on the connecting rod portion 2112, and a limiting structure is disposed on the shaft sleeve 23, and is adapted to cooperate with the wind shielding portion 2111 to limit the rotation angle of the wind shielding plate 211.

The shaft sleeve 23 is sleeved on the connecting rod portion 2112 and is used for limiting the rotation direction of the windshield portion 2111 perpendicular to the rotation direction of the windshield portion 2111 of the connecting rod portion 2112, so that the windshield portion 2111 and the connecting rod portion 2112 can be stably rotated between a closed position and an open position. And the shaft sleeve 23 is provided with a limiting structure, and the limiting structure is suitable for being matched with the wind shielding part 2111 to limit the rotation angle of the wind shielding plate 211, so as to avoid the situation that the wind shielding part 2111 obstructs the wind outlet of the front air outlet 13 due to excessive rotation or causes the damage of the flow guide mechanism.

Further, the limiting structure is a limiting groove, the limiting groove is located on the rotation track of the wind shielding portion 2111, and one end of the wind shielding portion 2111 connected with the connecting rod portion 2112 penetrates through the limiting groove to be connected to the connecting rod portion 2112 and is suitable for rotating in the limiting groove. Specifically, the limiting structure is preferably a limiting groove for cooperating with the wind blocking portion 2111 to limit the rotation angle of the wind blocking plate 211; the limiting groove is provided with two side walls vertical to a horizontal plane (namely, an XY plane in fig. 6) and one side wall parallel to the horizontal plane, wherein the one side wall parallel to the horizontal plane of the limiting groove has a limiting effect on the wind shielding part 2111 in the setting direction so as to ensure that the wind shielding part 2111 can stably horizontally rotate (namely, the rotation direction of the wind shielding part 2111 is parallel to the horizontal plane); when the wind shield 211 is located at the closed position, one groove wall of the limiting groove perpendicular to the horizontal plane is abutted against one side of the wind shield portion 2111 to limit the wind shield portion 2111 to continue rotating towards the direction departing from the cross-flow fan blade assembly 4; when the wind shield 211 is located at the opening position, the other groove wall of the limiting groove perpendicular to the horizontal plane is abutted against the other side of the wind shield portion 2111 to limit the wind shield portion 2111 to continue rotating towards the front air outlet 13; thus, the limiting structure cooperates with the wind blocking portion 2111 to limit the rotation angle of the wind blocking plate 211, so as to avoid the wind blocking portion 2111 from obstructing the front air outlet 13 or causing damage to the flow guiding mechanism due to excessive rotation.

Further, two shaft sleeves 23 are preferably provided, and the two shaft sleeves 23 are respectively sleeved at the upper end and the lower end of the connecting rod portion 2112 to further ensure that the wind blocking portion 2111 can stably horizontally rotate; at this time, the two stopper grooves limit the rotation angle of the upper and lower ends of the wind blocking portion 2111, and further ensure that the wind blocking plate 211 can be smoothly switched between the open position and the closed position.

Optionally, as shown in conjunction with fig. 3-6, the flow directing assembly 22 includes a first flow directing plate 221 disposed within the housing 1; one end of the first guide plate 221 is connected with the shaft sleeve 23, and the other end extends towards the side air outlet 14 and is connected to the shell 1; the first baffle 221 is adapted to direct the airflow flowing to the first baffle 221 to be blown out from the side air outlet 14 when the wind deflector 211 is in the open position.

Based on the shaft sleeve 23 sleeved on the connecting rod portion 2112, one end of the first guide plate 221 is connected with the shaft sleeve 23, that is, the shaft sleeve 23 is arranged on the first guide plate 221, so that the first guide plate 221 is rotatably connected with the wind deflector 211 through the shaft sleeve 23, and the wind deflector 211 can be ensured to smoothly rotate, so that the wind deflector 211 can be smoothly switched between the closed position and the open position; the other end of the first guide plate 221 is connected with the shell 1 to ensure the connection tightness between the first guide plate 221 and the shell 1, on one hand, the air outlet volume of the air conditioner during side air outlet is ensured, and the air flow flowing to the side air outlet 14 during side air outlet of the air conditioner is prevented from leaking between the first guide plate 221 and the shell 1; on the other hand, the stability of being connected of water conservancy diversion mechanism and casing 1 has been guaranteed. When the wind deflector 211 is located at the open position, the air-conditioning inner sub-stream (i.e. the air stream flowing to the first wind deflector 221) flows to the side wind outlet 14 along the first wind deflector 221 towards one side of the side wind outlet 14 and is blown out from the side wind outlet 14, so as to ensure smooth wind outlet when the air-conditioning side wind exits and the wind outlet amount at the side wind outlet 14.

Optionally, as shown in fig. 3 to fig. 6, the airflow guiding assembly 22 further includes a second airflow guiding plate 222, one end of the second airflow guiding plate 222 is connected to the shaft sleeve 23 or the first airflow guiding plate 221, and the other end extends towards the front air outlet of the air conditioner and is connected to the housing 1; the second baffle 222 is adapted to direct the airflow flowing toward the second baffle 222 to be blown out from the front air outlet.

In this embodiment, the first flow guiding plate 221 and the second flow guiding plate 222 are located between the front air outlet 13 and the side air outlet 14, and when the air conditioner is in operation, the second flow guiding plate 222 is adapted to guide the airflow flowing to the second flow guiding plate 222 to be blown out from the front air outlet 13; specifically, the end of the second flow guiding plate 222 away from the end connected to the housing 1 is connected to the shaft sleeve 23 or the first flow guiding plate 221, so that when the air blocking plate 211 is located at the open position, the side surfaces of the air blocking plate 211 and the first flow guiding plate 221 facing the side air outlet 14 are suitable for guiding the air flow flowing to the flow guiding mechanism to blow out from the side air outlet 14; when the wind deflector 211 is located at the closed position, the wind deflector 211 and the second flow deflector 222 are adapted to guide the airflow flowing to the flow guiding mechanism to be blown out from the front air outlet 13 towards the side of the cross-flow fan blade assembly 4. The guide mechanism guides the airflow, and avoids the generation of loud noise caused by the direct collision of the airflow with the inner wall of the shell 1.

Alternatively, as shown in fig. 3 and 4, the side air outlet 14 includes a left air outlet 141 and a right air outlet 142 respectively disposed at two ends of the housing 1 in the length direction; the two diversion mechanisms 2 are respectively arranged at an air channel turnout between the left air outlet 141 and the front air outlet 13 and an air channel turnout between the right air outlet 142 and the front air outlet 13; and the motors 212 of the two guiding mechanisms 2 are arranged in parallel.

In this embodiment, preferably, the left end (i.e. the end of the casing 1 located in the Y axis direction in fig. 3) and the right end (i.e. the end of the casing 1 located in the Y axis direction in fig. 3) of the casing 1 are both provided with the side air outlet 14, specifically, the left end of the casing 1 is provided with the left air outlet 141, and the right end of the casing 1 is provided with the right air outlet 142, so that the air conditioner can simultaneously perform front air outlet, left air outlet and right air outlet, so as to further enrich the air outlet mode of the air conditioner, and make the air outlet direction and the angle of the air conditioner wider. The diversion mechanisms 2 are respectively arranged at an air duct intersection between the left air outlet 141 and the front air outlet 13 and an air duct intersection between the right air outlet 142 and the front air outlet 13 so as to control the opening or closing of the left air outlet 141 and the right air outlet 142.

Further, the two diversion mechanisms 2 may be controlled synchronously or independently. When the two air guiding mechanisms 2 are synchronously controlled, the motors 212 of the two air guiding mechanisms 2 are arranged in series, namely the motors 212 of the two air guiding mechanisms 2 are suitable to be turned on or turned off simultaneously; when the two air guiding mechanisms 2 are independently controlled, the motors 212 of the two air guiding mechanisms 2 are arranged in parallel, that is, the motors 212 of the two air guiding mechanisms 2 can be simultaneously turned on or off, and one of the motors 212 of the two air guiding mechanisms 2 can be turned on while the other is turned off. In this embodiment, it is preferable that the motors 212 of the two diversion mechanisms 2 are arranged in parallel to enrich the air outlet mode of the air conditioner.

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

Claims (15)

1. An air conditioner is characterized by comprising a shell (1), a heat exchanger (5) arranged in the shell (1), a cross-flow fan blade assembly (4) and a flow guide mechanism (2); a front air outlet (13) is formed in one end of the shell (1) in the width direction; the heat exchanger (5) is positioned on one side, away from the front air outlet (13), of the cross-flow fan blade assembly (4); the air-conditioning device is characterized in that a side air outlet (14) is formed in the end part of the shell (1) in the length direction, the flow guide mechanism (2) is arranged at an air duct intersection between the side air outlet (14) and the front air outlet (13) and is suitable for opening or closing the side air outlet (14).

2. The air conditioner according to claim 1, wherein an upper air inlet (11) and a lower air inlet (12) are respectively provided at both ends of the housing (1) in the vertical direction, and the heat exchanger (5) is located between the upper air inlet (11) and the lower air inlet (12).

3. The air conditioner according to claim 1, wherein the cross-flow fan blade assembly (4) comprises a first cross-flow fan blade (41), a second cross-flow fan blade (42) and a fan blade motor (43), the fan blade motor (43) is arranged between the first cross-flow fan blade (41) and the second cross-flow fan blade (42), and the fan blade motor (43), the first cross-flow fan blade (41) and the second cross-flow fan blade (42) are coaxially arranged.

4. The air conditioner according to claim 3, characterized in that the fan blade motor (43) is located at a middle position in the housing (1), and the first and second through-flow fan blades (41, 42) are symmetrically arranged with respect to the fan blade motor (43).

5. The air conditioner according to claim 3 or 4, characterized in that it further comprises a wind guiding mechanism (3) arranged at said front outlet (13) and/or said side outlet (14), said wind guiding mechanism (3) being adapted to adjust the wind outlet angle of said front outlet (13) and/or said side outlet (14).

6. The air conditioner according to claim 5, wherein the front air outlet (13) comprises a first front air outlet (131) and a second front air outlet (132), and the positions of the first front air outlet (131) and the second front air outlet (132) correspond to the positions of the first cross-flow fan blade (41) and the second cross-flow fan blade (42), respectively; the air guide mechanism (3) comprises a first air guide structure (31) and a second air guide structure (32), and the first air guide structure (31) and the second air guide structure (32) are respectively arranged at the first front air outlet (131) and the second front air outlet (132).

7. The air conditioner as claimed in claim 6, wherein the air guiding mechanism (3) further comprises a first air guiding motor and a second air guiding motor, the first air guiding motor is adapted to drive the first air guiding structure (31) to rotate to adjust the air outlet angle at the first front air outlet (131), the second air guiding motor is adapted to drive the second air guiding structure (32) to rotate to adjust the air outlet angle at the second front air outlet (132), and the first air guiding motor and the second air guiding motor are arranged in parallel.

8. The air conditioner according to claim 6 or 7, wherein the first wind guiding structure (31) comprises a first wind guiding plate (311) and/or a second wind guiding plate (312), the first wind guiding plate (311) is adapted to adjust the wind outlet angle at the first front wind outlet (131) in the vertical direction, and the second wind guiding plate (312) is adapted to adjust the wind outlet angle at the first front wind outlet (131) in the length direction of the first front wind outlet (131).

9. The air conditioner according to any one of claims 1 to 4 or 6 to 7, wherein the deflector mechanism (2) comprises a wind shielding assembly (21) and a deflector assembly (22), the wind shielding assembly (21) is adapted to open or close the side outlet (14), and the deflector assembly (22) is adapted to guide the airflow flowing to the deflector assembly (22) to be blown out from the side outlet (14) and/or the front outlet (13) when the wind shielding assembly (21) opens the side outlet (14).

10. The air conditioner according to claim 9, characterized in that the wind deflector assembly (21) comprises a wind deflector (211) adapted to be arranged within the housing (1) and a motor (212), the wind deflector (211) having a closed position and an open position, the motor (212) being adapted to drive the wind deflector (211) to switch between the closed position and the open position; the wind deflector (211) is adapted to shield the side outlet vents (14) when the wind deflector (211) is in the closed position; when the wind deflector (211) is in the open position, the wind deflector (211) is adapted to open the side outlet vents (14) to communicate the side outlet vents (14) with the external space of the air conditioner.

11. The air conditioner according to claim 10, wherein the wind deflector (211) includes a wind-deflecting portion (2111) and a link portion (2112), the wind-deflecting portion (2111) being adapted to shield the side wind outlet (14), the link portion (2112) being connected to the motor (212), the motor (212) being adapted to drive the wind-deflecting portion (2111) to rotate about an axis of the link portion (2112) so that the wind deflector (211) is located at the closed position or the open position.

12. The air conditioner according to claim 11, wherein the wind shielding assembly (21) further comprises a shaft sleeve (23) sleeved on the connecting rod portion (2112), and a limiting structure is arranged on the shaft sleeve (23) and is adapted to cooperate with the wind shielding portion (2111) to limit the rotation angle of the wind shielding plate (211).

13. The air conditioner according to claim 12, wherein the air guide assembly (22) includes a first air guide plate (221) disposed within the housing (1); one end of the first guide plate (221) is connected with the shaft sleeve (23), and the other end of the first guide plate extends towards the side air outlet (14) and is connected to the shell (1); the first deflector (221) is adapted to direct an air flow flowing towards the first deflector (221) to be blown out from the side outlet opening (14) when the wind deflector (211) is in the open position.

14. The air conditioner according to claim 13, characterized in that the air guide assembly (22) further comprises a second air guide plate (222), one end of the second air guide plate (222) is connected with the shaft sleeve (23) or the first air guide plate (221), and the other end extends towards the front air outlet of the air conditioner and is connected to the shell (1); the second baffle (222) is adapted to direct the airflow flowing toward the second baffle (222) to exit the front air outlet.

15. The air conditioner according to any one of claims 10 to 14, wherein the side outlet (14) comprises a left outlet (141) and a right outlet (142) respectively provided at both ends of the housing (1) in a length direction thereof; the two diversion mechanisms (2) are respectively arranged at an air channel turnout between the left air outlet (141) and the front air outlet (13) and an air channel turnout between the right air outlet (142) and the front air outlet (13); and the motors (212) of the two diversion mechanisms (2) are arranged in parallel.

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