Patent Description:
With the improvement of people's living standards, vehicles have become an indispensable means of transportation for people's daily travel. To provide a comfortable in-vehicle environment for drivers and passengers, a ventilation system is usually arranged in a vehicle to supply air and adjust temperature according to actual requirements. The ventilation system comprises an air inlet and air vents. The air inlet is usually arranged in an upper left corner of a vehicle engine compartment and at a position close to a lower left corner of a front windshield. This position is a positive pressure area of the vehicle, and can ensure that enough air enters the vehicle. In addition, this position is relatively high, with relatively few pollutants such as vehicle exhaust gas and dust, which can also ensure quality of air entering a compartment. The air vents (or referred to as pressure relief ports or ventilation ports) are usually arranged on two sides of a vehicle trunk, below rear wheel arches or on left and right side walls. The positions are each a negative pressure area of the vehicle, with a pressure lower than that of the front of the vehicle and that inside the compartment. After the ventilation system of the vehicle is started, a fan rotates, and fresh air outside the vehicle is continuously sucked in from the air inlet. Next, fresh air enters the compartment through an air outlet arranged in the compartment along a ventilation pipe. After the air enters the compartment, the pressure in the compartment increases, which makes the air in the compartment flow out from the air vents in the negative pressure area, thereby implementing good air circulation. The ventilation system further comprises a cooling device and a heating device to regulate the air entering the compartment.

In the prior art, an air outlet of the vehicle ventilation system is usually arranged close to an instrument panel, so that the ventilation system can conveniently heat, cool and ventilate a local environment of a front row of the vehicle, and defrost a front windshield in a low temperature environment. For example, <CIT> discloses a vehicle interior ventilation system installed in a dashboard of a motor vehicle. <CIT> and <CIT> disclose similar ventilation systems installed in a vehicle front. However, most low-configuration vehicles each do not have an air outlet at a back row, resulting in uneven air output from the ventilation system and a difference between a front row temperature and a back row temperature, which greatly reduces user experience of the driver and the passenger. To solve the foregoing problems, <CIT> discloses a device for distributing and diffusing climatization air to the rear seats of passenger cars which device is located at backrests of front seats of the passenger cars. Further, an air outlet structure arranged on a vehicle column also has been developed in the prior art. For example, Chinese utility model patent <CIT> discloses a vehicle column and vehicle with an air outlet structure. An air duct arranged in a length direction of the column is arranged in the vehicle column, a column air outlet unit is arranged on the vehicle column to make the air duct communicate with a cabin of the vehicle, and an air door assembly capable of controlling on-off is arranged corresponding to the column air outlet unit. The air outlet structure can improve a situation of uneven air output of a back row space and a front row space of the vehicle. However, the air outlet structure outputs air through a plurality of air outlet micropores formed in the column, the air blown out from the air outlet micropores directly blows to the passenger, and an air supply range is relatively narrow.

To solve or at least improve the foregoing problems in the prior art, that is, the technical problems in the prior art that an air outlet structure of a vehicle directly blows air to a passenger and has a relatively narrow air supply range, the invention provides an air outlet structure as defined in independent claim <NUM>. Preferred embodiments of the present invention are laid down in the appended dependent claims.

The air outlet structure according to the invention comprises the air duct, the first air outlet, the second air outlet, the first air-inducing channel, and the second air-inducing channel. The first air-inducing channel is configured to extend to the first air outlet from the air duct, the second air-inducing channel is configured to extend to the second air outlet from the air duct, and the first air-inducing channel and the second air-inducing channel are configured in such a manner that a first airflow flowing out of the first air outlet and a second airflow flowing out of the second air outlet can intersect and scatter each other. The first air outlet and the second air outlet are configured to be spaced apart from each other and parallel to each other, which enables the first airflow and the second airflow to have a larger range of scattering each other, thereby enhancing the scattering effect. It should be noted that "the first air outlet and the second air outlet are parallel to each other" here means that a center line of the first air outlet in a height (also referred to as "length") direction thereof and a center line of the second air outlet in a height (also referred to as "length") direction thereof are parallel to each other, so as to increase a common coverage range of the first airflow and the second airflow in the height or length direction of the air outlet. In a situation that the common coverage range of the first airflow and the second airflow is increased, the first airflow and the second airflow are scattered by each other, so that the air supply range can be significantly expanded, the effect of three-dimensional air supply can be implemented, and the first airflow and the second airflow can be further prevented from directly blowing air to the passenger. In addition, the arrangement of the first air-inducing channel and the second air-inducing channel can further enhance the flow guide effect on the first airflow and the second airflow and improve air supply efficiency.

In a preferred technical solution of the foregoing air outlet structure, the first air outlet and the second air outlet are slit-shaped openings. Through the configuration of the first air outlet and the second air outlet into the slit-shaped openings, the effect of hiding the air outlet can be achieved, and hidden air output is implemented.

In a preferred technical solution of the foregoing air outlet structure, aspect ratios of the first air outlet and the second air outlet are each in a range of being greater than or equal to <NUM>. The setting of an appropriate aspect ratio enables the first air outlet and the second air outlet to have a relatively small width to meet requirements for hidden air output, and enables the first air outlet and the second air outlet to have a relatively large height (also referred to as "length"), thereby ensuring that the air outlet structure has a relatively large air outlet area and ventilation quantity.

According to the invention, the air duct comprises: a first air outlet section and a second air outlet section, the first air outlet section and the second air outlet section being spaced apart from each other and arranged side by side, the first air outlet section being provided with a first outlet that matches the first air-inducing channel, and the second air outlet section being provided with a second outlet that matches the second air-inducing channel; and an air inlet section, the air inlet section having a first air inlet section and a second air inlet section separated by a partition plate that extends in a height direction of the air inlet section, the first air inlet section communicating with the first air outlet section, and the second air inlet section communicating with the second air outlet section. The first air inlet section and first air outlet section for the first airflow to circulate and the second air inlet section and second air outlet section for the second airflow to circulate are arranged in one air duct, so that the structure of the air duct can be more compact, and an occupied space is smaller, thereby obtaining a larger ventilation quantity.

In a preferred technical solution of the foregoing air outlet structure, a first swing blade assembly extending in a height direction of the first air outlet section is formed in the first air outlet section, the first swing blade assembly comprises a plurality of first swing blades spaced apart from each other and a first connecting rod, and each of the first swing blades is configured to be rotatably attached to the first connecting rod and be capable of swinging up and down toward the first outlet; and a second swing blade assembly extending in a height direction of the second air outlet section is formed in the second air outlet section, the second swing blade assembly comprises a plurality of second swing blades that are spaced apart from each other and a second connecting rod, and each of the second swing blades is configured to be rotatably attached to the second connecting rod and be capable of swinging up and down toward the second outlet. Through the arrangement of the first swing blade assembly in the first air outlet section and the arrangement of the second swing blade assembly in the second air outlet section, the air outlet range of the first airflow and the second airflow in the height direction can be expanded, and the uniformity of air output is further improved.

In a preferred technical solution of the foregoing air outlet structure, an air valve is arranged in the air inlet section, and the air valve is configured to be capable of adjusting an air volume in the first air inlet section and an air volume in the second air inlet section. Through the arrangement of the air valve in the air inlet section, the air volume in the first air inlet section and the air volume in the second air inlet section can be conveniently adjusted, so that the air volume of the first airflow flowing out from the first air outlet section and the second airflow flowing out from the second air outlet section can be adjusted, so as to generate various combinations and obtain a more uniform air outlet effect.

The invention further provides a column as defined in the appended claims <NUM>-<NUM>. Through the use of the air outlet structure according to any one of the foregoing implementations, the column according to the invention can significantly expand the air supply range, improve uniformity of air supply, and prevent the airflow from directly blowing air to the passenger.

In a preferred technical solution of the foregoing column, the air outlet structure further comprises an air deflector, the air deflector has a first end and a second end opposite each other, the first end is configured to be spaced apart from the first longitudinal wall to form the first air-inducing channel, and the second end is configured to match the second air outlet section to form the second air-inducing channel. The air deflector is provided and the first end and the second end of the air deflector are configured to match the first longitudinal wall and the second air outlet section so as to form the first air-inducing channel and the second air-inducing channel, so that the air outlet structure according to the invention can be more compact in structure and more reasonable in design.

In a preferred technical solution of the foregoing column, the first end is configured as an arc-shaped wall extending from a body of the air deflector to the first outlet in a direction away from the body, the arc-shaped wall abuts against a first inner wall of the first air outlet section close to the body, and the arc-shaped wall is spaced apart from the first longitudinal wall to form the first air-inducing channel. The arc-shaped wall is configured to abut against the first inner wall of the first air outlet section close to the body of the air deflector, which can prevent the first airflow from flowing out from an assembly gap between the first air outlet section and the first end, thereby avoiding lowering air outlet efficiency. The first air-inducing channel formed by spacing the arc-shaped wall and the first longitudinal wall enables the first airflow flowing out of the first outlet to conveniently flow out from the first air outlet section, so as to improve air outlet efficiency. In addition, the arc-shaped first end matches the first longitudinal wall, so that after flowing out of the first air outlet, the first airflow can be affected by the body of the air deflector to generate the Coanda effect, and therefore flows in the direction close to the body of the air deflector, thereby further improving the flow guide effect.

In a preferred technical solution of the foregoing column, the first air outlet section has a first inner wall abutting against the first longitudinal wall extending in a horizontal direction and a first sidewall close to the second air outlet section, and the first inner wall and the first sidewall are spaced apart in a direction perpendicular to the first longitudinal wall to form the first outlet; and the first end extends in the horizontal direction and is connected to the first sidewall at the first outlet, and the first longitudinal wall is configured to be capable of covering the first outlet, so as to define the first air-inducing channel between the first end and the first longitudinal wall. The first end and the first longitudinal wall are both configured to extend in the horizontal direction to form, by spacing, the first air-inducing channel that also extends in the horizontal direction, so that the flow guide effect of the first air-inducing channel can be enhanced. In addition, more abundant products can be further obtained through the foregoing configuration.

In a preferred technical solution of the foregoing column, the second air outlet section is provided with a flow guide support that is capable of abutting against the second longitudinal wall, the flow guide support has a flow guide wall that extends obliquely toward the second longitudinal wall from the second outlet to the second air outlet, and the second end is configured to extend toward the second outlet from the body of the air deflector and be parallel to the flow guide wall to form the second air-inducing channel. Through the arrangement of the second air-inducing channel, the second airflow in the second air outlet section can be guided out more conveniently, so as to improve air outlet efficiency. In addition, the second end is configured to be parallel to the flow guide wall on the second air outlet section to form the second air-inducing channel, which can further reduce wind resistance and improve the flow guide effect.

The invention further provides a vehicle as defined in the appended claim <NUM>.

Through the foregoing configuration, the vehicle according to the invention can significantly expand the air supply range, improve uniformity of air supply, and prevent the airflow from directly blowing air to the passenger.

Preferred implementations of the invention are described below with reference to drawings. Among the drawings:.

List of reference numerals:
<NUM>. Vehicle; <NUM>. Column; 11a. A column; 11b. B column; 11c. C column; <NUM>. First longitudinal wall; <NUM>. Arc-shaped section; <NUM>. Second longitudinal wall; <NUM>. Air outlet structure; <NUM>. Air duct; <NUM>. First air outlet section; <NUM>. First outlet; <NUM>. First inner wall; <NUM>. First sidewall; <NUM>. Second air outlet section; <NUM>. Second outlet; <NUM>. Flow guide support; 2122a. Flow guide wall; 2122b. Inclined wall; 2122c. Straight wall; <NUM>. Second inner wall; <NUM>. Air inlet section; <NUM>. First air inlet section; <NUM>. Second air inlet section; <NUM>. Partition plate; <NUM>. Air valve; <NUM>. Blade; <NUM>. Rotating shaft; <NUM>. Air inlet; <NUM>. First air outlet; <NUM>. Second air outlet; <NUM>. First air-inducing channel; <NUM>. Second air-inducing channel; <NUM>. Air deflector; <NUM>. First end; <NUM>. Arc-shaped wall; <NUM>. Second end; <NUM>. Body; <NUM>. First swing blade assembly; <NUM>. First swing blade; <NUM>: First connecting rod; <NUM>. Second swing blade assembly; <NUM>. Second swing blade; and <NUM>: Second connecting rod.

Preferred implementations of the invention are described below with reference to the drawings. It should be understood by those skilled in the art that these implementations are only for explaining the technical principles of the invention and are not intended to limit the scope of protection of the invention.

It should be noted that, in the description of the invention, the terms that indicate the direction or positional relationship, such as "upper", "lower", "left", "right", "inner", and "outer", are based on the direction or positional relationship shown in the figures, which is merely for ease of description instead of indicating or implying that the device or element must have a particular orientation and be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only, and cannot be understood as indicating or implying relative importance.

In addition, it should also be noted that, in the description of the invention, the terms "arrange" and "connect" should be interpreted in a broad sense unless explicitly defined and limited otherwise. For example, a connection may be a fixed connection, a detachable connection, or an integral connection; and may be a direct connection, an indirect connection by means of an intermediary, or internal communication between two elements. For those skilled in the art, the specific meaning of the above-mentioned terms in the invention can be interpreted according to a specific situation.

To solve or at least improve the technical problems in the prior art that an air outlet structure of a vehicle directly blows air to a passenger and has a relatively narrow air supply range, the invention provides an air outlet structure <NUM>. The air outlet structure <NUM> comprises: an air duct <NUM>; a first air outlet <NUM> and a second air outlet <NUM>, the first air outlet <NUM> and the second air outlet <NUM> being configured to be spaced apart from each other and parallel to each other; and a first air-inducing channel <NUM> and a second air-inducing channel <NUM>, the first air-inducing channel <NUM> extending to the first air outlet <NUM> from the air duct <NUM>, the second air-inducing channel <NUM> extending to the second air outlet <NUM> from the air duct <NUM>, and the first air-inducing channel <NUM> and the second air-inducing channel <NUM> being configured in such a manner that a first airflow F<NUM> flowing out of the first air outlet <NUM> and a second airflow F<NUM> flowing out of the second air outlet <NUM> intersect and scatter each other.

The term "Coanda effect" mentioned herein refers to the tendency of a fluid (a water flow or an airflow, or the like) to move away from an original flow direction and instead flow along a convex object surface, unless expressly stated to the contrary. The term "aspect ratio" refers to a ratio of a dimension of an object in a height (or length) direction thereof to a dimension of the object in a width direction.

As shown in <FIG>, in one or more embodiments, the vehicle <NUM> comprising an air outlet structure <NUM> according to the invention is a car. Alternatively, the vehicle <NUM> comprising an air outlet structure <NUM> according to the invention may be an SUV, an MPV, a van or another suitable vehicle. The vehicle <NUM> comprises a column <NUM>. In one or more embodiments, the column <NUM> may be made of suitable steel by welding, hydroforming or other suitable processes, so that the column <NUM> has higher rigidity to achieve the effect of supporting a vehicle body structure. In one or more embodiments, one side of the column <NUM> close to the inside of the compartment is wrapped with a carbon fiber composite or other suitable materials, so as to achieve the effects of vibration reduction, noise reduction, vehicle body weight reduction, and the like. The column <NUM> comprises an A column 11a (or referred to as "front column") located in the front of the vehicle <NUM>, a B column 11b (or referred to as "middle column") located at the middle of the vehicle <NUM>, and a C column 11c (or referred to as "rear column") located at the rear of the vehicle <NUM>. The A column 11a, the B column 11b and the C column 11c are arranged in a bilateral symmetry manner along a center line of the vehicle <NUM>. As shown in <FIG>, in one or more embodiments, an air outlet structure <NUM> is arranged on the B column 11b on the right side of the vehicle <NUM>. The air outlet structure <NUM> is configured to communicate with a ventilation system (not shown in the figure) of the vehicle <NUM> through a ventilation pipeline (not shown in the figure), so that an airflow treated by the ventilation system can be conveniently conveyed through the inside of the compartment, so as to achieve objectives of ventilation and temperature regulation. Alternatively, the air outlet structure <NUM> may be arranged on another suitable column of the vehicle <NUM>, such as the column 11a or the C column 11c. Alternatively, the air outlet structure <NUM> may be arranged at another suitable position of the vehicle <NUM>, such as a ceiling.

A first embodiment of an air outlet structure according to the invention is described in detail below with reference to <FIG>.

As shown in <FIG>, in one or more embodiments, the air outlet structure <NUM> according to the invention comprises an air duct <NUM>, a first air outlet <NUM>, a second air outlet <NUM>, a first air-inducing channel <NUM>, a second air-inducing channel <NUM>, and an air deflector <NUM>. The air duct <NUM> is arranged in the column <NUM>, so that the air duct <NUM> can be hidden inside the column <NUM> without being seen by a user, so as to achieve an aesthetic effect. The air duct <NUM> is integrally molded by injection molding by using a suitable resin material to simplify a manufacturing process and reduce a manufacturing cost. As shown in <FIG>, the air duct <NUM> comprises a first air outlet section <NUM>, a second air outlet section <NUM>, and an air inlet section <NUM>. The first air outlet section <NUM> and the second air outlet section <NUM> are spaced apart from each other and arranged side by side. A first outlet <NUM> capable of communicating with the first air outlet <NUM> is formed on the first air outlet section <NUM>, and a second outlet <NUM> capable of communicating with the second air outlet <NUM> is formed on the second air outlet section <NUM>. Based on the orientation shown in <FIG>, the first air outlet section <NUM> is configured to extend from an upper portion of the air inlet section <NUM> toward an upper left side and abut against a first longitudinal wall <NUM> of the column <NUM>. Accordingly, the second air outlet section <NUM> is configured to extend from the upper portion of the air inlet section <NUM> toward an upper right side and abut against a second longitudinal wall <NUM> of the column <NUM>, so that the air duct <NUM> is substantially in a Y shape. Through the foregoing configuration, the structure of the air duct <NUM> is simpler, so as to fully utilize the space in the column <NUM> and improve a space utilization rate. Alternatively, the first air outlet section <NUM> is configured to extend from the air inlet section <NUM> toward the upper right side and abut against the second longitudinal wall <NUM>, and the second air outlet section <NUM> is configured to extend from the air inlet section <NUM> toward the upper left side and abut against the first longitudinal wall <NUM>. Alternatively, the air duct <NUM> may be configured as two independent air ducts or other suitable forms.

As shown in <FIG>, in one or more embodiments, the first air outlet section <NUM> has a first inner wall <NUM> close to one side of the air deflector <NUM>. The first inner wall <NUM> is configured to abut against the air deflector <NUM>, so as to prevent the first airflow F<NUM> from flowing out from an assembly gap between the first air outlet section <NUM> and the air deflector <NUM>, thereby avoiding lowering air outlet efficiency.

As shown in <FIG>, in one or more embodiments, a first swing blade assembly <NUM> is further arranged in the first air outlet section <NUM>. As shown in <FIG>, <FIG> and <FIG>, in one or more embodiments, the first swing blade assembly <NUM> comprises nine first swing blades <NUM> evenly spaced apart from each other in a vertical direction and a first connecting rod <NUM>. Alternatively, the number of the first swing blades <NUM> may be set to another suitable number greater or less than nine. As shown in <FIG>, based on the orientation shown in <FIG>, each first swing blade <NUM> is configured to swing toward the right side, that is, toward the first outlet <NUM>. A swinging angle of the first swing blade <NUM> may be adjusted according to actual needs, for example, to <NUM>°, <NUM>°, or <NUM>°. Each first swing blade <NUM> is configured to be rotatably attached to the first connecting rod <NUM>. The first connecting rod <NUM> is configured to be connected to a first motor (not shown in the figure). The first motor includes, but is not limited to, a stepping motor, a servo motor, or the like. The first motor is controlled to drive the first connecting rod <NUM> to reciprocate in the vertical direction, so that the first swing blade <NUM> swings up and down, further expanding the air outlet range of the first airflow F<NUM>.

As shown in <FIG>, in one or more embodiments, the second air outlet section <NUM> has a second inner wall <NUM> close to one side of the air deflector <NUM>. The second inner wall <NUM> is configured to abut against the air deflector <NUM>, so as to prevent the second airflow F<NUM> from flowing out from an assembly gap between the second air outlet section <NUM> and the air deflector <NUM>, thereby avoiding lowering air outlet efficiency. In one or more embodiments, the second air outlet section <NUM> is provided with a flow guide support <NUM> abutting against the second longitudinal wall <NUM>. The flow guide support <NUM> comprises a straight wall 2122c, an inclined wall 2122b and a flow guide wall 2122a that are connected in sequence. The straight wall 2122c abuts against the second longitudinal wall <NUM>. Based on the orientation shown in <FIG>, the inclined wall 2122b is configured to extend from a tail end of the straight wall 2122c toward the lower right to the second outlet <NUM>. The flow guide wall 2122a is configured to extend from the second outlet <NUM> toward the lower left to an edge of the second longitudinal wall <NUM>.

As shown in <FIG>, in one or more embodiments, a second swing blade assembly <NUM> is further arranged in the second air outlet section <NUM>. As shown in <FIG>, <FIG> and <FIG>, in one or more embodiments, the second swing blade assembly <NUM> comprises nine second swing blades <NUM> evenly spaced apart from each other in a vertical direction and a second connecting rod <NUM>. Alternatively, the number of the second swing blades <NUM> may be set to another suitable number greater or less than nine. As shown in <FIG>, based on the orientation shown in <FIG>, each second swing blade <NUM> is configured to swing toward the left side, that is, toward the second outlet <NUM>. A swinging angle of the second swing blade <NUM> may be adjusted according to actual needs, for example, to <NUM>°, <NUM>°, or <NUM>°. Each second swing blade <NUM> is configured to be rotatably attached to the second connecting rod <NUM>. The second connecting rod <NUM> is configured to be connected to a second motor (not shown in the figure). The second motor includes, but is not limited to, a stepping motor, a servo motor, or the like. The second motor is controlled to drive the second connecting rod <NUM> to reciprocate in the vertical direction, so that the second swing blade <NUM> swings up and down, further expanding the air outlet range of the second airflow F<NUM>.

As shown in <FIG>, in one or more embodiments, the air inlet section <NUM> is provided with an air inlet <NUM> capable of communicating with a ventilation system of the vehicle <NUM> so as to receive an airflow from the ventilation system. The air inlet section <NUM> is further provided with a partition plate <NUM> extending in a vertical direction to partition the air inlet section <NUM> into a first air inlet section <NUM> and a second air inlet section <NUM>. The first air inlet section <NUM> is configured to communicate with the first air outlet section <NUM>. Accordingly, the second air inlet section <NUM> is configured to communicate with the second air outlet section <NUM>. In one or more embodiments, an air valve <NUM> is arranged in the air inlet section <NUM> close to the air inlet <NUM> to adjust an air volume in the first air inlet section <NUM> and an air volume in the second air inlet section <NUM>. In one or more embodiments, the air valve <NUM> comprises a blade <NUM> and a rotating shaft <NUM>. The blade <NUM> is configured to rotate about the rotating shaft <NUM> so as to adjust an angle of the blade <NUM> in the air inlet section <NUM>. The rotating shaft <NUM> is configured to be connected to a third motor (not shown in the figure), so as to control a rotation angle of the blade <NUM> by driving the motor to rotate. The third motor includes, but is not limited to, a stepping motor, a servo motor, or the like.

As shown in <FIG>, in one or more embodiments, the air deflector <NUM> is a single part and is arranged between the first longitudinal wall <NUM> and the second longitudinal wall <NUM> opposite each other. The air deflector <NUM> is formed independently of the first longitudinal wall <NUM> and the second longitudinal wall <NUM>. The arrangement of the air deflector <NUM> can not only guide a wind direction, but also effectively shield the air duct <NUM>, which achieves an aesthetic effect. The air deflector <NUM> may be integrally molded by injection molding by using PP, ABS, or another suitable resin material to simplify a manufacturing process.

As shown in <FIG>, the air deflector <NUM> comprises a first end <NUM>, a second end <NUM>, and a body <NUM>. The body <NUM> is configured as a square plate extending substantially in a horizontal direction. In one or more embodiments, the body <NUM> is an arc-shaped body that bulges away from the column <NUM>, and has a predetermined radian that meets actual needs. Based on the orientation shown in <FIG>, the first end <NUM> is configured to extend from a right end of the body <NUM> to the first outlet <NUM> on the first air outlet section <NUM> in a direction away from the body <NUM>, that is, to extend obliquely toward the upper right. In one or more embodiments, the first end <NUM> is an arc-shaped wall <NUM>, and the arc-shaped wall <NUM> protrudes in a direction away from the first air outlet section <NUM>. The first longitudinal wall <NUM> has an arc-shaped section <NUM> approximately parallel to the arc-shaped wall <NUM>. The arc-shaped section <NUM> and the arc-shaped wall <NUM> are spaced apart from each other to form the first air-inducing channel <NUM>, and a tail end of the arc-shaped section <NUM> matches the arc-shaped wall <NUM> to form the first air outlet <NUM>. As shown in <FIG>, in one or more embodiments, the first air outlet <NUM> is an approximately slit-shaped opening extending in the vertical direction, so that the first air outlet <NUM> is not easily perceived by a user, to achieve the effect of hiding the air outlet, thereby implementing hidden air output and also achieving the beautifying effect. An aspect ratio of the first air outlet <NUM> is in a range of being greater than or equal to <NUM>. In one or more embodiments, the first air outlet <NUM> has a width of <NUM>, and the first air outlet <NUM> has a height of <NUM>, that is, the aspect ratio of the first air outlet <NUM> is <NUM>. The setting of an appropriate aspect ratio enables the first air outlet <NUM> to have a smaller width to achieve the objective of hidden air output, and a larger air outlet area can be obtained to increase the air output. It can be understood that the first airflow F<NUM> conveyed to the first air outlet section <NUM> through the ventilation system can conveniently flow from the first outlet <NUM> along the first air-inducing channel <NUM> and flow out from the first air outlet <NUM>. The arrangement of the first air-inducing channel <NUM> can improve air outlet efficiency of the first air outlet section <NUM>. In addition, the first airflow F<NUM> flowing out of the first air outlet <NUM> is affected by the air deflector <NUM> to generate the Coanda effect, and therefore flows in the direction close to the body <NUM>. Specifically, as shown in the direction of the arrow in <FIG>, the first airflow F<NUM> first flows toward the right side, and then is guided by the first air-inducing channel <NUM> to flow toward the left side.

As shown in <FIG>, in one or more embodiments, the second end <NUM> is configured to extend from the left side of the body <NUM> toward the upper right to the second outlet <NUM> of the second air outlet section <NUM>. Alternatively, the second end <NUM> may be configured to extend from the right side of the body <NUM> toward the upper left to the second outlet <NUM> of the second air outlet section <NUM>, while the first end <NUM> is configured to extend from the left side of the body <NUM> toward the upper left to the first outlet <NUM> of the first air outlet section <NUM>. At this time, the positions of the first air outlet section <NUM> and the second air outlet section <NUM> are exchanged, and the positions of the first longitudinal wall <NUM> and the second longitudinal wall <NUM> are also exchanged. In one or more embodiments, a tail end of the second end <NUM> is configured to be substantially parallel to the flow guide wall 2122a of the flow guide support <NUM>, and define the second air-inducing channel <NUM>. A tail end of the flow guide wall 2122a matches the second end <NUM> to form the second air outlet <NUM>. As shown in <FIG>, in one or more embodiments, the second air outlet <NUM> is an approximately slit-shaped opening extending in the vertical direction, so that a vertical center line of the second air outlet <NUM> is parallel to a vertical center line of the first air outlet <NUM>. The arrangement of the slit-shaped opening enables the second air outlet <NUM> not to be easily perceived by the user, to achieve the effect of hiding the air outlet, thereby implementing hidden air output and also achieving the beautifying effect. An aspect ratio of the second air outlet <NUM> is in a range of being greater than or equal to <NUM>. In one or more embodiments, the second air outlet <NUM> has a width of <NUM>, and the second air outlet <NUM> has a height of <NUM>, that is, the aspect ratio of the second air outlet <NUM> is <NUM>. The setting of an appropriate aspect ratio enables the second air outlet <NUM> to have a smaller width to achieve the objective of hidden air output, and a larger air outlet area can be obtained to increase the air output. In one or more embodiments, the second air outlet <NUM> is configured to have the same width and height as the first air outlet <NUM>, that is, the second air outlet <NUM> and the first air outlet <NUM> also have the same aspect ratio, so that the second air outlet <NUM> and the first air outlet <NUM> have the same air outlet area. It can be understood that the second airflow F<NUM> conveyed to the second air outlet section <NUM> through the ventilation system can conveniently flow from the second outlet <NUM> along the second air-inducing channel <NUM> and flow out from the second air outlet <NUM>. The arrangement of the second air-inducing channel <NUM> can improve air outlet efficiency of the second air outlet section <NUM>. As shown in the direction of the arrow in <FIG>, the second airflow F<NUM> flows toward the second outlet <NUM> on the left side from the inside of the second air outlet section <NUM>, and then is guided by the second air-inducing channel <NUM> to flow toward the lower left. At this time, the first airflow F<NUM> and the second airflow F<NUM> can intersect at a position close to the second air outlet <NUM> and scatter each other, which can not only improve uniformity of airflow distribution, but also expand the range of airflow distribution, and significantly improve air outlet uniformity of the air outlet structure <NUM>.

A second embodiment of an air outlet structure according to the invention is described in detail below with reference to <FIG>.

As shown in <FIG>, in one or more embodiments, the air outlet structure <NUM> according to the invention comprises an air duct <NUM>, a first air outlet <NUM>, a second air outlet <NUM>, a first air-inducing channel <NUM>, a second air-inducing channel <NUM>, and an air deflector <NUM>. The air duct <NUM> comprises a first air outlet section <NUM>, a second air outlet section <NUM>, and an air inlet section <NUM>. A first outlet <NUM> capable of communicating with the first air outlet <NUM> is formed on the first air outlet section <NUM>, and a second outlet <NUM> capable of communicating with the second air outlet <NUM> is formed on the second air outlet section <NUM>.

Based on the orientation shown in <FIG>, the first air outlet section <NUM> is configured to extend from an upper portion of the air inlet section <NUM> toward an upper left side and abut against a first longitudinal wall <NUM> of the column <NUM>. As shown in <FIG>, based on the orientation shown in <FIG>, the first longitudinal wall <NUM> is configured to extend leftward from the right side of the column <NUM> substantially in the horizontal direction, and be spaced apart from the second longitudinal wall <NUM> located on the left side of the column <NUM>. As shown in <FIG>, in one or more embodiments, the first air outlet section <NUM> has a first inner wall <NUM> abutting against the first longitudinal wall <NUM> and a first sidewall <NUM> close to the second air outlet section <NUM>. As shown in <FIG> and <FIG>, the first inner wall <NUM> and the first sidewall <NUM> are spaced by a certain distance in a direction perpendicular to the first longitudinal wall <NUM> to form a first outlet <NUM>.

As shown in <FIG>, in one or more embodiments, a first swing blade assembly <NUM> is further arranged in the first air outlet section <NUM>. As shown in <FIG>, <FIG> and <FIG>, in one or more embodiments, the first swing blade assembly <NUM> comprises nine first swing blades <NUM> evenly spaced apart from each other in a vertical direction and a first connecting rod <NUM>. Alternatively, the number of the first swing blades <NUM> may be set to another suitable number greater or less than nine. As shown in <FIG>, based on the orientation shown in <FIG>, each first swing blade <NUM> is configured to swing toward the left right, that is, toward the first outlet <NUM>.

As shown in <FIG>, in one or more embodiments, the air deflector <NUM> is arranged between the first longitudinal wall <NUM> and the second longitudinal wall <NUM> that are spaced apart from each other. As shown in <FIG>, the air deflector <NUM> comprises a first end <NUM>, a second end <NUM>, and a body <NUM>. The body <NUM> is configured as a square plate extending substantially in a horizontal direction. Based on the orientation shown in <FIG>, the first end <NUM> is configured to extend rightward from the body <NUM> to the first outlet <NUM> in a substantially parallel direction and abut against the first sidewall <NUM>. In other words, the first end <NUM> and the body <NUM> have an integral square plate structure. As shown in <FIG>, the first longitudinal wall <NUM> may cover the first outlet <NUM> and extend leftward from the first outlet <NUM> in a substantially horizontal direction. Therefore, the first longitudinal wall <NUM> and the first end <NUM> of the air deflector <NUM> are parallel to each other, and are spaced apart from each other by a predetermined distance to form the first air-inducing channel <NUM>. At this time, the first air-inducing channel <NUM> also extends substantially in the horizontal direction. The predetermined distance may be <NUM>, or another suitable distance greater or less than <NUM>. At the tail end of the left side of the first longitudinal wall <NUM>, the first longitudinal wall <NUM> matches the first end <NUM> to form the first air outlet <NUM>. It can be understood that the first airflow F<NUM> conveyed to the first air outlet section <NUM> through the ventilation system can conveniently flow from the first outlet <NUM> along the first air-inducing channel <NUM> and flow out from the first air outlet <NUM>.

It should be noted that other parts not mentioned in the second embodiment may be configured in the same way as the first embodiment, and will not be described in detail herein.

As shown in the arrow in <FIG>, the first airflow F<NUM> flows toward the first outlet <NUM> on the left side, then is guided by the first air-inducing channel <NUM> to flow leftward substantially in the horizontal direction, and flows out from the first air outlet <NUM>. The second airflow F<NUM> flows toward the second outlet <NUM> on the left side from the inside of the second air outlet section <NUM>, and then is guided by the second air-inducing channel <NUM> to flow toward the lower left. The first airflow F<NUM> and the second airflow F<NUM> intersect at a position close to the second air outlet <NUM> and scatter each other, which can not only improve uniformity of airflow distribution, but also expand the range of airflow distribution, and significantly improve air outlet uniformity of the air outlet structure <NUM>.

Claim 1:
An air outlet structure (<NUM>), comprising:
an air duct (<NUM>);
a first air outlet (<NUM>) and a second air outlet (<NUM>), the first air outlet (<NUM>) and the second air outlet (<NUM>) being configured to be spaced apart from each other and parallel to each other; and
a first air-inducing channel (<NUM>) and a second air-inducing channel (<NUM>), the first air-inducing channel (<NUM>) extending to the first air outlet (<NUM>) from the air duct (<NUM>), the second air-inducing channel (<NUM>) extending to the second air outlet (<NUM>) from the air duct (<NUM>), and the first air-inducing channel (<NUM>) and the second air-inducing channel (<NUM>) being configured in such a manner that a first airflow (F<NUM>) flowing out of the first air outlet (<NUM>) and a second airflow (F<NUM>) flowing out of the second air outlet (<NUM>) intersect and scatter each other, the air duct (<NUM>) comprises:
a first air outlet section (<NUM>) and a second air outlet section (<NUM>), the first air outlet section (<NUM>) and the second air outlet section (<NUM>) being spaced apart from each other and arranged side by side, the first air outlet section (<NUM>) being provided with a first outlet (<NUM>) that matches the first air-inducing channel (<NUM>), and the second air outlet section (<NUM>) being provided with a second outlet (<NUM>) that matches the second air-inducing channel (<NUM>); and
an air inlet section (<NUM>), characterized in that the air inlet section (<NUM>) has a first air inlet section (<NUM>) and a second air inlet section (<NUM>) separated by a partition plate (<NUM>) that extends in a height direction of the air inlet section (<NUM>), the first air inlet section (<NUM>) communicating with the first air outlet section (<NUM>), and the second air inlet section (<NUM>) communicating with the second air outlet section (<NUM>).