WO2023246547A1 - Vertical air conditioner indoor unit - Google Patents

Abstract

A vertical air conditioner indoor unit, comprising a first column shell, a second column shell, and a third column shell. The first column shell is vertical column-shaped, and a front side of the first column shell is provided with a first air outlet for blowing out a first airflow. The second column shell is vertical column-shaped, and a front side of the second column shell is provided with a second air outlet for blowing out a second airflow. The second column shell is arranged on a lateral side of the first column shell. An induced air space is formed between the second column shell and the first column shell, so that air in the induced air space flows forward under the action of negative pressure when air is discharged from the first air outlet and/or the second air outlet. The third column shell is vertical column-shaped, and a front side of the third column shell is provided with a third air outlet for blowing out a third airflow. The third column shell is rotatably arranged on a rear side of the induced air space around a first vertical axis. The vertical air conditioner indoor unit has an increased air discharge angle in an uniform air flow function mode.

Description

Vertical air conditioner indoor unit Technical field

The present invention relates to the technical field of air conditioning, and in particular to a vertical air conditioning indoor unit.

Background technique

With the development of the times and the advancement of technology, users not only expect faster cooling and heating speeds of air conditioners, but also pay more and more attention to the comfort performance of air conditioners. For example, when users use air conditioners for cooling, they may experience discomfort due to the low temperature and high wind speed of the air outlet air. This is what people often say is that the wind is too "hard" and not soft enough. Existing vertical air conditioner indoor units are usually equipped with a vertical strip-shaped air outlet on the front side of the casing, and the air guide device is used to swing the air up, down, left, and right to expand the air supply angle. On this basis, some existing technologies have made many improvements to the air outlet structure. However, due to the constraints of the direction of the air outlet itself, the air supply direction, air supply range and air supply distance of the air conditioner are still greatly restricted, making it difficult to satisfy users. needs.

Contents of the invention

In view of the above problems, the present invention is proposed to provide a vertical air conditioning indoor unit that overcomes the above problems or at least partially solves the above problems, and can solve the problems of too "hard" air blowing, small air supply angle, and short air supply distance. Able to achieve multiple air supply modes to improve user comfort.

Specifically, the present invention provides a vertical air conditioning indoor unit including:

A first column shell, the first column shell is in the shape of a vertical column, and a first air outlet for blowing out the first airflow is provided on the front side of the first column shell;

A second column shell, the second column shell is in the shape of a vertical column, and a second air outlet for blowing out the second airflow is provided on the front side of the second column shell; the second column shell is arranged on the first The lateral side of the column shell; an air induction interval is formed between the second column shell and the first column shell, so that the first air outlet and/or the second air outlet rely on negative pressure when they discharge air. The function drives the air in the air-inducing interval to flow forward;

A third column shell, the third column shell is in the shape of a vertical column, and a third air outlet for blowing out the third airflow is provided on the front side of the third column shell; the third column shell is arranged around the first vertical axis It is rotatably arranged on the rear side of the air induction partition.

Optionally, the ratio of the width of the second column shell in the transverse direction to the width of the first column shell in the transverse direction is less than 1/2; the depth dimension of the second column shell in the front-rear direction is the same as the width of the first column shell in front-to-back direction The ratio of depth to depth is less than 1/2;

The ratio of the width of the third column shell in the transverse direction to the width of the first column shell in the transverse direction is less than 1/2; the depth dimension of the third column shell in the front-to-back direction is the same as the width of the first column shell in the front-to-back direction. The ratio of depth to depth is less than 1/2.

Optionally, the third column housing is disposed on the rear side of the second column housing; the third column housing can rotate to a point where the third air outlet faces the second column housing and is away from the first column housing. side.

Optionally, the first vertical axis is located in the third column shell, and the first vertical axis is spaced apart from the third air outlet;

The first air outlet is in the shape of a vertical strip, the second air outlet is in the shape of a vertical strip, and the third air outlet is in the shape of a vertical strip; the first air outlet and the second air outlet are arranged in a transverse direction; The distance between the two side walls of the second cylindrical shell gradually becomes smaller from the back to the front, forming a tapered shape; the distance between the two side walls of the third cylindrical shell gradually becomes smaller from the back to the front, forming a tapered shape.

Optionally, the second column housing is rotatably disposed about a second vertical axis;

The second vertical axis is located in the second column shell, and the second vertical axis is spaced apart from the second air outlet.

Optionally, the vertical air conditioning indoor unit further includes a first cross-flow fan and a heat exchanger; the first cross-flow fan and the heat exchanger are arranged in the first column shell;

A first air inlet connected to the first air outlet is provided on the rear wall of the first column shell and the rear portions of the two side walls.

Optionally, the vertical air conditioner indoor unit also includes:

A second cross-flow fan, the second cross-flow fan is arranged vertically inside the second cylindrical shell; the second vertical axis is coaxial with the second cross-flow fan; the second cross-flow fan is A second air inlet connected to the second air outlet is provided at the rear; or,

The lower shell and the first induced draft fan are arranged below the second column shell and the third column shell; the lower end of the second column shell is provided with an inlet connected to the second air outlet. An air inlet, the first induced draft fan is disposed in the lower shell, and is used to introduce the second airflow into the air inlet at the lower end of the second column shell.

Optionally, the vertical air conditioner indoor unit also includes:

A third cross-flow fan, the third cross-flow fan is arranged vertically inside the third cylindrical shell; the first vertical axis is coaxial with the third cross-flow fan; the third cross-flow fan is A third air inlet connected to the third air outlet is provided at the rear; or,

The lower shell and the second induced draft fan are arranged below the second column shell and the third column shell; the lower end of the third column shell is provided with an inlet connected to the third air outlet. An air inlet, the second induced draft fan is disposed in the lower shell, and is used to introduce the third airflow into the air inlet at the lower end of the third column shell.

Optionally, the lower end of the second column housing is provided with an air inlet connected to the second air outlet;

The lower end of the third column shell is provided with an air inlet connected to the third air outlet;

The vertical air conditioner indoor unit also includes:

A lower shell, the lower shell is arranged below the second column shell and the third column shell;

A third induced draft fan, the third induced draft fan is disposed in the lower shell and is used to introduce the second airflow and the third airflow into the air inlet at the lower end of the second column shell and the The air inlet at the lower end of the third column shell.

Optionally, the second air outlet is in the shape of a vertical strip;

A first air duct connected to the second air outlet is provided in the second column shell;

A plurality of first guide fins arranged vertically are provided in the first air duct, each of the first guide fins extends from front to back, and the rear end is bent downward to form a first guide bending portion. ;The higher the position, the greater the distance between the front and rear ends of the first deflector;

The third air outlet is in the shape of a vertical strip;

A second air duct connected to the third air outlet is provided in the third column shell;

A plurality of second guide fins arranged vertically are provided in the second air duct. Each second guide fin extends from front to back, and the rear end is bent downward to form a second guide bend. ; The distance between the front and rear ends of the second guide vane is greater as it is positioned higher up.

The vertical air conditioner indoor unit of the present invention uses the first column housing to blow out the first air flow, and uses the second column housing to blow out the second air flow. An air induction interval is formed between the first column housing and the second column housing. In this way, when the first column shell and the second column shell discharge air in front of each other at the same time, a negative pressure environment is formed at the air induction interval, which promotes the indoor air behind the vertical air conditioner indoor unit to flow forward through the air induction interval, so as to The outlet airflow of the first column shell and the second column shell is mixed to form a diversion and air mixing effect. The temperature of the mixed airflow is closer to room temperature, the comfort is higher, and the wind feels softer, which is the so-called "soft wind". Moreover, when the second column shell blows out the indoor air, it can achieve a stronger air mixing effect, making the air flow closer to room temperature. When the second column shell blows out fresh air flow, purification air flow, humidification air flow or water washing air flow and other conditioning air flows, these conditioning air flows can be mixed with the heat exchange air flow earlier and more, enhancing the mixing rate and making it better spread throughout the room. In particular, by arranging the third column shell to blow out the third airflow, and with the direction of the third air outlet Change, the third airflow can either be converged into the mixed airflow through the induced air interval to increase the air volume and wind speed and make the air supply distance farther, or it can be directed away from the first column shell to be sent out at the vertical air conditioner indoor unit. While mixing the air flow, it also increases the air supply angle, which meets the various needs of users for the air supply angle of the vertical air conditioner indoor unit.

Furthermore, in the vertical air-conditioning indoor unit of the present invention, the different air supply types and rotational settings of the second column housing and the third column housing enable the vertical air-conditioning indoor unit to have various air supply modes. For example, the second column shell blows out the fresh air flow, the third column shell blows out indoor air, and the second column shell and the third column shell blow out air in different directions away from the first column shell at the same time. Without generating mixed air flow, The vertical air conditioner indoor unit of the present invention can send air to multiple angles and different types of air.

Further, in the vertical air conditioner indoor unit of the present invention, the lower shell is used to introduce or prepare the second airflow and the third airflow, and an induced draft fan is provided in the lower shell. There is no need to install fans in the second column shell and the third column shell. , in this way, the second column shell and the third column shell can be designed to be thinner, making them significantly thinner than the first column shell. This asymmetric design not only meets the needs of air mixing, but also makes the vertical air conditioner indoor unit The appearance is more novel and unique, which enhances the competitiveness of the product.

From the following detailed description of specific embodiments of the present invention in conjunction with the accompanying drawings, those skilled in the art will further understand the above and other objects, advantages and features of the present invention.

Description of the drawings

Some specific embodiments of the invention will be described in detail below by way of illustration and not limitation with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar parts or portions. Those skilled in the art will appreciate that these drawings are not necessarily drawn to scale. In the attached picture:

Figure 1 is a schematic front view of a vertical air conditioner indoor unit according to one embodiment of the present invention.

Fig. 2 is a schematic cross-sectional view taken along line N-N in Fig. 1 .

3 is a schematic cross-sectional view of the first column housing, the second column housing and the third column housing of the vertical air conditioner indoor unit according to one embodiment of the present invention.

4 is a schematic cross-sectional view of the first column housing, the second column housing and the third column housing of the vertical air conditioner indoor unit according to one embodiment of the present invention.

5 is a schematic cross-sectional view of the first column housing, the second column housing and the third column housing of the vertical air conditioner indoor unit according to one embodiment of the present invention.

6 is a schematic left side view of the vertical air conditioner indoor unit shown in FIG. 1 when the lower column housing is cut open and part of the second column housing is cut open.

Detailed ways

The vertical air conditioner indoor unit according to the embodiment of the present invention will be described below with reference to FIGS. 1 to 6 . Among them, the orientation or positional relationship indicated by "front", "back", "upper", "lower", "top", "bottom", "inner", "outer", "lateral", etc. are based on those shown in the accompanying drawings. The orientation or positional relationship is only for the convenience of describing the present invention and simplifying the description, and does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore cannot be understood as a limitation of the present invention. .

The terms "first", "second", etc. are used for descriptive purposes only and shall not be understood as indicating or implying relative importance or implicitly indicating the quantity of indicated technical features. Therefore, features defined as “first”, “second”, etc. may explicitly or implicitly include at least one of the features, that is, include one or more of the features. In the description of the present invention, "plurality" means at least two, such as two, three, etc., unless otherwise expressly and specifically limited. When a feature "includes or includes" one or some of the features it encompasses, unless specifically described otherwise, this indicates that other features are not excluded and may further be included.

Unless otherwise expressly stated and limited, the terms "installed", "connected", "connected", "fixed" and "coupled" should be understood in a broad sense. For example, it can be a fixed connection or a detachable connection, or into one. The connection can be mechanical or electrical. It can be a direct connection or an indirect connection through an intermediate medium. It can be an internal connection between two elements or an interactive relationship between two elements, unless otherwise explicitly limited. Those of ordinary skill in the art should be able to understand the specific meanings of the above terms in the present invention according to specific circumstances.

The invention provides a vertical air conditioning indoor unit. The vertical air conditioner indoor unit is the indoor part of the split air conditioner and is used to regulate indoor air, such as cooling/heating, dehumidification, introducing fresh air, etc. The vertical air conditioner indoor unit can be a conventional floor-standing cabinet unit or a vertical wall-mounted unit.

Figure 1 is a schematic front view of a vertical air conditioner indoor unit according to an embodiment of the present invention. The solid arrows in Figures 2 to 5 indicate the direction of air flow. Referring to Figures 2 to 6, the vertical air conditioner indoor unit according to an embodiment of the present invention The machine includes a first column housing 10 , a second column housing 20 and a third column housing 30 .

The first column housing 10 is in the shape of a vertical column, and a first air outlet 11 for blowing out the first airflow is provided on the front side of the first column housing 10 . The second column housing 20 is in the shape of a vertical column, and a second air outlet 21 for blowing out the second airflow is provided on the front side of the second column housing 20 . The second column shell 20 is disposed on the lateral side of the first column shell 10 , and an air induction interval 16 is formed between the second column shell 20 and the first column shell 10 so that the first air outlet 11 and/or the second air outlet 21 When the air is discharged, the air in the air-inducing interval 16 is driven forward by negative pressure. The third column housing 30 is in the shape of a vertical column, and a third hole for blowing out the third airflow is provided on the front side of the third column housing 30 . Three air outlets 31. The third column shell 30 is rotatably disposed on the rear side of the air induction space 16 around the first vertical axis.

The vertical air conditioner indoor unit of the present invention includes a large first column housing 10 and two small second column housings 20 and third column housings 30. The second column housing 20 is located on the lateral side of the first column housing 10. The column shell 30 is located on the rear side of the air induction compartment 16 . The third column housing 30 can rotate so that the air outflow from the third air outlet 31 is directed at different angles. The first column housing 10 , the second column housing 20 and the third column housing 30 respectively have independent first air outlets 11 , second air outlets 21 and third air outlets 31 . The first column housing 10 , the second column housing 20 and the third column housing 30 can supply air separately or at the same time, or through the first air outlet 11 , the second air outlet 21 and the third air outlet 31 . The setting of the wind direction enables diversified and multi-angle air supply. For example, one of the first column housing 10 , the second column housing 20 and the third column housing 30 can be individually supplied with air. For another example, the air guide swing blades at the first air outlet 11 swing and the air guide swing blades at the second air outlet 21 swing, so that the first column housing 10 and the second column housing 20 discharge air in front of each other at the same time, That is, in the uniform air mode, a negative pressure environment is formed at the induced air interval 16, which causes the indoor air behind the indoor unit of the vertical air conditioner to flow forward through the induced air interval 16 to mix into the air of the first column shell 10 and the second column shell 20. The outlet airflow creates a diversion and mixing effect. The temperature of the mixed airflow is closer to room temperature, the comfort is higher, and the wind feels softer, which is the so-called "soft wind". When the second column shell 20 blows out fresh air flow, purified air flow, humidified air flow or water washing air flow and other regulated air flows, these regulated air flows can be mixed with the heat exchange air flow earlier and more, thereby enhancing the mixing rate and making it more efficient. Spreads well throughout the room. In particular, when the first column housing 10 and the second column housing 20 blow out air in front of each other, the third column housing 30 blows out the third airflow. As the direction of the third air outlet 31 changes, as shown in Figure 3 It shows that the third air flow can be converged into the mixed air flow through the air induction interval 16, thereby strengthening the mixed air flow, increasing the air volume and wind speed, and making the air supply distance farther. As shown in Figure 4, the third air outlet 31 can also be oriented away from the first column shell 10, so that while the mixed air flow is sent out of the vertical air conditioning room, the air supply angle is also increased, which satisfies the user's need for vertical air conditioning. Various demands for air supply angles in air-conditioned rooms.

In some embodiments of the present invention, the ratio of the width of the second column shell 20 in the transverse direction to the width of the first column shell in the transverse direction 10 is less than 1/2. The ratio of the depth dimension of the second column housing 20 along the front-rear direction to the depth dimension of the first column housing 20 along the front-rear direction is less than 1/2. The first air outlet 11 is in the shape of a vertical strip, and the second air outlet 21 is in the shape of a vertical strip. The first air outlet 11 and the second air outlet 21 are arranged transversely. The distance between the two lateral side walls of the second column shell 20 gradually becomes smaller from the back to the front, forming a tapered shape.

The ratio of the width of the third column shell 30 in the transverse direction to the width of the first column shell 10 in the transverse direction is less than 1/2. The ratio of the depth dimension of the third column housing 30 along the front-rear direction to the depth dimension of the first column housing 10 along the front-rear direction is less than 1/2. The distance between the two side walls of the third column shell gradually becomes smaller from the back to the front, forming a tapered shape.

The above arrangement can make the front and rear positions of the second air outlet 21 and the first air outlet 11 flush or substantially flush, so that the airflows from the second air outlet 21 and the first air outlet 11 can be better mixed. The second column shell 20 and the third column shell 30 both have a tapered shape, which increases the wind speed of the second air outlet 21 and the third air outlet 31, which is beneficial to the second column shell 20 and the third column shell 30 sending air to a distant place. wind. The second column shell 20 and the third column shell 30 are significantly smaller than the first column shell 10 , forming two small and one large three-column shells arranged at intervals. The appearance is stable and unique, which enhances the decorative properties of the household air conditioner.

In some embodiments of the present invention, the third column housing 30 is disposed on the rear side of the second column housing 20 . The first vertical axis is located in the third column housing 30 , and is spaced apart from the third air outlet 31 . The third column housing 30 can rotate until the third air outlet 31 faces the second column housing 20 away from the first column housing 10 . The second column shell 20 and the third column shell 30 are arranged front and back on one side of the first column shell 10, which is both beautiful and increases the air outlet angle, especially when the second column shell 20 and the third column shell 30 discharge air in front of each other. When the third column housing 30 rotates to the third air outlet 31 toward the side of the second column housing 20 away from the first column housing 10, it can not only realize the air equalization function, but also expand the air supply range, the blowing angle is wider, and the user experience Better.

In some embodiments of the invention, the second cylinder housing is rotatably disposed about the second vertical axis. The second vertical axis is located in the second column housing 20 , and is spaced apart from the second air outlet 21 . The second column housing 20 rotates to blow air, so that the air outlet angle of the second column housing 20 is larger, and the air outlets of the second column housing 20 and the third column housing 30 can cooperate with each other. As shown in FIG. 5 , the first column shell 10 , the second column shell 20 and the third column shell 30 can also blow air in one direction at the same time. At this time, the air outlet angle will be about 100 degrees from the air outlet angle of the first column shell 10 alone. degrees expanded to about 120 degrees.

In some embodiments of the present invention, the distance between any point of the outer edge of the cross-sectional profile of the third cylindrical shell 30 and the first vertical axis is smaller than the distance between the first vertical axis and the first vertical axis of the first cylindrical shell 10 that is closest to the first vertical axis. The distance from the outer edge of the cross-section profile. The distance between any point of the outer edge of the cross-sectional profile of the third cylinder shell 30 and the first vertical axis is smaller than the distance between the first vertical axis and the outer edge of the cross-sectional profile of the second cylinder shell 20 that is closest to the second vertical axis. This arrangement allows the third column housing 30 to rotate 360 degrees without interference, which greatly expands the air supply angle of the vertical air conditioner indoor unit. Of course, in some alternative embodiments, the third column housing 30 can also be rotated 360 degrees through the non-simultaneous rotation of the second column housing 20 and the third column housing 30 , that is, the rotation of the second column housing 20 can be achieved. position, and then the second column housing 20 is returned to the position after the third column housing 30 is rotated, so that the structure can be made more compact.

In some embodiments of the present invention, the vertical air conditioning indoor unit further includes a first cross-flow fan 15 and a heat exchanger 14 . The first cross-flow fan 15 and the heat exchanger 14 are arranged in the first column shell 10 . The rear wall of the first column housing 10 and the rear portions of the two side walls are each provided with a first air inlet connected to the first air outlet 11 13.

The first air inlet 13 is connected with the indoor air. The first cross-flow fan 15 prompts the indoor air to enter the first column shell 10 through the first air inlet 13 and pass through the heat exchanger 14 to become a heat exchange air flow from the first air outlet 13 Blow out.

In some embodiments of the present invention, the vertical air conditioning indoor unit further includes a second cross-flow fan 24 and a third cross-flow fan 34 . The second cross-flow fan 24 is installed vertically inside the second column housing 20 . The second cross-flow fan 24 is coaxial with the second vertical axis. This arrangement eliminates the need for the second cross-flow fan 24 to follow the rotation of the second column housing 20 during rotation, thereby making the rotation structure of the second column housing 20 simple.

The third cross-flow fan 34 is installed vertically inside the third column housing 30 . The third cross-flow fan 34 is coaxial with the first vertical axis. This arrangement eliminates the need for the third cross-flow fan 34 to follow the rotation of the third column housing 30 during rotation, thereby making the rotation structure of the third column housing 30 simple.

A second air inlet 23 connected with the second air outlet 21 is provided on the rear portion of the second column housing 20 away from the side wall of the first column housing 10 and on the rear wall of the second column housing 20 . The second air inlet 23 is connected with the indoor air, and the second cross-flow fan 24 urges the indoor air to enter the second column shell 20 through the second air inlet 23 and blow out from the second air outlet 21 .

A third air inlet 33 connected with the third air outlet 31 is provided on the rear portion of the third column housing 30 away from the side wall of the first column housing 10 and on the rear wall of the third column housing 30 . The third air inlet 33 is connected with the indoor air, and the third cross-flow fan 34 urges the indoor air to enter the third column shell 30 through the third air inlet 33 and blow out from the third air outlet 31 .

In the above situation, the first column shell 10 blows out the heat exchange air flow, and the second column shell 20 and the third column shell 30 blow out the indoor air. In the uniform air mode, when the second column shell 20 and the third column shell 30 blow out indoor air, a more powerful air mixing effect can be achieved, making the air flow closer to room temperature.

In some embodiments of the present invention, an air inlet connected to the second air outlet 21 is provided at the lower end of the second column housing 20 . An air inlet connected to the third air outlet 31 is provided at the lower end of the third column housing 30 . The vertical air conditioner indoor unit also includes a lower shell 40 and a third induced draft fan 41. The lower shell 40 is disposed below the second column shell 20 and the third column shell 30 . The third induced draft fan 41 is disposed in the lower shell 40 for introducing the second airflow and the third airflow into the second column shell 20 and the third column shell 30 . The rear side wall of the lower shell 40 is provided with an outdoor fresh air inlet 43 and/or an indoor air inlet. The outdoor fresh air inlet 43 and/or the indoor air inlet are connected with the air inlet of the third induced draft fan 41. The third induced draft fan A functional module 42 is provided in front of the air inlet of 41 . The functional module 42 is a purification module and/or a humidification module.

In the above arrangement, the third induced draft fan 41 is arranged in the lower shell 40, so that the second column shell 20 and There is no need to install a fan inside the third column housing 30, so that the second column housing 20 and the third column housing 30 can be made slimmer and unique in shape. The air inlet of the second column shell 20 and the third column shell 30 are arranged at their respective lower ends. The outdoor fresh air inlet 41 and/or the indoor air inlet are connected with the air inlet of the third induced draft fan 41. The fan 41 prompts the fresh air and/or indoor air entering from the outdoor fresh air inlet 43 and/or the indoor air inlet to enter the second column housing 20 and the second column housing 20 from the air inlet of the third column housing 30. It is inside the third column shell 30 and blown out from the second air outlet 21 and the third air outlet 31 . This arrangement enables the third induced draft fan 41 to inhale both fresh air flow and indoor air, achieving the effect of killing two birds with one stone. The airflow from different sources allows the vertical air conditioner indoor unit to have a variety of air outlet types. At the same time, in order to meet the diverse needs of users, a functional module 42 can be provided in front of the air inlet of the third induced draft fan. The functional module 42 can be a purification module and/or a humidification module, that is, the second air flow can be indoor air, fresh air flow, One or more of purified air flow, humidified air flow or washed air flow, and the third air flow is one or more of indoor air, fresh air flow, purified air flow, humidified air flow or washed air flow.

Here, the induced draft fan 41 may be a centrifugal fan or an axial flow fan, and introduces fresh air and/or indoor air to the second column shell 20 and the third column shell 30 through an air distribution mechanism. In some embodiments of the present invention, valves may be provided between the outdoor fresh air inlet 43 and the air inlet of the third induced draft fan and between the indoor air inlet and the air inlet of the third induced draft fan. The provided valve is configured to controllably connect one of the outdoor fresh air inlet 43 and the indoor air inlet to the air inlet of the third induced draft fan. This arrangement allows the second column housing 20 and the third column housing 30 to blow out fresh air or indoor air in a controlled manner.

In some embodiments of the present invention, separate fans are used for the air inlet of the second column housing and the air inlet of the third column housing. Specifically, the vertical air conditioner indoor unit also includes a first induced draft fan and a second induced draft fan. The second column housing 20 takes in air from the air inlet at the lower end of the second column housing through the first induced draft fan. The third column housing 30 The air is taken in from the air inlet at the lower end of the third column shell through the second induced draft fan.

In some embodiments of the present invention, the second column housing 20 takes in air from the air inlet at the lower end of the second column housing through a first induced draft fan, and the third column housing 30 takes in air from the rear of the third column housing through a third cross-flow fan. Part of the wind. In this embodiment, the air inlet of the second column housing and the air inlet of the third column housing adopt different air inlet methods.

In some embodiments of the present invention, as shown in Figure 6, a vertical strip-shaped first air duct 28 connected to the second air outlet 21 is provided in the second column shell 20, and the airflow entering the first air duct 28 is the first air duct 28. A stream of air. A plurality of first guide fins 25 are arranged vertically in the first air duct 28 . Each first guide fin 25 extends from front to back, and the rear end is bent downward to form a first guide bend. 251, and the distance between the front and rear ends of the first guide plate 25 is larger as it is positioned higher.

The first airflow flows from bottom to top. After encountering each first guide plate 25, it is guided by its first flow guide plate 25. The bending portion 251 guides and gradually changes from upward flow to forward flow. Therefore, the first airflow bending portion 251 plays a role in changing the direction of the airflow, making the airflow turn more gentle and the wind loss smaller. There is a rounded transition between the first air guide bending portion 251 and the remaining portion of the first air guide plate 25 .

Furthermore, considering that the first airflow enters the second column housing 20 from the bottom of the second column housing 20 , the air outlet volume in the middle or upper part of the second air outlet 21 may be smaller. Therefore, in the embodiment of the present invention, a plurality of first guide fins 25 are arranged vertically in the second column housing 20 , and the distance between the front and rear ends of the first guide fins 25 that is located higher is larger, so that The air outflow from the second air outlet 21 is more uniform in the vertical direction. Of course, we can also make full use of the problem that the air volume in the middle or upper part of the second air outlet 21 is relatively small, so that the air mixing effect on the upper side is poor, and air can be supplied to places that need cooling, that is, to places that do not need soft air. wind.

In some embodiments of the present invention, a vertical strip-shaped second air duct connected to the third air outlet 31 is provided in the third column shell 30 , and the air flow entering the second air duct is the second air flow. A plurality of second guide fins arranged vertically are provided in the second air duct. Each second guide fin extends from front to back, and the rear end is bent downward to form a second guide bending portion, and the position is beyond The distance between the front and rear ends of the upper second deflector is larger.

The second airflow flows from bottom to upward. After encountering each second guide plate, it is guided by its second guide bending portion and gradually changes from upward flow to forward flow. Therefore, the second flow guide bending portion plays a role in changing the direction of the airflow, making the airflow turn more gentle and the wind loss smaller. There is a rounded transition between the second air guide bending portion and the remaining portion of the second air guide plate.

Furthermore, considering that the second airflow enters the third column housing 30 from the bottom of the third column housing 30 , the air outlet volume in the middle or upper part of the third air outlet 31 may be smaller. Therefore, in the embodiment of the present invention, a plurality of second guide fins are arranged vertically in the third column housing 30 , and the distance between the front and rear ends of the second guide fins located higher up is larger, so that the third guide fin is arranged vertically. The air outflow from the air outlet 31 is more uniform in the vertical direction.

By now, those skilled in the art will appreciate that, although a number of exemplary embodiments of the present invention have been shown and described in detail herein, the disclosed embodiments may still be practiced in accordance with the present invention without departing from the spirit and scope of the present invention. The content directly identifies or leads to many other variations or modifications consistent with the principles of the invention. Accordingly, the scope of the present invention should be understood and deemed to cover all such other variations or modifications.

Claims (10)

1. A vertical air conditioner indoor unit, including:

   A first column shell, the first column shell is in the shape of a vertical column, and a first air outlet for blowing out the first airflow is provided on the front side of the first column shell;

   A second column shell, the second column shell is in the shape of a vertical column, and a second air outlet for blowing out the second airflow is provided on the front side of the second column shell; the second column shell is arranged on the first The lateral side of the column shell; an air induction interval is formed between the second column shell and the first column shell, so that the first air outlet and/or the second air outlet rely on negative pressure when they discharge air. The function drives the air in the air-inducing interval to flow forward;

   A third column shell, the third column shell is in the shape of a vertical column, and a third air outlet for blowing out the third airflow is provided on the front side of the third column shell; the third column shell is arranged around the first vertical axis It is rotatably arranged on the rear side of the air induction partition.
2. The vertical air conditioner indoor unit according to claim 1, wherein,

   The ratio of the width of the second column shell in the transverse direction to the width of the first column shell in the transverse direction is less than 1/2; the depth dimension of the second column shell in the front-to-back direction is the same as the width of the first column shell in the front-to-back direction. The ratio of depth to depth is less than 1/2;

   The ratio of the width of the third column shell in the transverse direction to the width of the first column shell in the transverse direction is less than 1/2; the depth dimension of the third column shell in the front-to-back direction is the same as the width of the first column shell in the front-to-back direction. The ratio of depth to depth is less than 1/2.
3. The vertical air conditioning indoor unit according to claim 1 or 2, wherein,

   The third column housing is disposed on the rear side of the second column housing; the third column housing can rotate until the third air outlet faces the second column housing away from the first column housing.
4. The vertical air conditioning indoor unit according to claim 1 or 2, wherein,

   The first vertical axis is located in the third column shell, and the first vertical axis is spaced apart from the third air outlet;

   The first air outlet is in the shape of a vertical strip, the second air outlet is in the shape of a vertical strip, and the third air outlet is in the shape of a vertical strip; the first air outlet and the second air outlet are arranged in a transverse direction; The distance between the two side walls of the second cylindrical shell gradually becomes smaller from the back to the front, forming a tapered shape; the distance between the two side walls of the third cylindrical shell gradually becomes smaller from the back to the front, forming a tapered shape.
5. The vertical air conditioning indoor unit according to claim 1 or 2, wherein,

   The second column housing is rotatably disposed about a second vertical axis;

   The second vertical axis is located in the second column shell, and the second vertical axis is spaced apart from the second air outlet.
6. The vertical air conditioning indoor unit according to claim 1 or 2, further comprising a first cross-flow fan and a heat exchanger; the first cross-flow fan and the heat exchanger are arranged in the first column shell;

   A first air inlet connected to the first air outlet is provided on the rear wall of the first column shell and the rear portions of the two side walls.
7. The vertical air conditioner indoor unit according to claim 5, further comprising:

   A second cross-flow fan, the second cross-flow fan is arranged vertically inside the second cylindrical shell; the second vertical axis is coaxial with the second cross-flow fan; the second cross-flow fan is A second air inlet connected to the second air outlet is provided at the rear; or,

   The lower shell and the first induced draft fan are arranged below the second column shell and the third column shell; the lower end of the second column shell is provided with an inlet connected to the second air outlet. An air inlet, the first induced draft fan is disposed in the lower shell, and is used to introduce the second airflow into the air inlet at the lower end of the second column shell.
8. The vertical air conditioner indoor unit according to claim 5, further comprising:

   A third cross-flow fan, the third cross-flow fan is arranged vertically inside the third cylindrical shell; the first vertical axis is coaxial with the third cross-flow fan; the third cross-flow fan is A third air inlet connected to the third air outlet is provided at the rear; or,

   The lower shell and the second induced draft fan are arranged below the second column shell and the third column shell; the lower end of the third column shell is provided with an inlet connected to the third air outlet. An air inlet, the second induced draft fan is disposed in the lower shell, and is used to introduce the third airflow into the air inlet at the lower end of the third column shell.
9. The vertical air conditioning indoor unit according to claim 1 or 2, wherein,

   The lower end of the second column shell is provided with an air inlet connected to the second air outlet;

   The lower end of the third column shell is provided with an air inlet connected to the third air outlet;

   The vertical air conditioner indoor unit also includes:

   A lower shell, the lower shell is arranged below the second column shell and the third column shell;

   A third induced draft fan, the third induced draft fan is disposed in the lower shell and is used to introduce the second airflow and the third airflow into the air inlet at the lower end of the second column shell and the The air inlet at the lower end of the third column shell.
10. The vertical air conditioner indoor unit according to claim 9, wherein,

    The second air outlet is in the shape of a vertical strip;

    A first air duct connected to the second air outlet is provided in the second column shell;

    A plurality of first guide fins arranged vertically are provided in the first air duct, each of the first guide fins extends from front to back, and the rear end is bent downward to form a first guide bending portion. ;The higher the position, the greater the distance between the front and rear ends of the first deflector;

    The third air outlet is in the shape of a vertical strip;

    A second air duct connected to the third air outlet is provided in the third column shell;

    A plurality of second guide fins arranged vertically are provided in the second air duct. Each second guide fin extends from front to back, and the rear end is bent downward to form a second guide bend. ; The distance between the front and rear ends of the second guide vane is greater as it is positioned higher up.