KR20210098055A - Blower - Google Patents

Abstract

A blower according to an embodiment of the present invention includes a support body in which an inlet is formed; a dual discharge unit installed in a symmetrical pair on the upper surface of the support body and discharging air; a distribution duct provided on the support body and guiding the air sucked through the inlet to be branched and introduced into the dual discharge unit; a tower coupling unit forming an opening in the upper surface of the support body, and having the dual discharge unit installed therein; and a rotation module installed in the tower coupling unit and capable of individually rotating the dual discharge unit. The blower according to the present invention can minimize flow resistance and has improved supporting performance for a load of the dual discharge unit.

Description

blower {Blower}

The present invention relates to a blower.

In general, a blower is a mechanical device that drives a fan to generate air flow. For example, the blower may include blades that rotate about a rotation axis. And the blower may generate an air flow by the rotation of the blade.

The blower may be disposed relatively close to the user in an indoor environment such as a home or an office. In this case, the blower is usually referred to as a “fan”. In addition, the air flow generated by the blower may release heat from the room through convection and evaporation. Accordingly, the user in the room can feel cool and comfortable.

On the other hand, the conventional blower is visually provided with a blade attached to the rotating shaft, and is provided with a protective net mechanism such as a cage to prevent a safety accident related to the blade. However, these cages and wings are easily contaminated and inconvenient to maintain. Accordingly, recently, various blowers (or fans) in which the blades of the blower are invisible to the user's eyes have been disclosed.

In addition, the conventional blower may include a filter device for filtering dust and the like therein. In this case, the blower may perform indoor air cleaning.

As related prior art documents, Korean Patent Application Laid-Open No. 10-2011-0100274 (published on September 09, 2011) and Korean Patent Laid-Open No. 10-2019-0015325 (published on: February, 2019) 13) and Republic of Korea Patent Publication No. 10-2019-0025443 (published date: March 11, 2019).

On the other hand, the conventional blower may include a bearing for guiding the rotation of the discharge unit. In the conventional blower, a structure supporting the discharge unit, a ball or thrust bearing, a structure supporting the bearing, a structure for fastening, etc. may be located in a flow path connected to the discharge unit. Therefore, since the structure located in the flow path acts as a resistance to the flowing air, there is a problem in that the flow rate of the air toward the discharge unit decreases and the flow loss occurs.

In addition, in the conventional blower, when an additional component such as a heater and a camera module is installed inside the discharge unit and the load increases, a support supporting the same is added or the size of the existing support is inevitably increased. And in this case, there is a problem that an additional flow rate reduction occurs. That is, the conventional blower has a structural problem with insufficient rotational expandability.

In addition, the conventional blower has a problem in that tilting may occur during rotation of the discharge unit due to tolerances within the bearing. That is, it is necessary to fix the discharge part so that the position of the rotation shaft can be stably maintained.

It is an object of the present invention to provide a blower capable of solving the problems of the conventional blower described above.

Another object of the present invention is to provide a blower having a rotation module capable of minimizing flow resistance.

Another object of the present invention is to provide a blower having a rotation module having an improved ability to support a load of a dual discharge unit.

Another object of the present invention is to provide a blower capable of increasing an area of a rotating module (or bearing) supporting a dual discharge unit.

Another object of the present invention is to provide a blower capable of preventing shaft torsion during rotation of a dual discharge unit and stably maintaining equilibrium.

Another object of the present invention is to provide a hidden blower in which blades (or blades) of a rotating fan are non-visually provided.

Another object of the present invention is to provide a blower for discharging air sucked from a single suction port to a plurality of discharge ports by flowing upward along a double flow path.

Another object of the present invention is to provide a blower capable of reducing noise while maintaining the air volume.

In order to achieve the above object, a blower according to an embodiment of the present invention includes a support body in which a suction port is formed; a dual discharge unit installed in a symmetrical pair on the upper surface of the support body and discharging air; a distribution duct provided in the support body and guiding the air sucked from the suction port to be branched and introduced into the dual discharge unit; a tower coupling part that forms an opening in the upper surface of the support body, and in which the dual discharge part is installed; and a rotation module installed in the tower coupling unit and capable of individually rotating the dual discharge unit.

And the rotation module, a rotation motor for providing a rotational force; a motor gear coupled to the rotating motor to rotate; a driving gear engaged with the motor gear and transmitting rotational force to the dual discharge unit; and a bearing coupled to the driving gear in the vertical direction and rolling along the rotational direction of the driving gear.

In addition, the upper surface of the distribution duct, the receiving support surface for supporting the rotary motor; and a seating surface extending higher than the receiving support surface and on which the bearing is seated.

In addition, the driving gear and the bearing may have a ring shape.

In addition, the bearing may include a ball or roller that rolls along the rotational direction of the driving gear.

In addition, the rotation module may further include a coupling housing accommodated in the tower coupling unit and coupled to the lower portion of the dual discharge unit.

In addition, the driving gear may be rotatably coupled to a lower portion of the coupling housing.

In addition, the rotation motor and the motor gear may be located outside the coupling housing. And the bearing may be coupled to the lower side of the driving gear.

In addition, the bearing may include a lower ring coupled to the distribution duct; a connection ring inserted into a guide groove recessed in an inner circumferential surface of the lower ring; and an upper ring rotatably coupled to the lower ring and in contact with the connecting ring.

In addition, the connecting ring may include a plurality of balls performing a rolling motion along the circumferential direction.

In addition, the upper ring is. It may include a coupling rib protruding upward to be coupled to the lower surface of the driving gear.

In addition, the bearing may be coupled to the upper side of the driving gear.

In addition, the driving gear may be rotatably seated on the upper surface of the distribution duct.

In addition, the bearing may be coupled to the upper surface of the driving gear to rotate together.

In addition, the bearing may include: a bearing body coupled to the dual discharge unit and having a connection passage communicating with the inner space of the dual discharge unit formed by an inner circumferential surface; and a roller installed on the outer circumferential surface of the bearing body and rolling along the rotational direction of the driving gear.

In addition, the rotation module, disposed spaced apart from the lower end of the dual discharge unit, may further include a roller case surrounding the bearing.

In addition, the roller case may form a roller guide space extending in a circumferential direction so that the rollers come into contact with each other to perform rolling motion.

In addition, the roller, the upper roller in contact with the upper surface defining the roller guide space; and a lower roller in contact with a lower surface defining the roller guide space.

In addition, the inner surface of the roller case may form the roller guide space, and the outer surface of the roller case may form the exterior of the tower coupling part.

In addition, the rotation module may further include an anti-separation rib fitted to the upper portion of the bearing and the lower portion of the dual discharge unit to maintain the position of the rotation shaft of the dual discharge unit.

In addition, the support body, the front case forming the tower coupling portion on the upper surface; and

It may further include a rear case extending rearward from the front case and forming a discharge opening on the upper surface.

Also, the discharge opening may be located at a rear side of the dual discharge unit.

In addition, the support body, a fan for providing a flow pressure of air; and a diffuser installed above the fan and guiding air upward.

In addition, the distribution duct may extend to communicate with the discharge opening and the inner space of the dual discharge unit.

In addition, the distribution duct, the receiving support surface located below the upper surface of the rear case to form a space in which the rotary motor is accommodated; an upper end formed to be connected to the receiving support surface and forming an opening communicating with the inner space of the dual discharge unit; and a seating surface recessed on the upper surface of the upper end to seat the bearing.

In addition, the upper end portion, the inner surface connecting the receiving surface and the seating surface may be formed in a curved surface. Accordingly, it is possible to relatively reduce the flow loss of the air passing through the distribution passage.

In addition, the bearing and the driving gear may extend in a circumferential direction to form a hollow connecting the dual discharge unit and the inner space of the distribution duct, and may be supported in a load direction of the dual discharge unit.

According to the present invention, a bearing structure having a hollow to form a flow path and capable of rolling motion along the periphery is provided, thereby reducing the rotational friction of the dual discharge unit and stably guiding the rotation.

According to the present invention, since the structures of the bearing and the driving gear supporting the rotation of the dual discharge unit are arranged so as not to interfere with the flow passage through which the air flows therein, the resistance of the flow passage can be reduced and the flow loss can be reduced.

According to the present invention, a support point (or area) for the load of the dual discharge unit can be dispersed and increased without a separate support located in a flow path for guiding air into the inner space of the dual discharge unit. In addition, since the bearing of the present invention extends in the circumferential direction to support the driving gear or the dual discharge unit in a surface direction, it is possible to support a relatively high load of the dual discharge unit. That is, it is suitable for installing an additional configuration in the dual discharge unit, and it is possible to improve the scalability of the product.

According to the present invention, since the upper part of the dual discharge part is stably supported by the support filler and the lower part of the dual discharge part is stably supported by the rotating module, tilting of the dual discharge part due to the above-described tolerance of the bearing is prevented. can do.

According to the present invention, it is possible to prevent shaft torsion during rotation of the dual discharge unit by the coupling rib or the separation preventing rib.

According to the present invention, since air can be discharged to a discharge port located relatively close to the fan among a plurality of discharge ports, air cleaning performance can be maintained and noise of the product can be reduced.

1 to 3 are perspective views showing a blower according to an embodiment of the present invention;
4 is a 1-1' cross-sectional view of FIG.
5 is an exploded perspective view showing a rotation module according to a first embodiment of the present invention;
6 is an enlarged cross-sectional view showing a coupling state of the rotation module according to the first embodiment of the present invention;
7 is an exploded perspective view showing the bearing of the rotation module according to the first embodiment of the present invention;
8 is a perspective view showing a bearing of a rotation module according to a second embodiment of the present invention;
9 is an enlarged cross-sectional view showing a coupling state of the rotation module according to the second embodiment of the present invention;

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the components from other components, and the essence, order, or order of the components are not limited by the terms. When it is described that a component is “connected”, “coupled” or “connected” to another component, the component may be directly connected or connected to the other component, but another component is between each component. It will be understood that may also be "connected", "coupled" or "connected".

1 to 3 are perspective views showing a blower according to an embodiment of the present invention. In more detail, FIGS. 1 and 2 are front perspective views of a blower according to an embodiment of the present invention, and FIG. 3 is a rear perspective view of the blower according to an embodiment of the present invention.

1 to 3 , the blower 1 according to an embodiment of the present invention may include a support body 10 and dual discharge parts 50 and 60 supported by the support body 10 . there is.

The support body 10 may form a lower portion of the blower 1 , and the dual discharge units 50 and 60 may form an upper portion of the blower 1 .

The support body 10 and the dual discharge units 50 and 60 may form discharge ports 15, 53 and 63 for discharging air to the outside, respectively. A discharge opening 15 to be described later is formed in the support body 10 , and discharge slits 53 and 63 to be described later are formed in the dual discharge portions 50 and 60 .

The discharge port formed in the support body 10 may form a flow of air discharged upward from the rear portion of the blower (1). In addition, the discharge port formed in the support body 10 may be selectively opened and closed by the discharge module 100 .

The discharge ports formed in the dual discharge units 50 and 60 may form a flow of air discharged from the front portion of the blower 1 to the front.

Meanwhile, the discharge slits 53 and 63 may be referred to as “front discharge ports”, and the discharge opening 15 may be referred to as “rear discharge ports”.

The dual discharge units 50 and 60 may be coupled to the upper portion of the support body 10 . That is, the dual discharge units 50 and 60 may discharge air at a position higher than the support body 10 .

The dual discharge units 50 and 60 include tower cases 51 and 61 forming an exterior, discharge slits 53 and 63 forming openings having a predetermined width in the tower cases 51 and 61, and the discharge. It may include vanes 55 and 65 for guiding the vertical direction of the air discharged to the slits 53 and 63 .

The discharge slits 53 and 63 may extend long in the vertical direction of the cases 51 and 61 . In addition, air flowing through the inside of the blower 1 may be discharged through the discharge slits 53 and 63 .

A plurality of the vanes 55 and 65 may be spaced apart from each other in the extending direction of the discharge slits 53 and 63 . That is, a plurality of the vanes 55 and 65 may be disposed in the height direction of the tower cases 51 and 61 .

The vanes 55 and 65 may be installed inside the tower cases 51 and 61 to be rotatable in the vertical direction. In addition, the air introduced into the tower cases 51 and 61 may pass through the discharge slits 53 and 63 according to the guides of the lower surfaces of the vanes 55 and 65 while ascending.

The vanes 55 and 65 may have a curved surface when guiding the air to the discharge slits 53 and 63 .

In addition, the front end portions of the vanes 55 and 65 may be provided to contact the discharge slits 53 and 63 in a direction perpendicular to the extending direction of the discharge slits 53 and 63 . Accordingly, the air flowing upward from the inside of the tower cases 51 and 61 can be sequentially discharged by the guides of the vanes 55 and 65 spaced apart in the vertical direction along the discharge slits 53 and 63. there is.

The dual discharge units 50 and 60 may be installed as a pair symmetrical to the support body 10 . In addition, the dual discharge units 50 and 60 may form a dual discharge port.

In detail, the dual discharge units 50 and 60 may include a first discharge tower 50 and a second discharge tower 60 that are symmetrical to each other. The first discharge tower 50 and the second discharge tower 60 may be formed to have the same configuration. Accordingly, the description of any one of the first discharge tower 50 and the second discharge tower 60 will be referred to in the description of the other one.

The first discharge tower 50 and the second discharge tower 60 are provided as a pair, and may be coupled to the upper portion of the support body 10 , respectively.

Also, the first discharge tower 50 and the second discharge tower 60 may rotate independently of each other. Accordingly, the air discharged by the first discharge tower 50 and the second discharge tower 60 may flow in different directions through respective rotations.

The first discharge tower 50 is discharged from a first tower case 51 forming an exterior, a first discharge slit 53 formed in the first tower case 51, and the first discharge slit 53 It may include a first vane 55 for guiding the vertical direction of the air.

The first tower case 51 may have a cylindrical shape. And the first tower case 51 may be coupled to the upper portion of the support body (10).

The first discharge slit 53 may extend long in the vertical direction, that is, in the height direction of the first tower case 51 . The first discharge slit 53 may be formed as an opening having a preset width in the first tower case 51 . And the first discharge slit 53 may discharge the air flowing inside the first tower case 51 to the outside.

An end of the first vane 55 may contact an inner side of the first discharge slit 53 in a direction perpendicular to the extending direction of the first discharge slit 53 .

And the first vane 55 may be rotatably provided. That is, the end of the first vane 55 may be rotatably provided in the vertical direction. Therefore, when the air discharged from the first discharge slit 53 forms a straight-line flow forward, the end of the first vane 55 is in contact with the inner surface of the first discharge slit 53 . can In addition, the first vane 55 may rotate up and down based on a contact point with the first discharge slit 53 . Accordingly, the vertical flow direction of the air discharged from the first discharge slit 53 can be determined.

A plurality of first vanes 55 may be provided, and the plurality of first vanes 55 may be vertically spaced apart from each other along the first discharge slit 53 .

The first vane 55 may be located in the inner space of the first tower case 51 . In addition, the air flowing through the inner space of the first tower case 51 may be guided to the first discharge slit 53 to be discharged to the outside.

Similarly, the second discharge tower 60 includes a second tower case 61 forming an exterior, a second discharge slit 63 formed in the second tower case 61, and the second discharge slit 63 It may include a second vane 65 for guiding the vertical direction of the air discharged from the.

As described above, the second tower case 61 is disposed to be symmetrical with the first tower case 51 , and may have the same cylindrical shape as the first tower case 51 . The description of the second discharge slit 63 and the second vane 65 will refer to the description of the first discharge slit 53 and the first vane 55 described above.

The blower 1 may further include a support filler 80 for fixing the dual discharge parts 50 and 60 to the support body 10 .

The support filler 80 may include an upper head 83 coupled to the upper portion of the dual discharge units 50 and 60 and an extension portion 85 coupled between the dual discharge units 50 and 60 . there is.

The support filler 80 may be inserted into a space formed by the dual discharge parts 50 and 60 . For example, the support pillar 80 may have a “T” shape.

The dual discharge parts 50 and 60 may have a shape forming a sense of unity with the support body 10 by combining with the support filler 80 .

The support filler 80 may support the upper part downward so that the rotation shaft of the dual discharge part 50 and 60 is fixed.

That is, the upper head 83 may be rotatably coupled to the upper surface of the first discharge tower 50 and the upper surface of the second discharge tower 60 . For example, the upper head 83 may have a shape in which two circles are connected corresponding to the upper surface of the first discharge tower 50 and the upper surface of the second discharge tower 60 /

The extension part 85 may extend downward from the center of the upper head 83 to fill a space formed between the first discharge tower 60 and the second discharge tower 60 . The lower end of the extension part 85 may be coupled to the upper surface of the support body 10 .

The extension part 85 may have a curved inner surface or a hollow interior so that the first tower case 51 and the second tower case 61 positioned on both sides can rotate smoothly. .

That is, the first discharge tower 50 and the second discharge tower 60 may be rotated stably by having a rotation shaft fixed in the vertical direction by the support pillar 80 and the support body 10 . .

The support body 10 may include a front case 11 and a rear case 12 forming an exterior.

The front case 11 may form an exterior having a sense of unity with the first tower case 51 and the second tower case 61 . For example, the front case 11 may form a curved surface extending downward from the lower end of the first tower case 51 in the same way as the curvature of the first tower case 51 . Similarly, the front case 11 may form a curved surface extending downwardly from the lower end of the second tower case 61 in the same manner as the curvature of the second tower case 61 to achieve symmetry.

In addition, between the two curved surfaces formed on the outer peripheral surface of the front case 11, it may be formed to form a plane with the extension (85). Accordingly, the front exterior of the blower 1 may be formed so that the user can feel a sense of unity in the vertical direction.

The rear case 12 may be coupled to the rear surface of the front case 11 . The volume of the rear case 12 may be larger than the volume of the front case 11 .

For example, the rear case 12 may have a cylindrical shape. In detail, the rear case 12 may extend from the rear end of one side of the front case 11 to the rear end of the other side to have a set curvature.

An inlet 13 for introducing air may be formed on an outer peripheral surface of the rear case 12 .

The outer peripheral surface of the rear case 12, that is, the peripheral surface of the rear case 12 may have a grill shape extending in the vertical direction. And the suction port 13 may be formed in the space between the grill.

Accordingly, the ambient air of the rear case 12 may be introduced into the rear case 12 through the suction port 13 formed in the rear case 12 .

In the embodiment of the present invention, the suction port 13 is located on the outer peripheral surface of the rear case 12, but is not limited thereto. That is, the suction port 13 may also be formed in the front case 11 . In this case, air may be introduced into the filter 40 inside through the suction port 13 formed in the front case 11 and the rear case 12 .

The upper surface 14 of the rear case 12 may be inclined. For example, the upper surface 14 may be inclined upwardly extending toward the direction in which the front case 11 is located. That is, the upper surface 14 may be formed as an inclined surface that increases toward the front.

Accordingly, the flow rate of the air discharged from the discharge opening 15 formed in the upper surface 14 can be increased. In addition, since the diffuser 300 is positioned vertically below the upper surface 14 , the pressure loss of the air passing through the diffuser 300 can be relatively reduced.

In addition, according to the upper surface 14 extending obliquely upward toward the front, when the discharge opening 15 is closed by the discharge module 100, the air passing through the diffuser 300 is relatively It can flow smoothly into the inner space 62 of the dual discharge parts 50 and 60 located in the front.

That is, since the air that has passed through the diffuser 300 flows into the inner space 62 of the dual discharge units 50 and 60 according to the guide of the inclined upper surface 14, friction or collision with the distribution duct 400 to be described later. can be minimized, and the flow of air can be formed in a curved path.

Here, the inner space 62 of the dual discharge units 50 and 60, through which air flows to be discharged, may be referred to as a “discharge passage”. In addition, the discharge passage may be formed in each of the discharge units of the dual discharge units 50 and 60 , that is, the first discharge tower 50 and the second discharge tower 60 , respectively.

The above-described discharge port, that is, the discharge opening 15 may be formed on the upper surface 14 of the rear case 12 .

That is, the discharge opening 15 may be positioned lower than the discharge slits 53 and 63 . In addition, the discharge opening 15 may be formed such that the air discharge direction is different from the air discharge direction of the discharge slits 53 and 63 .

In detail, the discharge opening 15 may be formed to open the upper surface 14 in the vertical direction. For example, the discharge opening 15 may have a semicircular shape.

A guide grill 16 for guiding the direction of the air discharged from the discharge opening 15 may be installed on the upper surface of the rear case 12 .

The guide grill 16 may be located above the discharge opening 15 . And the guide grill 16 may be provided in plurality.

The guide grill 16 may be formed to guide the air discharged from the discharge opening 15 upward. For example, the guide grill 16 may extend in a direction perpendicular to the ground to guide the air discharged from the discharge opening 15 .

The upper end of the rear case 12 may be located lower than the upper end of the front case 11 . And between the upper end of the rear case 12 and the upper end of the front case 11, a handle case 18 having a recessed space for guiding the user's grip may be formed.

The front case 11 and the rear case 12 may be collectively referred to as “body cases 11 and 12”. As described above, the body cases 11 and 112 may form a suction port 13 through which external air is sucked.

4 is a 1-1' cross-sectional view of FIG.

3 and 4 , the support body 10 may further include a discharge module 100 for opening and closing the discharge opening 15 .

That is, the discharge module 100 may selectively open and close the discharge opening 15 . In addition, the discharge module 100 may open and close the discharge opening 15 in stages. For example, the discharge module 100 may open and close the discharge opening 15 to increase or decrease the open area in stages.

The discharge module 100 may close the discharge opening 15 in a normal blowing mode.

Here, the general blowing mode may be understood as an operation for generating an airflow in an area where a user can be located, that is, in front of the blower 1 . Accordingly, in the general blowing mode, air may be discharged only through the discharge slits 53 and 63 in order to provide a more pleasant and cool wind to the user.

The discharge module 100 may include a door (not shown) for opening and closing the discharge opening 15 . The door may open and close the discharge opening 15 by sliding or rotating.

The discharge module 100 may open the discharge opening 15 in a sleep wind mode, which is an operation for lowering noise and wind speed to preset values.

Meanwhile, the blower 1 may further include a control unit (not shown) capable of controlling the operation of each component. In addition, the control unit (not shown) may control the door to move or rotate when driving in the sleep wind mode. For example, in the sleep wind mode, the controller may control movement or rotation of the door so that the discharge opening 15 is completely opened.

The support body 10 may further include a base 20 placed on the ground, a filter support 30 disposed on the base 20 and a filter 40 coupled to the filter support 30 . .

The base 20 may be provided below the rear case 12 . Also, the base 20 may be spaced apart from the inside of the lower end of the rear case 12 .

The air sucked through the suction part 13 may pass through the filter 40 provided on the upper side of the base 20 to flow into the central suction passage 45 . That is, the filter 40 may filter (or purify) the air sucked in through the suction port 13 .

The filter 40 may have a donut or cylindrical shape that is opened along a central axis. Air sucked in through the suction port 13 may pass through the outer circumferential surface of the filter 40 having a cylindrical shape and be introduced into the filter 40 .

On the other hand, in the space formed inside the filter 40, a suction passage 45 for guiding the filtered air may be formed. That is, the air passing through the filter 40 may flow to the fan 210 along the suction passage 45 .

The filter support part 30 may be coupled to the upper surface of the base 20 . That is, the lower surface of the filter support part 30 may be supported by the base 20 .

The filter support part 30 may include a support device 31 forming a mounting space of the filter 40 and a filter frame 35 .

In detail, the support device 31 may form a lower portion of the filter support part 30 . In addition, the filter frame 35 may form an upper portion of the filter support unit 30 .

The support device 31 may support the lower surface of the filter 40 . For example, the support device 31 may have a ring shape. Also, the inner space of the support device 31 may form a lower portion of the suction passage 45 .

The filter 40 may be seated on the support device 31 . For example, the upper surface of the support device 31 may form a surface on which the filter 40 is seated.

In addition, the support device 31 may fix the filter 40 .

In detail, on the inner circumferential surface of the support device 31 , a lever device for guiding detachment or fixation of the filter 40 may be located.

The filter frame 35 may be positioned upwardly spaced apart from the support device 31 . For example, the filter frame 35 has a substantially ring shape.

The inner space of the filter frame 35 may form an upper portion of the suction passage 45 .

And the upper portion of the filter frame 35 can support the fan housing 200, which will be described later.

Meanwhile, the filter support part 30 may further include a plurality of filter posts (not shown) extending upwardly from the support device 31 toward the filter frame 35 . By the plurality of filter pillars, the support device 31 and the filter frame 35 may be spaced apart from each other.

The plurality of filter pillars may be arranged in a circumferential direction and connected to the support device 31 and edges of the filter frame 35 .

That is, the mounting space of the filter 40 may be defined by the support device 31 , the filter frame 35 and the filter pillar 132 .

The support body 10 includes a fan housing 200 positioned above the filter 40 , a fan 210 providing flow pressure so that air is sucked into the suction port 13 , and an upper side of the fan 210 . It may further include a diffuser 300 positioned in the and a distribution duct 400 for guiding the air passing through the diffuser 300 to the dual discharge units 50 and 60 .

The fan housing 200 may be installed on the outlet side of the filter 40 .

The fan housing 200 may accommodate the fan 210 . In addition, the fan housing 200 may be supported by the filter frame 35 .

An inlet grill 205 for guiding the inflow of air into the fan housing 200 may be formed at a lower portion of the fan housing 200 .

That is, the inlet grill 205 may communicate with the suction passage 45 . Since the inlet grill 205 is provided as a grill, it is possible to prevent the user from inserting a finger or the like into the fan housing 200 when the filter 40 is removed.

The fan 210 may provide a flow pressure of air through rotation. In addition, the fan 210 may be placed on the upper side of the inlet grill 205 .

The fan 210 may include a flow fan that introduces air in an axial direction and discharges air in an oblique direction.

In detail, the fan 210 includes a hub 211 to which the shaft of a motor (not shown) is coupled, a shroud 213 spaced apart from the hub 211 , and the hub 211 and the shroud 213 . It may include a plurality of blades 215 disposed between the.

The motor is installed in the motor accommodating part 310 of the diffuser 300 , and the shaft of the motor extends downward to be coupled to the hub 211 .

The hub 211 may be formed in a shape corresponding to the motor accommodating part 310 . For example, the hub 211 may have a bowl shape in which the diameter becomes narrower toward the bottom.

In addition, the hub 211 may form a shaft coupling part (not shown) to which the shaft of the motor is coupled. The shaft coupling portion may be formed on an inner circumferential surface of the hub 211 .

The shroud 213 may form a central opening through which the air passing through the inlet grill 205 is sucked. In addition, the shroud 213 may form an outer opening through which the air introduced through the central opening is discharged in an oblique direction by the guide of the blade 215 . The outer opening may be located above the central opening.

One surface of the blade 215 may be coupled to the outer circumferential surface of the hub 211 , and the other surface may be coupled to the inner circumferential surface of the shroud 213 .

The plurality of blades 215 may be disposed to be spaced apart from each other in a circumferential direction of the hub 211 .

The air passing through the filter 40 may be introduced into the fan housing 200 through the inlet grill 205 while flowing upward along the suction passage 45 .

In addition, the air introduced into the fan housing 200 may be introduced into a central opening (or axial direction) formed by the shroud 213 and discharged in an oblique direction through the blade 215 . In this case, the blade 215 may extend obliquely in an axial direction with respect to the axial direction so that air may flow in an oblique direction through the outer opening.

The diffuser 300 may be positioned above the fan 210 . In addition, the diffuser 300 may guide the flow of air passing through the fan 210 to the inner space of the distribution duct 400 .

The diffuser 300 may be connected to an upper end of the fan housing 200 . For example, the diffuser 300 may be stacked on the fan housing 200 to have the same outer diameter as the fan housing 200 . In addition, the diffuser 300 may guide the air passing through the fan 210 to rise to the discharge opening 50 or the discharge slits 53 and 63 .

The diffuser 300 may include an outer wall 320 forming an outer periphery and a motor accommodating part 310 positioned inside the outer wall 320 and extending in a circumferential direction. In addition, the diffuser 300 may further include a plurality of guide vanes 330 provided in a circumferential direction between the motor accommodating part 310 and the outer wall 320 .

A diameter of the outer wall 320 is greater than a diameter of the motor accommodating part 310 . That is, the diameter of the outer wall 320 may be understood as the outer diameter of the diffuser 300 . In addition, the diameter of the outer peripheral surface of the motor accommodating part 310 may be understood as the inner diameter of the diffuser (300).

The outer wall 320 may be positioned radially spaced apart from the outer circumferential surface of the motor accommodating part 310 . Between the inner circumferential surface of the outer wall 320 and the outer circumferential surface of the motor accommodating part 310, a guide flow path 335 through which the air passing through the fan 210 flows may be formed. In addition, the guide vanes 330 for guiding air upward may be disposed in the guide flow path 335 .

The motor accommodating part 310 may form an internal space. And the motor (not shown) may be installed in the inner space of the motor accommodating part 310 .

The lower part 315 of the motor accommodating part 310 may have a bowl shape in which the diameter decreases toward the bottom.

The shape of the lower part 315 of the motor accommodating part 310 may correspond to the shape of the hub 211 . In addition, the motor accommodating part 310 may be located inside the hub 211 .

The shaft of the motor may extend downward from the motor and may be coupled to the shaft coupling part of the hub 211 through a motor coupling hole 318 formed in the lower center of the motor receiving part 310 .

A plurality of sound absorbing holes 316 in which perforations are formed may be formed in the lower portion 315 of the motor accommodating part 310 . And a sound absorbing material (not shown) may be attached to the inside of the motor accommodating part 310 to correspond to the plurality of sound absorbing holes 316 .

The plurality of sound-absorbing holes 316 may be formed to be spaced apart from each other at preset intervals along the circumferential direction of the lower surface 315 around the motor coupling hole 318 . As an example, the interval between the plurality of sound-absorbing holes 316 may be set to 8 to 14 (mm).

A space may be formed by being spaced apart by a predetermined distance between the lower surface 315 of the motor accommodating part and the hub 211 . Here, the space formed between the lower surface 315 and the hub 211 is called an “air gap”.

A portion of the air that has passed through the fan 210 may be introduced into the air gap. The air introduced into the air gap may cause friction and collision in the air gap by the pressure generated by the rotation of the fan 210 . As a result, air entering the air gap may generate flow noise.

Therefore, according to the plurality of sound-absorbing holes 316 and the sound-absorbing material, it is possible to minimize the flow noise generated by the air gap.

The plurality of sound-absorbing holes 316 may have a preset diameter. For example, the diameter of the sound-absorbing hole 316 may be set to 2 (mm).

The guide vane 330 may extend from an outer circumferential surface of the motor accommodating part 310 to an inner circumferential surface of the outer wall 320 . A plurality of the guide vanes 330 may be disposed to be spaced apart along the circumferential direction.

The guide vane 330 may guide the air introduced into the guide passage 335 of the diffuser 300 through the fan 210 upward.

The air introduced through the suction port 13 and passed through the filter 40 flows upward by the flow pressure generated through the rotation of the fan 210 . After flowing into the fan housing 200 , the air flowing upward may ascend in an oblique direction while passing through the fan 210 .

The air rising in the oblique direction is introduced into the guide passage 335 of the diffuser 300, and the plurality of guide vanes 330 disposed in the guide passage 335 are introduced into the guide passage (33%). Air can be guided to flow upwards.

Meanwhile, most of the air rising in an oblique direction through the blade 215 may have a fluidity component in a circumferential direction and a fluidity component in a radial direction. Accordingly, the air passing through the blade 215 may flow upward while forming a rotating vortex airflow.

The plurality of guide vanes 330 may offset the fluid component forming the vortex airflow to guide the air to rise stably.

That is, the velocity component of the air passing through the guide vane 330 may decrease in radial and circumferential directions. On the other hand, the relative axial component, that is, the upward velocity component may be large.

The distribution duct 400 may be positioned above the diffuser 300 . In addition, the distribution duct 400 may guide the air rising through the diffuser 300 .

In detail, the distribution duct 400 may be connected to an upper end of the diffuser 300 . For example, the lower outer diameter of the distribution duct 400 may be the same as the upper outer diameter of the diffuser 300 . That is, the distribution duct 400 may be coupled to the outer wall 320 of the diffuser 300 . In addition, the distribution duct 400 may extend from the outer wall 320 to the lower ends of the dual discharge units 50 and 60 .

The distribution duct 400 may be formed such that the flow cross-sectional area is gradually reduced along the flow direction of the air. For example, the distribution duct 400 may be formed to have a smaller flow cross-sectional area toward the upper side.

In addition, the distribution duct 400 may have a curved inner circumferential surface so that a curved air flow is formed between the dual discharge units 50 and 60 and the diffuser 300 .

Since the upper surface 14 of the rear case extends obliquely upward toward the dual discharge parts 50 and 60, the distribution duct 400 is the vertical distance between the diffuser 300 and the discharge opening 15 ( 4) may be formed to increase toward the dual discharge parts 50 and 60. Accordingly, the air that has passed through the diffuser 300 may flow along the distribution flow path 410 while minimizing collision with the dual discharge units 50 and 60 positioned relatively forward.

The inside of the distribution duct 400 may form a distribution flow path 410 in which the air passing through the diffuser 300 is branched into the first discharge tower 50 or the second discharge tower 60 .

The distribution passage 410 may communicate with the inner space of the first discharge tower 50 and the inner space of the second discharge tower 60 . That is, the distribution duct 400 may guide the air passing through the diffuser 300 to the first discharge tower 50 and the second discharge tower 60 . As a result, the distribution duct 400 may guide the air passing through the diffuser 300 to be branched and introduced into the dual discharge units 50 and 60 .

Meanwhile, the distribution duct 400 may extend to communicate with the discharge opening 15 and the inner space of the dual discharge units 50 and 60 .

In detail, the distribution duct 400 may form an opening surface corresponding to the discharge opening 15 . That is, the distribution duct 400 may form an opening surface in an area corresponding to the vertical downward direction of the discharge opening 15 .

Accordingly, the air introduced into the distribution duct 400 according to the opening and closing operation of the discharge module 100 is directed to the discharge slits 53 and 63 of the discharge opening 15 or the dual discharge units 50 and 60. can move

In addition, the opening surface may be in contact with the lower end of the upper surface 14 defining the discharge opening 15 . That is, the lower end of the upper surface 14 may define the opening of the distribution duct 400 . Accordingly, it is possible to prevent air from leaking between the rear case 12 and the distribution duct 400 .

The support body 10 is formed on the upper surface, and further includes a tower coupling part 19 supporting the dual discharge parts 50 and 60 and a rotation module 500 installed in the tower coupling part 19. can do.

The tower coupling part 19 may be formed on the support body 10 . And the tower coupling portion 19 may be formed to communicate with the distribution passage (410).

In detail, the tower coupling part 19 may form an opening in the upper surface of the main body cases 11 and 12 into which the first discharge tower 50 and the second discharge tower 60 are respectively inserted or supported. .

For example, the tower coupling part 19 may be formed on the upper surface of the front case 11 . That is, the tower coupling part 19 may be higher than the upper surface 14 of the rear case 12 or located at the same height.

The tower coupling unit 19 may be formed to correspond to the number of the dual discharge units 50 and 60 . For example, the tower coupling part 19 may include a first tower coupling part into which the first discharge tower 50 is inserted or supported and a second tower coupling part into which the second discharge tower 60 is inserted or supported. can

The distribution duct 400 may extend to branch the air introduced into the distribution passage 410 into the first discharge tower 50 and the second discharge tower 60 . That is, the distribution duct 400 may extend from the diffuser 300 along the flow direction of the air, and then extend to branch to the lower end of the first tower coupling part and the lower end of the second tower coupling part, respectively.

The rotation module 500 may be installed inside the tower coupling part 19 . In addition, the rotation module 500 may be coupled to the dual discharge units 50 and 60 .

The rotation module 500 is installed in the first tower coupling portion and is installed in the first rotation module and the second tower coupling portion to be coupled to the first discharge tower 50 and the second discharge tower 60 and It may include a second rotation module coupled.

The first rotation module and the second rotation module may be formed in the same configuration. Accordingly, the first rotation module and the second rotation module will be collectively referred to as “rotation module 500”. That is, each configuration of the rotation module 500 to be described later can be understood as a configuration provided in the first rotation module and the second rotation module, respectively.

The rotation module 500 may provide a rotational force to rotate the dual discharge units 50 and 60 . That is, the first discharge tower 50 and the second discharge tower 60 may be rotated clockwise or counterclockwise by the respective coupled rotation modules.

The first discharge tower 50 may rotate independently of the second discharge tower 60 . That is, the rotation module 500 may be provided such that the first discharge tower 50 and the second discharge tower 60 rotate independently of each other.

Accordingly, the flow direction of the air discharged from the first discharge slit 53 may be controlled to be different from the flow direction of the air discharged from the second discharge slit 63 .

Accordingly, it is possible to provide various operating modes of the blower 1 that can provide a comfortable air flow to more users in the room. And faster indoor air circulation can be performed.

In detail, the rotation module 500 may form various discharge airflows by controlling the rotation angles of the first discharge tower 50 and the second discharge tower 60 .

The control unit (not shown) controls the rotation direction and angle of the rotation module 500 to control the range and intensity of air (hereinafter, “discharge air flow”) discharged from the dual discharge units 50 and 60, respectively (or wind speed), etc.

For example, the control unit may control a rotational direction (eg, clockwise) of the first discharge module to be opposite (eg, counterclockwise) to a rotational direction of the second discharge module, and adjust the rotation angle. You can control the same at a preset angle.

In this case, the air discharged through the first discharge slit 53 of the first discharge tower 50 and the air discharged through the second discharge slit 63 of the second discharge tower 60 are mixed with each other. Thus, it is possible to provide the user with a more powerful discharge airflow in a wider range.

Meanwhile, in FIG. 4 , the configuration of the second discharge tower 60 is shown. The configuration of the second discharge tower 60 described with reference to FIG. 4 can also be used for the first discharge tower 50 as described above.

A discharge passage 62 may be formed inside the second discharge case 61 . That is, a discharge passage 62 for guiding air to the discharge slits 53 and 63 may be formed in the inner space of the dual discharge units 50 and 60 .

The discharge passage 62 may be formed by a discharge housing (not shown) accommodated in the discharge case 61 .

That is, the second discharge tower 60 may further include a discharge housing (not shown) accommodated in the second discharge case 61 to form the discharge passage 62 .

In this case, the second vane 65 may be accommodated in the discharge housing. In addition, the discharge housing may be formed to be narrower in width toward the second discharge slit 63, that is, toward the front. In this case, the second discharge slit 63 may be formed at a front end of the discharge housing.

Meanwhile, the discharge passage 62 may communicate with the connection passage 515 . For example, the discharge passage 62 formed inside the second discharge case 61 may communicate with the connection passage 515 formed by the second coupling housing.

Accordingly, the air branched from the distribution flow path 410 into the connection flow path of the first coupling housing and the connection flow path of the second coupling housing is respectively separated from the discharge flow path formed in the first discharge case 51 and the second coupling flow path. 2 It can flow through the discharge passage 62 formed in the interior of the discharge case 61 .

The second discharge tower 60 may further include a vane link 66 for guiding the rotation of the second vane 65 .

The vane link 66 located in the second discharge tower 60 may be referred to as a “second vane link”. And the vane link located in the first discharge tower 50 may be called a “first vane link”.

The second vane link 66 may transmit a force for rotation of the second vane 65 . In addition, the second vane link 66 may control the vertical flow direction of the air discharged to the second discharge slit 63 through the rotation of the second vane 65 .

The second discharge tower 60 may further include a vane motor (not shown) installed inside the second discharge case 61 .

Meanwhile, the vane motor located in the second discharge tower 60 may be referred to as a “second vane motor”. And the vane motor located in the first discharge tower 50 may be called a “first vane motor”.

The vane motor is coupled to one end of the second vane link 66 , and when the vane motor operates, the second vane link 66 may move.

The second vane link 66 may be connected to a plurality of second vanes 65 spaced apart in the vertical direction. For example, the second vane link 66 may be coupled to the rear end of the plurality of second vanes 65 . Accordingly, the plurality of second vanes 65 may rotate depending on the movement of the second vane link 66 .

When the vane motor operates and the second vane link 66 moves upward, the second vane 65 may rotate clockwise with reference to FIG. 4 . At this time, the air discharged to the second discharge slit 63 may be guided more downward.

Conversely, when the second vane link 66 moves downward, the second vane 65 rotates counterclockwise, and the air discharged to the second discharge slit 63 can be guided more upward. there is.

Figure 5 is an exploded perspective view showing the rotation module according to the first embodiment of the present invention, Figure 6 is an enlarged cross-sectional view showing the coupling state of the rotation module according to the first embodiment of the present invention, Figure 7 is the first embodiment of the present invention It is an exploded perspective view showing the bearing of the rotation module according to the first embodiment.

5 to 7 , the rotation module 500 may include a coupling housing 510 accommodated inside the tower coupling unit 19 and coupled to the dual discharge units 50 and 60 . there is.

The coupling housing 510 may have a cylindrical shape opened in the vertical direction. In addition, a connection passage 515 through which air passes may be formed in the coupling housing 510 . The connection passage 515 may guide the air introduced through the distribution passage 410 into the inner space of the dual discharge units 50 and 60 . That is, the connection passage 515 may communicate with the distribution passage 410 and the discharge passage 62 .

The coupling housing 510 may be supported on the upper end of the distribution duct 400 . For example, the coupling housing 510 may be supported by an upper end of the distribution duct 400 extending to the first tower coupling part and an upper end of the distribution duct 400 extending to the second tower coupling part.

The coupling housing 510 may include a coupling part 512 for coupling with the dual discharge parts 50 and 60 . The fastening part 512 may be formed to protrude upward from the upper surface of the coupling housing 510 .

A hole forming the connection passage 515 may be formed in the upper surface of the coupling housing 510 . And in order to minimize the resistance of air passing through the connection passage 515, the inner circumferential surface of the coupling housing 510 may have a curved surface 514 with a hole leading to the discharge passage 62 in the vertical direction.

According to this, since the air passing through the connection passage 515 can be smoothly introduced into the discharge passage 62 , the connection is made by the upper surface of the coupling housing 510 forming the fastening part 512 . The flow cross-sectional area of the flow path 515 may be changed to minimize resistance that may occur.

Meanwhile, a tower hole 61a corresponding to the fastening part 521 may be formed at the lower ends of the dual discharge parts 50 and 60 .

That is, the fastening member passing through the tower hole 61a is fastened to the fastening part 512 to couple the dual discharge parts 50 and 60 and the coupling housing 510 . For example, a tower hole 61a corresponding to the lower end of the second tower case 61 may be formed to be positioned outside the fastening part 512 in the circumferential direction.

Due to the coupling of the tower hole 61a and the coupling part 512 , the dual discharge parts 50 and 60 may rotate together with the rotation of the coupling housing 510 .

On the other hand, the coupling housing 510 may be provided for each discharge tower (50, 60). As an example, it may include a first coupling housing accommodated in the first tower coupling portion and a second coupling housing accommodated in the second tower coupling portion.

The rotation module 500 may further include a rotation motor 520 providing rotational force, a motor gear 530 coupled to the rotation motor 520 and a driving gear 540 meshing with the motor gear 530 . can

The rotation motor 520 may provide a force for rotation of the dual discharge units 50 and 60 . For example, the rotation motor 520 may include a step motor.

The rotation motor 520 and the motor gear 530 may be located outside the coupling housing 510 .

The rotation motor 520 may be installed in a predetermined space formed in the support body 10 . That is, the support body 10 may form an accommodation space 450 in which the rotation motor 520 and the motor gear 530 are accommodated.

The accommodating space 450 may be located behind the dual discharge units 50 and 60 . That is, the accommodation space 450 may be formed outside the flow path through which the air flows.

The accommodating space 450 includes a case extension portion 19a extending rearward along the upper surface 14 of the rear case 12 from the tower coupling portion 19 and the upper surface of the distribution duct 400 . can be formed by

The tower coupling part 19 has a cylindrical shape opened in the vertical direction, and the rear end of the tower coupling part 19 may contact the upper surface 14 of the rear case 13 . And the case extension portion 19a extends along the upper surface 14 of the rear case from the point of contact with the upper surface 14 of the rear case 13, and the rear end is bent toward the receiving support surface 430. can

In addition, the upper surface of the distribution duct 400 may be spaced apart from the lower portion of the upper surface 14 of the rear case 12 where the discharge opening 15 is not formed. Accordingly, an accommodation space 450 in which the rotation motor 520 is installed may be formed between the upper surface of the distribution duct 400 and the upper surface 14 of the rear case 12 .

That is, the upper surfaces 420 and 430 of the distribution duct 400 may extend from the end edge of the discharge opening 15 to contact the tower coupling part 19 from the inside of the support body 10 .

In more detail, the upper surface of the distribution duct 400, the receiving support surface 430 for supporting the rotary motor 520, extends upward from the receiving support surface 430 to connect with the connection passage 515 It may include an upper end forming an opening and a seating surface 420 formed on the upper surface of the upper end and positioned higher than the receiving support surface 430 .

The receiving support surface 430 may extend downward from the upper edge of the discharge opening 15 and then extend to form a horizontal surface in the front. Since the upper surface 14 of the rear case 13 is inclined, the upper surface 14 or the case extension portion 19a may be positioned such that the vertical distance from the receiving support surface 430 toward the front is greater. . That is, the accommodating space 450 may form a space having a greater height toward the upper end of the upper surface 14 of the rear case.

The receiving support surface 430 may provide a bottom surface to which the rotary motor 520 is coupled. That is, the receiving support surface 430 may support the rotation motor 520 .

The upper end may form an opening through which the connection passage 515 and the distribution passage 410 are connected. And the inner peripheral surface of the upper end may be formed in a curved surface. That is, the inner surface connecting the receiving support surface 430 and the seating surface 420 may be formed as a curved surface.

According to this, since it is possible to minimize the collision of air flowing from the distribution passage 410 to the connection passage 515 and form a relatively smooth stream line, the loss of air flow is reduced. can be reduced

The seating surface 420 may be depressed downwardly on the upper surface of the upper end. On the seating surface 420 , the bearing 550 or the driving gear 540 (refer to FIG. 9 ) may be seated.

The upper end of the distribution duct 400 may form a circular opening in order to form a flow space connected to the connection passage 515 in the inner side of the tower coupling portion (19). For example, it may extend from the upper end of the distribution duct 400 to the connection passage 515 to have the same diameter. That is, it can be extended so that the flow cross-sectional area is maintained.

Since the seating surface 520 is formed on the upper surface of the upper end, it may extend along the circumferential direction of the upper end. In addition, the seating surface 520 may be depressed to a predetermined width so that the bearing 550 or the driving gear 540 is coupled and supported.

In addition, the rotary motor 520 may be provided to independently rotate the dual discharge units 50 and 60 , that is, each of the discharge towers 50 and 60 . For example, the rotation motor 520 and the motor gear 530 may be provided for each of the discharge towers 50 and 60 to provide rotational force.

For example, the rotation motor 520 may include a first rotation motor providing a rotational force to the first discharge tower 50 and a second rotation motor providing rotational force to the second discharge tower 60 . . And the motor gear 530, the rotational force of the rotary motor 520 to the first coupling housing coupled to the first discharge tower 50 and the second coupling housing coupled to the second discharge tower (50) In order to transmit independently, it may include a first motor gear coupled to the first rotary motor and a second motor gear coupled to the second rotary motor.

According to this, the first discharge tower 50 and the second discharge tower 60 may have rotation directions independent of each other.

The motor gear 530 may be located above the rotation motor 520 . And the motor gear 530 may be coupled to the shaft of the rotation motor 520 to rotate.

The gear teeth of the motor gear 530 may be positioned to mesh with the gear teeth of the driving gear 540 . Accordingly, the motor gear 530 may transmit the rotational force of the rotation motor 520 to the driving gear 540 .

The driving gear 540 may be rotatably coupled to a lower portion of the coupling housing 510 . That is, rotational force is transmitted to the driving gear 540 according to the operation of the rotating motor 520 , and the coupling housing 510 coupled to the driving gear 540 forms the dual discharge units 50 and 60 . can be rotated

The driving gear 540 may have a ring shape in which the center is opened so that the connection passage 515 is formed.

The driving gear 540 may include a coupling groove 545 recessed in the inner circumferential surface. A coupling rib 557 of a bearing 550 to be described later may be inserted and coupled to the coupling groove 545 .

That is, the rotation of the driving gear 540 may cause the coupling housing 510 to rotate and simultaneously perform a rolling motion of the bearing 550 , which will be described later.

The rotation module 500 may further include a bearing 550 capable of supporting the load of the dual discharge units 50 and 60 and reducing rotational friction.

The bearing 550 may be coupled to a lower portion of the driving gear 540 . In detail, a coupling rib 557 protruding upward may be positioned on the upper surface of the bearing 550 . The coupling rib 557 may be coupled to a coupling groove 545 that is recessed from the lower end of the driving gear 540 .

Accordingly, the bearing 550 may perform a rolling motion along the rotational direction of the driving gear 540 to reduce rotational friction. For example, the bearing 550 may include a ball or a roller that rolls along the rotational direction of the driving gear 540 . A detailed description related thereto will be provided later.

The bearing 550 and the driving gear 540 are circumferentially formed to form a hollow connecting the discharge flow path 62 of the dual discharge unit 50 and 60 and the distribution flow path 510 of the distribution duct 400 . direction can be extended. Here, the hollow may form a connection passage 515 .

That is, the bearing 550 may be formed to correspond to the shape of the driving gear 540 . For example, the bearing 550 may have a ring shape in which the center is opened so that the connection passage 515 is formed.

Accordingly, the bearing 550 may support the dual discharge units 50 and 60 in the load direction of the dual discharge units 50 and 60 . Of course, the driving gear 540 coupled to the bearing 550 may also be supported in the load direction of the dual discharge parts 50 and 60 .

Also, the bearing 550 may include a thrust bearing. Accordingly, the bearing 550 may be formed to have a larger diameter than that of a general ball bearing. According to this, it is possible to reduce the axial distortion compared to the tolerance of the bearing.

Specifically, the bearing 550 is rotatably coupled to a lower ring 551 coupled to the distribution duct 400 , a connection ring 554 inserted into the lower ring 551 , and the lower ring 551 . It may include an upper ring (556).

In the bearing 550 , an upper ring 556 and a lower ring 551 may be connected to the connecting ring 554 so as to be parallel to the load direction of the dual discharge units 50 and 60 . In addition, since the bearing 550 distributes and supports the load of the dual discharge parts 50 and 60 along a surface extending in the circumferential direction, the allowable load value may be relatively large.

The lower ring 551 may include a lower surface 552 extending to have a predetermined width in the central axis direction from the lower end and a guide groove 553 recessed along the lower surface 552 .

That is, the lower surface 552 may form an inner peripheral surface of the lower ring 551 . In addition, the guide groove 553 is recessed to have a predetermined curvature in the lower surface 552 and may extend in the circumferential direction.

A plurality of balls 555 provided in the connecting ring 554 may be seated in the guide groove 553 . In addition, the plurality of balls 555 may perform a rolling motion in the guide groove 553 .

The connection ring 554 may be provided to contact the upper ring 556 and the lower ring 551 in the vertical direction. For example, the connection ring 554 may be coupled between the upper ring 556 and the lower ring 551 .

The connecting ring 554 may include a ball 555 for reducing friction caused by the rotation of the upper ring 556 .

The ball 555 may be provided to protrude in the vertical direction of the connection ring 554 to perform a rolling motion. The upper ring 556 supporting the load of the dual discharge parts 50 and 60 by the rolling motion of the ball 555 may reduce rotational friction.

A plurality of the balls 555 may be provided. In addition, the plurality of balls 555 may be disposed to be spaced apart along the circumferential direction of the connecting ring 554 . In other words, the connecting ring 554 may connect the plurality of balls 555 .

The upper ring 556 may be rotatably coupled to the lower ring 551 . In addition, a groove (not shown) corresponding to the guide groove 553 may be formed on the bottom surface of the upper ring 556 . The ball 555 of the connection ring 554 may contact the groove (not shown) to perform a rolling motion.

That is, the upper ring 556 may be rotatably coupled to the lower ring 551 to cover the upper portion of the connection ring 554 .

In addition, the upper ring 556 may include a coupling rib 557 protruding upward to be coupled to the lower surface of the driving gear 540 .

The coupling rib 557 may be formed to correspond to the coupling groove 545 . For example, the coupling rib 557 may protrude in a shape to fit into the coupling groove 545 .

A plurality of coupling ribs 557 may be provided, and the plurality of coupling ribs 557 may be spaced apart from each other in a circumferential direction.

8 is a perspective view showing a bearing of a rotation module according to a second embodiment of the present invention, and FIG. 9 is an enlarged cross-sectional view showing a coupling state of the rotation module according to the second embodiment of the present invention.

The configuration of the second embodiment that is the same as the rotation module 500 according to the first embodiment described above is to refer to the description in the first embodiment.

8 and 9 , the rotation module according to the second embodiment includes a bearing 5500 provided with rollers 5520 and 5530 for rolling motion along an outer circumferential surface of the bearing 5500 and the dual discharge units 50 and 60 . It is spaced apart from the lower end, and may include a roller case 5550 surrounding the bearing 5500 .

The bearing 5500 may be coupled to the upper end of the driving gear 540 seated on the seating surface 420 . For example, the driving gear 540 and the bearing 5500 may extend such that a hollow is formed in the center to form the connection passage 515 .

That is, in the second embodiment, the bearing 5500 may be coupled to the upper side of the driving gear 540 . In detail, the driving gear 540 is rotatably seated on the upper surface of the distribution duct 400 , and the bearing 5500 is coupled to the upper surface of the driving gear 54 to rotate together.

In addition, the bearing 5500 may be coupled to the lower ends of the dual discharge units 50 and 60 .

Meanwhile, the rotation module may further include a separation prevention rib 5570 for preventing the rotation shaft of the dual discharge units 50 and 60 from being twisted.

The separation prevention rib 5570 may be disposed to be fitted between the upper portion of the bearing 5500 and the lower portion of the dual discharge portions 50 and 60 . For example, the separation prevention rib 5570 may be formed to have a ring shape to be seated along the upper end of the bearing 5500 . And the separation prevention rib 5570 prevents the play between the dual discharge parts 50 and 60 and the bearing 5500, thereby preventing tilting that may occur when the rollers 5520 and 5530 roll. there is.

Accordingly, the separation preventing rib 5570 may maintain the position of the rotation axis of the dual discharge units 50 and 60 .

The roller case 5550 may form a roller guide space 5555 extending to surround the outer circumferential surface of the bearing 5550 so that the rollers 5520 and 5530 contact and roll.

That is, the inner surface of the roller case 5550 may form the roller guide space 5555 .

The roller guide space 5555 may form a recessed space so that the rollers 5520 and 5530 may roll in contact with each other in the vertical direction. For example, the roller guide space 5555 may have a “C”-shaped longitudinal cross-section. And the roller guide space 5555 may extend in the circumferential direction.

On the other hand, the outer surface of the roller case 5550 may form the outer appearance of the tower coupling portion (19). That is, in the second embodiment, the roller case 5550 may be integrally formed with the tower coupling unit 19 .

Since the rollers 5520 and 5530 roll while in contact with the inner surface of the roller case 5550 , it is possible to prevent shaft torsion when the dual discharge parts 50 and 60 rotate.

The bearing 5500 is installed on the outer circumferential surface of the bearing body 5510 and the bearing body 5510 in which the connection flow path 515 communicating with the inner space of the dual discharge parts 50 and 60 is formed by the inner circumferential surface, , may include rollers 5520 and 5530 rolling along the rotational direction of the driving gear 540 .

The bearing body 5510 may have a ring shape. An inner peripheral surface of the bearing body 5510 may form a connection passage 515 .

A plurality of rollers 5520 and 5530 may be installed on the outer circumferential surface of the bearing body 5510 . The plurality of rollers 5520 are an upper roller 5530 that rolls in contact with an upper surface defining the roller guide space 5555 and a lower roller that rolls in contact with a lower surface defining the roller guide space 5555. (5520).

The lower roller 5520 may be located below the upper roller 5530 . In addition, a plurality of the lower rollers 5520 may be spaced apart along the circumferential direction of the bearing body 5510 .

A plurality of upper rollers 5530 may also be spaced apart along the circumferential direction of the bearing body 5510 . Accordingly, friction of the rotating dual discharge units 50 and 60 may be reduced by the rollers 5520 and 5530 . At the same time, the load of the dual discharge units 50 and 60 may be carried by the rollers 5520 and 530 .

And for stable support in the vertical direction, the upper roller 5530 may be alternately disposed with the lower roller 5520 in the circumferential direction. According to this, since the lower roller 5520 and the upper roller 5530 perform rolling motion while stably supporting the load along the circumferential direction, tilting can be prevented.

1: blower
10: support body
50, 60: dual discharge unit
80: support filler

Claims (20)

a support body in which the suction port is formed;
a dual discharge unit installed in a symmetrical pair on the upper surface of the support body and discharging air;
a distribution duct provided in the support body and guiding the air sucked from the suction port to be branched and introduced into the dual discharge unit;
a tower coupling part that forms an opening in the upper surface of the support body, and in which the dual discharge part is installed; and
It is installed in the tower coupling part, and includes a rotation module capable of individually rotating the dual discharge part,
The rotation module,
a rotation motor providing rotational force;
a motor gear coupled to the rotating motor to rotate;
a driving gear engaged with the motor gear and transmitting rotational force to the dual discharge unit; and
A blower comprising a bearing coupled to the driving gear in a vertical direction and rolling along a rotational direction of the driving gear.
The method of claim 1,
The upper surface of the distribution duct,
a receiving support surface for supporting the rotary motor; and
A blower extending higher than the receiving support surface and including a seating surface on which the bearing is seated.
The method of claim 1,
The driving gear and the bearing are a blower having a ring shape.
The method of claim 1,
The bearing is a blower including a ball or roller for rolling motion along a rotational direction of the driving gear.
The method of claim 1,
The rotation module,
It is accommodated in the tower coupling portion, further comprising a coupling housing coupled to the lower portion of the dual discharge portion,
The driving gear is a blower rotatably coupled to a lower portion of the coupling housing.
6. The method of claim 5,
The rotary motor and the motor gear are located outside the coupling housing,
The bearing is a blower coupled to the lower side of the driving gear.
The method of claim 1,
The bearing is
a lower ring coupled to the distribution duct;
a connection ring inserted into a guide groove recessed in an inner circumferential surface of the lower ring; and
A blower comprising an upper ring rotatably coupled to the lower ring and in contact with the connecting ring.
8. The method of claim 7,
The connecting ring is a blower including a plurality of balls performing a rolling motion along a circumferential direction.
8. The method of claim 7,
The upper ring. A blower comprising a coupling rib protruding upwardly to be coupled to a lower surface of the driving gear.
The method of claim 1,
The driving gear is rotatably seated on the upper surface of the distribution duct,
The bearing is coupled to the upper surface of the driving gear and rotates together.
11. The method of claim 10,
The bearing is
a bearing body coupled to the dual discharge unit and having a connection passage communicating with the inner space of the dual discharge unit formed by an inner circumferential surface; and
The blower comprising a roller installed on the outer peripheral surface of the bearing body and rolling along the rotational direction of the driving gear.
12. The method of claim 11,
The rotation module,
It is spaced apart from the lower end of the dual discharge unit, further comprising a roller case surrounding the bearing,
The roller case is a blower that forms a roller guide space extending in a circumferential direction so that the rollers contact and roll.
13. The method of claim 12,
The roller is
an upper roller in contact with an upper surface defining the roller guide space; and
A blower comprising a lower roller in contact with a lower surface defining the roller guide space.
14. The method of claim 13,
The inner surface of the roller case forms the roller guide space,
The outer surface of the roller case is a blower forming an outer appearance of the tower coupling part.
12. The method of claim 11,
The rotation module, the blower further comprising a separation prevention rib fitted to the upper portion of the bearing and the lower portion of the dual discharge unit, to maintain the position of the rotation shaft of the dual discharge unit.
The method of claim 1,
The support body,
a front case forming the tower coupling part on an upper surface; and
Extending rearward from the front case, further comprising a rear case forming a discharge opening on the upper surface,
The discharge opening is located at the rear of the dual discharge unit.
17. The method of claim 16,
The support body,
a fan providing a flow pressure of air; and
It is installed on the upper part of the fan and further comprises a diffuser for guiding the air upward,
The distribution duct extends to communicate with the discharge opening and the inner space of the dual discharge unit.
18. The method of claim 17,
The distribution duct is
a receiving support surface positioned below the upper surface of the rear case to form a space in which the rotary motor is accommodated;
an upper end formed to be connected to the receiving support surface and forming an opening communicating with the inner space of the dual discharge unit; and
A blower comprising a seating surface recessed to seat the bearing on the upper surface of the upper end.
19. The method of claim 18,
The upper end portion is a blower in which an inner surface connecting the receiving surface and the seating surface is formed in a curved surface.
The method of claim 1,
The bearing and the driving gear,
It extends in the circumferential direction to form a hollow connecting the dual discharge part and the inner space of the distribution duct,
A blower supporting the surface in the load direction of the dual discharge part.

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