KR102553488B1 - Blower - Google Patents

Abstract

The present invention relates to a blower, and a blower according to an embodiment of the present invention includes a lower case having a suction hole through which air is introduced; a fan disposed inside the lower case; a tower case disposed on the upper side of the lower case and having a discharge port extending vertically and a blowing space through which the air discharged from the discharge port flows forward; and an air current converter disposed so as to protrude toward the blowing space, wherein the air flow converter includes: a motor providing a driving force; a board extending in the vertical direction and protruding toward the blowing space by receiving driving force from the motor; And a guide slit into which a guide protrusion protruding from the board is inserted, and a board guide connected to the motor and moved, wherein the guide slit is recessed in a first direction crossing the moving direction of the board guide, , It extends in a second direction intersecting the first direction to form one end and the other end, and the one end and the other end extend outwardly of the guide slit along the first direction, Since one end and the other end extend outward with respect to the first direction, which is the direction in which the mold is pulled out, interference between the mold and the board guide does not occur in the process of pulling out the mold, and there is an advantage in preventing undercut generated during mold processing.

Description

blower {Blower}

The present invention relates to a blower, and more particularly to an air current converter.

A blower causes a flow of air to circulate the air in an indoor space or to form an airflow toward a user. When the blower is equipped with a filter, the blower can purify the polluted air in the room and improve the quality of the indoor air.

In order to adjust the wind direction of air discharged through the blower, an air current converter may be provided in the blower.

The air current converter may include a board protruding toward the flow path of discharged air, and a board guide for guiding movement of the board.

However, when a slit is formed in the board guide to guide the movement of the board through a protrusion inserted into the slit, there is a problem in that an undercut is generated in the slit in the process of removing the mold during mold processing of the board guide.

An object to be solved by the present invention is to provide a blower in which air direction control is smoothly performed.

Another object of the present invention is to provide a blower having an air current converter with reduced tolerances generated in the manufacturing process.

Another object of the present invention is to provide a blower having an air current converter with reduced friction.

Another object of the present invention is to provide a blower with improved formability of a board and a board guider included in an airflow converter.

Another object of the present invention is to provide a blower in which the movement of a board included in an air current converter is smoothly guided.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, a blower according to an embodiment of the present invention includes a lower case having a suction hole through which air is introduced; a fan disposed inside the lower case; a tower case disposed on the upper side of the lower case and having a discharge port extending vertically and a blowing space through which the air discharged from the discharge port flows forward; and an air current converter disposed so as to protrude toward the blowing space.

The air current converter may include a motor providing driving force; a board extending in the vertical direction and protruding toward the blowing space by receiving driving force from the motor; and a board guide having a guide slit into which a guide protrusion protruding from the board is inserted and moving in connection with the motor.

The guide slit is recessed in a first direction crossing the moving direction of the board guide, and extends in a second direction crossing the first direction to form one end and the other end.

The one end and the other end extend outwardly of the guide slit along the first direction.

The board guide moves in a vertical direction, and the first direction may be perpendicular to the moving direction of the board guide.

The second direction may be inclined with respect to the moving direction of the board guide.

The guide slit may include a first guide surface extending from one end toward the other end; and a second guide surface extending from the one end toward the other end and spaced apart from the first guide surface.

The first guide surface and the second guide surface may be inclined with respect to the first direction.

An inclined angle of the first guide surface with respect to the first direction at the one end may be greater than an inclined angle of the second guide surface.

An inclined angle of the first guide surface with respect to the first direction at the other end may be smaller than an inclined angle of the second guide surface.

The first guide surface may include a first support portion formed rearward with respect to the first direction, and a first extension portion formed forward.

The second guide surface may include a second support portion formed rearward with respect to the first direction, and a second extension portion formed forward.

The first central line of the one end may be inclined toward the central axis of the guide board with respect to the first direction.

The second central line of the other end may be inclined toward the central axis of the guide board with respect to the first direction.

The guide slit may have a bent portion extending upward from the one end.

The one end may include a first support edge formed at the rear with respect to the first direction, and a first extension edge formed at the front with respect to the first direction and positioned outside the first support edge. .

The other end may include a second support edge formed at the rear with respect to the first direction, and a second extended edge formed at the front with respect to the first direction and positioned outside the second support edge. there is.

The board guide may include: a first barrier rib formed outside the one end; and a second barrier rib formed outside the other end.

The first barrier rib may extend outward from the guide slit along the first direction at a position in contact with the one end.

The second barrier rib may extend outward from the guide slit along the first direction at a position in contact with the other end.

The guide protrusion may have a wide cross-sectional area along the first direction.

The guide protrusion may be formed with a stepped portion extending outward along the first direction.

Details of other embodiments are included in the detailed description and drawings.

According to the blower of the present invention, there are one or more of the following effects.

First, since one end and the other end of the guide slit extend outward in the first direction, which is the direction in which the mold is pulled out, interference between the mold and the board guide does not occur in the process of pulling out the mold, preventing undercuts that occur during mold processing. There is an advantage to

Second, since one end and the other end of the guide slit extend outward in the first direction, which is the direction in which the mold is pulled out, interference between the mold and the board guide does not occur, thereby reducing the tolerance of the guide slit.

Third, by forming the guide slit inclined with respect to the first direction, there is also an advantage of reducing friction with the guide protrusion.

Fourth, by forming the first guide surface and the second guide surface of the guide slit at an angle, there is an advantage in that shape synthesis between the guide protrusion and the guide slit is improved.

Fifth, there is also an advantage of smoothly guiding the movement of the board by preventing the occurrence of undercutting at one end and the other end of the guide slit to prevent shaking of the guide protrusion reaching one end and the other end.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view of a blower according to an embodiment of the present invention.
2 is a longitudinal cross-sectional view of a blower according to an embodiment of the present invention.
3 is another longitudinal cross-sectional view of a blower according to an embodiment of the present invention.
4 is a top perspective view of a blower according to an embodiment of the present invention.
5 is a cross-sectional perspective view of a blower according to an embodiment of the present invention.
6 is a diagram illustrating the operation of an air current converter according to an embodiment of the present invention.
7 is a perspective view of an air current converter according to an embodiment of the present invention.
8 is an exemplary operation diagram of an air current converter according to an embodiment of the present invention.
9 is an exploded perspective view of an air current converter according to an embodiment of the present invention.
Figure 10 (a) is a front view of the board guide according to an embodiment of the present invention.
10 (b) is a front view of a guide protrusion according to an embodiment of the present invention.
Figure 11 (a) is a cross-sectional view of the board guide A-A' according to an embodiment of the present invention.
Figure 11 (b) is a cross-sectional view of the board guide B-B' according to an embodiment of the present invention.
Figure 12 is an enlarged view of one end of the board guide according to an embodiment of the present invention.
Figure 13 (a) is a front view of the board guide according to another embodiment of the present invention.
13(b) is a front view of a guide protrusion according to another embodiment of the present invention.
Figure 14 (a) is a cross-sectional view of the board guide A-A' according to another embodiment of the present invention.
Figure 14 (b) is a cross-sectional view of the board guide B-B' according to another embodiment of the present invention.
15 is an enlarged view of one end of the board guide according to another embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Hereinafter, the present invention will be described with reference to drawings for explaining a blower according to embodiments of the present invention.

Referring to FIG. 1, the overall structure of the blower 1 will first be described. Figure 1 shows the overall appearance of the blower (1).

Since the blower 1 sucks in air and circulates the sucked air, it may be named by other names such as an air conditioner, an air clean fan, and an air purifier.

The blower 1 according to an embodiment of the present invention may include a suction module 100 through which air is sucked in and a blowing module 200 through which the sucked air is discharged.

The blower 1 may have a columnar shape in which the diameter decreases toward the top, and the blower 1 may have a cone or truncated cone shape as a whole. When the cross section becomes narrower toward the upper side, there is an advantage in that the center of gravity is lowered and the risk of overturning due to external impact is reduced. However, unlike the present embodiment, it may not be a shape in which the cross section becomes narrower toward the upper side.

The suction module 100 may be formed to gradually decrease in diameter toward the top, and the blowing module 200 may also be formed to gradually decrease in diameter toward the top.

The suction module 100 may include a base 110, a lower case 120 disposed above the base 110, and a filter 130 disposed inside the lower case 120.

The base 110 may be seated on the ground and support the load of the blower 1 . The lower case 120 and the filter 130 may be seated on the upper side of the base 110 .

The lower case 120 may have a cylindrical shape, and may form a space in which the filter 130 is disposed. The lower case 120 may have a suction hole 121 opened to the inside of the lower case 120 . A plurality of suction holes 121 may be formed along the circumference of the lower case 120 .

The outer shape of the filter 130 may be cylindrical, and foreign substances contained in the air introduced through the suction hole 121 may be filtered out.

The blowing module 200 may be disposed separately in the form of two vertically extending pillars. The blowing module 200 may include a first tower 220 and a second tower 230 spaced apart from each other. The blowing module 200 may include a tower base 210 connecting the first tower 220 and the second tower 230 to the suction module 100 . The tower base 210 may be disposed above the suction module 100 and may be disposed below the first tower 220 and the second tower 230 .

The tower base 210 may have a cylindrical shape, and may be disposed above the suction module 100 to form a continuous outer circumferential surface with the suction module 100.

The upper surface of the tower base 210 may be formed concave downward, and may form an upper surface 211 of the tower base extending forward and backward. The first tower 220 may extend upward from one side 211a of the upper surface 211 of the tower base, and the second tower 230 may extend upward from the other side 211b of the upper surface 211 of the tower base. there is.

The tower base 210 may distribute filtered air supplied from the inside of the suction module 100 and provide the distributed air to the first tower 220 and the second tower 230, respectively.

The tower base 210, the first tower 220, and the second tower 230 may be manufactured as separate parts or may be manufactured integrally. The tower base 210 and the first tower 220 may form a continuous outer circumferential surface of the blower 1, and the tower base 210 and the second tower 230 may form a continuous outer circumferential surface of the blower 1. A circumferential surface can be formed.

Unlike this embodiment, the first tower 220 and the second tower 230 may be directly assembled to the suction module 100 without the tower base 210, or may be manufactured integrally with the suction module 100.

The first tower 220 and the second tower 230 may be spaced apart from each other, and a blowing space S may be formed between the first tower 220 and the second tower 230 .

The blowing space (S) can be understood as a space between the first tower 220 and the second tower 230, the front, rear and upper sides are open.

The outer shape of the blowing module 200 composed of the first tower 220, the second tower 230 and the blowing space S may be a truncated cone shape.

The discharge ports 222 and 232 respectively formed in the first tower 220 and the second tower 230 may discharge air toward the blowing space S. When the discharge ports 222 and 232 need to be distinguished, the discharge port formed in the first tower 220 is referred to as the first discharge port 222, and the discharge port formed in the second tower 230 is referred to as the second discharge port 232.

The first tower 220 and the second tower 230 may be arranged symmetrically with respect to the blowing space (S). Since the first tower 220 and the second tower 230 are symmetrically arranged, the flow is uniformly distributed in the blowing space S, which is more advantageous for controlling the horizontal airflow and the ascending airflow.

The first tower 220 may include a first tower case 221 forming the outer shape of the first tower 220, and the second tower 230 may include a first tower case 221 forming the outer shape of the second tower 230. Two tower cases 231 may be included. The first tower case 221 and the second tower case 231 may be referred to as upper cases disposed above the lower case 120 and having outlets 222 and 232 through which air is discharged, respectively.

The first outlet 222 may be formed to extend vertically in the first tower 220 , and the second outlet 232 may be formed to extend vertically in the second tower 230 .

The flow direction of the air discharged from the first tower 220 and the second tower 230 may be formed in the forward and backward directions.

The width of the blowing space (S), which is the distance between the first tower 220 and the second tower 230, may be formed equally in the vertical direction. However, the width of the upper end of the blowing space (S) may be formed narrower or wider than the width of the lower end.

By forming the width of the blowing space (S) constant along the vertical direction, it is possible to evenly distribute the air flowing in the forward direction of the blowing space (S) in the vertical direction.

When the width of the upper side is different from the width of the lower side, the flow rate of the wide side may be formed low, and deviation of the speed may occur based on the vertical direction. When a deviation in flow velocity of air occurs in the vertical direction, the supply amount of clean air may vary according to the position in the vertical direction where the air is discharged.

After the air discharged from each of the first discharge port 222 and the second discharge port 232 is joined in the blowing space S, it may be supplied to the user.

The air discharged from the first discharge port 222 and the air discharged from the second discharge port 232 do not individually flow to the user, but may be joined in the blowing space S and then supplied to the user.

The blowing space (S) may be used as a space in which discharge air is joined and mixed. Indirect airflow is formed in the air around the blower 1 by the discharge air discharged to the blowing space S, so that the air around the blower 1 can also flow toward the blowing space S.

Since the discharge air of the first discharge port 222 and the discharge air of the second discharge port 232 are joined in the blowing space S, the straightness of the discharge air can be improved. By combining the discharge air of the first discharge port 222 and the discharge air of the second discharge port 232 in the blowing space (S), the air around the first tower 220 and the second tower 230 is also generated by the indirect air flow. It may be induced to flow forward along the outer circumferential surface of the blowing module 200 .

The first tower case 221 includes a first tower top 221a forming the upper side of the first tower 220; a first tower front end 221b forming the front surface of the first tower 220; a first tower rear end 221c forming the rear surface of the first tower 220; a first outer wall 221d forming an outer circumferential surface of the first tower 220; And it may include a first inner wall (221e) forming the inner surface of the first tower (220).

The second tower case 231 includes a second tower top 231a forming the upper side of the second tower 230; a second tower front end 231b forming the front surface of the second tower 230; a second tower rear end 231c forming the rear surface of the second tower 230; a second outer wall 231d forming an outer circumferential surface of the second tower 230; And it may include a second inner wall (231e) forming the inner surface of the second tower (230).

The first outer wall 221d and the second outer wall 231d may be formed convexly outward in the radial direction to form outer circumferential surfaces of the first tower 220 and the second tower 230, respectively.

The first inner wall 221e and the second inner wall 231e may be formed convexly inward in the radial direction to form inner circumferential surfaces of the first tower 220 and the second tower 230, respectively.

The first discharge port 222 may be formed to extend vertically from the first inner wall 221e and be opened radially inward. The second outlet 232 may be formed to extend vertically from the second inner wall 231e and be opened radially inward.

The first discharge port 222 may be formed at a position closer to the rear end 221c of the first tower than to the front end 221b of the first tower. The second discharge port 232 may be formed at a position closer to the rear end 231c of the second tower than to the front end 231b of the second tower.

The first board slit 223 through which the first air current converter 401 to be described later passes may be formed extending vertically from the first inner wall 221e. The second board slit 233 through which the second air current converter 402 to be described later passes may be formed to extend vertically on the second inner wall 231e. The first board slit 223 and the second board slit 233 may be formed to open radially inward.

The first board slit 223 may be formed at a position closer to the first tower front end 221b than to the first tower rear end 221c. The second board slit 233 may be formed at a position closer to the front end 231b of the second tower than to the rear end 231c of the second tower. The first board slit 223 and the second board slit 233 may face each other.

Hereinafter, the internal structure of the blower 1 will be described with reference to FIGS. 2 and 3 . FIG. 2 is a cross-sectional perspective view of the blower 1 cut along the P-P' line shown in FIG. 1, and FIG. 3 is a cross-sectional perspective view of the blower 1 cut along the Q-Q' line shown in FIG. am.

Referring to FIG. 2 , a driving module 150 for rotating the blower 1 in a circumferential direction may be disposed above the base 110 . A driving space 100S in which the driving module 150 is disposed may be formed on the upper side of the base 110 .

The filter 130 may be disposed above the driving space 100S. The filter 130 may have a cylindrical shape, and a cylindrical filter hole 131 may be formed inside the filter 130 .

Air introduced through the suction hole 121 may pass through the filter 130 and flow into the filter hole 131 .

On the upper side of the filter 130, a suction grill 140 through which air flowing upward through the filter 130 passes may be disposed. The suction grill 140 may be disposed between the fan assembly 300 and the filter 130 . The suction grill 140 can prevent a user's hand from being put into the fan assembly 300 when the lower case 210 is removed and the filter 130 is separated from the blower 1 .

The fan assembly 300 may be disposed above the filter 130 and may generate a suction force for air outside the blower 1 .

By the driving of the fan assembly 300, the air outside the blower 1 can pass through the suction hole 121 and the filter hole 131 in order and flow to the first tower 220 and the second tower 230. there is.

A pressurized space 300s in which the fan assembly 300 is disposed may be formed between the filter 130 and the blowing module 200 .

A first distribution space 220s in which air passing through the pressurized space 300s flows upward may be formed inside the first tower 220, and a pressurized space 300s inside the second tower 230. A second distribution space 230s through which the air passing through flows upward may be formed. The tower base 210 may distribute air passing through the pressurized space 300s into the first distribution space 220s and the second distribution space 230s. The tower base 210 may be a channel connecting the first and second towers 220 and 230 and the fan assembly 300 .

The first distribution space 220s may be formed between the first outer wall 221d and the first inner wall 221e. The second distribution space 230s may be formed between the second outer wall 231d and the second inner wall 231e.

The first tower 220 may include a first flow guide 224 guiding a flow direction of air in the first distribution space 220s. A plurality of first flow guides 224 may be arranged so as to be vertically spaced apart from each other.

The first flow guide 224 may be formed to protrude from the first tower rear end 221c toward the first tower front end 221b. The first flow guide 224 may be spaced apart from the first tower front end 221b in front and rear directions. The first flow guide 224 may extend obliquely downward toward the front. The first guide front end 224a forming the front surface of the first flow guide 224 may be positioned lower than the first guide rear end 224b forming the rear surface of the first flow guide 224 . An angle at which each of the plurality of first flow guides 224 is inclined downward may be smaller as they are disposed on the upper side.

The second tower 230 may include a second flow guide 234 guiding a flow direction of air in the second distribution space 230s. A plurality of second flow guides 234 may be disposed so as to be vertically spaced apart from each other.

The second flow guide 234 may be formed to protrude from the second tower rear end 231c toward the second tower front end 231b. The second flow guide 234 may be spaced apart from the second tower front end 231b in front and rear directions. The second flow guide 234 may extend obliquely downward toward the front. The front end 234a of the second guide forming the front surface of the second flow guide 234 may be positioned lower than the rear end 234b of the second guide forming the rear surface of the second flow guide 234 . An angle at which each of the plurality of second flow guides 234 is inclined downward may be smaller as they are disposed on the upper side.

The first flow guide 224 may guide the air discharged from the fan assembly 300 to flow toward the first outlet 222 . The second flow guide 234 may guide the air discharged from the fan assembly 300 to flow toward the second outlet 232 .

Referring to FIG. 3 , the fan assembly 300 includes a fan motor 310 generating power; a motor housing 330 in which the fan motor 310 is accommodated; a fan 320 rotated by receiving power from the fan motor 310; and a diffuser 340 guiding a flow direction of air pressurized by the fan 320 .

The fan motor 310 may be disposed above the fan 320 and may be connected to the fan 320 through a motor shaft 311 extending downward from the fan motor 310 .

The motor housing 330 may include a first motor housing 331 covering an upper portion of the fan motor 310 and a second motor housing 332 covering a lower portion of the fan motor 310 .

The first outlet 222 may extend upward from one side 211a of the top surface 211 of the tower base. The lower end 222d of the first outlet may be formed on one side 211a of the upper surface 211 of the tower base.

The first outlet 222 may be spaced apart from the lower side of the first tower top 221a. The first discharge port upper end 222c may be formed to be spaced apart from the lower side of the first tower upper end 221a.

The first outlet 222 may extend obliquely in the vertical direction. The first discharge port 222 may be inclined toward the front as it goes upward. The first outlet 222 may extend obliquely backward with respect to the vertical shaft Z extending in the vertical direction.

The front end 222a of the first discharge port and the rear end 222b of the first discharge port may extend obliquely in a vertical direction or may extend parallel to each other. The front end 222a of the first discharge port and the rear end 222b of the first discharge port may extend obliquely backward with respect to the vertical axis Z extending in the vertical direction.

The first tower 220 may include a first discharge guide 225 guiding the air in the first distribution space 220s to the first discharge port 222 .

The first tower 220 may be symmetrical to the second tower 230 based on the blowing space S, and may have the same shape and structure as the second tower 230. The description of the above-described first tower 220 may be equally applied to the second tower 230 .

Hereinafter, the air discharge structure of the blower 1 for inducing the Coanda effect will be described with reference to FIGS. 4 and 5 . FIG. 4 shows a form in which the blower 1 is viewed from above in a positive and downward direction, and FIG. 5 shows a form in which the blower 1 is cut along the line R-R′ shown in FIG. 1 and viewed upward it did

Referring to FIG. 4 , the distances D0 , D1 , and D2 between the first inner wall 221e and the second inner wall 231e may decrease as they get closer to the center of the blowing space S.

The first inner wall 221e and the second inner wall 231e may be convexly formed toward the inside in the radial direction, and the shortest distance between the vertices of the first inner wall 221e and the second inner wall 231e ( D0) can be formed. The shortest distance D0 may be formed at the center of the blowing space S.

The first discharge port 222 may be formed behind the position at which the shortest distance D0 is formed. The second outlet 232 may be formed behind the position where the shortest distance D0 is formed.

The first tower front end 221b and the second tower front end 231b may be spaced apart by a first distance D1. The first tower rear end 221c and the second tower rear end 231c may be spaced apart by the second distance D2.

The first interval D1 and the second interval D2 may be the same. The first distance D1 may be greater than the shortest distance D0, and the second distance D2 may be greater than the shortest distance D0.

The distance between the first inner wall 221e and the second inner wall 231e can be reduced from the rear ends 221c and 231c to the position where the shortest distance D0 is formed, and the shortest distance D0 is formed. From the position to the front end (221b, 231b) can be large.

The first tower front end 221b and the second tower front end 231b may be inclined with respect to the front and rear axis X.

A tangent line drawn at each of the first tower front end 221b and the second tower front end 231b may have a predetermined inclination angle A with respect to the front and rear axis X.

Some of the air discharged forward through the blowing space (S) may flow with the inclination angle (A) with respect to the front and rear axis (X).

With the above structure, the diffusion angle of the air discharged forward through the blowing space S can be increased.

The first air current converter 401, which will be described later, may be inserted into the first board slit 223 when air is discharged forward through the blowing space S.

The second air flow converter 402, which will be described later, may be inserted into the second board slit 233 when air is discharged forward through the blowing space S.

Referring to FIG. 5 , air discharged toward the blowing space S may be guided in a flow direction by the first discharge guide 225 and the second discharge guide 235 .

The first discharge guide 225 may include a first inner guide 225a connected to the first inner wall 221e and a first outer guide 225b connected to the first outer wall 221d.

The first inner guide 225a may be integrally manufactured with the first inner wall 221e, but may also be manufactured as a separate part.

The first outer guide 225b may be manufactured integrally with the first outer wall 221d, but may also be manufactured as a separate part.

The first inner guide 225a may protrude from the first inner wall 221e toward the first distribution space 220s.

The first outer guide 225b may protrude from the first outer wall 221d toward the first distribution space 220s. The first outer guide 225b may be formed to be spaced apart from the outside of the first inner guide 225a, and the first discharge port 222 may be formed between the first inner guide 225a.

The radius of curvature of the first inner guide 225a may be smaller than that of the first outer guide 225b.

Air in the first distribution space 220s may flow between the first inner guide 225a and the first outer guide 225b and flow into the blowing space S through the first outlet 222 .

The second discharge guide 235 may include a second inner guide 235a connected to the second inner wall 231e and a second outer guide 235b connected to the second outer wall 231d.

The second inner guide 235a may be integrally manufactured with the second inner wall 231e, but may also be manufactured as a separate part.

The second outer guide 235b may be integrally manufactured with the second outer wall 231d, but may also be manufactured as a separate part.

The second inner guide 235a may protrude from the second inner wall 231e toward the second distribution space 230s.

The second outer guide 235b may protrude from the second outer wall 231d toward the second distribution space 230s. The second outer guide 235b may be formed to be spaced apart from the outside of the second inner guide 235a, and the second outlet 232 may be formed between the second inner guide 235a.

The radius of curvature of the second inner guide 235a may be smaller than the radius of curvature of the second outer guide 235b.

Air in the second distribution space 230s may flow between the second inner guide 235a and the second outer guide 235b and flow into the blowing space S through the second outlet 232 .

The widths w1 , w2 , and w3 of the first discharge port 222 may gradually decrease and then increase from the inlet to the outlet of the first discharge guide 225 .

An entrance width w1 of the first discharge guide 225 may be greater than an exit width w3 of the first discharge guide 225 .

The entrance width w1 may be defined as a distance between the outer end of the first inner guide 225a and the outer end of the first outer guide 225b. The outlet width w3 is defined as the distance between the first outlet front end 222a, which is the inner end of the first inner guide 225a, and the first outlet rear end 222b, which is the inner end of the first outer guide 225b. It can be.

The size of the inlet width w1 and the outlet width w3 may be greater than the size of the shortest width w2 of the first outlet 222 .

The shortest width w2 may be defined as the shortest distance between the rear end 222b of the first discharge port and the first inner guide 225a.

The width of the first discharge port 222 may gradually decrease from the entrance of the first discharge guide 225 to a position where the shortest width w2 is formed, and from the position where the shortest width w2 is formed, the first discharge guide ( 225) may gradually increase.

Like the first discharge guide 225, the second discharge guide 235 may also have a front end 232a of the second discharge port and a rear end 232b of the second discharge port, and have the same width as the first discharge guide 225. can have a distribution.

Hereinafter, wind direction switching by the air current converter 400 will be described with reference to FIGS. 6 to 8 . 6 shows a form in which the air flow converter 400 protrudes into the blowing space S so that the blower 1 forms an updraft, and FIGS. 7 and 8 explain the operating principle of the air flow converter 400 It is also

Referring to Figure 6, the air flow converter 400 may protrude toward the blowing space (S), it is possible to convert the flow of air discharged forward through the blowing space (S) into upward wind.

The air current converter 400 may include a first air current converter 401 disposed in the first tower case 221 and a second air current converter 402 disposed in the second tower case 231 .

The first air current converter 401 and the second air current converter 402 protrude toward the blowing space S from the first tower 220 and the second tower 230, respectively, and the front of the blowing space S can block

When the first air flow converter 401 and the second air flow converter 402 protrude and block the front of the blowing space S, the air discharged through the first outlet 222 and the second outlet 232 It is blocked by 400 and can flow upward (Z).

When the first air current converter 401 and the second air current converter 402 are drawn into the first tower 220 and the second tower 230 and open the front of the blowing space S, the first discharge port 222 And the air discharged through the second discharge port 232 may flow in the front (X) through the blowing space (S).

7 and 8, the air current converters 401 and 402 include a board 410 protruding toward the blowing space S, a motor 420 providing driving force to the board 410, and a board ( It may include a board guide 430 for guiding the moving direction of the 410, and a cover 440 for supporting the motor 410 and the board guide 430.

Hereinafter, the first air current converter 401 will be described as an example, but the description of the first air current converter 401 to be described below may be equally applied to the second air current converter 402.

As shown in FIGS. 4 and 5 , the board 410 may be inserted into the first board slit 223 . When the motor 420 is driven, the board 410 may protrude into the blowing space S through the first board slit 223 . The board 410 may have an arc shape in cross section. When the motor 420 is driven, the board 410 may move in a circumferential direction and protrude into the blowing space S.

The motor 420 may be connected to the pinion gear 421 to rotate the pinion gear 421 . The motor 420 may rotate the pinion gear 421 clockwise or counterclockwise.

The board guide 430 may have a plate shape extending vertically. The board guide 430 may include a guide slit 450 extending obliquely up and down, and a rack 431 formed to protrude toward the pinion gear 421 .

The rack 431 may mesh with the pinion gear 421 . When the motor 420 is driven and the pinion gear 421 rotates, the rack 431 meshed with the pinion gear 421 may move up and down.

The guide protrusion 411 formed on the board 410 to protrude toward the board guide 430 may be inserted into the guide slit 450 .

When the board guide 430 is moved up and down according to the vertical movement of the rack 431, the guide protrusion 411 may be moved by receiving force from the guide slit 450. As the board guide 430 moves up and down, the guide protrusion 411 may be moved in an oblique direction within the guide slit 450 .

When the rack 431 is moved upward, the guide protrusion 411 may be moved along the guide slit 450 and positioned at the lowest end of the guide slit 450 . When the guide protrusion 411 is positioned at the lowermost end of the guide slit 450, the board 410 may be completely hidden within the first tower 220 as shown in FIGS. 4 and 5. When the rack 431 moves upward, since the guide slit 450 also moves upward, the guide protrusion 411 can move along the guide slit 450 in the circumferential direction on the same horizontal plane.

When the rack 431 is moved downward, the guide protrusion 411 may be moved along the guide slit 450 and positioned at an upper end of the guide slit 450 . When the guide protrusion 411 is positioned at the top of the guide slit 450, the board 410 may protrude toward the blowing space S from the first tower 220 as shown in FIG. Since the guide slit 450 also moves downward when the rack 431 moves downward, the guide protrusion 411 can move along the guide slit 450 in the circumferential direction on the same horizontal plane.

The cover 440 includes a first cover 441 disposed outside the board guide 430; a second cover 442 disposed inside the board guide 430 and in close contact with the first inner surface 221e; a motor support plate 443 extending upward from the first cover 441 and connected to the motor 420; And it may include a stopper 444 for limiting the vertical movement of the board guide 430.

The first cover 441 may cover the outside of the board guide 430, and the second cover 442 may cover the inside of the board guide 430. The first cover 441 may separate the space where the board guide 430 is disposed from the first distribution space 220s. The second cover 442 may prevent the board guide 430 from contacting the first inner wall 221e.

The motor support plate 443 extends upward from the first cover 441 to support the load of the motor 420 .

The stopper 444 may be formed to protrude from the first cover 441 toward the board guide 430 . A locking protrusion (not shown) may be formed on one surface of the board guide 430 to be caught by the stopper 444 according to the vertical movement. When the board guide 430 moves up and down, the locking protrusion (not shown) is caught by the stopper 444, so that the up and down movement of the board guide 430 can be restricted.

Hereinafter, with reference to FIG. 9, an exploded structure of the air current converter 400 will be described. 9 shows the air flow converter 400 disassembled into a board 410, a board guide 430 and a cover 440.

A plurality of guide protrusions 411 and guide slits 450 may be formed to be spaced apart in the vertical direction.

The cover 440 may have a cover protrusion 445a protruding toward the board guide 430 . The cover protrusion 445a may be inserted into the cover protrusion groove 445b formed by opening the board guide 430 to limit vertical movement of the board guide 430 .

The cover protrusion groove 445b may be formed between the plurality of guide slits 450 and may have a longer length than the cover protrusion 445a.

A plurality of cover protrusions 445a and cover protrusion grooves 445b may be formed to be spaced apart in the vertical direction.

The guide slit 450 obliquely extending is a slit boundary forming a boundary between a bent portion 459 extending upward from one end portion 451 and the guide slit 450 on the upper side of the bent portion 459 ( 459a).

Hereinafter, the board guide 430 and the guide protrusion 411 according to an embodiment of the present invention will be described with reference to FIGS. 10(a) and 10(b). Figure 10 (a) shows a board guide 430 according to an embodiment of the present invention, Figure 10 (b) shows a guide protrusion 411 according to an embodiment of the present invention.

The board guide 430 may include a guide body 432 forming an outer shape of the board guide 430 . The guide body 432 may have a plate shape.

The guide slit 450 may be formed to be recessed in the guide body 432 . The guide slit 450 may be recessed into the guide body 432 in a first direction P, which will be described later.

The guide slit 450 may include one end 451 constituting the upper part of the guide slit 450 and the other end 452 constituting the lower part of the guide slit 450 .

The guide slit 450 includes a first guide surface 453 extending obliquely from one end 451 toward the other end 452, and extending obliquely from one end 451 toward the other end 452. A second guide surface 454 facing the first guide surface 453 may be included.

The guide slit 450 may extend in a vertical direction and in a second direction Q crossing the first direction P. The first guide surface 453 and the second guide surface 454 may extend along the second direction (Q).

The board guide 430 may include a guide side surface 432a closer to one end 451 than the other end 452 and the other side surface 432b closer to the other end 452 than the other end 451. can

One side of the guide 432a and the other side of the guide 432b may face each other and may extend in the vertical direction.

A first partition wall 433 may be formed between the one side surface 432a of the guide and the one end 451 . The first partition wall 433 may refer to a predetermined portion of the guide body 432 located between the one side surface 432a of the guide and the one end 451 . The first barrier rib 433 may extend vertically.

A second partition 434 may be formed between the guide other side surface 432b and the other end 452 . The second partition wall 434 may refer to a predetermined portion of the guide body 432 located between the guide other side surface 432b and the other end 452 . The second partition wall 434 may extend vertically.

The guide slit 450 has a first edge 451a that is most adjacent to one guide side surface 432a and in contact with the first partition wall 433, and a second partition wall that is located most adjacent to the other guide side surface 432b. A second edge 452a contacting 434 may be included.

Among the parts of the guide slit 450, the one end 451 may refer to a part located on the same horizontal plane (A-A' cut plane) as the first edge 451a.

Among the parts of the guide slit 450, the other end 452 may refer to a part located on the same horizontal plane (B-B' cut plane) as the second edge 452a.

The guide protrusion 411 may move in the second direction Q or in a direction opposite to the second direction Q within the guide slit 450 .

The guide protrusion 411 may move only between one end 451 and the other end 452 .

The guide protrusion 411 includes a first protrusion 411a positioned rearward in a first direction P, which will be described later, and a second protrusion 411a positioned forward of the first protrusion 411a in the first direction P. A protrusion 411b and a stepped portion 411c connecting the first protrusion 411a and the second protrusion 411b may be included.

The cross-sectional area of the guide protrusion 411 may increase along the first direction P. The cross-sectional area of the second protrusion 411b may be larger than that of the first protrusion 411a.

Hereinafter, one end 451 and the other end 452 of the guide slit 450 according to an embodiment of the present invention will be described with reference to FIGS. 11(a) and 11(b). Figure 11 (a) shows the shape of the board guide 430 cut along the A-A' line shown in Figure 10 (a), Figure 11 (b) is B-B shown in Figure 10 (a) It shows the shape of the board guide 430 cut with a 'leading'.

The cover 440 may include a lower cover 446 supporting a lower portion of the board guide 430 .

The first direction P is defined as a direction in which the board guide 430 intersects with the movement direction and the guide slit 450 is depressed. The first direction P may intersect with the vertical direction and may be perpendicular to the vertical direction.

The first direction P may be a direction in which the mold is removed when the board guide 430 is molded.

Referring to FIG. 11 (a) , one end portion 451 may have a shape corresponding to the guide protrusion 411 .

The first edge 451a includes a first support edge 451a1 formed at the rear in the first direction P and a first support edge 451a1 formed at the front in the first direction P. It may include a first extension edge 451a3 positioned outside and a first extension portion 451a2 connecting the first support edge 451a1 and the first extension edge 451a3.

Each of the first support edge 451a1 , the first extension edge 451a3 , and the first extension portion 451a2 may contact the first partition wall 433 .

Referring to FIG. 11 (b) , the other end 452 may have a shape corresponding to the guide protrusion 411 .

The second edge 452a includes a second support edge 452a1 formed at the rear in the first direction P and a second support edge 452a1 formed at the front in the first direction P and formed at a higher level than the second support edge 452a1. It may include a second extension edge 452a3 located outside and a second extension portion 452a2 connecting the second support edge 452a1 and the second extension edge 452a3.

Each of the second support edge 452a1 , the second extension edge 452a3 , and the second extension portion 452a2 may contact the second partition wall 434 .

Hereinafter, a relationship between one end portion 451 and the first barrier rib 433 according to an embodiment of the present invention will be described with reference to FIG. 12 . 12 is an enlarged view of one end 451 .

The first support edge 451a1 may be inclined toward the center of the board guide 430 in the first direction P. The first extension 451a2 may extend from the first support edge 451a1 toward the side surface 432a of the guide. The first extended edge 451a3 may be inclined toward the center of the board guide 430 toward the first direction P from the first extension portion 451a2.

A first vertex 451a4 may be formed on the first support edge 451a1, and a second vertex 451a5 may be formed on the first extended edge 451a3.

A first undercut region 433a may be formed between the first line B1 drawn along the first direction P from the first vertex 451a4 and the first supporting edge 451a1.

A second undercut region 433b may be formed between the second line B2 drawn along the first direction P from the second vertex 451a5 and the first extended edge 451a3.

The first undercut region 433a and the second undercut region 433b may be part of the first barrier rib 433 .

In the process of manufacturing the board guide 430, when trying to take out the mold in the first direction (P) after forming the guide body 432 by injecting slag into the mold, by the shape of the above-described one end portion 451 The mold may not come out of the one end 451 because it is blocked by the first undercut region 433a and the second undercut region 433b. Also, in the process of withdrawing the mold in the first direction (P), the first barrier rib 433 may be partially cut in the first undercut area 433a and the second undercut area 433b.

Since the description of the above-described one end 451 is equally or similarly applied to the other end 452, a detailed description thereof will be omitted.

Hereinafter, the board guide 530 and the guide protrusion 511 according to another embodiment of the present invention will be described with reference to FIGS. 13(a) and 13(b). Figure 13 (a) shows a board guide 530 according to another embodiment of the present invention, Figure 13 (b) shows a guide protrusion 511 according to another embodiment of the present invention.

The board guide 530 may include a guide body 532 forming an outer shape of the board guide 530 . The guide body 532 may have a plate shape.

The guide slit 550 may be formed to be recessed into the guide body 532 . The guide slit 550 may be recessed into the guide body 532 in the first direction P.

The guide slit 550 may include one end 551 constituting the upper part of the guide slit 550 and the other end 552 constituting the lower part of the guide slit 550 .

The guide slit 550 includes a first guide surface 553 extending obliquely from one end 551 toward the other end 552, and extending obliquely from one end 551 toward the other end 552. A second guide surface 554 facing the first guide surface 553 may be included.

The first guide surface 553 may include a first support portion 553a formed rearward in the first direction P and a first extension portion 553b formed forward.

The first support part 553a may protrude toward the center of the slit 550 more than the first extension part 553b.

The first support portion 553a may contact the first protrusion 511a of the guide protrusion 511 to support the first protrusion 511a.

The first extension 553b may come into contact with the second protrusion 511b of the guide protrusion 511 to support the second protrusion 511b.

The second guide surface 554 may include a second support portion 554a formed at the rear with respect to the first direction P, and a second extension portion 554b formed at the front.

The second support part 554a may protrude toward the center of the slit 550 more than the second extension part 554b.

The second support portion 554a may contact the first protrusion 511a of the guide protrusion 511 to support the first protrusion 511a.

The second extension 554b may contact the second protrusion 511b of the guide protrusion 511 to support the second protrusion 511b.

The guide slit 550 may have a bent portion 559 extending upward from one end portion 551 . The bent portion 559 may vertically extend upward from each of the first guide surface 553 and the second guide surface 554 . A slit boundary 559a, which is an upper boundary of the slit 550, may be formed on the upper side of the bent portion 559, and the shape of the slit boundary 559a may be a part of a circular shape.

The guide slit 550 may extend in a vertical direction and in a second direction Q crossing the first direction P. The first guide surface 553 and the second guide surface 554 may extend along the second direction (Q).

The board guide 530 may include a guide side surface 532a closer to one end 551 than the other end 552, and another guide side surface 532b closer to the other end 552 than the other end 551. can

One side of the guide 532a and the other side of the guide 532b may face each other and may extend in the vertical direction.

A first partition wall 533 may be formed between the one side surface 532a of the guide and the one end 551 . The first partition wall 533 may refer to a predetermined portion of the guide body 532 located between the one side surface 532a of the guide and the one end 551 . The first partition wall 533 may extend vertically.

A second partition 534 may be formed between the guide other side surface 532b and the other end 552 . The second partition 534 may refer to a predetermined portion of the guide body 532 located between the guide other side surface 532b and the other end 552 . The second partition wall 534 may extend vertically.

The guide slit 550 has a first edge 551a that is most adjacent to one guide side surface 532a and in contact with the first partition wall 533, and a second partition wall that is located most adjacent to the other guide side surface 532b. A second edge 552a contacting 534 may be included.

The first edge 551a may mean a predetermined portion of one end 551 farthest from the center line C of the board guide 530.

The second edge 552a may refer to a predetermined portion of the other end 552 farthest from the center line C of the board guide 530.

Among the parts of the guide slit 550, the one end 551 may refer to a part located on the same horizontal plane (A-A' cut plane) as the first edge 551a.

Among the parts of the guide slit 550, the other end 552 may refer to a part located on the same horizontal plane (B-B' cut plane) as the second edge 552a.

The guide protrusion 511 may move in the second direction Q or in a direction opposite to the second direction Q within the guide slit 550 .

The guide protrusion 511 may move only between one end 551 and the other end 552 .

The guide protrusion 511 includes a first protrusion 511a positioned rearward in the first direction P and a second protrusion positioned forward of the first protrusion 511a in the first direction P ( 511b) and a stepped portion 511c connecting the first protrusion 511a and the second protrusion 511b.

The cross-sectional area of the guide protrusion 511 may increase along the first direction P. A cross-sectional area of the second protrusion 511b may be larger than that of the first protrusion 511a.

Hereinafter, one end 551 and the other end 552 of the guide slit 550 according to another embodiment of the present invention will be described with reference to FIGS. 14(a) and 14(b). Figure 14 (a) shows the shape of the board guide 530 cut along the A-A' line shown in Figure 13 (a), Figure 14 (b) shows the B-B shown in Figure 13 (a) 'It shows the shape of the board guide 530 cut with a line.

The cover 540 may include a lower cover 546 supporting a lower portion of the board guide 530 .

The first direction P is defined as a direction in which the board guide 530 intersects with the movement direction and the guide slit 550 is depressed. The first direction P may intersect with the vertical direction and may be perpendicular to the vertical direction.

The first direction P may be a direction in which the mold is removed when the board guide 530 is molded.

Referring to FIG. 14( a ) , one end portion 551 may have a shape corresponding to the guide protrusion 511 .

The first edge 551a includes a first support edge 551a1 formed at the rear with respect to the first direction P and a first support edge 551a1 formed at the front with respect to the first direction P and formed higher than the first support edge 551a1. It may include a first extension edge 551a3 positioned outside and a first extension portion 551a2 connecting the first support edge 551a1 and the first extension edge 551a3.

Each of the first support edge 551a1 , the first extension edge 551a3 , and the first extension portion 551a2 may contact the first partition wall 533 .

The first edge 551a may be a part of the second guide surface 554 .

The first guide surface 553 and the second guide surface 554 may be inclined with respect to the first direction P.

An inclined angle θ3 of the first guide surface 553 with respect to the first direction P at one end 551 may be greater than an inclined angle of the second guide surface 554 .

The first guide surface 553 at one end 551 may be inclined so as to approach the central axis X of the board guide 530 in the first direction P. The central axis X may be an imaginary straight line parallel to the first direction P. The first guide surface 553 may have a third inclination angle θ3 with respect to the first direction P.

The second guide surface 554 at one end 551 may extend parallel to the first direction P. The first support edge 551a1 and the first extension edge 551a3 may extend parallel to the first direction P. The second guide surface 554 may have an inclination angle of 0 degrees with respect to the first direction P. However, the second guide surface 554 at one end 551 may be inclined to be farther away from the central axis X along the first direction P.

The first central line CL1 of one end 551 may be inclined toward the central axis X of the board guide 530 along the first direction P.

One end portion 551 may be formed to be inclined toward the central axis X with respect to the first direction P by a first inclination angle θ1. Accordingly, the first center line CL1 may form a first inclination angle θ1 between the first center line CL1 and the first direction P. The first inclination angle θ1 may be smaller than the third inclination angle θ3.

Referring to FIG. 14( b ), the other end 552 may have a shape corresponding to the guide protrusion 511 .

The second edge 552a includes a second support edge 552a1 formed rearward with respect to the first direction P and a second support edge 552a1 formed forward with respect to the first direction P and formed more than the second support edge 552a1. It may include a second extended edge 552a3 located outside and a second extension 552a2 connecting the second support edge 552a1 and the second extended edge 552a3.

Each of the second support edge 552a1 , the second extension edge 552a3 , and the second extension portion 552a2 may contact the second partition wall 534 .

The second edge 552a may be a part of the first guide surface 553 .

The first guide surface 553 and the second guide surface 554 may be inclined with respect to the first direction P.

An inclined angle θ4 of the second guide surface 554 with respect to the first direction P at the other end 552 may be greater than an inclined angle of the first guide surface 553 .

The second guide surface 554 at the other end 552 may be inclined so as to approach the central axis X of the board guide 530 in the first direction P. The central axis X may be an imaginary straight line parallel to the first direction P. The second guide surface 554 may have a fourth inclination angle θ4 with respect to the first direction P.

The first guide surface 553 at the other end 552 may extend parallel to the first direction P. The second support edge 552a1 and the second extension edge 552a3 may extend parallel to the first direction P. The first guide surface 553 may have an inclination angle of 0 degrees with respect to the first direction P. However, the first guide surface 553 at the other end 552 may be inclined to be farther away from the central axis X along the first direction P.

The second center line CL2 of the other end 552 may be inclined toward the central axis X of the board guide 530 along the first direction P.

The other end 552 may be inclined toward the central axis X with respect to the first direction P by a second inclination angle θ2. Accordingly, the second center line CL2 may form a second inclination angle θ2 between the second center line CL2 and the first direction P. The second inclination angle θ2 may be smaller than the fourth inclination angle θ4.

Hereinafter, a relationship between one end portion 551 and the first partition wall 533 according to another embodiment of the present invention will be described with reference to FIG. 15 . 15 is an enlarged view of one end portion 551.

The first support edge 551a1 may extend parallel to the first direction P, or may extend obliquely toward the side surface 532a of the guide along the first direction P. The first extension part 551a2 may extend from the first support edge 551a1 toward the side surface 532a of the guide. The first extension edge 551a3 may extend parallel to the first direction P from the first extension 551a2, or may extend obliquely toward the side surface 532a of the guide along the first direction P. there is.

A first vertex 551a4 and a third vertex 551a6 may be formed on the first support edge 551a1, and a second vertex 551a5 and a fourth vertex 551a7 may be formed on the first extended edge 551a3. It can be.

A line drawn from the first vertex 551a4 to the third vertex 551a6 may be parallel to the first direction P, and thus the first undercut region 433a as in the present embodiment is not formed. may not be

A line drawn from the second vertex 551a5 to the fourth vertex 551a7 may be parallel to the first direction P, and thus, the second undercut region 433b as in an embodiment of the present invention is not formed. may not be

The first partition wall 533 may contact the first support edge 551a1 and the first extension edge 551a3.

In the process of manufacturing the board guide 530, when trying to take out the mold in the first direction (P) after forming the guide body 532 by injecting slag into the mold, the shape of the one end 551 described above Unlike one embodiment of the present invention, the mold can easily come out of one end 551 . In addition, in the process of withdrawing the mold in the first direction P, the first barrier rib 533 may not be cut because it does not interfere with the mold.

Since the description of the above-described one end portion 551 is equally or similarly applied to the other end portion 552, a detailed description thereof will be omitted.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and in the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Various modifications and implementations are possible by those skilled in the art, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

100: intake module 120: lower case
200: blowing module 220: first tower
230: second tower 300: fan assembly
400: air flow converter 410: board
420: motor 430: board guide
440: cover 450: slit

Claims (12)

A lower case having a suction hole through which air is introduced;
a fan disposed inside the lower case;
a tower case disposed on the upper side of the lower case and having a discharge port extending vertically and a blowing space through which the air discharged from the discharge port flows forward; and
Including an air current converter disposed so as to be able to protrude toward the blowing space,
The airflow converter,
a motor that provides driving force;
a board extending in a vertical direction and protruding toward the blowing space by receiving driving force from the motor; and
A guide slit into which a guide protrusion protruding from the board is inserted is formed and includes a board guide connected to the motor and moving,
The guide slit,
It is depressed in a first direction intersecting the moving direction of the board guide and extends in a second direction intersecting the first direction to form one end and the other end,
The one end and the other end,
A blower extending outwardly of the guide slit along the first direction.
According to claim 1,
The board guide is moved in the vertical direction,
The first direction is a blower perpendicular to the moving direction of the board guide.
According to claim 1,
The second direction is
A blower inclined with respect to the moving direction of the board guide.
According to claim 1,
The guide slit,
a first guide surface extending from the one end toward the other end; and
A second guide surface extending from the one end toward the other end and spaced apart from the first guide surface,
The first guide surface and the second guide surface,
A blower inclined with respect to the first direction.
According to claim 4,
The inclined angle of the first guide surface with respect to the first direction at the one end is greater than the inclined angle of the second guide surface,
An inclined angle of the first guide surface with respect to the first direction at the other end is smaller than an inclined angle of the second guide surface.
According to claim 4,
The first guide surface,
A first support part formed in the rear with respect to the first direction and a first expansion part formed in the front,
The second guide surface,
A blower comprising a second support part formed at the rear with respect to the first direction and a second expansion part formed at the front.
According to claim 1,
The first center line of the one end is inclined toward the central axis of the board guide along the first direction,
The second center line of the other end is inclined toward the central axis of the board guide along the first direction.
According to claim 1,
The guide slit,
A blower having a bent portion extending upward from the one end.
According to claim 1,
The first part,
A first support edge formed rearward with respect to the first direction, and a first extension edge formed forwardly with respect to the first direction and positioned outside the first support edge,
The other end,
A blower comprising a second support edge formed at the rear with respect to the first direction and a second extended edge formed at the front with respect to the first direction and positioned outside the second support edge.
According to claim 1,
The board guide,
a first barrier rib formed outside the one end; and
And a second partition wall formed outside the other end,
The first barrier rib extends outward from the guide slit along the first direction at a position in contact with the one end,
The second partition wall extends outwardly of the guide slit along the first direction at a position in contact with the other end of the blower.
According to claim 1,
The guide protrusion,
A blower formed to have a wide cross-sectional area along the first direction.
According to claim 1,
The guide protrusion,
A blower having a stepped portion extending outward along the first direction.

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