阅读说明：本技术 送风机 (Air blower ) 是由 郑载赫 金起东 金厚辰 郑惠仁 崔硕浩 朴亨镐 金容民 崔致英 于 2021-05-13 设计创作，主要内容包括：提供一种送风机,其包括：第一塔,在其第一壁形成有第一吐出口；第二塔,其第二壁面向第一壁且与第一壁隔开,在第二壁形成有第二吐出口；风扇,配置在第一塔和第二塔的下侧,分别向第一塔和第二塔形成空气流动；第一引导板,配置成位于第一塔的内部或从第一壁凸出；第二引导板,配置成位于第二塔的内部或从第二壁凸出；第一引导马达,改变第一引导板的位置；以及第二引导马达,改变第二引导板的位置；在第一壁和第二壁之间形成有吹风间隙,从第一吐出口和第二吐出口吐出的空气在吹风间隙沿一个方向流动,第一引导板和第二引导板分别从第一吐出口和第二吐出口以隔开的方式配置在吹风间隙的前方,以改变从吹风间隙流动的空气的风向。(Provided is a blower, including: a first tower having a first discharge port formed in a first wall thereof; a second tower having a second wall facing and spaced apart from the first wall, the second wall being formed with a second discharge opening; a fan disposed under the first tower and the second tower, and configured to generate air flow to the first tower and the second tower, respectively; a first guide plate configured to be located inside the first tower or to protrude from the first wall; a second guide plate configured to be located inside the second tower or to protrude from the second wall; a first guide motor changing a position of the first guide plate; and a second guide motor changing a position of the second guide plate; a blowing gap is formed between the first wall and the second wall, air discharged from the first discharge port and the second discharge port flows in one direction through the blowing gap, and the first guide plate and the second guide plate are arranged in front of the blowing gap in a spaced manner from the first discharge port and the second discharge port, respectively, so as to change the wind direction of the air flowing from the blowing gap.)

1. A blower, comprising:

a first tower having a first discharge port formed in a first wall thereof;

a second tower having a second wall facing the first wall and spaced apart from the first wall, the second wall having a second discharge port formed therein;

a fan disposed under the first tower and the second tower, and configured to generate air flows to the first tower and the second tower, respectively;

a first guide plate configured to be located inside the first tower or to protrude from the first wall;

a second guide plate configured to be located inside the second tower or to protrude from the second wall;

a first guide motor that changes a position of the first guide plate; and

a second guide motor that changes a position of the second guide plate;

a blowing gap is formed between the first wall and the second wall, and air discharged from the first discharge port and the second discharge port flows in one direction in the blowing gap,

the first guide plate and the second guide plate are arranged in front of the air blowing gap so as to be spaced apart from the first discharge port and the second discharge port, respectively, so as to change the direction of the air flowing from the air blowing gap.

2. The blower according to claim 1, wherein,

the first guide motor positions the first guide plate inside the first tower or adjusts a length of the first guide plate protruding from the first wall,

the second guide motor positions the second guide plate inside the second tower or adjusts a length of the second guide plate protruding from the second wall.

3. The blower according to claim 1, wherein,

the first guide motor and the second guide motor operate independently of each other.

4. The blower according to claim 1, wherein,

the first wall and the second wall respectively form curved surfaces that are convex toward directions facing each other.

5. The blower according to claim 4, wherein,

the distance between the first wall and the second wall is a shortest distance between a portion where the first discharge port and the second discharge port are formed and a portion where the first guide plate and the second guide plate are arranged.

6. The blower according to claim 1, wherein,

the downstream end of the first wall and the downstream end of the second wall form an inclination angle in a direction away from an imaginary center line passing through centers of the first tower and the second tower, respectively.

7. The blower according to claim 1, wherein,

the first discharge port is open so that air discharged from the first discharge port flows along the first wall, and the second discharge port is open so that air discharged from the second discharge port flows along the second wall.

8. The blower according to claim 1, comprising:

a first plate guide disposed inside the first tower and guiding movement of the first guide plate; and

and a second plate guide disposed inside the second tower and guiding movement of the second guide plate.

9. The blower according to claim 8,

the first and second plate guides respectively include:

a fixed guide fixedly disposed inside the first tower or the second tower; and

a moving guide connected to the first guide plate or the second guide plate and movably disposed at the fixed guide,

a rack is disposed on one surface of each of the first guide plate and the second guide plate, and the rack is connected to the first guide motor or the second guide motor to move the first guide plate or the second guide plate,

the movement guides are disposed on the other surfaces of the first guide plate and the second guide plate, respectively.

10. The blower according to claim 1, wherein,

the first guide plate and the second guide plate are respectively disposed inside the first tower and the second tower in a horizontal airflow mode in which air is discharged to the front of the blowing gap.

11. The blower according to claim 1, wherein,

in an updraft mode in which air is discharged to an upper side of the blowing gap, an end of the first guide plate contacts an end of the second guide plate.

12. The blower according to claim 1, wherein,

in a biased airflow mode in which air discharged from the blowing gap forms a biased airflow, a length of the first guide plate protruding from the first wall is different from a length of the second guide plate protruding from the second wall.

13. The blower according to claim 12, wherein,

in the biased airflow mode, one of the first guide plate and the second guide plate protrudes toward the blowing gap, and the other does not protrude toward the blowing gap.

14. The blower according to claim 12, wherein,

operating the first guide motor and the second guide motor such that the first guide plate protrudes from the first wall or the second guide plate protrudes from the second wall in the biased airflow mode.

15. The blower according to claim 1, wherein,

the first guide plate and the second guide plate are alternately protruded in a moving mode in which a wind direction of air discharged from the blowing gap is continuously changed.

16. The blower according to claim 15, wherein,

in the case of the said mode of movement,

the second guide plate is arranged inside the second tower when the first guide plate protrudes from the first wall,

the first guide plate is arranged inside the first tower when the second guide plate protrudes from the second wall.

17. The blower according to claim 15, wherein,

in the case of the said mode of movement,

the second guide plate is disposed inside the second tower when the length of the first guide plate protruding from the first wall is changed,

the first guide plate is disposed inside the first tower when a length of the second guide plate protruding from the second wall is changed.

18. The blower according to claim 15, wherein,

in the case of the said mode of movement,

the interval between the first guide plate and the second guide plate is kept constant.

19. The blower according to claim 15, wherein,

in the case of the said mode of movement,

the length of the second guide plate protruding from the second wall is decreased as the length of the first guide plate protruding from the first wall is increased,

the length of the first guide plate protruding from the first wall decreases when the length of the second guide plate protruding from the second wall increases.

Technical Field

The present invention relates to a blower. In particular, the present invention relates to a blower capable of adjusting a blowing direction.

Background

The blower may circulate air in the indoor space or form an air flow toward a user by generating a flow of air. In recent years, studies have been made on an air discharge structure of a blower capable of providing a user with a comfortable feeling.

In this regard, korean patent nos. KR2011-0099318, KR2011-0100274, KR2019-0015325 and KR2019-0025443 disclose an air blowing device and a fan for blowing air using the coanda effect.

On the other hand, in order to adjust the blowing direction, the conventional blower needs to be provided with a plurality of motors that are individually driven or to move or rotate the blower. Therefore, it is difficult to efficiently adjust the blowing direction in stages, and there are problems of excessive power consumption.

Disclosure of Invention

The present invention is directed to solving the above problems and other problems.

It is another object of the present invention to provide a blower capable of selectively providing a horizontal flow or an ascending flow.

It is another object of the present invention to provide a blower for providing a deflected airflow in a forward direction.

It is also an object of the present invention to provide a blower that changes the area of discharged air without rotation of the entire body.

In order to achieve the above object, a blower of an embodiment of the present invention includes: a first tower having a first discharge port formed in a first wall thereof; a second tower having a second wall facing the first wall and spaced apart from the first wall, the second wall having a second discharge port formed therein; a fan disposed under the first tower and the second tower, and configured to generate air flows to the first tower and the second tower, respectively; a first guide plate configured to be located inside the first tower or to protrude from the first wall; a second guide plate configured to be located inside the second tower or to protrude from the second wall; a first guide motor that changes a position of the first guide plate; and a second guide motor changing a position of the second guide plate. A blowing gap is formed between the first wall and the second wall of the blower, air discharged from the first discharge port and the second discharge port flows in one direction through the blowing gap, and the first guide plate and the second guide plate are arranged in front of the blowing gap in a spaced manner from the first discharge port and the second discharge port, respectively, so as to change the wind direction of the air flowing through the blowing gap.

The first guide motor configures the first guide plate to be located inside the first tower or to adjust a length protruding from the first wall, and the second guide motor configures the second guide plate to be located inside the second tower or to adjust a length protruding from the second wall, whereby the lengths of the first guide plate and the second guide plate protruding to the direction of the blowing gap can be adjusted.

The first guide motor and the second guide motor are operated separately, whereby the length of the first guide plate and the second guide plate protruding to the blowing gap can be set differently.

The first wall and the second wall respectively form curved surfaces protruding toward directions facing each other, whereby air flowing in the blowing gap can flow along the first wall and the second wall.

The interval between the first wall and the second wall forms the shortest distance between the portion where the first discharge port and the second discharge port are formed and the portion where the first guide plate and the second guide plate are arranged, whereby the air flowing in the air blowing gap can flow along the first wall and the second wall.

The downstream end of the first wall and the downstream end of the second wall form an inclination angle in a direction away from an imaginary center line passing through centers of the first tower and the second tower, respectively, whereby the air discharged from the blowing gap can flow to a wider area.

The first discharge port is opened so that air discharged from the first discharge port flows along the first wall, and the second discharge port is opened so that air discharged from the second discharge port flows along the second wall, whereby air flowing in the blowing gap can flow along the first wall and the second wall.

The forced draught blower includes: a first plate guide disposed inside the first tower and guiding movement of the first guide plate; and a second plate guide disposed inside the second tower and guiding movement of the second guide plate. Whereby the first guide plate and the second guide plate can be stably moved.

The first and second plate guides respectively include: a fixed guide fixedly disposed inside the first tower or the second tower; and a moving guide connected to the first guide plate or the second guide plate and movably disposed at the fixed guide; a rack that is connected to the first guide motor or the second guide motor and moves the first guide plate or the second guide plate is disposed on one surface of the first guide plate or the second guide plate; the movement guide is disposed on the other surface of the first guide plate and the second guide plate. Thereby the position of the first guide plate and the second guide plate can be changed.

In the horizontal airflow mode in which the air is discharged forward of the blowing gap, the first guide plate and the second guide plate are respectively disposed inside the first tower and the second tower, so that the air flowing in the blowing gap can be discharged forward.

In an updraft mode in which air is discharged to an upper side of the blowing gap, an end of the first guide plate is in contact with an end of the second guide plate, whereby air flowing in the blowing gap can flow to the upper side.

In a biased airflow mode in which the air discharged from the blowing gap forms a biased airflow, a length of the first guide plate protruding from the first wall is different from a length of the second guide plate protruding from the second wall, whereby the air flowing in the blowing gap can flow biased to the front side.

In the biased airflow mode, one of the first guide plate and the second guide plate protrudes toward the blowing gap, and the other does not protrude toward the blowing gap, whereby air flowing in the blowing gap can flow biased toward the front side.

In the biased airflow mode, the first guide motor and the second guide motor are operated such that the first guide plate protrudes from the first wall or the second guide plate protrudes from the second wall, whereby air flowing in the blowing gap can flow biased toward the front side.

In a moving mode in which the wind direction of the air discharged from the blowing gap is continuously changed, the first guide plate and the second guide plate are alternately protruded, whereby the wind direction of the air flowing forward can be continuously changed.

In the moving mode, when the first guide plate protrudes from the first wall, the second guide plate is arranged inside the second tower, and when the second guide plate protrudes from the second wall, the first guide plate is arranged inside the first tower, whereby the wind direction of the air can be changed to a wide area toward the front.

In the moving mode, when the length of the first guide plate protruding from the first wall is changed, the second guide plate is disposed inside the second tower, and when the length of the second guide plate protruding from the second wall is changed, the first guide plate is disposed inside the first tower, whereby the wind direction of the air can be changed to a wide area in the forward direction.

In the moving mode, the interval between the first guide panel and the second guide panel is kept constant, whereby the wind direction of the air can be changed toward a concentrated area.

In the moving mode, when the length by which the first guide plate protrudes from the first wall increases, the length by which the second guide plate protrudes from the second wall decreases, and when the length by which the second guide plate protrudes from the second wall increases, the length by which the first guide plate protrudes from the first wall decreases, whereby the wind direction of the air can be changed toward a concentrated area.

Specifics with respect to other embodiments are contained in the detailed description and drawings.

The blower of the present invention has one or more of the following effects.

First, there is an advantage that the wind direction of the air discharged from the blower can be changed without rotating the blower itself.

Second, the air discharged from the blower forms an ascending air current in addition to a horizontal air current, thereby having an advantage of being able to form an air circulation of the indoor space.

Thirdly, there is an advantage that the wind direction of the air discharged from the blower can be deflected.

Fourth, there is an advantage that the wind direction of the air discharged from the blower can be continuously changed without rotating the blower itself.

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

Drawings

Fig. 1 is a perspective view of a blower according to a first embodiment of the present invention.

Fig. 2 is a diagram illustrating an operation of fig. 1.

Fig. 3 is a front view of fig. 1.

Fig. 4 is a top view of fig. 1.

Fig. 5 is a cross-sectional view taken along line v-v of fig. 3.

Fig. 6 is a cross-sectional view taken along line vi-vi of fig. 4.

Fig. 7 is a partially exploded perspective view illustrating the inside of the second tower of fig. 1.

Fig. 8 is a right side view of fig. 7.

FIG. 9 is a cross-sectional view taken along line IX-IX of FIG. 3.

FIG. 10 is a cross-sectional view taken along line X-X of FIG. 3.

FIG. 11 is a cross-sectional view taken along line XI-XI of FIG. 3.

Fig. 12 is a perspective view of the airflow converter shown in fig. 7.

Fig. 13 is a perspective view of the airflow converter viewed from the opposite side of fig. 12.

Fig. 14 is a top view of fig. 12.

Fig. 15 is a bottom view of fig. 12.

Fig. 16 is an explanatory view showing a horizontal airflow of the blower of the first embodiment of the invention.

Fig. 17 is an explanatory view showing an ascending air flow of the blower according to the first embodiment of the present invention.

Fig. 18 is an explanatory view showing a wide air flow of the blower of the first embodiment of the invention.

Fig. 19 is an explanatory view showing a biased airflow of the blower of the first embodiment of the present invention.

Fig. 20 is a graph showing the deflection airflow that varies according to the protrusion length.

Fig. 21 is an explanatory view showing a wide air flow of the blower of the first embodiment of the invention.

Fig. 22 (a) - (b) are exemplary diagrams showing the biased airflow of the blower of the first embodiment of the present invention.

Fig. 23 is a graph showing the deflection airflow that varies according to the protrusion length.

Fig. 24 is a graph showing the moving angle of the center point of the air flow which changes according to the protrusion length.

Fig. 25 (a) - (b) are explanatory views showing concentrated rotation of the blower of the first embodiment of the present invention.

Fig. 26 is a right sectional view of a blower according to a second embodiment of the present invention.

Fig. 27 is a graph showing the airflow speed that changes according to the angle of the air guide measured at 50cm in front.

Fig. 28 is a graph showing the airflow velocity that changes according to the angle of the air guide, measured at the upper side end.

Detailed Description

The advantages, features and methods of accomplishing the same will become more apparent from the following detailed description of the embodiments with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be embodied in various shapes different from each other, and the embodiments are provided only for the purpose of fully disclosing the present invention and fully disclosing the scope of the present invention to those skilled in the art, which is determined only by the scope of the appended claims. Like reference numerals denote like constituent elements throughout the specification.

The upper, lower, left, right, front and rear direction marks shown in fig. 1 to 11, 16 to 17, and 21 are for convenience of explanation and do not limit the scope of the present invention. Therefore, if the reference is changed, the direction may be set differently.

Referring to fig. 1 to 4, the blower 1 includes a casing 100 providing an outer shape. The case 100 may include: a base housing 150, the filter 200 being disposed in the base housing 150; and a tower housing 140 for ejecting air using the coanda effect.

The tower case 140 includes a first tower 110 and a second tower 120, and the first tower 110 and the second tower 120 are separately configured in two column shapes. First tower 110 is disposed on the left side, and second tower 120 is disposed on the right side.

The first tower 110 and the second tower 120 are disposed in a spaced apart relationship. A blowing gap 105 is formed between the first tower 110 and the second tower 120.

The blowing gap 105 is opened forward, rearward, and upward, and the upper end and the lower end of the blowing gap 105 have the same interval.

The tower housing 140 including the first tower, the second tower and the blowing gap is formed in a circular truncated cone shape.

The discharge ports 117, 127 disposed in the first tower 110 and the second tower 120, respectively, discharge air to the air blowing gap 105. The first tower 110 has a first discharge port 117, and the second tower 120 has a second discharge port 127.

The first discharge port 117 and the second discharge port 127 are formed in the first tower 110 and the second tower 120, respectively, at positions where the blowing gaps are formed. The air discharged through the first discharge port 117 or the second discharge port 127 can be discharged in a direction crossing the blowing gap 105.

The air discharge direction of the air discharged through the first tower 110 and the second tower 120 may be formed in the front-rear direction and the vertical direction.

Referring to fig. 2, the air discharge direction across the blowing gap 105 may include: a first air discharge direction S1 formed in the horizontal direction; and a second air discharge direction S2 formed in the up-down direction.

The air flowing in the first air ejection direction S1 may be defined as a horizontal air flow, and the air flowing in the second air ejection direction S2 may be defined as an ascending air flow.

The horizontal airflow is a case where the main flow direction of the air is the horizontal direction, and may indicate that the flow rate of the air flowing in the horizontal direction is more. Similarly, the updraft is a case where the main flow direction of air is the upper direction, and may indicate that the flow rate of air flowing in the upper direction is larger.

The upper end interval and the lower end interval of the blowing gap 105 may be the same. However, it is also possible that the interval of the upper ends of the blowing gaps 105 is narrower or wider than the interval of the lower ends of the blowing gaps 105, differently from the present embodiment.

By making the left-right width of the blowing gap 105 constant, the flow of air flowing in front of the blowing gap can be made relatively uniform.

For example, when the width of the upper side and the width of the lower side are different, the flow velocity formed on the wider side is low, and thus a velocity deviation may occur in the up-down direction. When the flow velocity of the air varies in the vertical direction, the distance that the discharged air reaches may vary.

The air discharged from the first discharge port and the second discharge port may flow after the air blowing gaps 105 are merged.

That is, the air discharged from the first discharge port 117 and the air discharged from the second discharge port 127 may be caused to flow forward or upward after merging in the blowing gap 105, without causing the air discharged from the first discharge port 117 and the air discharged from the second discharge port 127 to flow toward the user separately.

The blowing gap 105 can be used as a space for discharged air to merge and mix. Further, by the discharged air discharged to the blowing gap 105, the air behind the blowing gap can be made to flow also to the blowing gap.

The discharged air passing through the first discharge port 117 and the discharged air passing through the second discharge port 127 are merged at the blowing gap, and the straight-ahead traveling property of the discharged air can be improved. Further, by merging the air discharged from the first discharge port 117 and the air discharged from the second discharge port 127 at the blowing gap, the air around the first tower and the second tower can also flow indirectly in the air discharge direction.

Referring to fig. 2, the first air discharge direction S1 is a direction from the rear to the front, and the second air discharge direction S2 is a direction from the lower side to the upper side.

Referring to fig. 1, upper end 111 of first tower 110 and upper end 121 of second tower 120 are spaced apart in second air discharge direction S2. That is, the air discharged in the second air discharge direction S2 does not interfere with the casing of the blower 1.

Referring to fig. 1, in order to achieve first air discharge direction S1, front end 112 of first tower 110 is spaced apart from front end 122 of second tower 120, and rear end 113 of first tower 110 is also spaced apart from rear end 123 of second tower 120.

In the first tower 110 and the second tower 120, a face facing the blowing gap 105 is referred to as an inner side face, and a face not facing the blowing gap 105 is referred to as an outer side face.

Referring to fig. 4, the outer sidewall 114 of the first tower 110 and the outer sidewall 124 of the second tower 120 are arranged in opposite directions to each other. The inner sidewall 115 (or first wall) of the first tower 110 and the inner sidewall 125 (or second wall) of the second tower 120 are configured to face each other.

The first inner sidewall 115 is formed to protrude toward the second tower, and the second inner sidewall 125 is formed to protrude toward the first tower.

The first tower 110 and the second tower 120 are formed to be streamlined with respect to the flow direction of the air.

Specifically, the first inner sidewall 115 and the first outer sidewall 114 are formed to be streamlined with respect to the front-rear direction, and the second inner sidewall 125 and the second outer sidewall 124 are formed to be streamlined with respect to the front-rear direction.

Referring to fig. 4, the first discharge port 117 is disposed on the first inner wall 115, and the second discharge port 127 is disposed on the second inner wall 125.

The first and second inner side walls 115 and 125 are spaced apart by a shortest distance B0 at a central portion 115a of the first inner side wall 115 and a central portion 125a of the second inner side wall 125. The central portion 115a of the first inner sidewall 115 may be an area between the front end 112 and the rear end 113 of the first inner sidewall 115. Likewise, the central portion 125a of the second inner sidewall 125 may be an area between the front end 122 and the rear end 123 of the second inner sidewall 125. The first discharge port 117 and the second discharge port 127 are disposed at positions behind the center portion 115a of the first inner wall 115 and the center portion 125a of the second inner wall 125, respectively. That is, the first discharge port 117 is disposed between the central portion 115a and the rear end 113 of the first inner wall 115. The second discharge port 127 is disposed between the central portion 125a and the rear end 123 of the second inner wall 125.

The spacing between the front end 112 of the first tower 110 and the front end 122 of the second tower 120 is referred to as a first spacing B1. The spacing between the rear end 113 of the first tower 110 and the rear end 123 of the second tower 120 is referred to as a second spacing B2.

The first B1 and second B2 spacings are greater than the shortest distance B0. The first and second intervals B1 and B2 may have the same length as each other, or may be different from each other.

The closer the positions of the discharge ports 117, 127 are to the rear ends 113, 123, the easier it is to control the airflow by the coanda effect, which will be described later.

The inner sidewall 115 of the first tower 110 and the inner sidewall 125 of the second tower 120 may directly provide the coanda effect, while the outer sidewall 114 of the first tower 110 and the outer sidewall 124 of the second tower 120 may indirectly provide the coanda effect.

The inner side walls 115 and 125 direct the air discharged from the discharge ports 117 and 127 to the leading ends 112 and 122. That is, the inner side walls 115 and 125 can directly supply the air discharged from the discharge ports 117 and 127 as a horizontal air flow.

The outer side walls 114, 124 also indirectly generate an air flow due to the air flow in the blowing gap 105.

The outer side walls 114, 124 induce a coanda effect on the indirect air flow and direct the indirect air flow towards the front end 112, 122.

The left side of the blowing gap is closed by a first inner side wall 115 and the right side of the blowing gap is closed by a second inner side wall 125, but the upper side of the blowing gap 105 is open.

The later-described airflow converter may convert a horizontal airflow passing through the blowing gap into an ascending airflow, and the ascending airflow may flow toward the opened upper side of the blowing gap. The updraft can suppress the direct flow of the discharged air to the user and positively convect the indoor air.

Further, the width of the discharged air can be adjusted by the flow rate of the air merged in the blowing gap.

The vertical lengths of the first and second discharge ports 117, 127 are formed to be much longer than the horizontal widths B0, B1, B2 of the blowing gap, whereby the discharged air from the first discharge port and the discharged air from the second discharge port are guided to merge together in the blowing gap.

Referring to fig. 1 to 3, a casing 100 of a blower 1 includes: a base housing 150, the filter being detachably provided in the base housing 150; and a tower housing 140 disposed above the base housing 150 and supported by the base housing 150.

The tower housing 140 includes a first tower 110 and a second tower 120.

After the tower base 130 connecting the first tower 110 and the second tower 120 is disposed, the tower base 130 is assembled to the base housing 150. The tower base 130 may be integrally manufactured with the first tower 110 and the second tower 120.

Unlike the present embodiment, the first tower 110 and the second tower 120 may be directly assembled to the base housing 150 without using the tower base 130, and the first tower 110 and the second tower 120 may be integrally manufactured with the base housing 150.

The base case 150 forms a lower portion of the blower 1, and the tower case 140 forms an upper portion of the blower 1.

The blower 1 can suck in ambient air from the base casing 150 and discharge filtered air from the tower casing 140. The tower housing 140 may spit air at a higher position than the base housing 150.

The blower 1 may be a cylindrical shape whose diameter becomes smaller as it approaches the upper portion. The blower 1 may be in the shape of a cone or a Truncated cone as a whole.

Unlike the present embodiment, the blower 1 may be configured to include both of the towers. Unlike the present embodiment, the cross section may not be narrowed toward the upper side.

However, in the case where the cross section becomes narrower as it approaches the upper side as in the present embodiment, the center of gravity is low, and there is an advantage that the risk of falling over by an external force is reduced.

To facilitate assembly, the present embodiment may manufacture the base housing 150 and the tower housing 140 separately. Unlike the present embodiment, the base housing 150 and the tower housing 140 may be formed in one body. For example, the base housing and the tower housing may be assembled after the front housing and the rear housing are fabricated as one body.

The base housing 150 is formed such that its diameter becomes gradually smaller as it approaches the upper end. The tower housing 140 is also formed such that its diameter becomes gradually smaller as it approaches the upper end.

The outer sides of the base housing 150 and the tower housing 140 may be continuously formed. In particular, the lower end of the tower base 130 and the upper end of the base housing 150 are closely attached, and the outer side surface of the tower base 130 and the outer side surface of the base housing 150 may form a continuous surface.

To this end, the diameter of the lower end of the tower base 130 may be the same as or slightly smaller than the diameter of the upper end of the base housing 150.

The tower base 130 distributes the air supplied from the base housing 150 and provides the distributed air to the first and second towers 110 and 120.

The tower base 130 connects the first tower 110 and the second tower 120. The blowing gap 105 is disposed above the tower base 130.

The discharge ports 117 and 127 are disposed above the tower base 130, and the ascending air flow and the horizontal air flow are formed above the tower base 130.

To minimize friction with air, the upper side 131 of the tower base 130 is formed as a curved surface. In particular, the upper side is formed as a curved surface that is concave downward, and extends in the front-rear direction. Referring to fig. 2, one side 131a of the upper surface 131 is connected to the first inner sidewall 115, and the other side 131b of the upper surface 131 is connected to the second inner sidewall 125.

Referring to fig. 4, the first tower 110 and the second tower 120 are bilaterally symmetrical with respect to the center line L-L'. In particular, the first discharge port 117 and the second discharge port 127 are arranged symmetrically with respect to the center line L-L'.

The center line L-L' is an imaginary line passing through the centers of the first tower 110 and the second tower 120, and in the present embodiment, is arranged in the front-rear direction and is arranged to pass through the upper side 131.

Unlike the present embodiment, the first tower 110 and the second tower 120 may be formed in an asymmetric form. However, when the first tower 110 and the second tower 120 are symmetrically arranged with respect to the center line L-L', the control of the horizontal air flow and the ascending air flow is more facilitated.

The downstream end of the first inner sidewall 115 and the downstream end of the second inner sidewall 125 may form an inclination angle in a direction away from the center line L-L', respectively.

Referring to fig. 1, 5, or 6, the blower 1 includes: a filter 200 disposed inside the case 100; and a fan device 300 disposed inside the casing 100 and configured to flow air to the discharge ports 117, 127.

The filter 200 and the fan device 300 are disposed inside the base housing 150. The base housing 150 is formed in a circular truncated cone shape and is open at the upper side.

Referring to fig. 5, the base housing 150 includes: a base 151 disposed on the ground; the base housing 152 is coupled to an upper side of the base 151, and has a space formed therein and a suction port 155.

The base 151 may be circular in shape.

The base housing 152 is formed in a circular truncated cone shape with upper and lower sides opened. Referring to fig. 2, a portion of the side of the base housing 152 is formed as an opening. The portion of the opening of the base housing 152 is referred to as a filter insertion port 154.

Referring to fig. 2, the housing 100 further includes a cover 153 shielding the filter insertion port 154. The cover 153 may be detachably assembled to the base housing 152, and the filter 200 may be placed on or assembled to the cover 153.

The user can separate the cover 153 and draw the filter 200 out of the housing 100.

The suction port 155 may be formed in either one of the base housing 152 and the cover 153. The suction port 155 may be formed at both the base housing 152 and the cover 153, and sucks air in all directions at 360 degrees at the circumference of the case 100.

The suction port 155 may be formed in a hole shape, and the suction port 155 may be formed in various shapes.

The filter 200 is formed in a hollow cylindrical shape with a vertical direction formed therein. The outer side surface of the filter 200 may be disposed to face the suction port 155 formed in the base housing 152 or the cover 153.

The indoor air flows through the filter 200 from the outside to the inside, and foreign substances or harmful gas in the air can be removed in the process.

The fan device 300 is disposed above the filter 200. The fan apparatus 300 may flow the air passing through the filter 200 to the first tower 110 and the second tower 120.

Referring to fig. 5, the fan apparatus 300 includes: a fan motor 310; and a fan 320 rotated by the fan motor 310. The fan device 300 is disposed inside the base housing 150.

The fan motor 310 is disposed above the fan 320, and a motor shaft of the fan motor 310 is coupled to the fan 320 disposed below. A motor cover 330 for the fan motor 310 is disposed above the fan 320.

The motor housing 330 has a shape surrounding the entire fan motor 310. Since the motor cover 330 surrounds the entire fan motor 310, the flow resistance to the air flowing from the lower side to the upper side can be reduced.

Unlike the present embodiment, the motor cover 330 may be formed in a shape to surround only the lower portion of the fan motor 310.

The motor housing 330 includes a lower motor housing 332 and an upper motor housing 334. Either one of the lower motor cover 332 and the upper motor cover 334 is coupled to the housing 100.

The fan motor 310 may be surrounded by disposing the fan motor 310 on the upper side of the lower motor cover 332 and then covering the upper motor cover 334. The motor shaft of the fan motor 310 penetrates the lower motor cover 332 and is assembled to the fan 320 disposed on the lower side.

The fan 320 may include: a hub to which a shaft of a fan motor is coupled; a shroud disposed in spaced relation to the hub; and a plurality of blades connecting the hub and the shroud.

The air passing through the filter 200 is sucked into the shroud, and then pressurized by the rotating blades to flow. The hub is disposed above the blades, and the shroud is disposed below the blades. The hub may be formed in a BOWL (BOWL) shape recessed to the lower side, and a portion of the lower side of the lower motor cover 332 may be inserted into the hub.

The fan 320 uses a diagonal flow fan. The diagonal flow fan sucks air in along the axial center and discharges the air in the radial direction, and the discharged air may be inclined with respect to the axial direction.

Since the entire air flow flows from the lower side to the upper side, when the air is discharged in the radial direction like a general centrifugal fan, a large flow loss occurs due to the change of the flow direction.

Since the diagonal flow fan discharges air toward the radially upper side, the flow loss of air can be minimized.

Referring to fig. 5, a diffuser 340 may be further disposed above the fan 320. The diffuser 340 may guide the air flow induced by the fan 320 in an upper direction. The diffuser 340 may reduce a radial component in the air flow while reinforcing an air flow component in an upper direction.

The motor housing 330 is disposed between the diffuser 330 and the fan 320.

In order to minimize the vertical setting height of the motor housing, the lower end of the motor housing 330 is configured to be inserted into the fan 320. The lower end of the motor housing 330 may be configured to overlap the fan 320 in the up-down direction. In addition, the upper end of the motor housing 330 may be configured to be inserted into the diffuser 340. The upper end of the motor housing 330 may be configured to overlap the diffuser 340 in the up-down direction.

The lower end of the motor housing 330 is disposed higher than the lower end of the fan 320, and the upper end of the motor housing 330 is disposed lower than the upper end of the diffuser 340.

In order to optimize the installation position of the motor cover 330, the upper side of the motor cover 330 may be disposed inside the tower base 130, and the lower side of the motor cover 330 may be disposed inside the base housing 150. Unlike the present embodiment, the motor housing 330 may be disposed inside the tower base 130 or the base housing 150.

Referring to fig. 5, a suction grill 350 may be disposed inside the base housing 150. When the filter 200 is separated, the suction grill 350 blocks the user's fingers from entering the fan 320 side, thereby protecting the user and the fan 320.

Filter 200 is disposed below suction grill 350, and fan 320 is disposed above suction grill 350. The suction grill 350 is formed with a plurality of through holes formed in the up-down direction to allow air to flow.

Referring to fig. 5, a filter installation space 101, which is a space below the suction grill 350, is formed inside the case 100, and the filter 200 is disposed in the filter installation space 101. Referring to fig. 5, an air supply space 102 is formed inside the casing 100, and the air supply space 102 supplies air to flow between the suction grill 350 and the discharge ports 117 and 127. Referring to fig. 6, a discharge space 103 is formed inside the first tower 110 and the second tower 120, and air flows upward through the discharge space 103 and flows to the first discharge port 117 or the second discharge port 127. Here, the blowing space 102 may include a discharge space 103.

The indoor air flows into the filter installation space 101 through the intake port 155, and is then discharged from the discharge ports 117 and 127 through the blowing space 102 and the discharge space 103.

Referring to fig. 5 to 8, an air guide 160 for converting the flow direction of air into a horizontal direction is disposed in the discharge space 103. The air guide 160 may be provided in plural.

The air guide 160 converts air flowing from the lower side to the upper side into a horizontal direction. The air guide 160 may guide the air flowing upward in the direction in which the first discharge port 117 or the second discharge port 127 is formed.

The air guide 160 may include: a first air guide 161 disposed inside the first tower 110; and a second air guide 162 disposed inside the second tower 120.

Referring to fig. 6, the first air guide 161 may be combined with an inner sidewall and/or an outer sidewall of the first tower 110. A front side end 161a of the first air guide 161 may be disposed near the first ejection outlet 117, and a rear side end 161b of the first air guide 161 may be disposed spaced apart from a rear end of the first tower 110.

In order to guide the air flowing on the lower side to the first discharge port 117, the first air guide 161 is formed as a curved surface protruding from the lower side to the upper side, and is disposed such that the rear side end 161b is lower than the front side end 161 a.

Referring to fig. 6, at least a portion of the left side end 161c of the first air guide 161 may be abutted or coupled to the left side wall of the first tower 110. At least a portion of the right side end 161d of the first air guide 161 may be abutted or coupled to the right side wall of the first tower 110.

Therefore, the air moving upward along the discharge space 103 flows from the rear end to the front end of the first air guide 161.

The second air guide 162 is disposed to be bilaterally symmetrical to the first air guide 161.

Referring to fig. 6, the second air guide 162 may be combined with an inner sidewall and/or an outer sidewall of the second tower 110. Referring to fig. 8, a front side end 162a of the second air guide 162 is close to the second discharge port 127, and a rear side end 162b of the second air guide 162 is spaced apart from the rear end of the second tower 120.

In order to guide the air flowing on the lower side to the second discharge port 127, the second air guide 162 is formed in a curved surface protruding upward from the lower side, and the rear side end 162b is disposed lower than the front side end 162 a.

Referring to fig. 6, at least a portion of the left side end 162c of the second air guide 162 may be abutted or coupled to the left side wall of the second tower 120. At least a portion of the right side end 162d of the second air guide 162 may be abutted or bonded to the right side wall of the first tower 110.

Next, referring to fig. 5 or 8, the first discharge port 117 and the second discharge port 127 are arranged to extend long in the vertical direction.

The first discharge opening 117 is disposed between the front end 112 and the rear end 113 of the first tower 110. The first discharge opening 117 is disposed closer to the rear end 113 than the front end 112. The air discharged from the first discharge port 117 can flow along the first inner sidewall 115 due to the coanda effect. Air flowing along the first inner side wall 115 may flow toward the front end 112.

Referring to fig. 5, the first discharge port 117 includes: a first boundary 117a forming an air discharge side (front end in the present embodiment) edge; a second boundary 117b forming an edge on the opposite side (rear end in the present embodiment) from the air discharge; an upper boundary 117c forming an upper edge of the first discharge port 117; and a lower boundary 117d forming a lower edge of the first discharge opening 117.

Referring to fig. 5, the first boundary 117a and the second boundary 117b may be configured to be parallel to each other. The upper side boundary 117c and the lower side boundary 117d may be arranged parallel to each other.

Referring to fig. 5, the first boundary 117a and the second boundary 117b are arranged to be inclined with respect to the vertical direction V. In addition, the rear end 113 of the first tower 110 is also arranged inclined with respect to the vertical direction V.

The inclination a1 of the discharge opening 117 may be greater than the inclination a2 of the outer side of the tower. Referring to fig. 5, the inclination a1 of the first and second boundaries 117a and 117b may be 4 degrees, and the inclination a2 of the rear end 113 may be 3 degrees, with respect to the vertical direction V.

The second discharge port 127 may be formed to be bilaterally symmetrical to the first discharge port 117.

Referring to fig. 8, the second discharge port 127 includes: a first boundary 127a forming an air discharge side (front end in the present embodiment) edge; a second boundary 127b forming an edge on the opposite side (rear end in the present embodiment) from the air discharge; an upper boundary 127c forming an upper edge of the second discharge port 127; and a lower boundary 127d forming a lower edge of the second discharge opening 127.

Referring to fig. 9, the first discharge port 117 of the first tower 110 is disposed toward the second tower 120, and the second discharge port 127 of the second tower 120 is disposed toward the first tower 110.

The air discharged from the first discharge port 117 flows along the inner wall 115 of the first tower 110 due to the coanda effect. The air discharged from the second discharge port 127 flows along the inner wall 125 of the second tower 120 due to the coanda effect.

The blower 1 further includes a first discharge case 170 and a second discharge case 180.

Referring to fig. 9, the first discharge port 117 is formed in the first discharge casing 170. First spit housing 170 may be assembled to first tower 110. The second discharge port 127 is formed in the second discharge casing 180. The second discharge casing 180 may be assembled to the second tower 120.

The first spit housing 170 may be disposed to penetrate the inner sidewall 115 of the first tower 110. The second spit housing 180 may be provided to penetrate the inner sidewall 125 of the second tower 120.

The first discharge casing 170 having the first discharge opening 118 formed therein is disposed in the first column 110, and the second discharge casing 180 having the second discharge opening 128 formed therein is disposed in the second column 120.

Referring to fig. 9, the first discharge casing 170 includes: a first discharge guide 172 that forms the first discharge port 117 and is disposed on the air discharge side of the first discharge port 117; and a second discharge guide 174 forming the first discharge port 117 and disposed on the opposite side of the first discharge port 117 from the air discharge.

Referring to fig. 10, outer side faces 172a, 174a of first and second discharge guides 172, 174 provide a portion of inner side wall 115 of first tower 110.

The inner side of the first discharge guide 172 is disposed toward the first discharge space 103a, and the outer side of the first discharge guide 172 is disposed toward the air blowing gap 105. The inner side of the second discharge guide 174 is disposed toward the first discharge space 103a, and the outer side of the second discharge guide 174 is disposed toward the air blowing gap 105.

The outer side surface 172a of the first ejection guide 172 may be formed in a curved surface. The outer side surface 172a of the first discharge guide 172 may provide a surface continuous with the first inner side wall 115. The outer surface 172a of the first discharge guide 172 may be formed as a curved surface continuous with the outer surface of the first inner sidewall 115.

The outer side surface 174a of the second ejection guide 174 may provide a surface continuous with the first inner side wall 115. The inner surface 174b of the second ejection guide 174 may be formed in a curved surface. The inner surface 174b of the second discharge guide 174 is formed into a curved surface continuous with the inner surface of the first outer wall 115, and thus the air in the first discharge space 103a can be guided to the first discharge guide 172.

A first discharge port 117 is formed between the first discharge guide 172 and the second discharge guide 174, and the air in the first discharge space 103a is discharged to the air blowing gap 105 through the first discharge port 117.

The air in the first discharge space 103a is discharged from between the outer surface 172a of the first discharge guide 172 and the inner surface 174b of the second discharge guide 174. A discharge passage 175 through which air is discharged is formed between the outer surface 172a of the first discharge guide 172 and the inner surface 174b of the second discharge guide 174.

The discharge passage 175 is formed such that the width of the intermediate portion 175b is narrower than the width of the inlet 175a and the outlet 175 c. The middle portion 175b may be defined as a portion where the second boundary 117b and the outer side surface 172a of the first ejection guide 172 form the shortest distance.

Referring to fig. 10, the cross section from the inlet of the spouting passage 175 to the intermediate portion 175b may be gradually narrowed, and the cross section from the intermediate portion 175b to the outlet 175c may be widened again. The middle portion 175b is located inside the first tower 110. The outlet 175c of the discharge passage 175 may be regarded as the discharge port 117 when viewed from the outside.

In order to induce the coanda effect, the inner side surface 174b of the second discharge guide 174 may be formed to have a larger radius of curvature than the outer side surface 172a of the first discharge guide 172.

The center of curvature of the outer surface 172a of the first discharge guide 172 may be located forward of the outer surface 172a, and may be formed inside the first discharge space 103 a. The center of curvature of the inner surface 174b of the second discharge guide 174 may be located on the first discharge guide 172 side and formed inside the first discharge space 103 a.

Referring to fig. 10, the second discharge housing 180 includes: a first discharge guide 182 forming a second discharge port 127 and disposed on the air discharge side of the second discharge port 127; and a second discharge guide 184 forming the second discharge port 127 and disposed on the opposite side of the second discharge port 127 from the air discharge.

A discharge channel 185 is formed between the first discharge guide 182 and the second discharge guide 184.

Since the second discharge casing 180 is bilaterally symmetrical to the first discharge casing 170, detailed description of the second discharge casing 180 will be omitted.

On the other hand, the width of the air flow based on the coanda effect will be described in detail with reference to fig. 4, 9, 10, and 18.

Referring to fig. 4, the air discharged from the first discharge port 117 may flow along the first inner surface 115 toward the first tip 112, and the air discharged from the second discharge port 127 may flow along the second inner surface 125 toward the second tip 122.

The shortest distance B0 between the first inner wall 115 and the second inner wall 125 can be determined so that the discharged air is discharged forward intensively by the coanda effect.

The larger the shortest distance B0, the weaker the coanda effect, but a wider blowing gap 105 can be ensured; the smaller the shortest distance B0, the stronger the coanda effect, but the narrower the blowing gap 105.

The shortest distance B0 may be 20mm to 30mm, in which case an airflow width (left-right width) of 1.2m may be ensured at a distance of 1.5m forward from the front ends 112, 122.

In addition, the discharge angle a of the first and second inner sidewalls 115 and 125 may be designed to limit the left and right diffusion range of the discharged air.

Referring to FIG. 4, the spit angle A may be defined as the angle between the centerline L-L' of the first tower 110 and the second tower 120 and the tangent formed at the front ends 112, 122 of the inner sidewalls 115, 125.

Referring to fig. 18, it can be confirmed that: the airflow width was 1.1m when the discharge angle a was 11.5 degrees, 1.2m when the discharge angle a was 18.5 degrees, and 1.22m when the discharge angle a was 25.5 degrees.

That is, it was confirmed that the smaller the discharge angle a, the narrower the air flow width (left-right direction) of the discharged air, and the larger the discharge angle a, the wider the air flow width of the discharged air.

The discharge angle a may be set to 11.5 to 30 degrees. When the discharge angle a is less than 11.5 degrees, the airflow width of the discharged air can be very narrow, and when the discharge angle a exceeds 30 degrees, it is difficult to form an airflow concentrated in the discharge region.

On the other hand, the blower 1 may further include an air flow converter 400(air flow converter) that changes the air flow direction of the blowing gap 105.

Next, an airflow converter 400 capable of forming an updraft will be described with reference to fig. 7 and 11 to 15.

The airflow converter 400 may convert the horizontal airflow flowing through the blowing gap 105 into the updraft airflow.

Referring to fig. 11, the airflow converter 400 includes: a first air flow converter 401 disposed in the first tower 110; and a second gas flow converter 402 disposed in second tower 120. The first airflow converter 401 and the second airflow converter 402 may be left-right symmetrical, and their configurations may be the same.

The airflow converter 400 includes: a guide plate 410(guide board) disposed on the tower and protruding toward the blowing gap 105; a guide motor 420 providing a driving force for guiding the movement of the plate 410; and a power transmission member 430 supplying a driving force of the guide motor 420 to the guide panel 410; and a plate guide 440 disposed inside the tower to guide the movement of the guide plate 410.

The guiding plate 410 may be hidden inside the tower or protrude towards the blowing gap 105.

The air flowing through the blowing gap 105 flows from the first discharge port 117 or the second discharge port 127 to the front of the blowing gap 105. That is, with the air blowing gap 105 as a reference, the portion where the first discharge opening 117 and the second discharge opening 127 are arranged may be set upstream of the air blowing gap 105, and the portion where the first guide plate 411 and the second guide plate 412 are arranged may be set downstream of the air blowing gap 105. Referring to fig. 11, the guide panel 410 includes: a first guide plate 411 disposed on the first tower 110; and a second guide plate 412 disposed at the second tower 120.

The first guide plate 411 is disposed inside the first tower 110, and may selectively protrude toward the blowing gap 105. The second guide plate 412 is disposed inside the second tower 120, and may selectively protrude toward the blowing gap 105.

A first plate slit 119 is formed in the inner wall 115 of the first tower 110, and a second plate slit 129 is formed in the inner wall 125 of the second tower 120.

The first plate slit 119 and the second plate slit 129 are arranged to be bilaterally symmetrical. The first plate slit 119 and the second plate slit 129 are formed to extend long in the vertical direction. The first plate slit 119 and the second plate slit 129 may be configured to be inclined with respect to the vertical direction V.

An inner end 411a of the first guide plate 411 may be exposed from the first plate slit 119, and an inner end 412a of the second guide plate 412 may be exposed from the second plate slit 129.

When the first guide plate 411 is disposed inside the first tower 110, it may be configured that an inside end 411a of the first guide plate 411 does not protrude from the inner sidewall 115. When the second guide plate 412 is disposed inside the second tower 120, it may be configured that an inside end 412a of the second guide plate 412 does not protrude from the inner sidewall 115.

The first plate slit 119 and the second plate slit 129 may be disposed to be more inclined than the front end 112 of the first tower 110 or the front end 122 of the second tower 120, respectively, with reference to the vertical direction.

For example, the front end 112 of the first tower 110 may be formed at an inclination of 3 degrees, and the first plate slit 119 may be formed at an inclination of 4 degrees. Likewise, the front end 122 of the second tower 120 may be formed with an inclination of 3 degrees, and the second plate slit 129 may be formed with an inclination of 4 degrees.

The first guide plate 411 is disposed parallel to the first plate slit 119, and the second guide plate 412 is disposed parallel to the second plate slit 129.

The guide panel 410 may be formed in a panel shape of a plane or a curved surface. The guide plate 410 may be formed to extend long in the vertical direction, and may be disposed in front of the blowing gap 105.

The guide plate 410 switches the direction to the upper side by crossing the horizontal air flow flowing to the air blowing gap 105.

The updraft may be formed by contacting or approaching the inner side end 411a of the first guide plate 411 and the inner side end 412a of the second guide plate 412. Unlike the present embodiment, one guide plate 410 may be closely attached to the tower on the opposite side to form the ascending air current.

As shown in fig. 16, when the blower 1 forms a horizontal air flow, the inner side end 411a of the first guide plate 411 may close the first plate slit 119, and the inner side end 412a of the second guide plate 412 may close the second plate slit 129.

As shown in fig. 17, when the blower 1 forms an updraft, an inner end 411a of the first guide plate 411 may penetrate the first plate slit 119 and protrude toward the air blowing gap 105, and an inner end 412a of the second guide plate 412 may penetrate the second plate slit 129 and protrude toward the air blowing gap 105.

The first guide plate 411 closes the first plate slit 119, and thus air in the first discharge space 103a can be prevented from leaking from the first plate slit 119. The second guide plate 412 closes the second plate slit 129, and thus air in the second discharge space 103b can be prevented from leaking from the second plate slit 129.

The first guide plate 411 and the second guide plate 412 protrude toward the blowing gap 105 by the rotating action. Unlike the present embodiment, at least one of the first guide plate 411 and the second guide plate 412 may be linearly moved in a sliding manner to protrude toward the blowing gap 105.

When referring to fig. 11, the first guide plate 411 and the second guide plate 412 are formed in an arc shape. The first guide plate 411 and the second guide plate 412 form a prescribed radius of curvature, and the center of curvature may be located at the blowing gap 105.

The guide panel 410 may be formed of a transparent material. Referring to fig. 14, a light emitting part 450 such as an LED may be configured at the guide panel 410, and the entire guide panel 410 is emitted with light generated by the light emitting part 450. The light emitting member 450 may be disposed in the discharge space 103 inside the tower and may be disposed at the outer end 412b of the guide plate 410.

The light emitting part 450 may be disposed in plural along the longitudinal direction of the guide plate 410.

Referring to fig. 11, the guide motor 420 includes: a first guide motor 421 that provides a rotational force to the first guide plate 411; and a second guide motor 422 providing a rotational force to the second guide plate 412.

Referring to fig. 13, the second guide motor 422 may include: an upper second guide motor 422a disposed above the second guide plate 412; and a lower second guide motor 422b disposed below the second guide plate 412.

Likewise, the first guide motor 421 may include an upper first guide motor 421 and a lower first guide motor 421.

The rotation shafts of the first guide motor 421 and the second guide motor 422 are arranged in the vertical direction, and a rack-and-pinion structure is used to transmit the driving force.

Referring to fig. 14, power transmission member 430 includes: a drive gear 431 coupled to a motor shaft of the guide motor 420; and a rack 432 coupled to the guide panel 410.

The driving gear 431 uses a pinion gear and rotates in a horizontal direction.

Referring to fig. 14, a rack 432 is combined with the inner side surface of the guide plate 410. The rack 432 may be formed in a shape corresponding to the guide panel 410. The rack 432 is formed in an arc shape. The teeth of rack 432 are configured to face the inner side wall of the tower.

The rack 432 is disposed in the discharge space 103 and can perform a revolving motion together with the guide plate 410.

Next, referring to fig. 12 to 15, the plate guide 440 will be explained. The plate guide 440 shown in fig. 12 to 15 may be applied to the plate guide 440 disposed at the second tower 120 or equally to the plate guide disposed at the first tower 110. The plate guide 440 illustrated in fig. 12 to 15 may be divided into a first plate guide disposed at the first tower 110 and a second plate guide disposed at the second tower 120. In addition, the structure of the plate guide 440 described below may be referred to as "first" when disposed on the first tower 110, and may be referred to as "second" when disposed on the second tower 120.

The plate guide 440 may guide the swiveling motion of the guide plate 410. The plate guide 440 may support the guide plate 410 while guiding the plate 410 to perform a swiveling motion.

Referring to fig. 14, the plate guide 440 is disposed on the opposite side of the rack 432 with respect to the guide plate 410. The plate guide 440 may support a force applied from the rack 432. Unlike the present embodiment, it is also possible to form a groove corresponding to the turning radius of the guide plate in the plate guide 440 and move the guide plate along the groove.

The plate guide 440 may be assembled to the outer sidewalls 114, 124 of the tower. The plate guide 440 may be disposed radially outward of the guide plate 410, thereby minimizing contact with air flowing through the discharge space 103.

Referring to fig. 14, the plate guide 440 includes a moving guide 442, a fixed guide 444, and a friction reducing member 446.

The moving guide 442 may be combined with a structure that moves together with the guide plate. The moving guide 442 may be combined with the rack 432 or the guide panel 410 and may rotate together with the rack 432 or the guide panel 410.

Referring to fig. 14, the movement guide 442 is disposed on the outer side surface 410b of the guide plate 410.

The moving guide 442 is formed in an arc shape and may have the same center of curvature as the guide plate 410.

The length of the moving guide 442 is less than the length of the guide plate 410.

The moving guide 442 is disposed between the guide plate 410 and the fixed guide 444. The radius of the moving guide 442 is greater than that of the guide plate 410 and less than that of the fixed guide 444.

The movement of the moving guide 442 may be restricted by contact with the fixed guide 444.

The fixed guide 444 is disposed radially outward of the moving guide 442, and can support the moving guide 442.

A guide groove 445 is formed in the fixed guide 444, and the moving guide 442 is disposed in the guide groove 445. The guide groove 445 may be formed corresponding to the radius of rotation and curvature of the movement guide 442.

The guide groove 445 is formed in an arc shape, and at least a portion of the movement guide 442 is inserted into the guide groove 445. The guide groove 445 is formed to be recessed toward a lower side.

The moving guide 442 may move along the guide groove 445.

The front side end 445a of the guide groove 445 may restrict movement of the movement guide 442 in one side direction (a direction protruding toward the blowing gap). The rear side end 445b of the guide groove 445 may restrict movement of the other side direction of the movement guide 442 (the direction for housing into the tower).

The friction reducing member 446 may reduce friction of the moving guide 442 and the fixed guide 444. The friction reducing member 446 may use a roller. The friction reducing member 446 provides rolling friction between the moving guide 442 and the fixed guide 444. The axis of the roller may be formed in the up-down direction. The friction reducing member 446 is combined with the moving guide 442.

By the friction reducing member 446, friction and running noise can be reduced. At least a portion of the friction reducing member 446 may be configured to protrude further radially outward than the moving guide 442.

The friction reducing member 446 may be formed of an elastic material and elastically supported by the fixing guide 444 in a radial direction.

The friction reducing member 446 may be in contact with the front side end 445a or the rear side end 445b of the guide groove 445.

The blower 1 may further include a motor mounting part 460 that supports the guide motor 420 and serves to fix the guide motor 420 to the tower.

Referring to fig. 13, the motor mounting part 460 is disposed at a lower portion of the guide motor 420 and supports the guide motor 420. The guide motor 420 is assembled to the motor mounting part 460.

The motor mount 460 may be coupled to the tower inner side walls 115, 125. The motor mounting portion 460 may be integrally formed with the inner side walls 115, 125.

Next, the position of the blower 1 and the flow of air in the horizontal flow and the ascending flow will be described with reference to fig. 16 to 17.

Referring to fig. 16, when a horizontal air flow is provided, the first guide plate 411 is hidden inside the first tower 110, and the second guide plate 412 is hidden inside the second tower 120.

The air discharged from the first discharge port 117 and the air discharged from the second discharge port 127 can merge in the blowing gap 120 and flow forward through the leading ends 112 and 122.

The air behind the blowing gap 105 may be introduced to the inside of the blowing gap 105 and then flow forward.

In addition, air around the first tower 110 may flow forward along the first outer sidewall 114, and air around the second tower 120 may flow forward along the second outer sidewall 124.

Since the first and second discharge ports 117, 127 are arranged to be long in the vertical direction and symmetrical to each other, the air flowing above and below the first and second discharge ports 117, 127 can be formed relatively uniformly.

Further, since the air discharged from the first discharge port and the second discharge port are merged at the blowing gap, the straight-ahead movement of the discharged air can be improved, and the air can be made to flow to a distant position.

Referring to fig. 17, when the updraft is supplied, the first guide plate 411 and the second guide plate 412 protrude toward the blowing gap 105, closing the front of the blowing gap 105.

At this time, the inner side end 411a of the first guide plate 411 and the inner side end 412a of the second guide plate 412 may be closely attached to each other or slightly spaced apart.

As the front of the air blowing gap 105 is closed by the first guide plate 411 and the second guide plate 412, the air discharged from the discharge ports 117, 127 rises along the back surfaces of the first guide plate 411 and the second guide plate 412, and is discharged from the upper portion of the air blowing gap 105.

By forming the ascending air flow in the blower 1, the discharged air can be prevented from flowing directly to the user. In order to circulate the indoor air, the blower 1 may be operated with an updraft.

For example, when an air conditioner and a blower are used together, convection of indoor air can be promoted by operating the blower 1 with an ascending airflow, and the indoor air can be cooled or heated more quickly.

On the other hand, referring to fig. 4, 11, 19, or 20, the concentrated airflow by the airflow converter 400 will be described in more detail.

The air discharged forward with the guide plate hidden is referred to as a wide air flow, and the air concentrated toward the center line L-L' with respect to the wide air flow is referred to as a concentrated air flow.

The concentrated airflow is an airflow for concentrating the discharged air toward the center line L-L' side by the coanda effect and increasing the straight-ahead distance.

In the case where the guide plate 410 protrudes toward the blowing gap 105 side through the inner side walls 115 and 125, the guide plate 410 can concentrate the air diffused in the left-right direction toward the center line L-L'.

In order to form an effective concentrated air flow, it is necessary to determine the positions of the first plate slits 119 and the second plate slits 129 and the protrusion angle B of the guide plate 410.

Referring to fig. 11, the protrusion angle B may be an angle between the outer side surface 410B of the guide plate 410 and the center line L-L'. Since the guide plate 410 is formed in a curved surface, the projection angle B may also be defined as an angle between a tangent line of a portion of the guide plate 410 passing through the plate slits 119, 129 and the center line L-L'.

Referring to fig. 11, the distance from the front ends 112 and 122 of the guide plate 410 to the plate slits 119 and 129 is set to D.

The separation length D from the front ends 112, 122 of the guide plates 410 to the plate slits 119, 129 may be 5mm to 10 mm. Specifically, the separation length D may be a length between the inner side surface 410a of the guide plate 410, which is in direct contact with the discharged air, and the leading ends 112 and 122. And the projection angle B may be 0 to 60 degrees.

Fig. 19 is a graph of concentrated airflow that varies according to the protrusion angle and the separation length, and fig. 20 is a graph of maximum airflow velocity that varies according to the protrusion angle and the separation length.

Referring to fig. 19, it was confirmed that when the protrusion angle B was changed from 60 degrees to 0 degrees under the condition that the separation length D was identically set to 10mm, the maximum wind speed was increased and then decreased. That is, it was confirmed that the maximum wind speed increased to 2.3m/s when the protrusion angle B was decreased from 60 degrees to 20 degrees. In addition, the maximum wind speed decreases from 2.3m/s to 1.7m/s when the protrusion angle B decreases from 20 degrees to 0 degrees.

In addition, it was confirmed that when the separation length D was changed from 10mm to 5mm under the condition that the projection angle B was identically set to 60 degrees, the maximum wind speed was increased from 1.5m/s to 2.4 m/s.

Referring to fig. 19 and 20, it can be confirmed that the maximum velocity of the air flow becomes smaller as the separation length D becomes larger. It is confirmed that the maximum velocity of the air flow becomes smaller as the projection angle B becomes larger.

Referring to fig. 19, it was confirmed that when the separation length D was 7mm and the projection angle B was 50 degrees, the air current was spread in the up-down direction or the left-right direction to the minimum, and the air current was concentrated toward the center. It was confirmed that the air flow forms the maximum wind speed when the separation length D is 7mm and the protrusion angle B is 50 degrees.

Referring to fig. 20, it can be confirmed that when the separation length D is formed to be 5 to 7mm and the protrusion angle is formed to be 50 to 60 degrees, the maximum wind speed of 2m/s or more can be formed.

The horizontal airflow in which air flows to the front of the blower 1 includes: a wide air flow that forms an air flow forward along the inner side wall 115 of the first tower 110 and the inner side wall 125 of the second tower 120; and a biased air flow, and the air flowing along the inner sidewalls 115 and 125 of the first and second towers 110 and 120 is inclined to the left or right by the first or second guide plates 411 and 412.

Fig. 21 is an explanatory view showing a wide air flow of the blower of the first embodiment of the invention. Next, the wide air flow of the blower will be described with reference to fig. 14 or 21.

When a wide air flow is set, the first guide plate 411 is arranged not to protrude toward the air blowing gap 105 side, and the second guide plate 412 is arranged not to protrude toward the air blowing gap 105 side. When a wide air flow is set, the first guide plate 411 is hidden in the first tower 110, and the second guide plate 412 is hidden in the second tower 120. The wide airflow may be selected directly by the user or as a default.

Specifically, the inner end 411a of the first guide plate 411 is located within the first plate slit 119 without protruding outward of the inner side wall 115. The inner end 412a of the second guide plate 412 is located within the second plate slit 129 without protruding outward of the inner side wall 125.

When the wide air flow is selected, the discharge air flowing through the blowing gap 105 spreads in the left-right direction according to the discharge angle a (see fig. 4) and flows.

Next, the deflection airflow of the blower will be described with reference to fig. 22 to 24.

The biased airflow may be formed when a first protrusion length t1 of the first guide plate 411 protruding from the first inner side wall 115 and a second protrusion length t2 of the second guide plate 412 protruding from the second inner side wall 125 are different from each other.

By forming the first projecting length t1 of the first guide plate 411 and the second projecting length t2 of the second guide plate 412 differently, the discharged air can be turned. Here, the first guide plate 411 or the second guide plate 412 cannot protrude beyond the center line L-L'.

The position forming the maximum speed of the airflow is defined as the central point of the airflow, and the included angle formed by the central line L-L' and the central point of the airflow is defined as the steering angle.

Referring to fig. 22 (a), when the right-hand biased airflow is set, the inner end 411a of the first guide plate 411 protrudes from the first plate slit 119 toward the air blowing gap 105, and the second guide plate 412 is disposed inside the second tower 120.

The angle of the rightward biased airflow can be adjusted by adjusting the first protrusion length t1 of the first guide plate 411. The right-hand deviation angle may become larger as the first protrusion length t1 becomes larger.

Referring to fig. 22 (b), when the left-hand biased airflow is set, the inner end 412a of the second guide plate 412 protrudes from the second plate slit 129 in the direction of the air blowing gap 105, and the first guide plate 411 is disposed inside the first tower 110.

The angle of the leftward biased airflow can be adjusted by adjusting the second protrusion length t2 of the second guide plate 412. The left-hand deviation angle may become larger as the second projection length t2 becomes larger.

The left and right directional deflection airflows may be received and activated by a remote control, control panel buttons, or the like. In contrast, in the case where a camera capable of recognizing the position of a user in a room is arranged, the left and right directional bias airflows may be automatically selected according to the position of the user recognized by the camera.

Fig. 23 is a graph showing the deflection airflow varying according to the first protrusion length t1 of the first guide plate at 75cm from the ground.

It is confirmed that the center of the air current forming the maximum velocity moves to the right side as the first protrusion length t1 becomes larger.

Referring to fig. 24, it can be confirmed that the maximum velocity of the air flow increases in the case where the first protrusion length t1 increases from 0mm to 10mm, and decreases again in the case where it exceeds 10 mm.

The maximum speed of the air flow is increased by the concentration of the discharged air by the coanda effect until the first projecting length t1 reaches the critical point, but when the maximum speed exceeds the critical point, the resistance of the discharged air is increased to decrease the maximum speed of the air flow.

Referring to fig. 24, the direction of the center point of the air flow forming the maximum velocity moves toward one side as the first protrusion length t1 becomes larger.

Fig. 25 is an explanatory view showing concentrated rotation of the blower of the first embodiment of the present invention.

The concentrated rotation is a mode in which the discharged air is reciprocated from the left side to the right side or from the right side to the left side. The center point of the air flow may reciprocate in the left-right direction while rotating concentratedly.

In the case where the concentrated rotation is set, the first airflow converter 401 and the second airflow converter 402 may operate simultaneously. In the case where the concentrated rotation is set, the first guide plate 411 and the second guide plate 412 may protrude toward the blowing gap 105.

At this time, the first guide plate 411 and the second guide plate 412 may reciprocate without being stationary.

Specifically, in the concentrated rotation, the first protrusion length t1 may be gradually increased and the second protrusion length t2 may be gradually decreased. Conversely, second projection length t2 may gradually increase and first projection length t1 gradually decreases. Here, the interval of the inner ends 411a, 412a of the first and second guide plates 411, 412 may be kept constant.

The first guide plate 411 or the second guide plate 412 cannot protrude beyond the center line L-L'.

When the first protrusion length t1 is gradually increased and the second protrusion length t2 is gradually decreased, the discharged air is gradually formed into a rightward biased airflow.

The airflow width of the right-hand deviation airflow formed at the time of the concentrated rotation may be smaller than that of the non-rotating deviation airflow. This is because the interval between the inner side ends 411a, 412a of the first guide plate 411 and the second guide plate 412 becomes smaller.

Similarly, as the second protrusion length t2 gradually increases and the first protrusion length t1 gradually decreases, the discharged air is gradually formed into a leftward biased airflow.

The concentrated rotation may alternately provide a right-hand biased airflow and a left-hand biased airflow. In addition, the concentrated rotation enables not only a narrower range of airflow to be provided with a large wind amount, but also a wider range of angles, as compared to when only a right-hand or left-hand biased airflow is provided.

On the other hand, the wide rotation may be selected differently from the collective rotation.

The wide rotation causes the discharged air to reciprocate from the left side to the right side or from the right side to the left side, and the center point of the air flow can reciprocate in the left-right direction. But wide spinning provides a wider airflow width than concentrated spinning.

At the time of the wide rotation, the first airflow converter 401 and the second airflow converter 402 may operate in sequence.

While the first guide plate 411 gradually reciprocates forming the first protrusion length t1, the second guide plate 412 maintains a state of being received in the second tower 120. In contrast, when the second guide plate 412 is gradually reciprocated by forming the second protrusion length t2, the first guide plate 411 maintains a state of being received in the second tower 110.

That is, the first guide plate 411 is projected to the center line L-L 'and then received in the first plate slit 119, and the second guide plate 412 is projected to the center line L-L' and then received in the second plate slit 129, by repeating the following process in the wide rotation.

Next, a blower including the third air guide 133 will be described with reference to fig. 26 to 28.

Referring to fig. 26, a third discharge port 132 may be formed to vertically penetrate the upper surface 131 of the tower base 130. A third air guide 133 for guiding the rising air may be disposed at the third discharge port 133.

Referring to fig. 26, the third air guide 133 is disposed to be inclined with respect to the vertical direction. The upper end 133a of the third air guide 133 is disposed forward of the lower end 133 b.

The third air guide 133 includes a plurality of blades arranged to be spaced apart in the front-rear direction.

The third air guide 133 is disposed between the first tower 110 and the second tower 120. The third air guide 133 is disposed below the blowing gap 105. The third air guide 133 is formed to discharge air to the blowing gap 105.

Referring to fig. 26, the inclination of the third air guide 133 with respect to the vertical direction is defined as an air guide angle C.

Fig. 27 is a value of the airflow speed that changes according to the air guide angle C measured at P50 cm in front of the upper side end 133 a. The air flow velocities that vary according to the air guide angle C are measured by the number of blades, respectively.

Referring to fig. 27, it can be confirmed that, in the case where the number of the blades is four or more, if the air guide angle C is less than 30 degrees, the airflow velocity at P converges to 0. In the case where the number of blades is two, even if the air guide angle C is reduced, the forward airflow is measured at P.

Fig. 28 is a value of the airflow velocity measured at the upper end 111. Referring to fig. 28, in the case where the number of blades is two, four, or six, the airflow velocity is measured at the upper side end 111.

In particular, in the case where the number of blades is four or six, it is confirmed that the airflow velocity decreases as the air guide angle C increases.

As a result of combining fig. 27 and 28, only if the third air guide 133 is configured with at least four blades, it is possible to minimize the air flowing in the forward direction and secure the airflow speed of the air flowing to the upper side.

It will be appreciated by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the embodiments set forth above are illustrative in all respects and not restrictive. It should be understood that the scope of the present invention is defined by the claims, and all modifications and variations derived from the meaning and scope of the claims and equivalent concepts thereof are included in the scope of the present invention.