KR20140144402A - A diffusing apparatus of indoor air - Google Patents

Abstract

The present invention relates to an indoor air diffusing apparatus comprising: a ceiling-fixed part; a power generation unit coupled to the ceiling-fixed part; and a fan including a hub rotated by the power transmitting unit and a plurality of blades coupled to the hub wherein each of the blades has a front surface formed to ascend to the top thereof having curved parts, and has a bottom surface formed to descend to the bottom thereof by having an angle (a) of attack in a perpendicular direction of an extended blade from the hub horizontally. According to the present invention, when the fan is rotated, convex parts formed on the curved parts of the blades are capable of reducing drag by dispersing a fluid and are capable of preventing the vortices of the fluid from being generated on the bottom surfaces of the fluid such that the vibrations of the blade can be prevented from being caused by the vortices on the ends of the blades, thereby uniformly diffusing cold or hot air from an air conditioner to the entire area of an indoor space. In addition, according to the present invention, even if the blades have a large angle of attack, the vortices on the ends of the blades and the vibrations of the blades can be prevented to generate a large amount of air volume, thereby improving the efficiency of air volume.

Description

[0001] The present invention relates to an air diffusing apparatus for indoor air,

More particularly, the present invention relates to an indoor air diffuser, and more particularly, to an indoor air diffuser in which a curved portion is formed in a blade of a fan, the fluid is dispersed by unevenness formed in a curved portion at the time of rotation of the fan, The vortex phenomenon of the generated fluid is prevented so that the vibration of the blade due to the vortex phenomenon at the blade tip is prevented so that the cold air or the hot air in the air conditioner that generates cold air or hot air can be evenly diffused throughout the room The present invention relates to an indoor air diffusion device capable of generating a large amount of airflow without generating fluid vortex and blade vibration at the blade tip even when the angle of attack of the blade is increased, thereby improving airflow efficiency.

Generally, an air conditioner is a device capable of selectively generating cold wind or hot wind or cold wind and hot wind, and is used in summer or winter to maintain a room temperature at a certain level.

However, since the fluid formed in the room is concentrated in the lower part of the room due to the convection phenomenon, and the hot fluid is concentrated in the upper part of the room, the efficiency of the air conditioner is lowered.

1 is a perspective view of a ceiling fan (Korean Patent Laid-Open No. 10-2008-0074045 (Aug. 12, 2008)), which comprises a fan 110 having a blade 111 formed in a ceiling fixing portion 113 So that the indoor air can be diffused.

Generally, in order to improve the airflow of the ceiling fan 100, it is necessary to increase the angle of attack of the blades 111 of the fan 110 or to increase the size of the blades 111 themselves.

However, forming the blade 111 in a limited space with a large size has a limitation, and also a risk of falling.

Therefore, in order to increase the airflow of the ceiling fan 100, the angle of attack of the blade 111 must be increased. However, if the angle of attack is increased, the area of contact with the fluid becomes wider, Resulting in a problem of operation due to the above-mentioned problems.

In addition, when the angle of attack is made large, air is unstably moved at the blade end as shown in FIG. 7, and vortexing phenomenon occurs. As a result of this vortex phenomenon, vibration occurs at the blade tip, And the durability of the ceiling fan 100 is deteriorated.

Therefore, the general blade 111 has a problem that the angle of attack is formed at an angle of less than 7 degrees, thereby deteriorating the efficiency of airflow.

In order to solve the above problems, an indoor air diffusion device of the present invention includes a ceiling fixture; Power generating means coupled to the ceiling mount; A fan including a hub rotatable by the power generating means and a plurality of blades coupled to the hub, the blades of the fan having an angle of attack (a And a bottom surface descending to the lower end, and a curved portion is formed on the front surface.

In the present invention, the angle of attack formed on the blades of the fan is 7 to 21 degrees.

In the present invention, the curved portion is formed integrally with the blade.

In the present invention, the curved portion is formed separately from the blade, and the first and second coupling portions are formed on the blade and the curved portion so that the coupling and the disengagement are made possible.

In the present invention, the curved portion is characterized in that the concave and convexities forming the round are repeatedly formed.

The present invention forms a curved portion in the blade of the fan, and the fluid is dispersed by the unevenness formed at the curved portion when the fan is rotated, thereby reducing the drag and at the same time preventing the swirling phenomenon of the fluid generated in the lower side of the blade, The vibration of the blades due to the vortex phenomenon in the air conditioner in the air conditioner can be prevented and the cold air or the hot air in the air conditioner generating the cold air or the hot air can be diffused evenly throughout the room.

Further, even if the angle of attack of the blades is increased, fluid vortex and blade vibration do not occur at the end of the blades, and a large amount of airflow can be generated, which is a useful invention to improve the airflow efficiency.

1 is a perspective view showing a conventional ceiling fan.
2 is a side view of an indoor air diffusion device according to the present invention.
Figure 3 is a plan view of Figure 2;
4 is a plan view showing the blade of the present invention.
5 is a plan view showing another embodiment of Fig.
6 is a view showing a pressure acting on the blade.
7 is a state diagram showing a state in which a vortex is generated in the blade.
8 is an analysis view showing a general vortex phenomenon of a blade.
9 is a state diagram showing the action of a curved portion in the present invention.
10 is a first analysis view showing the action of the bending portion of the present invention.
11 is a second analysis diagram showing the action of the bending portion of the present invention.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.

The present invention is to be installed in the vicinity of an air conditioner (not shown) for generating cold air or hot air (hereinafter referred to as "fluid") to spread the fluid evenly in the room

Looking at the configuration,

First, as shown in Figs. 2 to 3, a ceiling fixing part 10 is constructed.

The ceiling fixing part 10 is generally constituted by a conventional coupling member (not shown in the drawings) which can be fixedly mounted on a ceiling, and a detailed description thereof will be omitted.

Further, the power generating means M is also provided in a usual manner, and a detailed description thereof will be omitted.

However, the power generating means M may be of any configuration as long as it can generate rotational force like a motor and can rotate forward and reverse.

Next, the fan 20 is connected to the power generating means M so as to be able to rotate by receiving the power of the power generating means M.

The fan 20 includes a hub 21 directly connected to the power generating means M and a plurality of blades 22 coupled to the hub 21.

At this time, the hub 21 and the blade 22 can be coupled using a normal bolt / nut, though not shown in detail in the drawings.

Particularly, in the present invention, an angle of attack a is formed on the blade 22 to constitute a front face 22a which rises to the top and a rear face 22b which goes down to the bottom.

Here, the angle of attack (a) may be between 2 and 21 degrees.

Next, the curved portion 30 is formed on the front surface 22a formed on the blade 22 of the fan 20.

The curved portion 30 has a plurality of grooves 31 and concavities and convexities 32 on which a round R is formed are repeatedly formed in the same pattern so as to have a length corresponding to an extended length of the blade 22. [

4, the curved portion 30 may be integrally formed when the blade 22 of the fan 20 is manufactured. Alternatively, the curved portion 30 may be formed by integrally forming the blade 22 and the curved portion 30 separately A first engaging portion J1 is formed on the blade 22 and a second engaging portion J2 is formed on the curved portion 30 so that various coupling means such as bolts and nuts or rivets So that they can be combined with each other.

The function and effect of the indoor air diffusion device of the present invention having the above-described structure will be described as follows.

First, the indoor air diffusing device 50 of the present invention is used to diffuse a fluid such as hot air or cold air formed by a normal air conditioner (not shown in the drawings). More specifically, And the heat generated by the air conditioner of the stand type or the wall type is diffused in the whole room to improve the heat efficiency.

That is, in winter or summer, the user operates an air conditioner in which hot air or cold air is emitted.

However, in the case of warm air or cold air spreading in the room, an air flow is formed by the convection phenomenon of the room.

For example, when the air conditioner is operated so that the user can generate warm air, the convection phenomenon causes hot air to concentrate on the upper part of the room, thereby deteriorating thermal efficiency.

As a result, people in the actual residential area will not be able to receive the warm air, and the user will operate the air conditioner to continuously generate warm air.

On the contrary, when the user operates the cold air, the cold air is concentrated only in the lower part of the room, which also causes a problem that the thermal efficiency is lowered.

The present invention is installed to prevent deterioration of thermal efficiency due to convection in a room, and it is usually used by being attached to a ceiling.

The indoor air diffusing apparatus 50 of the present invention drives the fan 20 composed of the plurality of blades 22 coupled to the hub 21 through the power generating means M to operate the air conditioner in summer The hot air generated by operating the air conditioner in the winter is guided to the lower portion of the indoor by moving the blade 22 in the opposite direction to induce the hot air in the upper portion of the room, And the like.

Here, the blade 22, which is a component of the above-described fan 20, forms a certain angle of attack a to change the flow of the fluid.

That is, when the lower end surface 22c of the blade 22 rotates so as to be in contact with the fluid (clockwise direction), the fluid in the lower part of the chamber acts to move the fluid to the upper part of the room. So that the fluid can be moved to the lower portion of the room.

In detail, as shown in FIG. 6, the blade 22 passing through the fluid generally generates a resistance, in other words, a drag that is received by the fluid.

Further, in the fluid passing through the blade 22, a static pressure acting in a direction perpendicular to the direction in which the fluid flows and the dynamic pressure acting in the direction of flow of the fluid are generated.

That is, the pressure generated in the blade can be expressed as 'voltage = dynamic pressure + static pressure'.

On the other hand, the pressure acting on the blade 22 is made by the pressure of the fluid moving to the upper side 22d of the blade 22 and the pressure moving to the lower side 22c of the blade 22. [

When the blade 22 forming the angle of attack a is rotated in the direction in which the lower surface 22c is in contact with the fluid, the pressure generated in the lower surface 22c of the blade 22 is lower than the pressure applied to the upper surface 22d. Which is greater than the pressure generated by the pressure sensor.

This principle can be explained using a typhoon that generates centrifugal force.

That is, at the central portion where the centrifugal force of the typhoon occurs, the rotational force is small and the pressure and the air volume are small, and at the position deviated from the center of the typhoon where the centrifugal force is relatively generated,

In view of this principle, the general blade 22 is manufactured in a streamlined shape, so that some rotational force is generated when the fluid is moved.

Here, the fluid that moves on the upper side 22d of the blade 22 exists at the center of the centrifugal force when the fluid is rotated because the fluid moves from the upper side 22d as a starting point, The fluid moving along the side surface 22c exists at the same position as the outermost periphery at the center of the centrifugal force.

Therefore, the pressure and the fluid movement amount generated in the upper surface 22d of the blade 22 become smaller than the pressure and the fluid movement amount generated in the lower side surface 22c of the blade 22. [

7, the fluid moving along the lower side surface 22c of the blade 22 moves upward at the end of the blade 22, as shown in FIG. 7, .

Particularly, as described above, the fluid to move from the lower side 22c to the upper side 22d is proportional to the size of the angle of attack a of the blade 22.

The fluid that has moved from the lower side 22c to the upper side 22d of the blade 22 is collided with the fluid moving on the upper side 22d as the angle of attack a becomes larger, will be.

When the angle of incidence a of the blades 22 is 7 ° or more as described in the prior art, as shown in the analysis chart showing the fluid flow using the fluid analysis program of Fig. 8, the blades 22 The air flow is unstably formed. As a result, vibration is generated at the end of the blade 22 and the efficiency is lowered, so that the angle of attack a can not be made large.

In the present invention, the curved portion 30 including the concave and convex portions 32 and the concave groove 31 in which the round R is formed on the front surface 22a of the blade 22 is formed, By stabilizing the flow, the vibration at the end of the blade 22 is prevented from occurring.

In detail, when the blade 22 rotates in the clockwise direction, a drag force with the fluid is generated, and the fluid abuts against the curved portion 30.

The fluid that abuts against the curved portion 30 is dispersed in the direction of the groove 31 in the convexo-concave portion 32 of the curved portion 30 as shown in Fig. 9 and the upper side surface 22d of the blade 22 and the lower And movement to the side surface 22c is performed.

That is, as described above, the vortex phenomenon of the fluid generated at the end of the blade 22 is formed such that the pressure generated at the lower side 22c of the blade 22 is higher than the pressure generated at the upper side 22d, When the fluid is dispersed by the protrusions and depressions 32 of the curved portion 30 as described above, the lower side 22c of the blade 22 And the upper surface 22d of the blade 22 is reduced, thereby preventing the fluid from swirling and preventing the vibration of the blade 22 from occurring.

The operation of the curved portion 30 can be seen in an experiment using a fluid analysis program as shown in Figs. 10 to 11. Fig.

FIG. 10 shows a process in which a first fluid passes through a blade having a curved portion, and FIG. 11 shows a flow of a fluid passing through a curved portion and a blade, and it can be confirmed that a swirling phenomenon does not occur at the blade end.

The present invention prevents the blade 22 from vibrating even when the angle of the blade 22 is increased due to the action of the curved portion 30 so that the airflow can be increased more, It is possible to more easily perform the fluid diffusion when moving the upper part of the room or moving the air in the upper part of the room to the lower part.

In this case, when the angle of the angle of attack a is made larger, the size and number of the grooves 31 and the concave and convex portions 32 of the curved portion 30 are changed, It is of course possible to reduce the pressure difference generated between the lower surface 22d and the lower surface 22c.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: Ceiling fixing part
M: Power generating means
20: Fans
21: hub 22: blade 22a: front face 22b: rear face
30: Bunch
31: groove 32: concave R: round
50: Indoor air diffuser

Claims (5)

A ceiling fixing part 10;
Power generating means (M) coupled to the ceiling mount (10);
A fan 20 including a hub 21 rotated by the power generating means M and a plurality of blades 22 coupled to the hub 21,
The blade 22 of the fan 20 has an angle of attack a in a direction perpendicular to the transverse direction of the hub 21 to form a front face 22a that has risen to the top, (22b), and a curved portion (30) is formed on the front surface (22a).
2. The indoor air diffusion device according to claim 1, characterized in that the angle of attack (a) formed in the blade (22) of the fan (20) is 2 to 21 degrees.
2. The indoor air diffusion device according to claim 1, characterized in that the curved portion (30) is formed integrally with the blade (22) of the fan (20).
The method of claim 1, wherein the curved portion (30) is formed separately from the blade (22) of the fan (20) to form first and second engaging portions (J1, J2) in the blade (22) And an indoor air diffuser characterized by being configured to be decomposable.
The indoor air diffusing device according to claim 1, wherein the curved portion (30) is characterized in that the groove (31) and the concave and convex portions (32) forming the round (R) are repeatedly formed.

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