KR20140124196A - turbo fan and ceiling type air conditioner using thereof - Google Patents

Abstract

A turbo fan according to the present invention comprises a main plate rotating by power provided by a fan motor; and blades having one ends connected to the main plate and forming positive pressure surfaces and negative pressure surfaces which are surfaces opposite to the positive pressure surfaces, wherein the blade forms a tilted part connected to one side of the positive pressure surface and tilted at a set angle in the direction from the positive pressure surface to the negative pressure surface. A ceiling type air conditioner according to the present invention comprises a case forming the exterior and forming an intake hole for taking in indoor air; the turbo fan arranged within the case and discharging the air passing through the intake hole in a radial direction; and a heat exchanger arranged at the outside of the turbo fan.

Description

[0001] The present invention relates to a turbo fan and a ceiling type air conditioner using the same,

The present invention relates to a turbo fan and a ceiling type air conditioner using the same.

Background Art [0002] Generally, a ceiling-type air conditioner is a device that is embedded in an indoor ceiling to introduce indoor air and then heat-exchanged air is discharged from the ceiling to the room. In the ceiling-type air conditioner, air is sucked through a suction port disposed at the center, and the sucked air can be air-conditioned by a heat exchanger disposed inside the ceiling-type air conditioner. The air-conditioned air can be discharged to the room through the discharge part disposed at the rim of the ceiling-type air conditioner to adjust the temperature and humidity of the indoor space.

As disclosed in the publication No. 10-2008-0054153 (entitled " turbo fan and air conditioner equipped therewith "), the air sucked through the suction port is sucked by a turbo fan disposed inside the ceiling type air conditioner Its movement can be guided. That is, the turbo fan can discharge air in the radial direction of the turbo fan by introducing air from the axial direction with reference to the turbo fan.

Open No. 10-2012-0023320 (entitled " Turbo fan for an air conditioner ") discloses a moving flow of air introduced through the turbo fan.

Specifically, the turbo fan may include a plurality of blades spaced apart from each other by a predetermined distance to move radially the air introduced through the inlet. The blade may include a static pressure surface defined by a surface facing the rotating direction of the turbo fan and a negative pressure surface opposite to the static pressure surface.

However, as the turbo fan rotates, a pressure difference may be generated between the static pressure surface and the negative pressure surface due to the pressure applied from the static pressure surface of the blade, through the suction port. Some of the air discharged in the radial direction by the pressure difference passes from the static pressure surface of the blade to the negative pressure surface.

Generally, the edge formed between the static pressure surface and the negative pressure surface is formed as a flat surface. Therefore, a vortex may be generated in the air passing from the static pressure surface to the negative pressure surface. The vortex refers to a phenomenon in which air or matter performs rotational motion with respect to a fixed center of rotation. When the vortex is generated, there is a problem that noise is generated due to the frictional force of the air.

SUMMARY OF THE INVENTION An object of the present invention is to provide a turbo fan and an air conditioner using the turbo fan which reduce the vortex phenomenon of air generated at the upper end of the blade when the air is moved from the static pressure surface to the negative pressure surface of the blade.

It is another object of the present invention to provide a turbo fan and an air conditioner using the turbo fan, which prevent the air flowing from the blade from swirling, thereby reducing air flow noise.

A turbo fan according to the present invention comprises: a main plate rotated by a power provided by a fan motor; And a blade having one end connected to the main plate and formed with a negative pressure surface which is a surface opposite to the static pressure surface and the static pressure surface, the blade being connected to one side of the static pressure surface, An inclined portion having a predetermined angle inclination is formed.

A ceiling-type air conditioner according to the present invention comprises: a case having an inlet formed with an appearance and sucking indoor air; A turbo fan provided in the case and discharging the air passing through the inlet in a radial direction; And a heat exchanger disposed in an outer chamber of the turbo fan, wherein the turbo fan comprises: a main plate rotated by a power provided by the fan motor; And a blade having one end connected to the main plate and formed with a negative pressure surface which is a surface opposite to the static pressure surface and the static pressure surface, the blade being connected to one side of the static pressure surface, An inclined portion having a predetermined angle inclination is formed.

According to the present invention, the upper end of the blade has an inclined portion inclined at a predetermined angle in the direction from the static pressure surface toward the negative pressure surface, thereby minimizing the vortex phenomenon of the air.

Further, since the friction between the air and the blade can be minimized by the inclined portion when the air sucked into the turbo fan through the suction port is moved from the static pressure surface to the negative pressure surface, the flow noise of the air is reduced .

In addition, the air sucked into the turbo fan by the inclined portion can be smoothly moved from the static pressure surface to the negative pressure surface.

1 is a perspective view of an indoor unit of a ceiling-type air conditioner according to the present invention.
2 is a sectional view of an indoor unit of a ceiling-type air conditioner according to the present invention.
3 is a perspective view of a turbo fan according to the present invention.
Fig. 4 is an enlarged perspective view of a portion A of Fig. 3; Fig.
FIG. 5A is a cross-sectional view showing the configuration of the upper end of the blade cut along the line II 'of FIG. 4; FIG.
FIG. 5B is a cross-sectional view showing a configuration of a blade top according to another embodiment of the present invention. FIG.
FIG. 6 is a graph showing a correlation between air volume and noise when a blade according to the present invention is applied to a ceiling-type air conditioner. FIG.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

FIG. 1 is a perspective view of an indoor unit of a ceiling-type air conditioner according to the present invention, and FIG. 2 is a sectional view of an indoor unit of a ceiling-type air conditioner according to the present invention.

1 and 2, a ceiling-type air conditioner according to the present invention includes an outdoor unit (not shown) installed in an outdoor space, an indoor unit 100 installed in an indoor space, and an outdoor unit (not shown) And a refrigerant pipe (not shown) in which the refrigerant is moved.

The indoor unit 100 includes a case 105 forming an outer appearance, a turbo fan 200 provided inside the case 105, a fan motor 120 coupled to the turbo fan 200 and providing power, And a heat exchanger (130) provided outside the fan motor (120).

The case 105 may include a main body 101 forming a side surface and a front panel 102 coupled to the main body 101 and forming a front surface.

The main body 101 is installed on the ceiling of the room and can be opened to communicate with the suction port 150 formed on the front surface of the front panel 102. The main body 101 is preferably installed on the ceiling in consideration of space utilization or aesthetics, but the installation space of the main body 101 is not limited thereto. For example, the main body 101 may be installed on the side wall of the room.

The front panel 102 may be detachably coupled to the lower portion of the main body 101. The front panel 102 may be disposed to be exposed to the room so as to suck or discharge air into the indoor unit 100. The front panel 102 may cover an open portion of the main body 101. For example, the front panel 102 may have a rectangular plate shape to cover the opening of the main body 101. In addition, the front panel 102 may include a suction port 150 for sucking room air and a discharge port 140 for discharging air to the room.

The suction port 150 may be disposed at a central portion of the front panel 102. The discharge ports 140 may be formed to be symmetrical to the outer sides of the suction port 150. The suction port 150 may be formed in a grill structure, and the discharge port 140 may have a rectangular shape having a predetermined width and length. However, the shapes of the suction port 150 and the discharge port 140 are not limited thereto.

A filter 190 may be provided on the inside of the front panel 102 to remove various foreign substances contained in the air sucked into the main body 101 through the suction port 150.

The turbo fan 200 may be installed at a position corresponding to the suction port 150 to improve suction efficiency of the air sucked into the main body 101. 2, the turbo fan 200 may be installed to correspond to the intake port 150 in the vertical direction.

The turbo fan 200 blows the indoor air sucked through the suction port 150 to the heat exchanger 130.

The heat exchanger 130 may surround the outside of the turbo fan 200. For example, the heat exchanger 130 may have a rectangular shape corresponding to the side surface shape of the main body 101. The heat exchanger 130 may perform heat exchange of the air sucked into the main body 101 through the turbo fan 200. Specifically, during the cooling operation of the ceiling-type air conditioner, the temperature of the air passing through the heat exchanger 130 is lowered, and during the heating operation of the ceiling-type air conditioner, the temperature of the air passing through the heat exchanger 130 Can be increased.

A drain plate 131 may be disposed below the heat exchanger 130 to receive condensed water generated during a heat exchange process between the refrigerant passing through the heat exchanger 130 and the room air. A drain pipe (not shown) for discharging the condensed water collected in the drain plate 131 to the outside may be connected to the drain plate 131.

A guide passage 180 for guiding the moving direction of the air may be formed in the inner periphery of the main body 101. Specifically, the guide passage 180 may guide the air heat-exchanged by the heat exchanger 130 to the discharge port 140.

The discharge port 140 may be provided with a vane 141 for controlling the moving direction of the air. The vane 141 may be configured to be rotatable at a predetermined angle. In addition, the vane 141 may be inclined outward from the front surface of the front panel 102. This is to provide a wind having a uniform wind velocity in all parts of the room. However, the direction of rotation of the vane 141 is not limited thereto. Also, the arrangement, construction, and operation of the vane 141 are not limited thereto.

In operation of the turbo fan 200, air introduced into the turbo fan 200 may be discharged to the outside through a space formed between the blades 400. That is, the air can be moved along the surfaces of the plurality of blades 400.

However, the air that moves along the blade 400 may leak from the surface of the blade 400 due to a pressure difference generated between one side of the blade 400 and the other side. Specifically, the air introduced through the inlet 150 during the operation of the turbo fan 200 can be radiated in the radial direction by the operation of the blade 400. However, due to the pressure difference between the surfaces of the blades 400, a part of the air can not be discharged in the radial direction but leak to the outside.

At this time, the air leaked from the surface of the blade 400 may generate a vortex. The vortex means a phenomenon in which the air performs rotational motion with respect to one point. The vortex phenomenon caused by the leakage flow of air causes noise generation. Therefore, in the blade 400 according to the present invention, an inclined portion (see 510 in FIG. 5) may be formed to prevent the eddy current due to the leakage flow of air.

Hereinafter, the configuration of the turbo fan 200 will be described in detail.

FIG. 3 is a perspective view of a turbo fan according to the present invention, and FIG. 4 is an enlarged perspective view of a portion A of FIG.

3 and 4, the turbo fan 200 according to the present invention includes a hub (see 112 in FIG. 2) connected to the rotation axis of a fan motor (see 120 in FIG. 2) A plurality of blades 400 connected at one end to the main plate 115 and disposed at regular intervals along the circumferential direction on the main plate 115 and a plurality of blades 400 connected to the main plate 115, And a shroud 300 disposed opposite to the other ends of the blades 400 and connecting the other ends of the blades 400. The shroud 300 may guide the inflow of air into the inlet 150 when the turbo fan 200 rotates.

Between the plurality of blades 400, a discharge port 435 through which the air introduced into the suction port 150 can be discharged to the heat exchanger (see 130 in FIG. 2) may be formed. The hub (see 112 in FIG. 2) can guide air to the outlet 435. 2) is provided at the center of the hub (see 112 in FIG. 2), and a boss portion 113 having a shaft hole for allowing the fan motor (refer to FIG. 2) A through hole 114 may be formed. The passage 114 may be configured to cool the fan motor (see 120 in FIG. 2) by guiding cold air into the fan motor 120 (see FIG. 2).

The blade 400 may include a static pressure surface 410 and a negative pressure surface 420 defined by the opposite surface of the static pressure surface 410. The static pressure surface 410 may be defined as a surface facing a rotational direction of the turbo fan 200 with a pressure higher than atmospheric pressure. Referring to FIG. 3, the turbo fan 200 may be rotated counterclockwise. The negative pressure surface 420 may be defined as a surface facing a pressure lower than atmospheric pressure and a surface facing the direction opposite to the rotating direction of the turbo fan 200.

The blade 400 is disposed adjacent to the hub (see 112 in FIG. 2) and includes a blade front end 430 constituting one side of the blade 400 and a blade rear end 440). The air introduced into the suction port 150 may be moved from the blade front end 430 to the blade rear end 440 along one side of the blade 400.

In other words, the blade 400 may guide the air introduced through the suction port 150 to be moved to the discharge port 435. Specifically, as the turbo fan 200 rotates, air can be introduced into the front ends 430 of the plurality of blades through the inlet 150. [ The internal pressure of the turbo fan 200 can be increased by the pressure applied from the static pressure surface 410 of the blade. Accordingly, the air can be moved from the blade front end 430 to the blade rear end 440 by the internal pressure.

However, the pressure of the air moving along the static pressure surface 410 may be greater than the pressure of the air moving along the negative pressure surface 420. Accordingly, the air that moves along the static pressure surface 410 can be transferred to the negative pressure surface 420 due to the pressure difference. That is, the flow direction of air introduced through the inlet port 150 can be moved from the blade front end 430 to the blade rear end 440 along the static pressure surface 410. However, due to the pressure difference between the static pressure surface 410 and the negative pressure surface 420, the air moved along the static pressure surface 410 may be moved to the negative pressure surface 420. That is, air leakage may occur due to the pressure difference between the static pressure surface 410 and the negative pressure surface 420.

The air leakage may occur at the blade top 450. The blade top 450 may be defined as a boundary between the static pressure surface 410 and the negative pressure surface 420 which are spaced apart from the main plate 115. According to the prior art, the blade tops 450 are configured in a rectangular shape having a pair of edges. However, if the upper end of the blade 450 is formed in a rectangular shape, a flow of air passing through the upper end of the blade 450 may be cut off and a vortex may be generated. Noises may be generated during operation of the turbo fan 200 by the vortex.

Accordingly, the blade upper end 450 according to the present invention may be formed with an inclined portion (refer to 510 in FIG. 5A) for preventing air vortex. The inclined portion (see 510 in FIG. 5A) can smoothly guide the flow of air passing through the upper end of the blade 450 to prevent air vortex formation.

Hereinafter, the specific configuration of the blade top 450 will be described.

5A is a cross-sectional view showing the configuration of the upper end of the blade cut along the line I-I 'in FIG.

5A, a blade 400 according to the present invention includes a positive pressure surface 410, a negative pressure surface 420 opposite to the static pressure surface 410, and a negative pressure surface 420 at the static pressure surface 410. [ And a blade upper end 450 for guiding the flow of air to be moved to the lower end of the blade.

The blade upper end 450 may be formed with an inclined portion 510 for preventing a vortex from being formed in the air moving from the static pressure surface 410 to the negative pressure surface 420. The blade top 450 may further include a horizontal portion 520 disposed in parallel with the main plate 115.

One side of the inclined portion 510 may be connected to the static pressure surface 410 and the other side of the inclined portion 510 may be connected to the horizontal portion 520. One side of the horizontal part 520 is connected to the inclined part 510 and the other side of the horizontal part 520 is connected to the negative pressure surface 420. That is, the inclined portion 510 may be inclined from the static pressure surface 410 toward the negative pressure surface 420.

If a point at which the inclined portion 510 meets the static pressure surface 410 is referred to as a contact point 505 and an imaginary line extending parallel to the main plate 115 from the contact point 505 is defined as an extension line 515 can do. The inclined portion 510 may be provided on the extension line 515.

The cross-sectional area of the blade 400 may gradually become narrower toward the blade upper end 450 with respect to the extension line 515. That is, the sectional area of the blade 400 formed in the direction of the extension line 515 in the main plate 115 may be uniform. However, the cross-sectional area of the blade 400 formed in the extension line 515 in the direction of the blade upper end 450 may be reduced by the slope 510 to prevent the air from swirling. In other words, the size of the cross-section of the blade 400 with respect to the direction parallel to the main plate 115 may be smaller toward the direction of the horizontal portion 520 from the extension line 515.

The vertical distance between the inclined portion 510 and the main plate 115 may increase with respect to the direction from the static pressure surface 410 toward the negative pressure surface 420. That is, the inclined portion 510 may be inclined at a predetermined angle in the direction from the static pressure surface 410 to the negative pressure surface 420 for smooth movement of the air.

The sum of the length of the static pressure surface 410 and the length of the inclined portion 510 is set to be smaller than the sum of the length of the constant pressure surface 410 and the length of the inclined portion 510, Lt; RTI ID = 0.0 > 420 < / RTI > Accordingly, leakage of air generated in the upper end of the blade 450 can be reduced.

The angle formed between the extension line 515 and the inclined portion 510 may be?. For example, the value of? May be an acute angle. In other words, the sum of the length of the static pressure surface 410 and the length of the inclined portion 510, as viewed from the movement path of the air moving along one blade of the plurality of blades 400, May be longer than the length of the surface 420.

Therefore, the air that moves along the static pressure surface 410 can be smoothly moved to the negative pressure surface 420 by the inclined portion 510. That is, the air moving along the static pressure surface 410 may minimize the leakage of air from the blade top 450 by the inclined portion 510, so that vortex generation can be suppressed. Therefore, noise generated during operation of the turbo fan 200 can be reduced.

However, the configuration of the blade upper end 450 is not limited thereto. For example, the blade top 450 may be formed only of the inclined portion 510 without forming the horizontal portion 520. However, in consideration of the flow direction of the air, the inclined portion 510 may be formed in the direction of the negative pressure surface 420 from the static pressure surface 410.

5B is a view showing a configuration of a blade top according to another embodiment of the present invention.

Referring to FIG. 5B, the blade upper end 550 according to the present embodiment may include a plurality of inclined portions 611 and 612 and horizontal portions 621 and 622.

The plurality of inclined portions 611 and 612 and the plurality of horizontal portions 621 and 622 may be alternately arranged. More specifically, the blade upper end 550 has a first inclined portion 611, a first horizontal portion 621, and a second inclined portion 612. The first inclined portion 611, the first horizontal portion 621, Two inclined portions 612 and a second horizontal portion 622 in this order.

Therefore, air passing through the static pressure surface 410 can be smoothly moved toward the negative pressure surface 420 by the plurality of slopes 610. Also, it is possible to prevent air vortex from occurring at the upper end of the blade (550), and to reduce noise generated during operation of the turbo fan (200).

6 is a graph showing the relationship between air volume and noise when the blades according to the present invention are applied to a ceiling type air conditioner.

Referring to FIG. 6, when the conventional ceiling type air conditioner to which the blade is applied operates, the relationship between the air volume and the noise may have the relationship of N disclosed in FIG. When the ceiling type air conditioner to which the blade according to the present invention is applied operates, the relationship between the air volume and the noise may have the relationship of M disclosed in FIG.

If the air volume of the air discharged from the ceiling-type air conditioner is the same, noises generated during operation of the ceiling-type air conditioner to which the blades according to the present invention are applied are generated during operation of the ceiling- It may be smaller than noise.

That is, the blade upper end 450 according to the present invention may be formed with an inclined portion 510 for preventing a vortex from being generated in the air moving in the direction from the static pressure surface 410 toward the negative pressure surface 420 .

Therefore, the air that moves along the static pressure surface 410 can be smoothly moved to the negative pressure surface 420 by the inclined portion 510. Also, the air moving along the static pressure surface 410 minimizes air leakage from the blade top 450 by the inclined portion 510, and vortex generation can be suppressed. Therefore, noise generated during operation of the turbo fan 200 can be reduced.

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

100: indoor unit 420: inlet
200: Turbo Fan 400: Blade
410: static pressure side 420: negative side
430: blade front end 440: blade rear end
450: top of blade 510:
515: Extension line 520: Horizontal part

Claims (10)

Abacus rotating by the power provided by the fan motor; And
A blade having one end connected to the main plate and having a positive pressure surface and a negative pressure surface opposite to the static pressure surface,
The blade
And an inclined portion connected to one side of the static pressure surface and having a predetermined angle inclined from the static pressure surface toward the negative pressure surface. The method according to claim 1,
When viewed from the direction toward the negative pressure surface from the static pressure surface,
The inclined portion,
Wherein a vertical distance between the main plate and the main plate is increased. The method according to claim 1,
And a control unit that, based on the movement path of the air moving from the static pressure surface to the negative pressure surface,
Wherein the sum of the length of the static pressure surface and the length of the inclined portion has a larger value than the length of the negative pressure surface. The method according to claim 1,
The inclined portion,
And is formed at an upper end of the blade spaced from the main plate and defined by an interface between the static pressure surface and the negative pressure surface. 5. The method of claim 4,
The upper end of the blade
Further comprising a horizontal portion having one side connected to the inclined portion and the other side connected to the negative pressure surface and disposed parallel to the main plate. 6. The method of claim 5,
A contact point at which the inclined portion meets the static pressure surface; And
And an extension line that is a virtual line extending in a direction parallel to the main plate from the contact,
The size of the cross section of the blade, as viewed from a direction parallel to the main plate,
And the distance from the extension line toward the horizontal portion decreases. The method according to claim 6,
On the basis of the extension line,
Wherein the inclination angle of the inclined portion is an acute angle. 5. The method of claim 4,
A plurality of inclined portions and a plurality of horizontal portions are formed on an upper end of the blade,
Wherein the plurality of ramps and the plurality of horizontal portions are alternately arranged. A case having a suction port formed therein for sucking indoor air;
A turbo fan provided in the case and discharging the air passing through the inlet in a radial direction; And
And a heat exchanger disposed in an outer chamber of the turbo fan,
The turbofan comprises:
Abacus rotating by the power provided by the fan motor; And
A blade having one end connected to the main plate and having a positive pressure surface and a negative pressure surface opposite to the static pressure surface,
The blade
And an inclined portion connected to one side of the static pressure surface and inclined at a predetermined angle in the negative pressure surface direction from the static pressure surface. 10. The method of claim 9,
The blade further includes a blade top disposed to be spaced apart from the main plate and defined by an interface between the static pressure surface and the negative pressure surface,
The inclined portion,
Wherein the air inlet is formed at the upper end of the blade.

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