KR20070000900A - Turbo fan - Google Patents

Abstract

A turbo fan is provided to prevent collision of the fan and an orifice by maintaining a predetermined gap with an orifice even when the fan is shaken. A turbo fan includes a hub(52), a shroud(54), and a plurality of blades(56). The shroud guides sucked air from the axial direction to the radial direction. The plurality of blades are circumferentially installed between the outer peripheral end of the hub to the outer peripheral end of the shroud to blow the sucked air so that the sucked air can be radially discharged. An orifice guiding the suction flow is installed close to the shroud. An interference preventing recess(56h) is formed at an end of the blade of the shroud to maintain a predetermined interval with the blade even when the turbo fan is vibrated.

Description

Turbo Fan {TURBO FAN}

1 and 2 are a perspective view and an exploded perspective view showing an indoor unit for a frame-type air conditioner to which the turbofan is applied according to the present invention;

3 is a perspective view of each of the turbofans according to the present invention;

Figure 4 is a side view showing the installation structure of the turbofan and orifice in the portion A of Figure 2,

5 is a graph showing the suction flow rate and the noise during the operation of the turbofan in the prior art and the present invention.

<Explanation of symbols on main parts of the drawings>

10: case 12: air guide

14a, 14b, 14c: discharge grill 16: air filter

20: front panel 30: evaporator

32: drain pan 40: orifice

42: guide hole 44: control box

46: operation button 50: turbo fan

52: Hub 54: Shroud

56: blade 56h: interference prevention groove

60: motor 62: motor shaft

64: elastic material 66: motor support

The present invention relates to a turbo fan that sucks air in an axial direction and discharges it in a radial direction. In particular, the fan itself is shaken due to various factors in a state where it is installed in close proximity to an orifice for guiding suction flow in a space having a small axial height. The present invention relates to a turbofan capable of preventing a collision by maintaining a predetermined distance from the orifice even if it is.

In general, a turbo fan sucks air in an axial direction and discharges it in a radial direction. However, even when the height is low, the turbo fan has a relatively large amount of airflow, but the flow resistance is large as the flow is rapidly changed to 90 °, resulting in large noise. Such a turbofan is used in a indoor unit for a ceiling type air conditioner or an indoor unit for a frame type air conditioner because the installation amount is limited because the amount of air flow is large compared to the size of the fan itself.

Recently, the indoor unit for the frame type air conditioner is not only beautiful in terms of design, but also occupies a small installation space. Such an indoor unit for the frame type air conditioner is installed at the front of the thin rectangular parallelepiped case at the same time as the front panel on which various pictures are drawn. An evaporator and a turbo fan are built inward.

Specifically, looking at the configuration of the indoor unit for the frame-type air conditioner, the front panel is installed to open and close the front of the case is open, the inlet is formed between the case and the front panel at the same time the discharge port on both sides and bottom of the case Is formed, the inside of the case is installed so that the evaporator, the turbo fan and the motor overlap, an orifice is installed to guide the flow of air between the evaporator and the turbo fan.

In particular, the turbofan is composed of a hub connected to the motor for transmitting power and a ring-shaped shroud spaced apart from the shaft, and a plurality of blades arranged in the circumferential direction therebetween, The wood is installed facing the front panel.

Accordingly, as the turbo fan is operated, indoor air is sucked axially through the suction port, and the indoor air is cooled through heat exchange with a refrigerant while passing through the evaporator, and then sucked into the turbo fan by the orifice. The flow is guided.

Thereafter, the suction flow guided in the axial direction by the orifice flows radially through the shroud, the blade and the hub of the turbofan and is discharged through each discharge port.

However, the conventional turbofan applied to the indoor unit for the frame type air conditioner as described above is installed in close proximity to the orifice as the installation space is limited, because the diameter of the fan itself is formed at the same time as the axial height is thinner, the operation is unbalanced and Shake is easily generated due to external impact, and the like, and thus, collides with orifices installed in close proximity, thereby causing damage or noise of the fan itself.

The present invention has been made in order to solve the above problems of the prior art, even if installed in close proximity to the orifice for guiding suction flow in a limited space in the axial direction to maintain a certain interval to prevent the turbo fan and the collision with the orifice The purpose is to provide.

Turbo fan according to the present invention for solving the above problems is connected to the inner peripheral end of the motor shaft, the hub and the power, and the inner circumferential end and the outer circumferential end is formed gently between the hub and the axially spaced position is suction A shroud for guiding air radially from the axial direction, and a plurality of blades spaced in the circumferential direction so as to be perpendicular between the outer circumferential end of the hub and the outer circumferential end of the shroud so as to blow intake air radially; In the turbo fan, the turbo fan has an orifice for guiding suction flow is installed in close proximity to the shroud, and the interference prevention groove in the blade end of the shroud side to maintain a constant distance from the blade even if the turbo fan is vibrated Characterized in that formed.

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

1 and 2 are a perspective view and an exploded perspective view showing an indoor unit for a frame-type air conditioner to which a turbofan according to the present invention is applied, FIG. 3 is a perspective view showing a turbofan according to the present invention, and FIG. 4 is A of FIG. The side view shows the installation structure of the turbofan and the orifice in the part.

The indoor unit for the frame-type air conditioner to which the turbo fan is applied according to the present invention has a thin case 10 having a discharge opening formed at both sides and a bottom surface thereof at the same time as the front surface is opened to form an intake port, and the A front panel 20 installed on the front of the case 10 so as to be opened and closed, an evaporator 30 built in the case 10 and a refrigerant circulated therein, and located on a rear surface of the evaporator 30 to pass through the evaporator. An orifice 40 for guiding the cold air in the axial direction and partitioning the suction flow and the discharge flow, and is located on the rear of the orifice 40 to generate a blowing force to suck the indoor air from the suction port to the evaporator 30 After passing through, and comprises a turbo fan 50 and a motor 60 for discharging to the discharge port.

Of course, such an indoor unit 100 is installed to be connected to an outdoor unit (not shown) including an expansion unit such as a compressor, a condenser, a capillary tube, or an electronic expansion valve, and the refrigerant is connected to the compressor, the condenser, the expansion unit, and the evaporator 30. At the same time, the indoor air and outdoor air are blown to pass through the evaporator 30 and the condenser, respectively.

In more detail, looking at each component of the indoor unit 100, the case 10 is formed in the shape of a thin rectangular parallelepiped with the front open to form a receiving space for the various components therein, the inner corner The air guide 12 may be integrally formed to guide the suction flow flowing by the turbo fan 50.

At this time, the front panel 20 is installed on the front of the case 10 so that the internal components are not visible and the noise can be blocked so that indoor air can be sucked when the front panel 20 is opened. Discharge grills 14a, 14b, and 14c are installed on both side surfaces and the bottom surface of the case 10 to control the discharge direction, so that cold air is discharged through the discharge grills 14a, 14b and 14c.

In addition, an air filter 16 and a dust collector (not shown) are installed inside the front surface of the case 10 to filter dust and the like from the sucked indoor air, so that the air filter 16 and the dust collector can be cleaned. It is detachably mounted.

At this time, the air filter 16 is installed to slide between the guide projections (not shown) formed on both inner sides of the front of the case 10 is operated to filter foreign matter such as dust from the intake air, the dust collector It is installed to be fixed to the front of the air filter 16 is operated to collect dust and the like during power supply.

Next, the front panel 20 is installed so that the lower end is hinged to the front lower side of the case 10 so that the upper end can be opened and closed at a set angle, the hinge shaft is connected to the step motor (not shown) on both lower ends Can be opened and closed automatically.

In this case, the front panel 20 is positioned with a gap from the front surface of the case 10 so that the front panel 20 does not interfere with the front surface of the case 10 even though the front panel 20 is opened and closed.

Of course, the front panel 20 is composed of at least one panel may be installed so that each panel is horizontally installed and opened and closed at a set angle at the same time.

Next, the evaporator 30 is connected to the compressor, condenser, expansion means of the outdoor unit to configure a refrigeration cycle, a plurality of fins are installed in the refrigerant pipe is installed inside the case 10 front, The refrigerant passing through the refrigerant pipe causes heat exchange with the indoor air by a plurality of fins to generate cold air.

Of course, the evaporator 30 is formed in a thin rectangular parallelepiped shape so that the evaporator 30 may be installed inside the case 10, and the front shape is formed in a square shape like the case 10.

Next, the orifice 40 is formed with a guide hole 42 in the center convex ring shape to guide the suction air to the center of the turbo fan 50 so that turbulence does not occur, the portion other than the guide hole 42 Is formed flat to partition the cold air sucked into the turbo fan 50 and the cold air discharged through the turbo fan 50.

Mainly, the control box 44 for controlling the operation of the turbo fan 50 and the front panel 20 is installed on the front side of the orifice 40, and the motor for driving the turbo fan 50 ( 40) and the power supplied to the step motor for opening and closing the front panel 20 at a set angle, and also controls the power supplied to the dust collector.

Of course, the control box 44 is directly connected to various operation buttons 46 so that the user can directly operate the indoor unit, or configured to receive an operation control signal from a remote control, etc. It controls the operation of, and further connected to the display unit (not shown) to display the operation state of the indoor unit directly through the display unit for the user to see.

Next, the turbo fan 50 to suck the indoor air in the axial direction to discharge radially to pass through the evaporator 30, as shown in Figure 3, but also to be installed inside the case 10 While the thickness is formed to be thin, it is preferable to form a large diameter to increase the suction direction.

At this time, the turbo fan 50 is positioned so as to be spaced apart in the center of the disc-shaped hub 52 and the hub 52 in the axial direction so as to be connected to the motor 60, the shaft to guide the suction flow A ring-shaped shroud 54 gently slanted in a direction, and a plurality of blades 56 positioned at regular intervals in a circumferential direction between the hub 52 and the shroud 54, wherein the shra The wood 54 guides the suction flow in the axial direction, while the hub 52 and the blade 56 guide the discharge flow in the radial direction.

In particular, since the turbofan 50 has a large diameter and a thin thickness as shown in FIG. 3, shaking may occur due to factors such as unbalanced operation, external impact, and the like. It is installed at a predetermined distance from the orifice 40 in order to prevent from hitting the adjacent components, such as, for preventing interference at the end of each blade 56 of the shroud side located close to the guide hole 42 of the orifice The groove 56h is formed.

Of course, the interference preventing grooves 56h are formed to be small so as not to affect the blowing efficiency and the blowing amount when the turbo fan 50 is operated, but the interference preventing grooves 56h have depths of the blades 56. It is preferable to form so that it may become 10% or less of the height).

Therefore, even when the turbo fan 50 is installed close to the orifice 40 in a space limited in the axial direction, the turbo fan 50 and the orifice 40 are maintained at a predetermined interval by the interference preventing groove 56h. As shown in FIG. 4, the guide hole 42 of the orifice may be installed to be partially inserted into the turbofan 50, thereby providing an axial installation space of the turbofan 50 and the orifice 40. Further, the suction flow guided by the orifice 40 can be introduced directly into the turbo fan 50 to minimize the loss of the suction flow, thereby increasing the suction efficiency and reducing the noise.

In addition, the turbo fan 50 has an outer circumferential end of the hub 52 and an outer circumferential end of the shroud 54 in the axial direction than the inner circumferential end of the hub 52 and the inner circumferential end of the shroud 54, respectively. As the thickness is thinner, the height of the blade 56 is formed at the outer end than the inner end, so that the height of the outer end of the blade 56 is higher than the height of the inner end of the blade 56. It is formed to be higher.

At this time, even if the thickness of the hub 52 and the shroud 54 is thinner at the outer circumferential end than the inner circumferential end, the outer circumferential end thickness is 60 to 80 to the inner circumferential end thickness so as to stably fix the blade 56. Keep%.

Of course, the hub 52 and the shroud 54 may be formed so that the thickness thereof becomes gradually thinner from the inner circumferential end to the outer circumferential end, or may be formed so as to be stepped at least one or more times, and only the hub 52 and the shroud ( 54 only, both the hub 52 and shroud 54 may be formed thinner at the outer circumferential end than at the inner circumferential end.

Therefore, even if the turbo fan 50 is manufactured with limited axial height in order to install in an installation space limited in the axial direction, the thickness of the hub 52 and the shroud 54 is thinner at the outer circumferential end than at the inner circumferential end. Accordingly, the height of the blade 56 is higher at the outer end than the inner end, thereby increasing the size of the blade 56 compared with the conventional it can increase the amount of air blown by each blade 56.

On the other hand, in the turbo fan 50 as described above, in terms of blowing efficiency, the inner diameter of the shroud 54 is preferably larger than the outer diameter of the hub 52, but a pair of molds are engaged therebetween. Since the shroud 54, the hub 52 and the blade 56 is integrally injection molded, the inner diameter of the shroud 54 is at least equal to the outer diameter of the hub 52 due to a mold manufacturing problem. , Larger.

Next, the motor 60 is installed on the rear side of the turbo fan 50 so that the motor shaft 62 is fitted to the hub 52 to transmit power to the turbo fan 50, but the motor shaft An elastic material 64 is installed between the 62 and the hub 52 to absorb the vibration as well as to buffer the power transmission.

Of course, the turbo fan 50 is installed so that the shroud 54 faces the front surface of the case 10, and the motor 60 is attached to the motor support 66 on the inner rear surface of the case 10. It is installed to be fixed by.

5 is a graph showing the suction flow rate and the noise during the operation of the turbofan in the prior art and the present invention.

Looking at the suction flow rate and the noise in the conventional turbofan and the turbofan of the present invention respectively applied to the indoor unit for the frame-type air conditioner as described above, the conventional turbofan essentially maintains a constant distance from the orifice so as not to collide even if shaking occurs. On the other hand, the turbofan 50 of the present invention is installed to maintain a distance closer to the orifice 40 in consideration of the depth of the interference preventing groove 56h, as a result as shown in Figure 5 In the turbofan 50 of the present invention, the noise is reduced by about 2dB, that is, about 5% of the total noise, rather than the turbofan. This is the same even if the noise increases as the suction flow increases.

That is, the turbo fan 50 of the present invention can be installed closer to the orifice 40 than the conventional turbo fan, so that the suction flow flows directly into the fan to reduce the flow loss, thereby increasing the amount of suction air and reducing noise. Can be reduced.

In the above, the present invention has been described in detail by taking a turbo fan applied to the indoor unit for the frame type air conditioner based on the embodiments of the present invention and the accompanying drawings as an example. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the contents described in the claims below.

The turbofan according to the present invention configured as described above has a large diameter and a low height turbo because an interference preventing groove is formed at one end of the blade to maintain a constant distance with the orifice even when an orifice for guiding suction flow is installed in close proximity. Even if the fan is shaken by unbalanced operation or external impact, there is an advantage of preventing collision with the orifice and reducing damage and noise generated by the collision.

Claims (9)

A hub that the motor shaft is connected to the inner circumferential end to transmit power, A shroud that is gently formed between the inner circumferential end and the outer circumferential end at a position spaced axially from the hub to guide suction air radially from the axial direction; In the turbo fan comprising a plurality of blades installed in the circumferential direction so as to be perpendicular to the outer circumferential end of the hub and the outer circumferential end of the shroud to blow the suction air in a radial direction, The turbo fan is characterized in that the orifice for guiding the suction flow is installed in close proximity to the shroud, and the interference prevention groove is formed in the blade end of the shroud side to maintain a predetermined distance from the blade even if the turbo fan is vibrated. Turbofan. The method of claim 1, The interference preventing groove is a turbo fan, characterized in that the depth is formed to be less than 10% of the height of the blade. The method according to claim 1 or 2, Turbo outer fan characterized in that the outer peripheral end thickness of the shroud is formed thinner than the inner peripheral end thickness is greater than the inner end of the blade. The method of claim 3, wherein The shroud is formed so that the thickness gradually becomes thinner from the inner circumferential end to the outer circumferential end, the turbo fan, characterized in that the height becomes larger toward the outer end from the inner end of the blade. The method of claim 4, wherein The shroud is a turbo fan, characterized in that the outer peripheral thickness is formed to be 60 ~ 80% of the inner peripheral thickness. The method of claim 5, Turbo hub, characterized in that the outer peripheral end thickness of the hub is formed thinner than the inner peripheral end thickness is greater than the inner end of the blade. The method of claim 6, The hub is formed so that the thickness gradually becomes thinner from the inner circumferential end to the outer circumferential end, the turbo fan, characterized in that the height increases from the inner end of the blade to the outer end. The method of claim 7, wherein The hub is a turbo fan, characterized in that formed so that the outer peripheral thickness is 60 ~ 80% of the inner peripheral thickness. The method according to any one of claims 4 to 8, And the inner diameter of the shroud is at least equal to or larger than the outer diameter of the hub so that the shroud, the hub and the blade can be integrally formed.

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