KR100416780B1 - A fan housing - Google Patents

Abstract

The present invention relates to a fan housing in which a blower fan installed in a home appliance such as an air conditioner or a vacuum cleaner to generate a blowing force is installed therein, and particularly, prevents the generation of turbulence in the air discharged by the blower fan. The present invention relates to a fan housing in which the structure of the discharge port is improved.

The fan housing according to the present invention has a blower fan driven by a motor installed therein, and has a suction part formed on one side thereof, a hopper part extending from one side of the main body part to form a discharge hole, and an inner wall of the hopper part. A plurality of guides are formed to include a plurality of guides to suppress the generation of turbulence inside the discharge port.

Description

Fan housing {A fan housing}

The present invention relates to a fan housing in which a blower fan installed in a home appliance such as an air conditioner or a vacuum cleaner to generate a blowing force is installed therein, and particularly, prevents the generation of turbulence in the air discharged by the blower fan. The present invention relates to a fan housing in which the structure of the discharge port is improved.

In general, a blower is a device for generating a blowing force installed in household appliances or automobiles of air conditioners and vacuum cleaners, and includes a motor for generating driving force, a fan driven by the motor to generate air flow, and a fan. It includes a swirl fan housing for guiding the flow of air generated.

1 is a side cross-sectional view showing a fan housing according to the prior art.

The fan housing according to the prior art has a main body portion 2 formed in a circular shape so as to surround the blowing fan as shown in FIG. 1, and is formed to be biased to one side on the upper side of the main body portion 2, and the discharge area is gradually widened. It consists of a hopper portion 4 formed to be built.

Here, the main body portion 2 and the hopper portion 4 are integrally formed to communicate with each other, forming a front shape shown in FIG. 1, a front surface having a suction port at a center thereof, and the same shape as the front surface shape. It is composed of a rear surface arranged to maintain the gap, and a circumferential surface arranged to connect the ends of the front and rear surfaces excluding the upper surface to form the inner space of the fan housing, and the discharge port 4a is formed on the upper side.

In addition, the circumferential surface is formed with an edge at a portion connected to the front and back, the chamfered shape is formed in the corner formed on the front side of the main body portion 2, bar cut off this portion (6) This is to prevent the air discharged by the blowing fan 10 from colliding with the inner wall of the hopper part 4 by the centrifugal force to generate vortices.

In addition, the suction port formed on the front surface of the main body 2 is formed to be biased toward the side where the cutoff 6 is formed, and the blowing fan 10 and a motor (not shown) are installed inside the suction port.

Looking at the operation of the fan housing according to the prior art configured as described above are as follows.

First, when power is applied, the motor is driven to drive the blower fan 10 connected to the motor, and the air introduced through the suction port by the blower fan 10 is driven in the circumferential direction of the blower fan 10. The direction of movement is switched and moved to the hopper part 4 along the inner surface of the main body part 2 of the fan housing.

At this time, the discharged air is discharged to the discharge port 4a along the flow path gradually expanding from the cutoff 6 position, and then discharged outside the discharge port 4a while restoring dynamic pressure to the static pressure around the discharge port 4a. Will be.

However, in the fan housing according to the related art, since the air discharged along the discharge port 4a consisting of the hopper portion 4 is rotated along the circumferential surface of the blower fan, its direction of movement is converted into a straight line and discharged. After being moved along the circumferential surface of the blower fan, the air pushed into the discharge port 4a has a centrifugal force, so that the air farthest from the rotational center of the blower fan is discharged most quickly.

For this reason, the suction force is generated to move the air toward the faster discharge speed of the air is generated three-dimensional turbulence, thereby causing a problem that can not achieve a stable operation due to the increased noise.

The present invention has been made to solve the above problems of the prior art, a plurality of guides are formed to partition the inside of the discharge port in a direction parallel to the direction in which air is discharged, so that the discharged air is driven to one side in the discharge port The purpose of the present invention is to provide a fan housing that prevents the generation of three-dimensional turbulence, thereby improving the blowing efficiency of the fan and at the same time reducing the noise.

1 is a side view showing a fan housing according to the prior art,

2 is a side view of the fan housing according to the present invention.

<Explanation of symbols on main parts of the drawings>

52: body portion 54: hopper portion

56: cutoff 60: blowing fan

70: guide

The fan housing according to the present invention for solving the above problems is a blower fan driven by a motor is installed inside, the main body portion formed with a suction port on one side; A hopper part extending from one side of the main body part to form a discharge hole; A plurality of guides are formed on the inner wall of the hopper to suppress the generation of turbulence inside the discharge port, wherein the hopper is formed to be offset from one side from the upper side of the main body at the center of rotation of the blowing fan The far side is formed to extend vertically upward, the side close to the center of rotation of the blowing fan is characterized in that it extends upwardly inclined in the outward direction so that the discharge cross-sectional area gradually widens.

Hereinafter, an embodiment of the fan housing according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a side sectional view showing a fan housing according to the present invention.

The fan housing according to the present invention has a main body portion 52 formed in a circular shape so as to surround the blower fan 60, and is installed to be biased to one side on the upper portion of the main body portion 52 and the blower fan 60 in the main body portion 52. The hopper portion 54 is formed to gradually increase the discharge area in order to guide the air compressed by the) to be discharged to the upper side.

Here, the main body 52 and the hopper 54 are integrally formed to communicate with each other, and the front surface and the main body 52 and the hopper 54 are integrally formed as shown in FIG. It is formed in the same shape as the front surface and is arranged to maintain a constant there, and the circumferential surface to form the inside of the fan housing by connecting the ends of the front and rear, except the upper surface.

In addition, a corner is formed at a portion where the front surface and the rear surface contact the circumferential surface, and a bevel surface having a chamfered shape is formed at a corner formed on the front surface of the main body portion 52, which is referred to as a cutoff 56. The cutoff 56 prevents the air discharged by the blower fan 60 from colliding with the inner wall of the discharge port 54a by the centrifugal force to generate vortices.

The hopper 54 is formed to have a larger discharge area toward the upper side, one side is formed perpendicular to the circumferential surface of the main body 52, the other side is inclined outward and the one side It is formed in a hopper shape that is gradually moving away.

In addition, a plurality of guides 70 are formed in the hopper 54 so as to be parallel to the direction of the discharged air, so that the air discharge speed farthest from the rotation center of the blower fan 60 is different from that of other parts. The ejection force generated by the relatively high discharge speed prevents the discharged air from gathering to one side.

The guide 70 is formed of a plurality of bars, the guide 70 formed on the farthest side from the rotation center of the blowing fan 60 is disposed in the vertical direction, close to the rotation center of the blowing fan 60 It is arranged to form a stepped slope in the outward direction as it increases.

As a result, the air discharged after being rotated along the circumferential surface of the blower fan 60 is introduced between the guide 70 and the guide 70 regardless of the discharge speed thereof, so that the air discharged along each portion of the air is discharged from each other. It can be discharged without interference.

In addition, an air inlet of the fan housing is provided with a blower fan 60 for causing a flow of air and a motor connected to the blower fan 60 to generate a driving force.

Looking at the operation of the fan housing according to the present invention configured as described above are as follows.

First, when power is applied, the motor is driven to rotate the blower fan 60 so that air outside the suction port of the fan housing is introduced into the fan housing, and the introduced air is blown around by the blower fan 60 around the fan. The direction of movement is switched in the direction.

The air thus switched is pumped upward along the inner wall of the main body 52 of the fan housing and discharged to the outside through the hopper 54.

At this time, since a plurality of guides 70 are formed on the inner wall of the hopper part 54, the discharged air flows into and discharged between the guide 70 and the guide 70, so that the air passing through the respective portions is mutually different. Since it does not interfere with the generation of turbulence, it is possible to achieve stable operation in which the blowing efficiency is improved and noise is also reduced.

In the fan housing according to the present invention configured as described above, since a plurality of guides are formed inside the discharge port, the air discharged after being rotated along the circumferential surface of the blower fan is introduced into the guide and the guide and discharged while being linearly moved. Since the air discharged along the part does not cause interference with each other, the generation of turbulence is suppressed, and thus the blowing efficiency is improved, and the noise is also reduced, thereby achieving a stable operation.

Claims (5)

A main body unit having a blowing fan driven by the motor and having a suction port formed at one side thereof; A hopper part extending from one side of the main body part to form a discharge hole; It is configured to include a plurality of guides are formed on the inner wall of the hopper portion to suppress the generation of turbulence inside the discharge port, The hopper portion is formed to be biased toward one side from the upper side of the main body portion, the side farther from the rotation center of the blower fan is formed to extend vertically upward, the side closer to the rotation center of the blower fan has a gradually wider cross-sectional area Fan housing, characterized in that the inclined in the outward direction to extend to extend upward. delete delete delete delete