KR200248773Y1 - Fan and Shroud Assembly - Google Patents

Abstract

Disclosed is a fan and shroud assembly. The fan and shroud assembly according to the present invention includes a fan having a plurality of blades and a shroud having a housing portion formed along a rotational trajectory of the blade end. It is characterized in that a plurality of rubles having a predetermined length and a predetermined thickness in the radial direction are provided at an end portion of the discharge side. By adopting the present invention, the weight is significant and the noise is reduced.

Description

Fan and shroud assembly

1 is a cross-sectional view of a conventional fan and shroud assembly,

2 is a cross-sectional view showing a conventional airflow guide,

3 is a cross-sectional view showing the airflow guide according to the present invention,

4 is a side view seen from the direction (a) of FIG.

5 is a cross-sectional view showing another embodiment of the airflow guide.

* Explanation of symbols for main parts of the drawings

30,40: shroud 31,41: fan

32,46: Blade 33,43: Band

34,44 housing part 35,42 rib

36,45: air flow guide

The present invention relates to an assembly of a fan and a shroud, and more particularly, to an assembly of a fan and a shroud having an improved structure of the shroud.

Typically, the fan and shroud assembly is combined with a fan mounted in the heat exchanger to generate air flow to the heat exchanger, and a shroud for guiding the flow of air while preventing recirculation of air generated from the fan.

A typical fan and shroud assembly is a fan 10 and a shroud 20, as shown in FIG. 1, wherein the fan 10 is coupled to a rotating shaft of an electric motor or an engine ( 11) and a plurality of blades 12 provided on the outer circumferential surface of the hub 11. And the shroud 20 is a housing portion 71 surrounding a portion adjacent to the blade 12 end of the fan 10 with a predetermined width, and a predetermined distance from the housing portion 21, the fan ( 10) and a plurality of stators 23 for connecting the motor support 22 located on the same axis.

In the fan and shroud assembly configured as described above, as the fan 210 rotates, air flows from the low pressure side (inflow side) to the high compression (discharge side) as shown in FIG. 2. The flow is relatively complicated. .

That is, as the fan 210 rotates, the blade 211 is driven in an inclined direction with respect to the axis, thereby generating air flow.

Therefore, the airflow discharged by the blade 211 of the fan has an axial component and a rotational component, and the component in the rotational direction becomes larger from the center of the fan 210 toward the end of the blade 211. The airflow discharged to the edge of the fan is discharged at a predetermined angle outward with respect to the axial direction so that it hits the inner surface of the housing portion 201 of the shroud 200, and furthermore, the air generated from the fan 210. It generates a large static pressure that impedes wind power.

The generation of such static pressure not only lowers the blowing efficiency of the fan 210 but also causes noise.

In addition, the turbulent streamline generated at the end of the bleed is directly transmitted to the front of the heat exchanger, thereby causing a loss of flow and generating noise due to the turbulent airflow.

The present invention has been devised to solve the above problems, the fan and shroud to prevent the flow loss caused by the flow of turbulent stream generated at the blade end directly to the front of the heat exchanger and to reduce the noise due to the turbulent air flow It is an object to provide an assembly.

In order to achieve the above object, the present invention provides a fan and shroud assembly comprising a fan having a plurality of blades and a shroud having a housing portion formed along a rotational trajectory of the blade end. A plurality of ribs are formed on the wall at a predetermined thickness and a predetermined length in the radial direction.

In the present invention, the air flow guide portion bent from the discharge side end to the blade end side is formed at the discharge port side of the housing part.

Hereinafter, a preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view showing an airflow guide according to the present invention, FIG. 4 is a side view seen from the direction (a) of FIG. 3, and FIG. 5 is a cross-sectional view showing another embodiment of the airflow guide.

Fan and shroud assembly according to the present invention consists of a fan (31,41) and a shroud (30,40), the fan (31,41) has a hub coupled to the rotation axis of the motor and the outer peripheral surface of the hub A plurality of blades 32 and 46 are installed at equal intervals, and bands 33 and 43 are connected to ends of the blades 32 and 46 to connect them to each other.

A fan having a plurality of blades (32, 46) is mounted to the heat exchanger to generate air flow to the heat exchanger, the shroud (30, 40) blades 32 along the rotational trajectory of the ends of the blades (32, 46) The housing portions 34 and 44 are formed so as not to contact the 46.

A plurality of ribs 35 and 42 are formed on the inner wall surfaces of the housing parts 34 and 44 in a radial direction at a predetermined length and a predetermined thickness, and guide air flow formed by the blades 32 and 46 toward the heat exchanger. The airflow guides 36 and 45 are bent from the inner wall surface of the housing portion to the end portions of the blades 32 and 46.

The airflow guides 36 and 45 are inclined toward the discharge side of the fans 31 and 41 with respect to the rotation shafts of the fans 31 and 41 at a predetermined angle, and the starting point is below the ends of the blades 32 and 46. Characterized in that located.

The fan and shroud assembly having the structure as described above functions as follows.

Conventional fans and shroud assemblies generate turbulent streamlines at the blade ends of the fans, so that turbulent flow is delivered directly to the front of the heat exchanger, resulting in flow losses and noise. The plurality of ribs 35 and 42 installed on the extension lines of the airflow guides 36 and 45 make the turbulent streamline formed at the ends of the blades 32 and 46 into laminar flow, thereby maintaining a constant amount of parallel flow of the fluid flowing into the heat exchanger in a predetermined direction. Create airflow

Turbulence is less efficient due to unpredictable directions and associated energy losses.

However, the current flow is more efficient and significant than turbulent flow because the direction is constant and predictable and a certain amount is concentrated in one direction.

In addition, turbulent flow is larger than laminar flow, so it is inadequate compared to laminar flow where it concentrates the air volume.

As described above, the shroud assembly according to the present invention has the following effects.

First, the air volume increases.

A plurality of ribs installed at the shroud exit make the turbulent stream stream into the airflow and make the airflow flowing in the heat exchanger into the parallel airflow, thus increasing the increase in volume. .

Second, the noise is reduced.

Due to the action of the ribs, the airflow is reduced from turbulent flows in which the flow is indefinite to a constant flow in a predetermined amount in a predictable direction, thereby reducing noise. In the embodiment according to the present invention, the noise is reduced to 0.3 to 0 5 decibels (dB) compared with the conventional one.

Third, it is advantageous to strengthen the strength and secure the source.

Ribs, which convert turbulent flows into air currents, also play a role of strength reinforcement, and are advantageous for securing a fluid source that supplies sufficient fluid at a significant increase.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. . Therefore, the true technical protection scope of the present invention should be defined by the technical spirit of the appended claims.

Claims (4)

Shrouds 30 and 40 having fans 31 and 41 having a plurality of blades 32 and 46 and housing parts 34 and 44 formed along a rotational trajectory of the ends of the blades 32 and 46. In the assembly of the fan and shroud comprising a plurality of ribs (35, 42) formed on the inner wall surface of the housing portion (34, 44) to a predetermined thickness and a predetermined length in the radial direction. Fan and shroud assembly. The housing parts 34 and 44 are provided with airflow guides 36 and 45 formed on the discharge port side of the housing parts 34 and 44 by bending from the discharge end to the blade 32 and 46 end. Fan and shroud assembly. The airflow guide (36,45) is a fan and shroud assembly, characterized in that inclined toward the discharge side of the fan (31,41) with respect to the rotation axis of the fan (31,41) at a predetermined angle. The airflow guide (36,45) is a fan and shroud assembly, characterized in that the starting point is located below the end of the blade (32,46).