KR100264350B1 - The structure of shroud for Air-absorption device - Google Patents

Abstract

PURPOSE: Shroud structure of an air suction system is provided to reduce a vortex of air and to increase running of a fan by promoting air turbulence with a groove formed on a sidewall of a shroud. CONSTITUTION: A shroud(103) is mounted in a circumferential direction of a fan(101) to prevent discharge air from flowing back as well as to protect the fan. To promote air turbulence, a radial groove is formed on a sidewall of the shroud. The radial groove has specific width and depth in a radial direction from the center of the shroud. Preferably, the radial groove has width of 0.2-10 degrees from the center of the shroud and depth of 0.1t-0.7t wherein the t is the thickness of the shroud. When a motor(102) is driven, the fan is rotated to suck air with force. The sucked air is discharged again after performing specific function. Most of the air is discharged through the fan but the air between the fan and the shroud generates a vortex by partial pressure difference. Air turbulence is promoted by the radial groove. Therefore, the vortex of air is offset by the turbulence through the radial groove.

Description

The structure of shroud for air-absorption device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air intake apparatus for use in a separate or window type air conditioner, and more particularly, to a structure of a shroud for forming turbulence in inducing and inducing air.

Conventionally, the air suction device is used in a separate type or window type air conditioner and the like, and its structure is a fan 1 for forcibly sucking air by rotation and a motor for driving the fan 1 as shown in FIG. 2) and a shroud 3 formed outside thereof in the circumferential direction of the fan 1 to protect the fan 1 and to prevent the backflow of discharged air.

When power is applied to the motor 2 in the state configured as described above, the motor 2 is driven to rotate the fan 1, and the air is accelerated by the suction force according to the rotation of the fan 1 and discharged at a high speed. do.

At this time, the air discharged by the fan 1 passes through a heat exchanger (not shown in the drawing) inside the apparatus to gain or lose heat.

On the other hand, the fluid flowing through the heat exchanger is input to other elements of the system in the state of losing or obtaining heat from the air to perform cooling or heating.

At this time, most of the air is discharged through the fan 1, but as shown in Figure 2, the side wall of the shroud (3) close to the fan 1 has a predetermined inclination angle, the fan 1 and the shroud (3) The air passing between) generates a swirl recirculation area due to the pressure difference between the fan 1 and the shroud 3 and elsewhere.

Since the air recirculation flow acts as a resistance to the smooth air flow, there was a problem that causes a decrease in flow rate and noise.

In view of this point, the present invention forms a groove in the side wall portion of the shroud where the vortex is formed until the air is induced and discharged to promote turbulence of the air, thereby reducing the size of the vortex flow of the air and increasing the flow rate of the fan. The purpose is to prevent noise.

1 is a block diagram of a conventional air intake device.

2 is an operation diagram of a conventional air intake device,

A side view.

(B) is front view.

3 is a block diagram of an air intake apparatus according to the present invention.

4 is a shroud of the air intake apparatus according to the present invention,

(A) Front view.

(B) is A-A 'section of (a).

(C) is a detail view of Part B of (B).

*** Explanation of symbols for the main parts of the drawing ***

101: fan 102: motor

103: shroud 104: spinning groove

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

3 is a configuration diagram of an air intake device according to the present invention, which includes a fan 101 for forcibly inhaling air by rotation, a motor 102 for driving the fan 101, and a fan 101. It is composed of a shroud 103 formed on the outside in the circumferential direction of the fan 101 to protect and prevent the reverse flow of the discharged air.

In addition, on the side wall of the shroud 103 where contact is made until the air is guided and discharged, a predetermined direction in the radial direction from the center of rotation of the fan 1, that is, the center of the shroud 103, to promote turbulence of air. The spinning groove 104 having a width and a depth is formed.

In addition, the width of the radiation groove 104 is configured to be located between 0.2 ° to 10 ° centered around the center of the shroud 103, the depth of the concentric groove 104 is the thickness of the shroud 103 If t is configured to be between 0.1t and 0.7t.

When power is applied to the motor 102 in the state configured as described above and the motor 102 is driven, the fan 101 rotates to force suction of air.

The air sucked in this way is discharged to the outside of the device again after performing a certain role, most of the air is discharged through the fan 101, but the air passing between the fan 101 and the shroud 103 is the fan 101 The vortex recirculation region is generated by the pressure difference between the and shroud 103 and other portions, which acts as a resistance to smooth air flow.

Embodiment according to the present invention is to improve the efficiency by reducing the recirculation area of the air, the fan on the side wall of the shroud 103 in contact with the air in the process of induction of air between the fan 101 and the shroud 103 Swirl by forming a spinning groove 104 having a predetermined width and depth in the radial direction with respect to the center of rotation of the 101 or the center of the shroud, and promoting turbulence of air by the spinning groove 104. The recirculating flow of the shape is to be offset by turbulence by the spinning groove 104.

Here, the width of the spinning groove 104, which was experimentally calculated as the best case for the turbulence formation of the discharged air in the recirculation area of the air, is between the radiation angles of 0.2 ° to 10 ° with respect to the center of the shroud 103. It is preferable to form, and the depth of the radiating groove 104 is formed so as to form a range of depth of 0.1t ~ 0.7t when the thickness of the shroud 103 is t to implement a more improved air intake device It becomes possible.

As described above, the present invention has a plurality of radially formed on the side wall of the shroud which is contacted in the process of introducing air through the fan and the shroud in the radial direction with respect to the rotation center of the fan, that is, the central center of the shroud. The turbulence of the air induced by the formation of the spin groove is promoted, and in the induction process, the swirl recirculating flow area of the air is reduced by the effect of turbulence, so that the air flows smoothly, and thus the amount of air flow It is increased, and the noise is also reduced.

Claims (3)

A motor driven by an applied power source; A fan that rotates by driving of the motor to forcibly suck outside air; In the circumferential direction of the fan spaced apart at regular intervals to form a predetermined shape and a shroud formed to protect the fan in the form of an extended plate and to prevent the backflow of the discharge air; Shroud structure of the air intake device, characterized in that a radial groove having a predetermined width and depth in the radial direction from the center of rotation of the fan on the side wall of the shroud having a predetermined inclination angle close to the drive of the fan. The method of claim 1, The angle formed by the width of the radial groove is the shroud structure of the air intake device, characterized in that 0.2 to 10 ° from the center of the center of the shroud. The method of claim 1, Shroud structure of the air intake device, characterized in that the depth of the radial groove is between 0.1 times to 0.7 times the thickness of the shroud.

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