KR100480872B1 - Fan filter unit - Google Patents

Abstract

The present invention relates to a fan filter unit, comprising: a fan filter unit in which a fan and a filter are integrally integrated with each fan housing mounted on a partition frame of a system ceiling formed of a partition frame in a clean room. A fan guide having wall surfaces spaced apart from each other in a circumferential direction thereof is disposed, and a vortex region generated at the fan guide wall surface by suppressing collision waves generated at upper and lower ends of the fan guide guiding the flow of air discharged by the fan. The strips are arranged to be spaced apart at both upper and lower ends of the fan guide so as to reduce the vortices. It creates a smooth flow of air and increases the air volume while preventing noise It was so.

Description

Fan filter unit

The present invention is a fan filter for a clean room that blows the purified air to a clean room such as an electronics assembly room, a semiconductor assembly room, a hospital operating room, a sterile room, a bacterial culture room, etc. It's about the unit.

In general, in a clean room such as a hospital or a semiconductor manufacturing factory, a conventional fan filter unit (FFU) method and a pressurized ceiling chamber method are mainly used. Fig. 1 is a configuration diagram of a conventional fan filter unit method. The clean room 2 in) has a system ceiling 3 formed of the partition frame 5. The fan filter unit 16, which is a combination of the filter 14 and the blower fan 13, is incorporated in a rectangular fan housing 15 formed by the partition frame 5 of the system ceiling 3. have.

The blowing fan 13 of the fan filter unit 16 sucks air in the ceiling 17 and supplies it to the clean room 2 through the filter 14. The air in the clean room 2 flows to the bottom of the floor through the free access floor 4 and is also dehumidified through the dry coil 9, flows through the return space 12 and returns to the ceiling interior 17 to circulate. . In this FFU method, since the air inside the ceiling 17 is sucked by each blower fan 13 provided in the ceiling, the ceiling 17 is negative for the surroundings.

In such an FFU system, since the inside of the ceiling 17 is a negative pressure, the air in the ceiling does not pass through the filter due to the leakage of the portion of the partition frame 5 of each fan housing 15,... By ensuring that nothing flows in, cleanliness in the clean room 2 is reliably maintained. Therefore, regarding the sealing property between the filter 14 and the partition frame 5, there is no problem of leaking to the clean room 2 side even if there is some gap.

Moreover, since a fan is provided for each fan housing 15, only the individual blower fan 13 is stopped and the filter 14 is replaced without stopping the operation of the whole clean room 2 in the case of filter replacement. As a result, the operation rate of the clean room 2 is increased and the usability is improved.

However, as mentioned above, since the inside of the ceiling becomes a negative pressure with respect to the clean room 2, the cleanliness of the clean room 2 can be maintained reliably, and an individual filter is performed without stopping the operation of the whole clean room. (14) While having the advantage of being able to carry out an exchange, etc., since the use of a plurality of blower fans 13, the energy efficiency is bad, as a whole, consumes a lot of power and a large number of fans in the ceiling Since the noise of one fan is small because it is provided, there is a problem such that the combined noise of a plurality of fans is excessively large.

In other words, in the conventional fan filter unit, as shown in FIG. 2, the snail-shaped fan guide surrounds the periphery of the fan, and when the motor rotates, the flow form in the fan guide that guides the air to be sucked and discharged is a fan. The vortices caused by the interference of the flow wind on the upper and lower ends of the wall surface of the guide and the separation of the flow from the fan guide wall are generated. As a result, the core region, in which the fluid flows smoothly, that is, the high-speed flow region is reduced to generate noise along with the decrease in the air volume.

Accordingly, the present invention has been made in view of the above-described concerns, and an object of the present invention is to provide strips with a predetermined distance spaced apart from each other on the upper and lower ends of the wall along the wall of the fan guide, and the upper and lower ends of the wall of the fan guide. Even if the output of the motor in the fan filter unit is reduced by preventing the eddy current caused by the maximum force, reducing the boundary layer thickness of the wall of the fan guide wall, and thereby limiting the noise generation while increasing the air volume in the fan guide, The present invention provides a fan filter unit capable of maintaining a filtering air flow amount, thereby allowing a low power type and a low noise type fan filter unit to be derived.

In other words, the fan guide is guided by the lower side of the suction grill which forms the fan guide and the upper and lower parts of the fan at the center side of the fan guide, and the flowing air inclined by the fan while the air pressure is concentrated on the upper side of the filter. Noise is generated based on collision waves generated at the upper and lower ends of the wall of the fan guide due to the air pressure concentrated at the upper and lower ends of the fan guide, and the flow rate of the air discharged by the fan decreases due to the collision wave. The outbreak involved design difficulties in that measures such as increasing the speed of the fan must be taken.

In order to realize this, the present invention,

In a fan filter unit in which a fan and a filter are integrated with each fan housing mounted on a partition frame of a system ceiling formed as a partition frame in a clean room,

A fan guide having a wall surface spaced apart from the circumferential direction toward the periphery of the fan,

Characterized in that the strips are spaced apart in the upper and lower ends of the fan guide to reduce the vortex wave generated in the upper and lower ends of the fan guide for guiding the flow of air discharged by the fan to reduce the vortex area generated on the wall of the fan guide do.

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

In the description of the present invention, the same or equivalent parts as in the prior art will be described with the same reference numerals.

5 is an internal configuration corresponding to FIG. 3 of the fan filter unit according to an embodiment of the present invention, FIG. 6 is a cross-sectional view taken along the line BB of FIG. 5, and FIG. 7 is a detailed view of the fan and the fan guide in FIG. 6. 8 is a detailed perspective view illustrating the fan guide of the fan filter unit according to the second embodiment of the present invention.

The fan filter unit of the present application is a part of the clean room 2 filtering unit which is installed on the ceiling of the clean room 2 and supplies purified air to the clean room 2, and minimizes the air flow resistance in the fan filter unit. The airflow noise is minimized and the power consumption of the motor is reduced.

The fan filter unit 20 includes a fan housing 21, a grille 22, a filter 23, and a fan in a partition frame 5 provided in a grid like a checkerboard on the ceiling of the clean room 2. ) And the motor (M).

In addition, in the clean room fan filter unit 20, the fan guide 30 is provided to surround the fan 25 to guide the flow of air discharged by the fan 25 with a minimum of resistance.

In addition, the fan guide 30 is configured to have a wall surface 31 spaced apart from the periphery of the fan 25 toward the circumferential direction.

In addition, at both upper and lower ends of the fan guide 30, collision waves generated at both upper and lower ends of the fan guide 30 for guiding the flow of the air discharged by the fan 25 are suppressed, The strips 40 are spaced apart so that the generated vortex area is reduced.

In addition, the space | interval of the said strip 40 is formed at 1.3-1.5 times the height of a fan discharge port side in consideration of the flow spreading until air flow reaches a housing wall surface after fan discharge.

In addition, the protrusion width t of the strip 40 starting from the wall surface of the fan guide 30 is configured to increase at a predetermined ratio toward the discharge portion side of the fan guide 30 (see Fig. 8).

Next, the operation of the fan filter unit according to the present invention will be described.

First, when the fan 25 is driven by applying power to the FFU, air intake and discharge flows are generated.

When air is discharged in a direction orthogonal to the rotational axis of the fan 25, the air flows toward the discharge portion of the fan guide 30 while rotating along the wall surface of the fan guide 30 surrounding the fan 25. The primary flow F1 is generated.

In addition, by adopting the configuration of the strip 40 of the present invention it is possible to increase the blowing efficiency inherent to the fan filter unit by suppressing the vortex movement of the upper and lower ends of the fan guide 30.

Here, the outflow to the upper and lower sides of the axial fan guide 30 of the fan in order to increase the primary flow amount (F1) to rotate the flow direction in the fan guide 30 along the wall surface of the fan guide 30 By suppressing the secondary flow amount F2 through the strip 40, it is possible to regulate the vortices that occur intensively in the upper and lower spaces of the fan guide 30, in particular, on the upper and lower ends of the wall surface of the fan guide 30. Will be.

In other words, the air discharged from the discharge port 25a of the fan 25 hits the primary air flow F1 flowing in the direction along the wall of the fan guide 30 and the wall of the fan guide 30, and then the primary air. At a predetermined angle with the air flow (F1), a secondary air flow (F2) that flows to the upper and lower space of the fan guide 30 occurs, at this time, flows into the upper and lower space on the wall surface side of the fan guide 30 In the prior art without a configuration capable of regulating the secondary air flow (F2), strong air collision waves are generated in the vertical space of the fan guide 30, especially on the upper and lower ends of the wall surface of the fan guide 30, thereby causing a strong impact. Vortex occurs.

Therefore, the air flow loss can be reduced by the strip 40. The distance S between the strips 40 at the discharge portion 33 of the fan guide 30 is greater than the height of the fan discharge port side. When air is discharged, the flow causes diffusion by the viscous effect of the air guide of the strip 40. As a result, the flow of the secondary air F2 flowing into the upper and lower portions of the fan guide 30 is switched to the flow direction of the primary air F1, and as a result, the rotation flow along the wall surface of the fan guide 30 is performed. The flow rate of the primary air F1 is increased to improve the flow uniformity of the fan filter unit 20, and the secondary air flow rate F2 is reduced by the reduction of the secondary air flow amount F2 discharged to the fan housing side. F2) will have an improved effect of reducing the noise generated by the impact on the upper and lower surfaces of the fan housing (21).

In other words, by reducing the vortices generated at the upper and lower ends of the wall of the fan guide 30 to reduce the boundary layer area on the wall of the fan guide 30, at the same time, the separation of the primary flow (F1) is suppressed to form a smooth flow of fluid. In order to increase the volume of air at the same time to prevent the occurrence of noise.

As described above, the present invention, by providing a strip in the fan guide for guiding the flow of the fan discharge air, to increase the primary air flow rate to rotate the flow along the wall of the fan guide, There is a very excellent effect that the noise generated by the impact wave with the casing of the fan filter unit due to the uniformity and the air flow discharged to the region other than the guide region of the fan guide can be eliminated as much as possible.

Herein, while the invention has been illustrated and described in connection with one embodiment of the invention, various modifications may be made by those skilled in the art without departing from the spirit and scope of the claims.

1 is a plan view of a conventional fan filter unit for a clean room,

2 is an internal configuration of a fan filter unit for a conventional clean room,

3 is a view illustrating an internal configuration of a state in which a top plate and a grill of a fan filter unit are removed in FIG. 1 according to the related art;

4 is a cross-sectional view taken along the line A-A of FIG.

Figure 5 is an internal configuration corresponding to Figure 3 of the fan filter unit according to an embodiment of the present invention,

6 is a cross-sectional view taken along the line B-B of FIG.

Figure 7 is a detailed perspective view for showing the fan and the fan guide in detail in Figure 6, and

8 is a plan view showing a fan guide of the fan filter unit according to the second embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

  20: fan filter unit 21: fan housing

  22: grill 23: filter

  25: fan 30: fan guide

  31 wall 40 strip

Claims (3)

In a fan filter unit in which a fan and a filter are integrated with each fan housing mounted on a partition frame of a system ceiling formed as a partition frame in a clean room, A fan guide having a wall surface spaced apart from the circumferential direction toward the periphery of the fan, Strips are spaced on both upper and lower ends of the fan guide so as to reduce the vortex wave generated at the upper and lower ends of the fan guide for guiding the flow of air discharged by the fan, thereby reducing the vortex area occurring at the wall of the fan guide. The projecting width of the strip is a fan filter unit, characterized in that formed to increase toward the discharge port side of the fan guide, starting from the wall surface of the fan guide. The method of claim 1, The spacing of the strip is a fan filter unit, characterized in that formed by 1.3 to 1.5 times the height of the fan discharge port in consideration of the diffusion of air until the air flow reaches the housing wall surface after discharging the fan. delete