KR101170160B1 - Local ventilator with swirler - Google Patents

Abstract

PURPOSE: A swirl type local ventilation device is provided to prevent a warm current generation and an exhaust pressure loss due to a gap between a hood and swirler because the hood and swirler formed into one body rotate together. CONSTITUTION: A swirl type local ventilation device comprises a swirler(110) and driving unit(120). The swirler is installed in an intake end of a vent pipe, thereby generating a swirl. The swirler comprises a hood member(111) of a disc shape and a plurality of blades(112). The blades are arranged along an outer side edge of the hood member, thereby forming the spiral while rotating with the hood member. The driving unit is connected to the swirler, thereby rotating the swirler.

Description

Local ventilator with swirler

The present invention relates to a local exhaust device for sucking and discharging contaminated air to the outside. More particularly, the present invention relates to a vortex type local exhaust device for expanding an exhaust area and improving exhaust efficiency by forming a vortex using a rotary swirler. It is about.

Local exhaust systems are generally used in factories, homes, restaurants, etc., where pollutants are generated a lot, especially when partial pollutants are generated on the floor away from the exhaust vents or by other installations. In this case, it can be usefully used when pollutant occurs instantaneously.

However, the conventional local exhaust apparatus used for this purpose had various problems. That is, in the conventional local exhaust device, the efficiency of inhaling and removing pollutants rapidly decreases as the source of contamination is farther from the exhaust pipe. Therefore, the local exhaust device is preferably installed as close as possible to the location of the pollutant. And there is a limitation in the installation conditions because it interferes with the movement of the workers.

In order to supplement the problems of the conventional local exhaust device, local exhaust devices have been developed to expand the exhaust area by using the vortex (vortex), and the vortex type local exhaust device is Korean Patent No. 10-0529002, No. 10. -0821295, 10-0873521 and 10-0873522. The vortex type local exhaust device has a configuration in which a rotary swirler is installed on the inlet side of the exhaust pipe.As the swirler rotates, a donut-shaped vortex is generated around the exhaust pipe, thereby contaminating the contaminated air in a larger area. Inhalation into the exhaust duct more efficiently.

As described above, the vortex type local exhaust device is installed on the inlet side of the exhaust pipe, and is generally used with a conventional hood to further increase the effect.

FIG. 1 shows a conventional vortex type local exhaust system having a swirler with a hat-shaped hood.

Referring to Figure 1, the lower suction port side of the exhaust pipe 10 is provided with a hatch shaped hood 20 and a swirler 30 to form a vortex. Hood 20 is fixed to the lower end of the exhaust pipe 10, the swirler 30 is connected to the rotation shaft 43 of the drive motor 41 is installed to be rotatable. The drive motor 41 is installed inside the exhaust pipe 10 by the support 42. The swirler 30 includes a rotating plate 31 rotated by the drive motor 41 and a plurality of wings 32 attached along the outer edge of the rotating plate 31.

In the state where the exhaust operation through the exhaust pipe 10 is being performed, when the rotating plate 31 of the swirler 30 rotates, the vanes 32 blow air from the inside of the rotating plate 31 in the radial direction outside of the rotating plate 31. To the side. In addition, the exhaust pipe 10 draws not only the contaminated air but also air around the exhaust pipe 10 and the inside of the rotary plate 31. Due to the flow of air, a donut-shaped vortex F1 is formed at the lower portion of the rotating plate 31. The vortic flow F1 formed as described above divides a region where pollutants are generated and a region where no pollutants are generated. It will act as an air curtain.

By the way, since the hood 20 is fixed to the exhaust pipe 10 and the swirler 30 is to be rotatable, a predetermined gap is formed between the hood 20 and the swirler 30. Accordingly, vortices F1 are formed on the lower both sides of the swirler 30 by the vanes 32, and the normal exhaust flow F2 from the exhaust area toward the exhaust pipe 10 is formed at the lower center of the swirler 30. ) Is formed, as well as the air flow F3 through the gap between the hood 20 and the swirler 30.

This air flow F3 causes a loss of the exhaust pressure of the exhaust pipe 10, and at the edge portion A of the hood 20 collides with the vortex F1 to generate turbulent flow, thereby forming a smooth vortex F1. There is a problem that not only decreases the exhaust efficiency by obstructing, but also increases noise while passing a narrow gap between the fixed hood 20 and the rotating swirler 30.

Patent Document 1: Republic of Korea Patent Registration No. 10-0529002 (2005. 11. 09. registered) Patent Document 2: Republic of Korea Patent No. 10-0821295 (2008. 04. 03. registration) Patent Document 3: Republic of Korea Patent No. 10-0873521 (2008. 12. 04. registration) Patent Document 4: Republic of Korea Patent No. 10-0873522 (Dec. 4, 2008 registration)

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems as described above, and an object thereof is to provide a vortex type local exhaust device having an improved exhaust efficiency by integrally forming a hood and a swirler.

In order to achieve the above technical problem, according to an aspect of the present invention,

A swirler installed at an inlet end of the exhaust pipe and rotating to generate a vortex; And a driving part installed at the exhaust pipe and connected to the swirler to rotate the swirler.

The swirler may include a hood member having a disc shape and formed in a groove shape in which an air inflow side is concave; It is installed on the air inlet side of the hood member, disposed along the outer edge of the hood member, a plurality of wings to form a vortex while rotating with the hood member; includes;

The air inflow side surface of the hood member is composed of a planar portion of the center region and an inclined surface portion of the outer edge region, each of the plurality of wings is provided with a vortex type local exhaust device, characterized in that installed in close contact with the inclined surface portion.

In addition, the inclined surface portion may be inclined to gradually increase in diameter toward the exhaust region.

In addition, an air suction hole communicating with the exhaust pipe may be formed in a central region of the hood member, the flat portion may be formed around the air suction hole, and the inclined surface portion may be formed along the periphery of the flat portion.

In addition, each of the plurality of wings may have a shape extending from the air inlet side surface of the hood member in the radial direction.

In addition, the height of each of the plurality of wings may be equal to the depth of the air inlet side of the hood member.

In addition, each of the plurality of wings may be formed over the inclined surface portion and the planar portion.

In addition, each of the plurality of wings may extend in the radial direction from the inclined surface portion to a portion of the flat portion.

In addition, a plurality of wing installation grooves are formed in the inclined surface portion of the hood member to extend radially and penetrate to the outer surface of the hood member, and the plurality of wings may be inserted into the plurality of wing installation grooves, respectively. .

According to the vortex type local exhaust device according to the embodiment of the present invention, since the hood and the swirler are integrally formed and rotate together, there is no gap between the hood and the swirler. Accordingly, the loss of exhaust pressure due to the gap between the hood and the swirler and the generation of turbulence are prevented, so that a smooth vortex is formed, thereby improving the exhaust efficiency, and the noise caused by the air flow through the gap. There is an advantage that can be prevented.

In addition, since the air inlet side edge portion of the hood member of the swirler is formed as an inclined surface, the flow of air forming the vortex is induced to be inclined toward the exhaust region, so that the generated vortex has a longer shape toward the exhaust region. . Therefore, there is an advantage that the contaminated air far from the exhaust pipe can be more easily sucked into the exhaust pipe.

1 is a cross-sectional view showing a conventional vortex type local exhaust device having a swirler with a hat shaped hood.
2 is a cross-sectional view showing a vortex type local exhaust device according to an embodiment of the present invention.
3 is a perspective view illustrating the bottom of the swirler illustrated in FIG. 2.
FIG. 4 is a partially exploded perspective view illustrating a coupling portion of a hood member and a wing of the swirler shown in FIG. 3.

Hereinafter, a vortex type local exhaust device according to an embodiment of the present invention will be described with reference to the accompanying drawings. In the drawings, the same reference numerals denote the same elements.

Figure 2 is a cross-sectional view showing a vortex type local exhaust device according to an embodiment of the present invention, Figure 3 is a perspective view showing the bottom of the swirler shown in Figure 2, Figure 4 is a view of the swirler shown in Figure 3 Partially exploded perspective view of the engaging portion of the hood member and the wing.

First, referring to FIG. 2 and FIG. 3, a swirler type local exhaust device 100 according to an embodiment of the present invention is installed on the suction end of the exhaust pipe 10 to rotate and generate a swirler 110. And a driver 120 connected to the swirler 110 to rotate the swirler 110.

The exhaust pipe 10 is a conduit for sucking contaminated air through the open suction end and discharging the contaminated air to the outside. The exhaust pipe 10 may be formed of various kinds of pipes such as a flexible pipe or a metal pipe. The contaminated air may be sucked into the exhaust pipe 10 by natural negative pressure, or forcedly sucked by the operation of the exhaust fan.

The swirler 110 is rotatably installed at the suction end of the exhaust pipe 10, and a hood member 111 corresponding to a conventional hood and a plurality of wings 112 for generating a vortex are integrally formed. Has a configuration.

The hood member 111 corresponds to a conventional hood, and has a disk shape, and the bottom surface thereof, that is, the air inflow side surface 118, is formed in a concave groove shape having a predetermined depth. An air suction hole 116 communicating with the exhaust pipe 10 is formed in the central region of the hood member 111. The contaminated air sucked from the exhaust area is sucked into the exhaust pipe 10 through the air suction hole 116.

The center of the air suction hole 116 is provided with a protruding boss-shaped rotary shaft coupling portion 113, the rotary shaft coupling portion 113, as will be described later, the rotary shaft 123 of the drive motor 121 Connected. To this end, the rotation shaft insertion hole 114 is vertically penetrated at the center of the rotation shaft coupling portion 113, and the fixing screw after the rotation shaft 123 of the drive motor 121 is inserted into the rotation shaft insertion hole 114. Firmly coupled by 115.

The rotation shaft coupling portion 113 is connected to and supported by the hood member 111 by a plurality of connection portions 117 crossing the air suction hole 116 in the radial direction.

As described above, the air inflow side surface 118 of the hood member 111 facing the exhaust area is formed in a concave groove shape, and may be formed of the planar portion 118a of the center region and the inclined surface portion 118b of the outer edge region. have. That is, the flat portion 118a is formed around the air intake hole 116, and the inclined surface portion 118b is formed along the circumference of the flat portion 118a. The inclined surface portion 118b is formed downward so that the diameter gradually widens toward the exhaust region.

The plurality of wings 112 is to form a vortex while rotating with the hood member 111, is installed on the air inlet side 118 of the hood member 111, the circumference of the hood member 111 It is arranged at equal intervals along the direction. Each of the plurality of wings 112 has a shape extending from the air inlet side 118 of the hood member 111 and extending in the radial direction. The height of each of the plurality of wings 112 may be equal to the depth of the air inlet side 118 of the hood member 111.

Each of the plurality of wings 112 is installed to be in close contact with the inclined surface portion 118b of the hood member 111 air inlet side 118. Therefore, a gap does not occur between the inclined surface portion 118b of the air inflow side surface 118 of the hood member 111 and the blade 112. Each of the plurality of vanes 112 may extend in a radial direction from the inclined surface portion 118b to a part of the flat portion 118a. That is, each of the plurality of wings 112 may be formed over the inclined surface portion 118b and the flat portion 118a of the air inflow side surface 118 of the hood member 111.

Next, referring to FIG. 4, a plurality of wing installation grooves 119 extending in the radial direction and penetrating to the outer surface of the hood member 111 may be formed in the inclined surface portion 118a of the hood member 111. In addition, a plurality of wings 112 may be inserted into the plurality of wing installation grooves 119, respectively. The plurality of wings 112 may be inserted into the plurality of wing installation grooves 119 and then may be integrally and firmly coupled to the hood member 111 by welding or other adhesive means.

Referring back to FIG. 2, the driver 120 is connected to the swirler 110 to provide power to rotate the swirler 110. The driving unit 120 includes a driving motor 121 disposed on the center line of the exhaust pipe 10, a motor supporting member 122 supporting the driving motor 121 inside the exhaust pipe 10, and the driving motor 121. It includes a rotating shaft 123 drawn out from. As described above, the rotation shaft 123 is coupled to the rotation shaft coupling portion 113 provided at the center of the hood member 111 of the swirler 110.

However, the driving unit 120 having the above configuration is illustrative, and may have various configurations capable of providing power for rotating the swirler 110, and the installation position thereof is not limited to the above. For example, the driving unit 120 may be installed inside or outside the exhaust pipe 10 by a means such as a bracket to rotate the swirler 110 through a power transmission means such as a belt or a gear.

Hereinafter, with reference to Figure 2, it will be described the operation of the vortex-type local exhaust device 100 according to an embodiment of the present invention having the above configuration and the flow of air accordingly.

Referring to FIG. 2, when the swirler 110 is rotated by the driving unit 120 while the exhaust operation is performed through the exhaust pipe 10, the plurality of wings 112 are inside the hood member 111. Push the air outward in the radial direction. In addition, the exhaust pipe 10 draws not only the contaminated air but also air around the exhaust pipe 10 into the inside of the exhaust pipe 10 and the hood member 111. Due to the flow of air, a donut-shaped vortex F1 is formed at the lower portion of the hood member 111. The vortic flow F1 formed as described above partitions a region where pollutants are generated and a region where no pollutants are generated. It acts as an air curtain. Accordingly, a vortex F1 is formed at the lower edge of the swirler 110 by a plurality of wings 112, and a normal exhaust flow from the exhaust region toward the exhaust pipe 10 is formed at the lower center of the swirler 110. (F2) is formed.

In particular, according to an embodiment of the present invention, the hood member 111 corresponding to the conventional hood and Since the plurality of vanes 112 forming the vortex are integrally formed and rotate together, there is no gap between the hood and the swirler in the prior art. Therefore, the loss of exhaust pressure and turbulence caused by such a gap can be prevented, so that a smooth vortex (F1) can be formed to improve the exhaust efficiency, and can prevent noise caused by air flow through the gap. have.

In addition, since the edge portion of the air inlet side 118 of the hood member 111 of the swirler 110 is formed as the inclined surface portion 118b, the flow of air forming the vortex F1 is induced to be inclined toward the exhaust region. As a result, the generated vortex F1 has a longer shape downwardly, that is, toward the exhaust region. Therefore, contaminated air far from the exhaust pipe 10 can be more easily sucked into the exhaust pipe 10.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention. Accordingly, the true scope of protection of the present invention should be defined by the appended claims.

10.Exhaust pipe 100 ... Vortex type local exhaust
110 Swallower 111 Hood member
112 ... wing 113 ... rotary shaft coupling
114.Rotating shaft insertion hole 115 ... fixed screw
116 Air intake hole 117 Connection
118 ... Air inflow side 118a ... Flat section
118b ... inclined surface 119 ... wing mounting groove
120 Drive 121 Drive motor
122 Motor support member 123 Rotary shaft

Claims (8)

A swirler installed at an inlet end of the exhaust pipe and rotating to generate a vortex; And
It is provided in the exhaust pipe, the drive unit is connected to the swirler to rotate the swirler;
The swirler,
A hood member having a disc shape and formed in a groove shape in which the air inflow side is concave;
It is installed on the air inlet side of the hood member, disposed along the outer edge of the hood member, a plurality of wings to form a vortex while rotating with the hood member; includes;
The air inlet side surface of the hood member is composed of a planar portion of the center region and the inclined surface portion of the outer edge region, each of the plurality of wings is vortex type local exhaust device, characterized in that installed in close contact with the inclined surface portion. The method of claim 1,
And the inclined surface portion is inclined so as to gradually widen in diameter toward the exhaust area. The method of claim 1,
An air intake hole communicating with the exhaust pipe is formed in a central region of the hood member, wherein the flat portion is formed around the air suction hole, and the inclined surface portion is formed along the periphery of the flat portion. . The method of claim 1,
And each of the plurality of vanes is erected from the air inlet side of the hood member and has a radially extending shape. The method of claim 1,
Vortex type local exhaust device, characterized in that the height of each of the plurality of wings is equal to the depth of the air inlet side of the hood member. The method of claim 1,
And each of the plurality of vanes is formed over the inclined surface portion and the planar portion. The method according to claim 6,
And each of said plurality of vanes extends radially from said inclined surface portion to a portion of said planar portion. The method of claim 1,
Vortex, characterized in that the inclined surface portion of the hood member is extended in the radial direction and a plurality of wing installation grooves penetrated to the outer surface of the hood member, the plurality of wings are inserted into the plurality of wing installation grooves, respectively. Type local exhaust system.

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