KR100970592B1 - Suction device for Vortex generating by compressed air - Google Patents

Abstract

The present invention relates to a suction device for vortex generation using compressed air, the configuration is the suction port 210 provided in the dust collector 200, the suction is installed at the end of the suction pipe 220 connected to the suction port 210 In the device 100, the discharge plate 10 is installed at the end of the suction pipe 220; A discharge cover 20 installed to surround the discharge plate 10; An air pipe (30) installed through the discharge cover (20) and connected to the discharge plate (10); An air supplier 40 connected to the air pipe 30 to supply compressed air; It is possible to improve the exhaust performance and prevent and eliminate the re-diffusion of contaminants by forming the vortex by the compressed air without using the drive unit and swirler for forming the vortex in the conventional configuration by the above configuration. In addition, since the configuration of the device is simple and can be installed regardless of the shape of the exhaust port, the cost can be reduced by utilizing the existing equipment without additional equipment.

Vortex, suction device, local exhaust device

Description

Suction device for Vortex generating by compressed air

The present invention relates to a vortex generation suction device using compressed air, and more particularly to the vortex generation using compressed air that can improve the suction efficiency by forming a vortex by the high-pressure compressed air and using the same to expand the suction region It relates to a suction device for.

A local exhaust device is a device that can inhale contaminants, that is, a device capable of inhaling only a part of the contaminant that is generated instead of the entire space in a workplace or a factory. The suction pipe 220 is connected to the suction port 210 of the 200 and each of the ducts to be sucked is installed in the suction pipe 220 to collect dust and the like, thereby increasing dust collection efficiency. Ducts of various shapes of circular, rectangular, and rectangular are attached to the pipe 220.

If air is sucked from the entire workplace and discharged into the atmosphere, installation costs, including facility maintenance costs, are high. Therefore, only the part where pollutants are generated is installed through the exhaust system.

If air containing pollutants sucked from the local exhaust is sent to the atmosphere, air pollution is generated, so it is sent to the dust collector through the duct, the suction pipe, to filter the pollutants and discharge only clean air into the atmosphere.

As a method of removing contaminated particulate matter, there are gravity removal methods, centrifugal force separation removal methods, cleaning methods, electrostatic precipitating methods, and filtration methods. The speed of capture decreases rapidly in the axial direction, making it inefficient for the removal of contaminants that are far from the exhaust pipe, which requires the exhaust system to be installed as close as possible to the location of the pollutants. In addition, there is a problem that the exhaust efficiency is lowered due to the movement of the workers.

In order to solve the above-mentioned problems, exhaust devices using concentrated vortices formed in the process of generating vortices by blowing air into the space similar to the exhaust flow rate and inhaling the exhaust devices have been developed. Noise is generated by the generation of turbulence caused by the mutual interference between the flow blowing in the area and the suction flow, and the flow blown into the space may cause additional diffusion of pollution in the space, It has the disadvantage of installing additional equipment such as filter and flow pipe.

In addition, the local exhaust device pushes the air inside the swirler outward by rotating the swirler, and sucks not only the air contaminated inside the swirler by the suction force of the exhaust pipe but also the air around the swirler. By the flow of air, the local exhaust system expands the exhaust area by forming a vortex around the exhaust pipe, like a donut shape. .

In the conventionally known technique, Document 1 has a 'local exhaust device using a swirler having a cover' and Patent Document 2 has a 'exhaust device using a vortex'.

Documents 1 and 2 include drive motors and swirlers, which are additional devices for forming vortices, which increase the installation cost and make it difficult to install the suction and duct pipes connected to the dust collector other than circular. If installed on the back has the disadvantage that the suction efficiency is lowered.

The present invention was created in view of the above-mentioned problems in the prior art, and solves this problem. Exhaust efficiency is achieved by forming a vortex in the radial direction by air rather than operating by a conventional swirler and driving unit. It is an object of the present invention to provide a suction device that can be installed in a suction pipe and a duct to be installed regardless of the shape of a circular or rectangular square.

The present invention is a means for achieving the above-described problems, the suction port 210 provided in the dust collector 200, the suction pipe 220 connected to the suction port 210 is installed at the end, the suction pipe 220 Discharge plate 10 is installed at the end of the; A discharge cover 20 installed to surround the discharge plate 10; An air pipe (30) installed through the discharge cover (20) and connected to the discharge plate (10); In the suction device 100 consisting of an air supply 40 for supplying compressed air connected to the air pipe 30, the discharge plate 10 is provided with a plurality of discharge holes 11 in the circumferential direction, The discharge cover 20 is spaced apart from the suction pipe 220, the upper cover 21 having a suction gap 24, the lower cover 22 fixed to the suction pipe 220 inward, and The upper cover 21 and the lower cover 22 is fixed by a connecting rib 25 provided with a plurality in the circumferential direction, by the connecting rib 25 at the same interval as the discharge hole 11 by the discharge gap ( 23) is formed.

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In addition, the discharge plate 10 and the discharge cover 20 can be installed in a variety of shapes, such as circular, rectangular, square, the same as the shape of the suction pipe 220, the suction device 100 is the air The dust is sucked into the vortex generated by the compressed air supplied from the feeder (40).

As described above, according to the present invention, by forming the vortex by compressed air without using the drive unit and the swirler for forming the vortex in the related art, it is possible to prevent and remove the exhaust performance and to prevent and eliminate the re-diffusion of contaminants. This simple and can be installed regardless of the shape of the exhaust port can be used in existing equipment without the addition of additional equipment can reduce the cost and can be used in factories, homes, restaurants and restaurants that generate a lot of pollutants .

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention. In addition, this embodiment does not limit the scope of the present invention, but is presented by way of example only.

Figure 2 is a cross-sectional view showing the configuration of the suction device for vortex generation using compressed air according to the present invention. Figure 3 is a side view of the suction device for vortex generation using the compressed air according to the present invention. Figure 4 is a perspective view showing the configuration of an embodiment of the suction device for vortex generation using the compressed air according to the present invention.

Referring to Figures 2 and 3 first look at the overall configuration of the suction device 100 first the discharge cover 20 consisting of a top and bottom cover (21, 22) wrapped around the discharge plate 10 fixed to the end of the suction pipe 220 And an air supply unit 40 for supplying compressed air (f: air) connected to the air pipe 30 and the air pipe 30 connected to the discharge plate 10 through the discharge cover 20. It is configured to supply compressed air (f: air) to the suction device 100 to generate the vortex.

First, the discharge plate 10 may be installed to be fixed to the end of the suction pipe 220 inwardly and variously provided according to the shape of the suction pipe 220.

Here, the suction pipe 220 includes a plurality of pipes connected to the dust collector 200 and various shapes connected to each pipe end, for example, a duct and a hood such as a circle, a rectangle, a square, and the like. It does not limit either.

In addition, a plurality of discharge holes 11 are provided in the circumferential direction of the discharge plate 10, which is discharged when the air (compressed air) supplied from the air supply 40 is supplied through the air pipe 30. It is ejected to the first vortex (b) in the radial direction to the outside through the hole (11).

The discharge cover 20 is installed to surround the discharge plate 10 and is spaced apart from the suction pipe 220, the upper cover 21 having a suction gap 24, and the suction pipe 220 in the lower inner side. And a lower cover 22 fixed to the upper cover 21 by a connecting rib 25.

In addition, as shown in Figure 4, the discharge plate 10 and the discharge cover 20 may be provided in the same shape as the shape of the suction pipe 220 or the suction pipe 220, although not shown, the conventional As mentioned in the art, there was a disadvantage in that it can not be installed other than circular to drive the swirler by driving the drive unit, but the suction device 100 of the present invention is circular, rectangular, regardless of the shape of the suction pipe to be installed. It is equipped with various shapes such as square and can be installed.

Here, the circular suction device 100 shown in FIG. 4 shows an embodiment, and the shape of the suction pipe 22 to be installed is not limited, and is the same as the shape of the suction pipe 22 to be installed. It can be provided in various shapes.

The air supply 40 is air (compressed air) to the discharge plate 10 through an air pipe 30 connected to a device for generating compressed air (f: air) for driving the suction device 100 of the present invention Injecting the fluid (a) into the inside by the first vortex (b) in the discharge plate 10 to discharge the fluid (a) to the outside.

Hereinafter, the principle of operation of the suction device for vortex generation using the compressed air of the present invention using such a device configuration will be described with reference to the drawings.

As shown in the drawing, when the air flows through the air pipe 30 in the air supply 40 in the state of suction operation is made to eject through the discharge hole 11 provided in the discharge plate 10, the upper Fluid (a) above the cover 21 is radially introduced through the discharge gap 23 formed in the same interval as the discharge hole 11 is introduced into the interior through the inlet gap 211 of the discharge cover 20 As a result, the first vortex (b) of the vortex form is ejected.

At this time, the flow under the inlet of the suction pipe 220 by the accelerated vortex flow is divided into a flow (c) pushed in the radial direction and a flow (d) toward the central axis by the exhaust operation.

Since the suction device 100 operates while maintaining a constant suction flow rate, the suction device 100 replenishes and exhausts the flow amount radially pushed down by the fluid below the axis, and the interaction of the flow expands the exhaust area in the axial direction. The vortices (b, c) ejected in the radial direction are gathered again in the axial direction by the exhaust flow, thereby forming a secondary vortex (e) under the suction device (100). Since the secondary vortex (e) is continuously supplied with energy by the first vortex (b) ejected from the discharge hole 11 and rotates at a constant speed, the air under the secondary vortex (e) is suction pipe 220. It is pushed toward). In this way, the exhaust region is expanded by being accelerated toward the inlet of the suction pipe 220 of the suction flow.

In addition, when the vortex component spreading in a large radius is gathered to the axis center by the exhaust flow, it has a stronger rotational speed by preserving the angular momentum, whereby a low pressure distribution is formed in the downward direction of the suction pipe 220, thereby providing a strong exhaust flow. To form.

1 is an overall configuration perspective view showing a connection configuration of a conventional local exhaust device.

Figure 2 is a cross-sectional view showing the configuration of the suction device for vortex generation using compressed air according to the present invention.

Figure 3 is a side view of the suction device for vortex generation using the compressed air according to the present invention.

Figure 4 is a perspective view showing the configuration of an embodiment of the suction device for vortex generation using the compressed air according to the present invention.

♧ description of the symbols for the main parts of the drawing ♧

10 .... outlet 11 .... outlet

20..Exhaust cover 21 .... Top cover

22..Lower cover 23 .... Ejection gap

24 .... Suction gap 25 .... Connection

30..Air pipe 40 .... Air supply

100 ... suction device 200 ... dust collector

210..Suction port 220..Suction line

Claims (5)

delete delete A discharge plate 10 installed at the end of the suction port 210 provided at the dust collector 200 and the suction pipe 220 connected to the suction port 210, and installed at the end of the suction pipe 220; A discharge cover 20 installed to surround the discharge plate 10; An air pipe (30) installed through the discharge cover (20) and connected to the discharge plate (10); In the suction device 100 consisting of an air supply 40 connected to the air pipe 30 to supply compressed air, The discharge plate 10 is provided with a plurality of discharge holes 11 in the circumferential direction, The discharge cover 20 is spaced apart from the suction pipe 220, the upper cover 21 having a suction gap 24, the lower cover 22 fixed to the suction pipe 220 inward, and The upper cover 21 and the lower cover 22 is fixed by a connecting rib 25 provided with a plurality in the circumferential direction, by the connecting rib 25 at the same interval as the discharge hole 11 by the discharge gap ( Suction device for vortex generation using compressed air, characterized in that 23) is formed. The method of claim 3, wherein The discharge plate 10 and the discharge cover 20 is a suction device for generating vortex using the compressed air, characterized in that it can be installed in a variety of shapes, such as circular, rectangular, square, the same as the shape of the suction pipe 220 . The method of claim 3, wherein The suction device 100 is a suction device for vortex generation using the compressed air, characterized in that for sucking the dust by the vortex generated by the compressed air (air) supplied from the air supply (40).

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