KR20190028954A - Local ventilator - Google Patents

Abstract

Disclosed is a local exhaust device for sucking contaminated air and discharging the polluted air to the outside. The local exhaust device includes a driving unit; a driving unit; a swirler disposed near an inlet of an exhaust pipe to generate a vortex when being rotated by the driving unit, wherein the swirler includes a rotating plate member connected to the driving unit and having an exhaust hole communicating with the exhaust pipe in a central region, and a plurality of blades installed on the rotating plate member to rotate together with the rotating plate member to generate an air flow forming the vortex; and a box contained in the swirler; and an auxiliary exhaust pipe connected to the box to discharge the air inside the box. An opening is formed in a portion of one side wall of the box corresponding to a vortex discharge surface of the swirler. A gap is formed between one side wall surface of the box on which the opening is formed and the vortex discharge surface of the swirler in the direction of the rotation center axis of the swirler, so that the vortex generated by the swirler and discharged through the vortex discharge surface flows into the box through the gap.

Description

(Local ventilator)

BACKGROUND OF THE INVENTION Field of the Invention [0002] The present invention relates to a local exhaust system for sucking contaminated air and discharging the polluted air to the outside, and more particularly, to a local exhaust system capable of improving exhaust efficiency by forming a stable exhaust flow.

Generally, the exhaust device is installed in a factory where a pollutant such as odor, noxious gas, soot, dust or the like is generated or in a kitchen of a home or a restaurant and sucks air containing such pollutant (hereinafter referred to as polluted air) It is used for discharging.

In the conventional exhaust system used for this purpose, as the distance between the contamination source and the exhaust system becomes larger, the exhaust efficiency for sucking and discharging the polluted air drops sharply. Even when the pollution source is located in a wide open space, The exhaust efficiency of the exhaust gas is reduced.

Therefore, in order to improve the exhaust efficiency, it is preferable to dispose the exhaust system as close as possible to the contamination source, and shut off the contamination source from the surrounding space.

However, in actual work sites, there are many cases where it is difficult to dispose the exhaust device near a contamination source and it is difficult to block the contamination source from the surrounding space. In such a case, there is a problem that satisfactory exhaust efficiency can not be obtained from the conventional exhaust device . In order to solve such a problem, an exhaust fan having a larger capacity than necessary is used to increase the suction amount of polluted air. However, in this case, noise is increased, installation and operation costs are excessive, There is a disadvantage that efficiency is not obtained.

In order to overcome the problems of the conventional exhaust system, a local exhaust system for improving the exhaust efficiency by using a swirler that forms a vortex has been developed. In Korean Patent No. 10-0873522, An example of an exhaust device is disclosed.

Such a conventional local exhaust system generally has a swirler which is installed near the intake port of the exhaust pipe to form a vortex. The airflow created by the rotation of the sweller forms a vortex around the exhaust stream of contaminated air rising from the source towards the inlet of the exhaust tube along the swirl center axis of rotation. The vortex thus formed serves as an air curtain for blocking the contamination source from the surrounding space, thereby allowing the contaminated air to be sucked into the exhaust pipe more efficiently.

Korean Patent No. 10-1606862 discloses another example of a conventional local exhaust system. The local exhaust system includes a swirler for forming a vortex and a guide member for vertically extending an air curtain formed by the vortex Respectively. Such a local exhaust system is advantageous in that the exhausted air can be more easily and efficiently sucked and exhausted from the exhaust pipe, thereby improving the exhaust efficiency.

As described above, in the local exhaust system using the swirler, the vortex formed by the sweller serves as an air curtain surrounding the exhaust flow. However, if there are walls or other devices around the source, or if there is an operator, the vortex formed by the sweller hits the surrounding wall, device, or worker, causing the flow to become unstable and disturbed. Thus, if the flow of the vortex serving as the air curtain is not stabilized, the exhaust flow toward the exhaust pipe is not stabilized and the exhaust efficiency is lowered.

Therefore, in conventional local exhaust systems using a swirler, it is necessary to improve the exhaust flow more stably.

Patent Document 1: Korean Patent No. 10-0873522 (Registered on December 04, 2008) Patent Document 2: Korean Patent No. 10-1606862 (Registered on Mar. 22, 2016)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a local exhaust device capable of improving exhaust efficiency by forming a more stable exhaust flow using a box surrounding a swirler .

According to an aspect of the present invention, there is provided a local exhaust system comprising:

A driving unit;

A rotating plate member disposed near the suction port of the exhaust pipe and generating a vortex by being rotated by the driving unit, the rotating plate member being connected to the driving unit and having an exhaust hole communicating with the exhaust pipe in a central region; A sweller including a plurality of blades for generating an air flow that rotates while forming the vortex;

A box for accommodating the sweller therein; And

And an auxiliary exhaust pipe connected to the box for discharging the air inside the box to the outside,

An opening is formed in one wall of the box at a portion corresponding to the vortex discharge surface of the sweller,

A vortex generated by the swirler and discharged through the vortex discharge surface is formed between a wall surface of the box on which the opening is formed and a vortex discharge surface of the swirler in the direction of the rotation center axis of the swirler And is introduced into the box through the gap.

Here, the diameter of the opening may be larger than the outer diameter of the sweller.

The auxiliary exhaust pipe may be connected to a wall opposite to the opening of the box.

In addition, a fan may be installed in the box to flow the vortex introduced into the box through the gap toward the auxiliary exhaust pipe.

The swirler includes a cylindrical first guide member provided at an outer side edge portion of the rotating plate member and a second guide member provided to surround the outer end of the plurality of blades, And a third guide member installed to cover the upper portion of the plurality of vanes.

The plurality of blades are radially disposed on the upper surface of the rotating plate member and the outer ends of the plurality of blades protrude from the outer edge of the rotating plate member and can be extended to the lower end of the outer peripheral surface of the first guide member .

The swirler may further include a plurality of auxiliary blades provided between the first guide member and the second guide member, the plurality of auxiliary blades being disposed at regular intervals along an outer circumferential surface of the first guide member, And may be alternately arranged with the plurality of blades.

The upper end of each of the plurality of auxiliary wings may extend to a lower surface of the third guide member, and the lower end may extend to a lower end of the first guide member.

The swirler may further include a delay means provided between the rotating plate member and the third guide member to suspend the airflow generated by the plurality of blades.

The retention means may include a plurality of barriers provided between the upper surface of the rotating plate member and the lower surface of the third guide member so as to have a height lower than the height of the plurality of blades.

In addition, the plurality of barriers may be installed such that a path of an air flow passing between the rotating plate member and the third guide member is serpentine.

The plurality of barriers may have different diameters and may be concentrically arranged with a radial spacing about the rotation center axis of the swirler, and some of the plurality of barriers protrude upward from the upper surface of the rotation plate member And the remainder may protrude downward from the lower surface of the third guide member.

The plurality of barriers include at least two first barriers protruding upward from the upper surface of the rotating plate member and at least two second barriers protruding downward from the lower surface of the third guide member, The first barrier and the at least two second barriers may be alternately arranged from the outer edge of the rotating plate member toward the rotational center axis.

In the above-described local exhaust system,

An outer guide member disposed to surround the outer periphery of the swirler and guiding the vortex generated by the swirler in a direction parallel to the rotation center axis of the swirler;

An inner guide member disposed on the inner side of the outer guide member and defining a vortex flow passage through which the vortex generated by the swirler passes between the inner guide member and the outer guide member; And

And an outer air guide unit installed on the outer guide member and guiding the air outside the outer guide member to the vortex flowing into the box through the gap.

In addition, at least one air inlet hole is formed in the upper portion of the swirler so as to allow air to flow into the swirler, and the outer guide member is formed in the swirler Wherein the inner guide member is a cylindrical member having a diameter smaller than a diameter of the outer guide member, the inner guide member being a cylindrical member having a diameter smaller than the diameter of the outer guide member, And may be installed to be fixed to the outer guide member.

Further, a plurality of connecting members extending in the radial direction and spaced circumferentially are provided between the inner guide member and the outer guide member, and the inner guide member is fixed to the outer guide member through the plurality of connecting members .

Further, the external air guide unit may include:

An outer air passage forming member provided outside the lower end portion of the outer guide member to form a passage through which the outside air passes between the outer guide member and the outer guide member;

And a plurality of external air guide members provided between the outer guide member and the outer air passage forming member and guiding the outer air in a direction parallel to the rotation center axis of the swirler.

The outer air passage forming member may have a cylindrical shape extending in parallel with the rotation center axis of the swirler and surrounding the outer circumferential surface of the outer guide member and spaced from the outer circumferential surface of the outer guide member,

The plurality of outer air guide members may have a plate shape elongated in a direction parallel to the rotation center axis of the swirler and may be disposed at regular intervals along the outer peripheral surface of the outer guide member.

According to the local exhaust system according to the embodiments of the present invention, the vortex generated by the sweller flows into the box surrounding the sweller while spreading sideways. Accordingly, the exhaust flow of the polluted air generated in the pollutant generating region can be stably raised toward the exhaust pipe without being directly influenced by the eddy current, so that the exhaust efficiency can be improved.

1 is a schematic view showing a local exhaust system according to an embodiment of the present invention.
FIG. 2 is a perspective view of the sweller shown in FIG. 1 from above. FIG.
Fig. 3 is a perspective view of the sweller shown in Fig. 1 as seen from below. Fig.
4 is a perspective view showing the box shown in Fig.
5 is a schematic view showing a local exhaust system according to another embodiment of the present invention.
FIG. 6 is a perspective view of the inner guide member and the outer guide member shown in FIG. 5, viewed from above.

Hereinafter, a local exhaust system according to embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same reference numerals denote the same elements.

FIG. 1 is a schematic view showing a local exhaust system according to an embodiment of the present invention, FIG. 2 is a perspective view of the sweller shown in FIG. 1, and FIG. 3 is a perspective view of the sweller shown in FIG. And Fig. 4 is a perspective view showing the box shown in Fig.

Referring to FIG. 1, the local exhaust system 100 according to the present invention may be installed such that the rotation center axis C of the sweller 120 is vertical. Also, the local exhaust system 100 according to the present invention may be installed so that the rotation center axis C of the sweller 120 is horizontal or inclined at a predetermined angle. In order to simplify the explanation and simplify the explanation, the local exhaust system 100 according to the present invention will be described with reference to an example in which the rotation center axis C of the sweller 120 is vertically installed .

1 to 4, a local exhaust apparatus 100 according to an embodiment of the present invention includes a driving unit 110 and a plurality of exhaust pipes 101, which are arranged near the intake port of the exhaust pipe 101 and rotate to generate a vortex Fs A swirler 120, a box 140 surrounding the swirler 120 and an auxiliary exhaust pipe 141 connected to the box 140.

Specifically, the exhaust pipe 101 is a pipe for sucking polluted air through an intake port opened at one end thereof and discharging the polluted air to the outside, and may be formed of various kinds of pipes such as a flexible pipe or a metal pipe generally known. The exhaust pipe 101 is inserted into the box 140 through the wall of the box 140 from the outside of the box 140. The contaminated air can be sucked into the exhaust pipe 101 by natural negative pressure and can be sucked into the exhaust pipe 101 by an exhaust fan such as a sirocco fan 102 installed in the exhaust pipe 101 It may be forced inhalation. 1, the sirocco fan 102 may be installed in the vicinity of the inlet of the exhaust pipe 101, but it is not limited thereto and may be installed near the outlet of the exhaust pipe 101. [

The driving unit 110 is connected to the swirler 120 to provide power for rotating the swirler 120. The driving unit 110 may include a driving motor 111 and a rotating shaft 112 connected to the driving motor 111. The driving motor 111 may be installed in the exhaust pipe 101 and may be installed in the box 140, but is not limited thereto. For example, the driving motor 111 may be installed in the box 140 or a separate support bracket, or may be installed outside the box 140. When the drive motor 111 is installed outside the box 140, the rotation shaft 112 may be inserted into the box 140 and coupled to the swirler 120.

The rotating shaft 112 is coupled to a rotating shaft coupling part 127 provided at a rotating center part of the rotating plate member 121 of the swirler 120 as described later. 1, when the sirocco fan 102 is installed near the suction port of the exhaust pipe 101, the driving unit 110 may rotate the sirocco fan 102 together with the sweller 120 . When the sirocco fan 102 is installed near the exhaust port 101, a separate driving motor for rotating the sirocco fan 102 is provided.

However, the driving unit 110 having the above-described configuration is illustrative and may have various configurations capable of providing power for rotating the sweller 120, and the mounting position is not limited to the above. For example, the driving unit 110 may be installed inside or outside the box 140 by a means such as a bracket, and may rotate the swirler 120 through a power transmitting means such as a belt or a gear.

The swirler 120 is disposed near the suction port of the exhaust pipe 101 and rotates to generate a vortex Fs. The swirler 120 is installed inside the box 140. The swirler 120 basically includes a rotating plate member 121 disposed and rotated near the suction port of the exhaust pipe 101 and an air flow Fa provided on the rotating plate member 121 to form a vortex Fs And a plurality of vanes 130 for generating the vanes.

The rotating plate member 121 may be formed in a disc shape having a diameter larger than the diameter of the exhaust pipe 101. The rotating plate member 121 is disposed near the suction port of the exhaust pipe 101. An exhaust hole 122 communicating with the exhaust pipe 101 is formed in the central region of the rotating plate member 121, (122) and sucked into the exhaust pipe (101).

The rotating plate member 121 is connected to the driving unit 110 and rotated. The rotation shaft member 121 is provided with a protruding boss-shaped rotation shaft coupling unit 127 and the rotation shaft 112 of the driving motor 111 is coupled to the rotation shaft coupling unit 127 . Specifically, a rotation shaft insertion hole 128 is vertically formed at the center of the rotation shaft engagement portion 127, and the rotation shaft 112 of the drive motor 111 is inserted into the rotation shaft insertion hole 128, And is tightly coupled by a screw 129. The exhaust hole 122 may be formed around the rotating shaft engaging part 127. The rotating shaft engaging part 127 may be formed by a plurality of connecting parts 126 radially crossing the exhaust hole 122, And may be connected to and supported by the base 121.

The rotary plate member 121 is provided with a cylindrical exhaust passage forming member 123 which surrounds the exhaust hole 122 to form an exhaust passage Pe communicating with the exhaust pipe 101 . The exhaust passage forming member 123 may have an inner diameter larger than the outer diameter of the exhaust pipe 10 and may be provided on the upper surface and the lower surface of the rotating plate member 121.

The plurality of blades 130 rotate together with the rotating plate member 121 to generate an air flow Fa so that the air flow Fa generated by the plurality of blades 124 is rotated by a rotating vortex (Fs).

The plurality of vanes 130 may be fixedly installed on the surface of the rotating plate member 121 on the side of the exhaust pipe 101. The vanes 130 may be formed radially around the exhaust hole 122 and the exhaust passage forming member 123, . Each of the plurality of vanes 130 may have a shape rising from the upper surface of the rotating plate member 121 and extending in the radial direction. The inner ends of the vanes 130 may be separated from the outer circumferential surface of the exhaust passage forming member 123 by a predetermined distance. The outer ends of the plurality of vanes 130 may protrude from the outer edge of the rotating plate member 121 by a predetermined length. That is, the plurality of blades 130 may be formed to have an outer diameter larger than the outer diameter of the rotating plate member 121.

Various components may be added to the swirler 120 in addition to the rotating plate member 121 and the plurality of blades 130. Preferably, the sweller 120 includes a first guide member 131, a second guide member 132, and a third guide member 132 for guiding the air flow Fa generated by the plurality of vanes 130. [ A member 133, and a retarding means for retarding the air flow Fa.

The first guide member 131 is fixed to the outer edge of the rotation plate member 121 and rotates together with the rotation plate member 121. The first guide member 131 may be formed in a cylindrical shape extending downward from the outer edge of the rotation plate member 121 in parallel with the rotation center axis C. The first guide member 131 may have a constant outer diameter, and the outer diameter of the first guide member 131 may be the same as the outer diameter of the rotating plate member 121.

When the outer ends of the plurality of vanes 130 are protruded by a predetermined length from the outer edge of the rotating plate member 121 as described above, the outer ends of the vanes 130 are connected to the first guide member 131 And the plurality of vanes 130 may be formed in a "? &Quot; shape. The vanes 130 may extend in a direction parallel to the rotation center axis C to the lower end of the outer periphery of the vanes 130.

The second guide member 132 may be installed to surround the plurality of vanes 130. The second guide member 132 may be formed in a cylindrical shape having an inner diameter larger than the outer diameter of the first guide member 131. That is, the plurality of vanes 130 are fixedly installed between the first guide member 131 and the second guide member 132 so that the rotation plate member 121, the first guide member 131, The blade 130 and the second guide member 132 rotate together. The lower end of the second guide member 132 may be positioned at the same height as the lower end of the first guide member 131.

The third guide member 133 may be installed to cover the upper portion of the plurality of vanes 130. The third guide member 133 is attached to and fixed to the upper end of the plurality of vanes 130, thereby rotating together with the plurality of vanes 130. The third guide member 133 has an inner diameter larger than the outer diameter of the exhaust passage forming member 123 and has an annular plate shape having an outer diameter larger than the outer diameter of the rotating plate member 121. The upper end of the second guide member 132 is fixedly coupled to the outer edge of the third guide member 133. Accordingly, a predetermined gap is formed between the outer circumferential surface of the exhaust path forming member 123 and the inner circumferential surface of the third guide member 133, and external air flows through the gap between the rotating plate member 121 and the third guide member 133, Member 133 as shown in Fig.

The first guide member 131, the second guide member 132 and the third guide member 133 rotate together with the rotation plate member 121 and the plurality of vanes 130, do. The air flow Fa generated by the plurality of vanes 130 between the rotating plate member 121, the first guide member 131, the second guide member 132, and the third guide member 133, The air flow path Pa through which the air passes is formed. More specifically, the third guide member 133 guides the air flow Fa passing through the air flow passage Pa in a direction perpendicular to the rotation center axis C, that is, in the horizontal direction, 131 and the second guide member 132 serve to guide the air flow Fa in a direction parallel to the rotation center axis C, that is, downward in the vertical direction.

When the plurality of vanes 130 are rotated, air flows into the air flow path Pa between the rotating plate member 121 and the third guide member 133 from the outside to generate the air flow Fa. The air flow Fa thus generated is rotated by the plurality of vanes 130 to form a vortex Fs and the vortex Fs thus formed is discharged from the lower surface of the swirler 120, Lt; / RTI > At this time, the vortex Fs flows into the box 140 while spreading by the centrifugal force while escaping from the lower end of the air flow passage Pa. This will be described later.

A plurality of auxiliary vanes 130a may be installed in the air flow passage Pa between the first guide member 131 and the second guide member 132. [ The plurality of auxiliary vanes 130a are arranged at regular intervals along the outer circumferential surface of the first guide member 131 and may be disposed alternately with the plurality of vanes 130. [ Each of the plurality of auxiliary vanes 130a may be formed in a rectangular plate shape extending parallel to the rotation center axis C, that is, vertically long, and the upper end thereof extends to the lower surface of the third guide member 133, And the lower end may extend to the lower end of the first guide member 131.

The plurality of auxiliary vanes 130a having the above-described configuration serves to apply additional rotational force to the air flow Fa passing through the air flow passage Pa, which will be described later.

The retention means may have various forms capable of retarding the air flow Fa and preferably have a plurality of barriers installed between the upper surface of the rotating plate member 121 and the lower surface of the third guide member 133, (135, 136).

Specifically, the plurality of barriers 135 and 136 have different diameters and are disposed concentrically with respect to the rotation center axis C at radial intervals. The plurality of barriers 135 and 136 may include at least two annular first barriers 135 protruding upward from the upper surface of the rotating plate member 121 and at least two second barriers 135 projecting downward from the lower surface of the third guide member 133 The at least two first barriers 135 and the at least two second barriers 136 may include at least two second barriers 136 which are annular in shape and which may extend from the outer edge of the rotating plate member 121, Can be alternately arranged at a distance from one another toward the center (C).

The first barriers 135 and the second barriers 136 are formed at a height lower than the height of the vanes 130 so that the upper ends of the first barriers 135 and the first guide members 133 And a predetermined gap is formed between the lower end of the second barriers 136 and the upper surface of the rotating plate member 121. [ The height of each of the first and second barriers 135 and 136 is preferably 50 to 75% of the height of the vane 130. If the height of the first barriers 135 and the second barriers 136 is less than 50% of the height of the vanes 130, the air flow Fa may be delayed as described later Is greater than 75% of the height of the vane 130, the gap may become too narrow and the air flow Fa may not pass smoothly through the gap.

The path of the air flow Fa passing between the rotating plate member 121 and the first guide member 133 by the first barriers 135 and the second barriers 136 having the above- The air flow Fa is delayed by the first walls 135 and the second walls 136. As a result, When the air flow Fa is delayed by the plurality of barriers 135 and 136, the air flow Fa is continuously transmitted from the plurality of vanes 130 during the delayed time, The rotational moment of the vortex Fs formed by the vortexes Fa is further increased. As the rotational moment of the vortex Fs increases, the centrifugal force of the vortex Fs becomes stronger. As a result, the vortex Fs can spread more widely as it passes through the lower end of the air flow passage Pa.

The box 140 is formed so as to surround the perimeter of the sweller 120 having the above-described configuration. That is, the sweller 120 is accommodated in the box 140. The driving unit 110 may be installed inside the box 140 or outside the box 140 as described above.

The box 140 may have a rectangular parallelepiped shape, for example, as shown in FIG. A circular opening 142 is formed on one wall of the box 140 at a portion corresponding to the vortex discharge surface of the sweller 120. The contaminated air flows through the opening 142 toward the sweller 120 Inhaled.

The opening 142 of the box 140 is formed to have a diameter Dh that is larger than the outer diameter Ds of the sweller 120. The diameter Dh of the opening 142 of the box 140 may be about 100 mm to 200 mm larger than the outer diameter Ds of the sweller 120. For example, when the outer diameter Ds of the swirler 120 is approximately 360 mm, the diameter Dh of the opening 142 may be approximately 520 mm. The gap H in the direction of the rotation center axis C between one wall surface in which the opening 142 of the box 140 is formed and the vortex discharge surface of the swirler 120 is approximately 30 mm to 120 mm, May be 50 mm to 100 mm, and more preferably 70 mm to 80 mm.

The vortex Fs discharged through the lower end of the air flow passage Pa formed on the vortex discharge surface of the swirler 120 spreads laterally by the centrifugal force, Through the gap H between the swirling surface of the box 140 and the swirling surface of the box 140. At this time, it is preferable to make the inside of the box 140 to a predetermined negative pressure state so that the vortex Fs can smoothly flow into the box 140. For this purpose, At least one, preferably two, auxiliary exhaust pipes 141 for discharging the air to the outside are connected. The auxiliary exhaust pipe 141 may be connected to a wall opposite the opening 142 of the box 140. The swirler 120 may be provided on the both sides of the box 140 so that the vortex Fs flowing into the box 140 can smoothly flow toward the auxiliary exhaust pipe 141. [ Two fans 144 may be installed.

Hereinafter, the operation of the local exhaust system 100 according to an embodiment of the present invention will be described.

Referring to FIG. 1, when the rotating plate member 121 and the plurality of blades 130 are rotated by the driving unit 110, air outside the sweller 120 (air inside the box 140) (Pa) between the first guide member (121) and the third guide member (133), and an air flow (Fa) is generated. The air flow Fa forms a vortex Fs that rotates along the direction of rotation of the vanes 130. When the exhaust operation is performed through the exhaust pipe 101, the contaminated air in the pollutant generating area A rises toward the exhaust hole 122 formed in the rotating plate member 121 to form the exhaust flow Fe.

The air flow Fa is delayed by a plurality of barriers 135 and 136 provided between the rotating plate member 121 and the third guide member 133 and the force is continuously transmitted from the plurality of blades 130 during the delayed time period . As a result, the rotational moment of the vortex Fs formed by the air flow Fa increases, so that the centrifugal force of the vortex Fs becomes stronger. Accordingly, the vortex Fs is spread out while escaping from the lower end of the air flow passage Pa formed in the vortex discharge surface of the swirler 120.

Since the plurality of vanes 130 extend vertically to the lower end of the outer circumferential surface of the first guide member 131, the air flow Fa forming the vortex Fs is formed at the lower end of the air flow passage Pa, Lt; RTI ID = 0.0 > 130 < / RTI > Therefore, the centrifugal force of the vortex Fs becomes stronger and can spread more widely as it passes through the lower end of the air flow passage Pa.

Since a plurality of auxiliary vanes 130a are provided in the air flow passage Pa between the first guide member 131 and the second guide member 132, the air flow Fa Is further subjected to a force by the plurality of auxiliary vanes 130a until it exits the lower end of the air flow passage Pa. Therefore, the centrifugal force of the vortex Fs becomes stronger, so that the vortex Fs exiting the lower end of the air flow passage Pa can spread more widely.

As described above, the vortex Fs discharged through the lower end of the air flow passage Pa formed on the vortex discharge surface of the swirler 120 spreads over the wall surface of the box 140 and the swirler 120 And can flow smoothly into the box 140 through the gap H between the vortex discharge surfaces. As described above, the vortex Fs flows more smoothly into the box 140 by the auxiliary exhaust pipe 141 connected to the box 140 and the fan 144 installed inside the box 140, And the airflow inside the box 140 is smoothly performed.

If the vortex Fs does not flow into the box 140 but falls downward, the exhaust flow Fe rising toward the exhaust pipe 101 may be influenced by the vortex Fs, , The exhaust flow becomes unstable and the exhaust efficiency is lowered and a part of the exhaust flow Fe flows out along the flow of the vortex Fs. Further, when there is a wall or other devices around the pollutant generating area A, or when there is an operator, the vortex Fs formed by the sweller 120 strikes the surrounding wall, device, or worker, The flow becomes unstable and disrupted. As described above, if the flow of the vortex Fs is not stabilized, the exhaust flow toward the exhaust pipe 101 is not stabilized, and the exhaust efficiency is lowered.

However, in the local exhaust system 100 according to the present invention, the vortex Fs formed by the sweller 120 is spread to the side and flows into the box 140, The exhaust flow Fe is hardly directly affected by the vortex Fs.

As described above, since the exhaust flow Fe of the polluted air generated in the pollutant generating region A can be stably raised toward the exhaust pipe 101 without being directly affected by the vortex Fs, the exhaust efficiency can be improved . The contaminated air Fo existing around the opening 142 of the box 140 may also flow into the box 140 along the flow of the vortex Fs flowing into the box 140 .

Meanwhile, in the local exhaust system 100 according to the present invention, the sweller 120 shown in Figs. 1 to 3 is merely a preferred example. Therefore, the local exhaust system 100 according to the present invention is not limited by the configuration of the swirler 120 shown in Figs. The swirler 120 used in the local exhaust system 100 according to the present invention includes a rotating plate member 121 connected to the driving unit 110 to rotate and a vortex Fs disposed on the rotating plate member 121, And a plurality of vanes 130 that generate a plurality of vanes 130. The vanes 130 may include various other components. For example, an embodiment in which other components are added to the sweller 120 shown in Figs. 1 to 3 is shown in Figs. 5 and 6. Fig.

FIG. 5 is a schematic view illustrating a local exhaust system according to another embodiment of the present invention, and FIG. 6 is a perspective view of the inner guide member and the outer guide member shown in FIG. 5, viewed from above.

5 and 6, the local exhaust system 100 'according to another embodiment of the present invention includes a driving unit 110 and an exhaust port 101, A box 140 surrounding the swirler 120 and an auxiliary exhaust pipe 141 connected to the box 140. The outer side of the swirler 120 is connected to the outer side of the swirler 120, An outer guide member 150 disposed to surround the outer guide member 150 and guiding the vortex Fs generated by the swirler 120 and an outer guide member 150 disposed inside the outer guide member 150 and between the outer guide member 150 An inner guide member 160 which forms a vortex flow passage Ps through which the vortex Fs generated by the swirler 120 passes and an inner guide member 160 provided on the outer guide member 150, And an external air guide unit 153 for guiding external air toward the eddy current Fs.

The driving unit 110, the exhaust pipe 101, the swirler 120, the box 140, and the auxiliary exhaust pipe 141 are the same as those of the local exhaust device 100 described with reference to FIGS. 1 to 4, do.

The outer guide member 150, the inner guide member 160 and the outer air guide unit 153 are installed in the box 140 in addition to the sweller 120.

The outer guide member 150 has a cylindrical shape extending a predetermined height in a direction parallel to the rotation center axis C, for example, in a vertical direction while surrounding the outer periphery of the swirler 120. The outer guide member 150 is spaced apart from the outer circumferential surface of the swirler 120, specifically, the outer circumferential surface of the second guide member 132, and the upper end thereof is horizontally The support plate 170 may be fixed to the support plate 170. Therefore, even if the swirler 120 rotates, the outer guide member 150 does not rotate.

The support plate 170 may be fixed to the exhaust pipe 101 and the swelller 120 may be spaced apart from the bottom surface of the support plate 170 by a predetermined distance Respectively. At least one, preferably a plurality of air inflow holes 172 may be formed in the support plate 170 to allow air to flow smoothly toward the sweller 120.

The outer guide member 150 may be formed in a cylindrical shape having a predetermined diameter. The height of the outer guide member 150 may be properly determined in consideration of the distance between the sweller 120 and the contamination source, the diameter of the sweller 120, and the like, for example, within a range of approximately 100 mm to 400 mm.

The outer guide member 150 having the above-described structure guides the vortex Fs generated by the plurality of blades 130 of the swirler 120 in the direction parallel to the rotation center axis C, It serves as a guide.

The inner guide member 160 is disposed inside the outer guide member 150. The inner guide member 160 is installed to be fixed to the outer guide member 150. For this purpose, the inner guide member 160 and the outer guide member 150 are spaced apart from each other in the circumferential direction and extend in the radial direction A plurality of connecting members 165 may be installed. The inner guide member 160 is disposed below the swirler 120 and spaced apart from the swirler 120 by a predetermined distance so as not to interfere with the rotation of the swirler 120.

The inner guide member 160 is formed in a cylindrical shape having a diameter smaller than the diameter of the outer guide member 150 so that the sweller 120 The vortex flow passage Ps through which the vortex Fs generated by the vortex flow passage Ps passes is formed. The inner guide member 160 not only forms the vortex flow passage Pa as described above but also a part of the vortex Fs passing through the vortex flow passage Pa flows inwardly toward the exhaust flow Fe It can prevent the water from flowing.

An annular fixing plate member 161 may be installed inside the inner guide member 160. The fixing plate member 161 may be horizontally disposed below the rotating plate member 121 of the swirler 120 at a predetermined interval from the rotating plate member 121.

The fixing plate member 161 is fixed to the inner guide member 160. Specifically, the outer edge portion of the fixing plate member 161 may be fixed to the inner guide member 160. Therefore, the fixing plate member 161 does not rotate in the same manner as the inner guide member 160.

A hollow 162 communicating with the exhaust hole 122 formed in the rotary plate member 121 is formed in the central region of the fixing plate member 161. The contaminated air in the exhaust region is discharged through the hollow 162 and the exhaust hole 162. [ (122) and sucked into the exhaust pipe (101). The fixing plate member 161 may be provided with a cylindrical exhaust passage forming member 163 which surrounds the hollow 162 and forms an exhaust passage Pe communicating with the exhaust pipe 101 . The exhaust passage forming member 163 may be installed on the upper surface and the lower surface of the fixing plate member 161, respectively.

Various attempts have been made to further stabilize the exhaust flow (Fe). Among these attempts, when the outer air guide unit 153 having the following configuration is additionally provided in the outer guide member 150, the exhaust flow Fe is further stabilized and the exhaust efficiency is further improved I could.

The outer air guide unit 153 guides the air outside the outer guide member 150 toward the vortex Fs and is installed outside the lower end of the outer guide member 150.

Specifically, the outer air guide unit 153 may include an outer air passage forming member 151 and a plurality of outer air guide members 152.

The outer air passage forming member 151 has a cylindrical shape extending a predetermined height in a direction parallel to the rotation center axis C, for example, in the vertical direction, surrounding the lower end of the outer peripheral surface of the outer guide member 150. The outer air passage forming member 151 is spaced apart from the outer circumferential surface of the outer guide member 150 by a predetermined distance so that external air passes between the outer guide member 150 and the external air passage forming member 151 Is formed.

The plurality of outer air guide members 152 are installed between the outer guide member 150 and the outer air passage forming member 151 to guide the outer air in a direction parallel to the rotation center axis C, And may have a plate shape elongated in a direction parallel to the rotation center axis C, for example, in the vertical direction. For example, the plurality of outer air guide members 152 may be spaced apart from each other along the outer circumferential surface of the outer guide member 150.

When the local exhaust system 100 'having the above-described configuration is operated, a flow of air is formed outside the outer guide member 150 by the rapid flow of the vortex Fs. At this time, the outside air flows into the passage between the outer air passage forming member 151 of the outside air guide unit 153 and the outside guide member 150, and the outside air introduced into the passage flows through the outside air guide member 152 To the vortex Fs while being guided in a direction parallel to the rotational center axis C of the swirler 120, that is, in the vertical direction. The flow of the outside air is discharged through the lower end of the vortex flow passage Pa and merges with the vortex Fs spreading sideways. Accordingly, the vortex Fs flows into the box 140 while being gently reversed by the flow of the external air. 1, the vortex Fs shown in FIG. 5 flows into the box 140 while being relatively sharply bent while exiting from the lower end of the air flow passage Pa, whereas the vortex FS shown in FIG. Flows out of the lower end of the vortex flow passage Pa and is influenced by the flow of the outside air and flows into the box 140 while bending it relatively gently.

As described above, when the swirling flow Fs that exits the lower end of the vortex flow passage Pa flows into the box 140 while bending it relatively gently, The angle becomes narrower, and thus the exhaust efficiency for a narrower contamination area can be improved.

On the other hand, when the pollutant generation area is relatively wide, it is possible to prevent the pollutant generation in a relatively wide working area such as a plating factory, a tire manufacturing factory, a semiconductor manufacturing factory, a welding workshop of a shipyard, an auto parts manufacturing factory, a soldering workshop, In the case where a large amount of air polluted by contaminants such as a substance, dust, or odor is generated, it is difficult to sufficiently exhaust such a large amount of polluted air by only one local exhaust system. In this case, by installing two or more of the local exhaust systems 100 and 100 'according to the present invention, contaminated air generated in a wider area can be efficiently exhausted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of protection of the present invention should be determined by the appended claims.

100, 100 '... local exhaust device 101 ... exhaust pipe
102 ... Sirocco fan 110 .. Drive
111 ... drive motor 112 ... rotation shaft
120 ... Sweller 121 ... Rotating plate member
122 ... exhaust hole 123 ... exhaust passage forming member
126 ... connecting portion 127 ... rotational axis connecting portion
128 ... Rotary shaft inserting hole 129 ... Securing screw
130 ... wing 130a ... secondary wing
131 ... first guide member 132 ... second guide member
133 ... third guide member 135 ... first barrier
136 ... second barrier 140 ... box
141 ... auxiliary exhaust pipe 142 ... opening
144 ... fan 150 ... outer guide member
151 ... outer air passage forming member 152 ... outer air guide member
153 ... External air guide unit 160 ... Inner guide member
161 ... fixing plate member 162 ... hollow
163 ... exhaust passage forming member 165 ... connecting member
170 ... support plate 172 ... air inflow hole

Claims (18)

A driving unit;
A rotating plate member disposed near the suction port of the exhaust pipe and generating a vortex by being rotated by the driving unit, the rotating plate member being connected to the driving unit and having an exhaust hole communicating with the exhaust pipe in a central region; A sweller including a plurality of blades for generating an air flow that rotates while forming the vortex;
A box for accommodating the sweller therein; And
And an auxiliary exhaust pipe connected to the box for discharging the air inside the box to the outside,
An opening is formed in one wall of the box at a portion corresponding to the vortex discharge surface of the sweller,
A vortex generated by the swirler and discharged through the vortex discharge surface is formed between a wall surface of the box on which the opening is formed and a vortex discharge surface of the swirler, And the air is introduced into the box through the gap. The method according to claim 1,
Wherein the diameter of the opening is larger than the outer diameter of the sweller. The method according to claim 1,
And the auxiliary exhaust pipe is connected to a wall opposite to the opening of the box. The method according to claim 1,
Wherein a fan is installed in the box to flow a vortex introduced into the box through the gap toward the auxiliary exhaust pipe. The method according to claim 1,
The swirler includes a cylindrical first guide member provided at an outer side edge portion of the rotating plate member and an air flow passage formed between the first guide member and the first guide member so as to surround the outer ends of the plurality of blades And a third guide member installed to cover an upper portion of the plurality of vanes. 6. The method of claim 5,
Wherein the plurality of blades are radially disposed on the upper surface of the rotating plate member and the outer ends of the plurality of blades protrude from the outer edge of the rotating plate member and extend to the lower end of the outer peripheral surface of the first guide member Local exhaust system. The method according to claim 6,
Wherein the swirler further comprises a plurality of auxiliary vanes provided between the first guide member and the second guide member and the plurality of auxiliary vanes are disposed at regular intervals along the outer circumferential surface of the first guide member, Is arranged alternately with the wings of the first and second exhaust manifolds. 8. The method of claim 7,
Wherein an upper end of each of the plurality of auxiliary wings extends to a lower surface of the third guide member and a lower end of the auxiliary wing extends to a lower end of the first guide member. 6. The method of claim 5,
Wherein the swirler further comprises a retarding means provided between the rotating plate member and the third guide member for retarding the airflow generated by the plurality of blades. 10. The method of claim 9,
Wherein the retarding means includes a plurality of barriers provided between the upper surface of the rotating plate member and the lower surface of the third guide member so as to have a height lower than a height of the plurality of blades. 11. The method of claim 10,
Wherein the plurality of barriers are installed such that a path of an air flow passing between the rotating plate member and the third guide member is serpentine. 12. The method of claim 11,
Wherein the plurality of barriers have diameters different from each other and are concentrically arranged with a radial spacing about the rotation center axis of the swirler,
Wherein some of the plurality of barriers are installed so as to protrude upward from the upper surface of the rotary plate member and the rest of the barriers protrude downward from the lower surface of the third guide member. 13. The method of claim 12,
Wherein the plurality of barriers include at least two first barriers protruding upward from the upper surface of the rotating plate member and at least two second barriers protruding downward from the lower surface of the third guide member, Wherein the barrier and at least two second barriers are alternately arranged from the outer edge of the rotating plate member toward the rotational center axis. 14. The method according to any one of claims 1 to 13,
An outer guide member disposed to surround the outer periphery of the swirler and guiding the vortex generated by the swirler in a direction parallel to the rotation center axis of the swirler;
An inner guide member disposed on the inner side of the outer guide member and defining a vortex flow passage through which the vortex generated by the swirler passes between the inner guide member and the outer guide member; And
And an outer air guide unit installed on the outer guide member and guiding the air outside the outer guide member to the vortex flowing into the box through the gap. 15. The method of claim 14,
Wherein at least one air inflow hole is formed in the support plate so as to allow air to flow into the sweller,
Wherein the outer guide member is a cylindrical member spaced from an outer circumferential surface of the swirler, and the upper end portion is fixed to the support plate,
Wherein the inner guide member is a cylindrical member having a diameter smaller than the diameter of the outer guide member and is disposed below the sweller and spaced apart from the swirler and fixed to the outer guide member. Device. 15. The method of claim 14,
A plurality of connecting members extending in the radial direction and spaced apart in the circumferential direction are provided between the inner guide member and the outer guide member and the inner guide member is fixed to the outer guide member through the plurality of connecting members . 15. The method of claim 14,
The external air guide unit includes:
An outer air passage forming member provided outside the lower end portion of the outer guide member to form a passage through which the outside air passes between the outer guide member and the outer guide member;
And a plurality of external air guide members installed between the external guide member and the external air passage forming member and guiding the external air in a direction parallel to the rotational center axis of the swirler. 18. The method of claim 17,
Wherein the outer air passage forming member has a cylindrical shape extending in parallel with a rotation center axis of the swirler and surrounding the outer circumferential surface of the outer guide member and being spaced from the outer circumferential surface of the outer guide member,
Wherein the plurality of outer air guide members have a plate shape elongated in a direction parallel to a rotation center axis of the swirler and are arranged at regular intervals from each other along the outer peripheral surface of the outer guide member. .

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