KR20190056930A - Local ventilation equipment - Google Patents

Abstract

Local ventilation equipment is disclosed. The disclosed equipment comprises: a main body forming a suction unit on a lower surface; a swirl forming device provided with a swirler arranged in the suction unit and rotating to form a swirl; a filter arranged in the suction unit and filtering air sucked into the main body through the suction unit; and a suction grill installed in the suction unit to be arranged at a lower part of the swirler and installing the filter to be attachable and detachable, wherein the suction grill is divided into a first area, positioned within the suction grill according to the diametric direction of the suction unit, and a second area positioned out of the first area, the filter is installed on the first area, and a passage for passing the swirl, formed by the swirler, through the suction grille. The present invention prevents a fault and enhances stability.

Description

[0001] LOCAL VENTILATION EQUIPMENT [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a local exhaust system, and more particularly, to a local exhaust system used for suctioning contaminants floating in a room and discharging it to the outside.

Generally, a kitchen is provided with a cooking table on which a heating device such as an electric heater or a gas range for cooking, such as boiling or baking, is provided by applying high-temperature heat to food.

At this time, the food to be heated by the high temperature of the heating mechanism disposed on the counter top generates contaminants such as smoke, odor and oil vapor during the heating process. Such contaminants may float by heat and spread throughout the kitchen or the entire room, and thus the dispersed contaminants provide an unpleasant odor, causing an aversion, and especially in a closed kitchen, such contaminants reduce the concentration of the worker It is a factor that harms the health of the worker.

Accordingly, the kitchen hood is provided with a range hood for discharging contaminants such as smoke, odor, and oil vapor generated when food is cooked outdoors.

The range hood includes a hood body having an intake port formed on a lower surface of the range hood and an air blower for generating airflow for sucking air into the hood body to discharge air into the hood body, A filter for filtering the air sucked into the main body, and a pipe for forming a passage for discharging the air sucked into the main body through the filter to the outside.

Hereinafter, the operation of the range hood constructed as described above will be described.

The pollutants generated in the process of heating the food to be cooked by the heating device in the cooking compartment are raised by self buoyancy due to the temperature higher than the ambient air or forcedly raised by the airflow formed by the blower of the range hood, The material passes through the filter and exits through piping connected to an external duct.

The range hood has a disadvantage in that air and contaminants near the suction port formed on the lower surface of the hood main body can be inhaled to some extent but air and contaminants far from the suction port can not be sucked properly.

This is because, as the distance from the suction port increases, the flow rate of the intake air flow decreases in inverse proportion to the square of the distance from the suction port. Therefore, increasing the suction flow rate of the suction fan does not increase the collecting efficiency of the pollutant proportionally Do not.

That is, the conventional range hood is not suitable for removing the contamination occurring at a position far from the intake port because the suction performance is rapidly reduced as the distance from the intake port is reduced, and the effective intake region is limited to a small region of the intake port diameter.

In order to overcome these disadvantages, a range hood using a vortex was developed. The range hood blows a quantity of air similar to the intake flow into the space to generate a vortex, and the collected vortex is used to increase the collection efficiency I will.

However, according to such a range hood, a noise is generated due to the turbulence caused by the mutual interference between the flow blowing in the narrow region below the intake port and the suction flow, and the flow of the pollutant in the space It is necessary to install additional equipment such as a blower, a filter, and a flow pipe for generating a vortex

On the other hand, recently, an exhaust device using a Swirler has been introduced. The swirler includes a rotary plate rotatably installed on the suction port side of the exhaust device, and includes a disk-shaped rotary plate, a plurality of blades arranged on the lower surface of the rotary plate to form vortices, and a drive motor for rotating the rotary plate do.

The swirler thus configured serves to generate a vortex around the suction port of the exhaust device during rotation to enlarge the suction area of the exhaust device.

However, in the exhaust system equipped with a swallower, the swallower is inevitably exposed to the lower portion of the exhaust device through the intake port, so that the user's finger or the like is introduced into the swirl side through the suction port, .

It is an object of the present invention to provide a local exhaust system with improved structure so as to prevent occurrence of injury of a user due to swirlers and to provide improved safety.

It is another object of the present invention to provide a local exhaust system having an improved structure so that the structure for preventing contamination of the local exhaust system can be easily and effectively installed.

The local exhaust device according to the present invention comprises: a main body portion having an intake port formed on a lower surface thereof; A vortex forming device disposed at the inlet port and having a swirl that is rotated to form a vortex; A filter disposed in the intake port for filtering air sucked into the main body through the intake port; And a suction grille disposed at the suction port and disposed at a lower portion of the swirler and having the filter detachably installed therein, wherein the suction grill is disposed inside the suction grille along the diametrical direction of the suction port Wherein the first region is divided into a first region and a second region located outside the first region, the filter is provided in the first region, and the vortex formed in the swirler in the second region passes through the suction grille A passageway is formed.

The suction grille may further include: a radial member having a plurality of ribs radially connected; A concentric member having a plurality of ribs arranged in a concentric form and connected to the radial member; And an outer frame member disposed on the outer side of the concentric member and connected to the radial member and coupled to the body portion.

The radial member is divided into an inner section including a lateral center of the radial member and an outer section disposed outside the inner section, and between the inner section and the inner section, the inner section and the outer section And the first connection unit connects the inner section and the outer section such that the inner section is positioned above the outer section.

The first region is an area including the inner section and the second region is an area including the outer section, and the first region and the second region are arranged in a concentric pattern And the first connection part forms a boundary between the first area and the second area.

A second connection part for connecting between the outer section and the outer frame member is formed between the outer frame member and the outer section so that the outer section is located below the outer frame member, It is preferable that the inner sections are arranged at the same height.

The suction grille may further include a protrusion protruding toward the lateral center of the radial member from the concentric member connected to the outer section to support the filter from below.

It is also preferable that a plurality of the protrusions are arranged at predetermined intervals along the circumferential direction of the concentric member.

It is also preferable that the protruding portion is formed so as to protrude in a rounded shape.

It is preferable that the outer frame member is formed in a circular ring shape, and the outer frame member is formed with a fastening hole for fastening between the body portion and the outer frame member.

The outer frame member is provided with a plurality of coupling holes spaced apart from each other along the circumferential direction of the outer frame member at an interval, and an outer frame member is provided at an outer periphery of the outer frame member, It is preferable that an alignment portion for guiding the installation position of the suction grille is formed so that the fastening hole is located at the position specified with respect to the main body portion.

According to the local exhaust system of the present invention, the suction grille is installed at the lower part of the swallow, and the suction grille serves as a blocking wall for blocking the user's fingers or other foreign substances from approaching the swallow side, It is possible to prevent the occurrence of a fault of the local exhaust device due to the collision between the foreign substance and the swirl of the user due to the swirl, and to provide the improved safety.

In addition, the present invention can easily and quickly install and replace filters by a simple and simple operation of inserting or removing the filter into or from the filter mounting space formed in the suction grille, thereby facilitating mounting of the structure for preventing contamination of the local exhaust system It is possible to provide an effect that can be effectively achieved.

1 is a perspective view illustrating a local exhaust system according to an embodiment of the present invention.
2 is a bottom perspective view of the local exhaust system shown in Fig.
3 is a sectional view taken along the line " AA " in Fig.
4 is a sectional view showing the internal structure of the fan apparatus shown in FIG.
FIG. 5 is a perspective view of a portion of the vortex forming apparatus shown in FIG. 3 separated.
6 is a front view of the vortex forming apparatus shown in Fig.
FIGS. 7 to 9 are views showing a manufacturing process of the vortex forming apparatus shown in FIG.
10 is a view showing the flow of air in the vortex forming apparatus shown in Fig.
11 is a perspective view showing another example of the vortex forming apparatus shown in Fig.
12 is a front view of the vortex forming apparatus shown in Fig.
13 is a view showing the flow of air in the vortex forming apparatus shown in Fig.
14 is a perspective view showing the suction grille and the filter shown in Fig.
15 is a sectional view taken along the line BB of Fig.
16 is a bottom view showing a state in which the suction grill is coupled to the main body;
17 and 18 are sectional views showing a state in which the filter is installed on the suction grill.

Hereinafter, embodiments of the local exhaust system according to the present invention will be described with reference to the accompanying drawings. For convenience of explanation, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

[Overall structure of whole exhaust system]

FIG. 1 is a perspective view showing a local exhaust system according to an embodiment of the present invention, FIG. 2 is a bottom perspective view of the local exhaust system shown in FIG. 1, and FIG. 3 is a cross- .

1 to 3, a local exhaust system 1 according to an embodiment of the present invention includes a main body 100 and a blower 200.

The main body 100 forms an appearance of the local exhaust system 1 according to the present embodiment and may include a lower housing 110 and an upper housing 120.

The lower housing 110 is disposed at a lower portion of the main body 100 and a space for allowing air sucked through the intake ports 110a and 110b to flow therein is formed in the lower housing 110. [ In the present embodiment, the lower housing 110 is illustrated as being formed in a flat box shape having a longitudinal length and a lateral width in comparison with a height.

In the lower surface of the lower housing 110 formed as described above, the intake ports 110a and 110b are formed. The intake ports 110a and 110b are formed to pass through the lower surface of the lower housing 110 to form a passage for allowing the outside air to be sucked into the space inside the lower housing 110. [

In the present embodiment, the intake ports 110a and 110b are illustrated as including the main intake port 110a and the auxiliary intake port 110b.

The main intake port 110a is disposed at the center in the width direction of the lower housing 110 so that a passage for sucking the outside air into the space inside the lower housing 110 is formed in the widthwise center of the lower housing 110 .

The auxiliary intake ports 110b are disposed on both sides in the width direction of the lower housing 110, respectively. Each auxiliary intake port 110b is spaced apart from the main intake port 110a by a predetermined distance along the width direction of the lower housing 110 so that the passage for sucking the outside air into the space inside the lower housing 110 Are formed on both sides in the width direction of the housing (110).

Thus, the local exhaust device 1 of the present embodiment can expand the intake-enabling region in the width direction not only to the region around the main intake port 110a but also to the region around the auxiliary intake port 110b, So that it can be collected and discharged.

According to the present embodiment, the lower housing 110 may be provided with a suction duct 111 and a lower panel 115 coupled to each other in a vertical direction.

The suction duct 111 is provided in the form of a flat box with its lower surface opened. A lower panel 115 is coupled to an open lower surface of the suction duct 111. An upper portion and a side portion of the suction duct 111 are surrounded by a suction duct 111 and a lower portion of the suction duct 111 is surrounded by a lower panel 115 An enclosed space portion is formed. The upper housing 120 is connected to the upper portion of the suction duct 111 and the connection portion of the suction duct 111 with the upper housing 120 is connected to the inside of the lower housing 110 and the inside of the upper housing 120, Are connected to each other.

The lower panel 115 is coupled to the open lower portion of the suction duct 111 to form the bottom surface of the lower housing 110. The lower panel 115 is provided at a lower portion of the suction duct 111 such that the width of the lower panel 115 is shorter than that of the suction duct 111 and the center of the lower panel 115 is positioned in the widthwise center of the suction duct 111. A gap is formed between the width direction end portion of the lower panel 115 and the width direction end portion of the suction duct 111. The gaps formed on both sides in the width direction of the lower housing 110 are formed in the auxiliary intake port 110b, Lt; / RTI >

The lower panel 115 is provided with a groove 116. The groove portion 116 is formed in a substantially central portion of the lower panel 115 to have a concave shape toward the inside of the lower housing 110. A main air inlet 110a is formed in the groove portion 116 so as to pass through the groove in the vertical direction.

The upper housing 120 is disposed at an upper portion of the main body 100, and a receiving space is formed at an upper portion of the upper housing 120. In the present embodiment, the upper housing 120 is illustrated as being formed in the shape of a box having an open bottom. The opened lower portion of the upper housing 120 is connected to the opened upper portion of the lower housing 110 so that the air sucked through the lower housing 110 can flow into the receiving space inside the upper housing 120 .

In the housing space inside the upper housing 120, a blowing device 200 is installed. The air blowing apparatus 200 is installed in a housing space inside the upper housing 120, that is, inside the main body 100, and forms an air flow for sucking the outside air into the main body 100 through the intake ports 110a and 110b do.

In addition, the local exhaust device 1 of the present embodiment may further include a vortex forming device 300. The vortex forming device 300 is installed in the main body 100 and more specifically in the lower housing 110 so that the suction of the outside air into the main body 100 through the intake ports 110a and 110b A vortex is formed in a region around the intake ports 110a and 110b so as to be guided.

[Structure of the blowing apparatus]

4 is a sectional view showing the internal structure of the fan apparatus shown in FIG.

Referring to FIGS. 3 and 4, the blower 200 may include a scroll housing 210, an impeller 220, and a first driving unit 230.

The scroll housing 210 forms an outer appearance of the fan unit 200 and a scroll housing 210 is formed on the side of the scroll housing 210 to form a passage through which external air is sucked into the impeller 220. The scroll housing 210 is formed at both sides of the scroll housing 210. The scroll housing 210 serves as a suction passage for sucking air through the both sides of the blower 200. [

In this embodiment, the scroll housing 210 is illustrated as being formed in a shape including a cylindrical shape in which both sides are open, and both open sides of the scroll housing 210 are provided with the scroll housing 210.

An accommodating space for accommodating the impeller 220 is formed inside the scroll housing 210. The inner circumferential surface of the scroll housing 210 facing the receiving space is formed as a curved surface surrounding the outer circumferential surface of the impeller 220.

The discharge portion 215 is provided at an upper portion of the scroll housing 210. A discharge port 216 connected to a receiving space inside the scroll housing 210 is formed to pass through the discharge port 215. The discharge port 216 is connected to the suction port Thereby forming a passage through which air is blown out of the air blowing device 200.

The discharging unit 215 may protrude upward from the main body 100 through the upper housing 120 in an upward direction and may be connected to an external duct (not shown) from the outside of the main body 100. The air sucked into the housing space in which the impeller 220 is accommodated can be discharged to the outside through the discharge port 216 formed in the discharge part 215 and the external duct connected thereto.

The impeller 220 is provided so as to be rotatable about a laterally extending axis. The impeller (220) has a space portion through which air sucked through the side of the impeller (220) flows.

The impeller 220 includes a hub 221 having a rotation shaft connection portion to which a rotation shaft of a motor provided in the first drive portion 230 is connected. The impeller 220 connected to the rotation axis of the motor provided in the first driving unit 230 through the hub 221 is provided to be rotatable about a laterally extending axis.

The impeller 220 includes a first blade 223 formed on one side of the hub 221, that is, a left side surface of the hub 221, and a second blade 223 formed on the other side of the hub 221, And the second blade 225 may be further included.

The impeller 220 may include a turbo fan, a sirocco fan, or the like. When the impeller 220 is provided in a form including a turbo fan, the first blade 223 and the second blade 225 may be configured in the form of a rear blade of a turbo fan. When the impeller 220 is provided in a form including a sirocco fan, the first blade 223 and the second blade 225 may be configured as multi-blade blades of a sirocco fan.

The first blade 223 may be installed so as to be positioned between the left side surface of the hub 221 and the left side surface of the scroll housing 210 and spaced apart from the left side surface of the scroll housing 210 have. The second blade 225 is installed between the right side surface of the hub 221 and the right side surface of the scroll housing 210 so as to be spaced apart from the right side surface of the scroll housing 210.

The first driving unit 230 is provided to provide power for rotating the impeller 220. The first driving part 230 includes a rotor 231 serving as a rotating part of the motor, a stator 233 serving as a stop part of the motor, and a rotor 231 and a stator 233 A motor case 235 for rotating the rotor 231, and a shaft 237 rotated together with the rotor 231. The coupling between the first driving unit 230 and the impeller 220 is achieved by coupling between the shaft 237 and the hub 221 so that the power generated by the first driving unit 230 is transmitted to the shaft 237 and the hub 221 To the impeller 220 so that the impeller 220 can be rotated.

The air blowing device 200 having the above-described configuration can be operated in any one of a plurality of modes in which the air blowing device 200 is classified according to the amount of air to which air is sucked.

For example, the air blowing device 200 may be operated in a high airflow mode that forms an airflow for sucking outside air into the main body 100 through the intake ports 110a and 110b at a high level of air volume, Mode, which forms an intake air flow at a relatively low flow rate as compared with the mode.

Whether the fan apparatus 200 is operated in the high airflow mode or the low airflow mode may be determined by the rotational speed of the first driving unit 230 that rotates the impeller 220. That is, since the first driving unit 230 is operated to rotate the impeller 220 at a high speed, the fan apparatus 200 can be operated in a high airflow mode and the impeller 220 can be rotated at a relatively low speed The fan unit 200 can be operated in the low airflow mode.

When the air blowing device 200 is operated in the high airflow mode, it is possible to form an intake air flow at a high flow rate, so that contaminants of a greater distance can be sucked, so that the trapping of pollutants in the local exhaust device 1 The efficiency can be increased.

When the air blowing device 200 is operated in the low airflow mode, the speed of the intake airflow is lower than that in the high airflow mode, so that the efficiency of collecting the pollutants in the local exhaust 1 is lowered. However, Thereby reducing noise and power consumption.

 According to the present embodiment, the operation of the vortex forming apparatus 300 can be performed together when the air blowing apparatus 200 is operated in the low airflow mode. The vortex forming device 300 generates a vortex in the form of a donut shape around the intake ports 110a and 110b and more specifically around the main intake port 110a to enlarge the intake area of the exhaust device, Even when the speed is low, the pollutants and air can be sucked in more efficiently.

[Structure of Vortex Forming Apparatus]

FIG. 5 is a perspective view showing a part of the vortex forming apparatus shown in FIG. 3, and FIG. 6 is a front view of the vortex forming apparatus shown in FIG.

Referring to FIGS. 3, 5 and 6, the vortex forming apparatus 300 includes a swirler 310, a second driving unit 320, and a flow guide 330.

The swirler 310 is disposed at the intake ports 110a and 110b, more specifically, at the main intake port 110a and can be rotated to form a vortex around the main intake port 110a. The swirler 310 may include a rotating plate 311 and a wing 315.

The rotation plate 311 is disposed so as to be positioned below the main air intake port 110a and to be disposed in a region surrounded by the groove portion 126 of the lower panel 125. [ The center of the rotation plate 311 is connected to the shaft of the second driving unit 320 and is rotatable about the shaft, that is, the rotation axis extending in the vertical direction.

A coupling portion 312 for coupling the rotary plate 311 to the shaft of the second driving portion 320 is provided at the center of the rotary plate 311 and air sucked into the rotary shaft 311 is sucked into the main intake port 110a And a through hole is formed for passing.

In this embodiment, the rotating plate 311 is illustrated as being formed in the form of a circular ring. The through hole of the rotating plate 311 is formed to pass through between the outer peripheral surface of the rotating plate 311 and the engaging portion 312. The coupling portion 312 is provided at a central portion of the rotary plate 311 at a position surrounded by the through hole and is connected to the rotary plate 311 by a connection portion 313 crossing between the outer peripheral surface of the rotary plate 311 and the coupling portion 312. [ ). ≪ / RTI > As an example, the rotary plate 311 may be formed in such a manner that the outer peripheral surface of the rotary plate 311, the coupling portion 312 and the coupling portion 313 are connected in a " shape ".

The wing portion 315 is disposed so as to surround the radially outer side of the rotating plate 311. The wing portion 315 may include a flat portion 316 and wings 317 and 318.

The plane portion 316 is formed to be flush with the rotating plate 311. A plurality of such planar portions 316 are arranged along the rotational direction of the rotary plate 311 so as to surround the outside of the rotary plate 311 in the radial direction.

A through hole 319 is formed between two adjacent planar portions 316. The through hole 319 is formed to penetrate between the flat surface portion 316 and the flat surface portion 316 so that the through hole portion 319 penetrates the wing portion 315 along the extending direction of the rotating shaft for rotating the rotating plate 311, Thereby forming a passage. The planar portion 316 and the through hole portion 319 are alternately arranged on the outer side in the radial direction of the rotary plate 311 along the rotation direction of the rotary plate 311. [

The blades 317 and 318 are formed so as to protrude from the flat surface portion 316 in the extending direction of the rotating shaft, that is, the downward direction. These vanes 317 and 318 act to push the air toward the outer side of the rotary plate 311 while being rotated together with the rotary plate 311. The vortex forming device 300 is operated by the vanes 317 and 318, 110a. ≪ / RTI >

A plurality of blades 317 and 318 are arranged along the rotating direction of the rotating plate 311 so as to surround the outside of the rotating plate 311 in the radial direction. That is, wings 317 and 318 are disposed for each of the flat portions 316, respectively. Each of the vanes 317 and 318 may be formed by bending a portion of the flat surface portion 316 downward.

According to the present embodiment, each of the vanes 317 and 318 may include a first vane 317 and a second vane 318.

The first wing 317 is disposed on one side of the plane portion 316 corresponding to the rotation direction of the rotation plate 311 and the second wing 318 is disposed on a side of the plane portion 316 corresponding to the rotation direction of the rotation plate 311 And is disposed on the other side.

That is, one side of the flat portion 316 is folded to form the first wing 317, and the other side of the flat portion 316 is folded to form the second wing 318.

Alternatively, each of the plurality of blades 317 and 318 may be coupled to the rotary plate 311.

The vortex forming apparatus 300 having the swirler 310 is installed on the main air intake port 110a through which the air is introduced. Accordingly, the flow of the air sucked through the main air inlet 110a may affect the operation of the vortex forming device 300, and the vortex forming device 300 may affect the flow of the air sucked through the main air inlet 110a Lt; / RTI >

For example, if the frequency of the air sucked into the main intake port 110a collides with the swallower 310 during the operation of the vortex forming device 300, The rotational speed of the main intake port 110a may be lowered and the formation of vortices may not be properly performed. In addition, the intake of air through the main intake port 110a may be interrupted.

In consideration of this, the vortex forming apparatus 300 of the present embodiment is formed with a through-hole portion 319 forming a passage passing through the swirler 310. A part of the air flowing into the swirler 310 is pushed outwardly of the swirler 310 by the action of the vanes 317 and 318 to form a vortex and the remaining portion is passed through the through hole 319 Through the swirler 310 and into the upper part of the vortex forming device 300.

This reduces the resistance caused by the collision between the air sucked into the main intake port 110a and the swirler 310, thereby further improving the performance of the vortex-forming device 300 and improving the performance of the main intake port 110a The air can be sucked in more smoothly.

Meanwhile, the second driving unit 320 is provided to provide power for rotating the swirler 310, and is installed inside the main body 100, more specifically, inside the second casing 120. [ The second driving unit 320 may include a motor disposed at the uppermost position in the structure of the vortex forming apparatus 300 and having a shaft extending in a downward direction to transmit a rotational force.

The flow guide 330 is disposed in the main air inlet 110a and is provided to surround the swirler 310 from the upper side so as to guide the air flowing downward during the rotation of the swirler 310 downward.

In addition, the local exhaust device 1 of the present embodiment may further include a filter 500 and a suction grill 600.

The filter 500 is provided for filtering the air sucked into the main body 100 through the main air inlet 110a.

The suction grill 600 is disposed under the vortex forming apparatus 300, and more specifically, below the swallow 310, as will be described later. The suction grill 600 is provided with a filter 500 detachably attached thereto.

In this embodiment, the suction grill 600 is illustrated as being formed in the shape of a circular grill, but the shape of the suction grill 600 is not limited thereto. The shape of the suction grill 600 may be a rectangular plate shape, may be formed in various shapes corresponding to the shape of the main air inlet 110a, and may be determined in various shapes as required.

The suction grill 600 may be installed at a lower part of the vortex forming device 300 while being coupled to the lower panel 115 of the lower housing 110 to cover the main air inlet 110a from the bottom. As an example, the suction grill 600 may be coupled to the lower panel 115 in a manner that is bolted thereto.

The filter 500 and the suction grill 600 installed as described above function not only to filter the air sucked through the main air inlet 110a but also to filter out the external object during the rotation of the swirler 310, Thereby preventing the user's hands, cooking utensils, and the like from approaching the swallower 310, thereby enhancing the safety of the appliance and the user.

[Formation structure of wing portion]

FIGS. 7 to 9 are views showing a manufacturing process of the vortex forming apparatus shown in FIG.

6 and 7, the rotating plate 311 and the wing 315 are formed by a single disk prepared for manufacturing the swaller 310. [ In this disk, the inside of the disk in the radial direction becomes the rotating plate 311, and the outside of the disk in the radial direction becomes the blade 315. At this time, the wing portion 315 is formed with only the planar portion 316 which is flush with the rotating plate 311.

6 and 8, when the wing portion 315 is cut so that the wing portion 315 is divided into a plurality of portions along the circumferential direction of the disk, the wing portion 315 is provided with a plurality of A flat portion 316 is formed.

Then, as shown in Figs. 6 and 9, when the both sides of each of the plurality of divided planar portions 316 are bent downward, the first wing 317 and the second wing 316 are formed on both sides of each planar portion 316, Two wings 318 are formed respectively.

For example, after the two adjacent planar portions 316 are cut out, one of the two planar portions 316 adjacent to each other is bent in the direction of extension of the rotation axis, that is, the downward direction, And the second wing 318 may be formed by bending the other incised side downward.

As a result, the first wing 317 is formed on the left side of the one flat surface portion 316 and the second wing 318 is formed on the right side. Thus, the first wing 317 and the second wing 318 are formed on both sides The wings 315 are formed in such a manner that a plurality of the flat portions 316 are arranged along the circumferential direction of the rotary plate 311 on the outer side in the radial direction of the rotary plate 311.

In order to form the first and second wings 317 and 318, a through hole 319 is formed between the two bent portions 316 adjacent to each other. The first wing 317 and the second wing 318 are formed on both sides of the flat surface portion 316 by one operation of bending the cut sides of the flat surface portion 316 downwardly, 316 can be performed at the same time. At this time, the through hole 319 is formed between the first wing 317 of two adjacent planar portions 316 and the second wing 318 of the other one of the two planar portions 316 adjacent to each other. .

Since the fixing structure for fixing the wing portion 315 to the rotary plate 311 and the fixing operation are not required by forming the wing portion 315 as described above, Reduce workload

The wing portion 315 is formed by cutting a part of the rotary plate 311 so that it is not necessary to fix the rotary plate 311 to the wing portion 315. Therefore, The range of the constraint depending on the strength of the swirler 310 is reduced, thereby reducing the manufacturing cost of the swirler 310.

[Action of Vortex Forming Apparatus]

10 is a view showing the flow of air in the vortex forming apparatus shown in Fig.

Hereinafter, the operation and effect of the local exhaust system and the vortex forming apparatus according to the present embodiment will be described with reference to FIGS. 3 to 5 and 10. FIG.

3 and 4, when the operation of the local exhaust device 1 is started, the operation of the air blowing device 200 is started, and thereby, the air outside the local exhaust device 1 is introduced into the main body 100 A suction air flow for sucking the air into the air blowing device 200 side is formed.

The suction air flow thus formed acts on the external air to be sucked through the suction ports 110a and 110b formed in the lower portion of the main body 100. The external air around the suction ports 110a and 110b is sucked Passes through the intake ports (110a, 110b) by the airflow, and is sucked into the main body (100).

The air sucked into the main body 100 and the contaminants sucked together with the air sucked into the main body 100 are sucked into the ventilator 200 through both sides of the ventilator 200, Discharged through the discharging unit 215 and the external duct connected thereto.

In this case, when the air blowing device 200 is operated in the high air flow mode, a suction flow of a high flow rate is formed and contaminants of a longer distance can be sucked, so that the efficiency of collecting pollutants in the local exhaust device 1 increases .

In contrast, when the air blowing device 200 is operated in the low airflow mode, the speed of the intake airflow is lower than that in the high airflow mode, so that the efficiency of collecting the pollutants in the local exhaust 1 is lowered. Noise and power consumption due to driving can be reduced.

According to the present embodiment, the operation of the vortex forming apparatus 300 can be performed together when the air blowing apparatus 200 is operated in the low airflow mode. The vortex forming device 300 generates a vortex around the intake ports 110a and 110b and more particularly around the main intake port 110a to enlarge the intake region of the exhaust system so that even when the intake air flow velocity is low, So that the suction of the material and the air can be performed more efficiently.

The action of the vortex forming device 300 is such that the vanes 317 and 318 rotating together with the rotating plate 311 rotated by the power provided by the second driving portion 310 move air flowing toward the main air inlet 110a, The air is pushed outward in the direction of the outer surface 311, and the air thus pushed out forms a vortex having the same shape as the donut shape.

Since the vortex forming device 300 is installed on the main air intake port 110a through which the air is introduced, the flow of air sucked through the main air intake port 110a may affect the operation of the vortex forming device 300 And the vortex forming device 300 may affect the flow of air sucked through the main air inlet 110a.

For example, if the frequency of the air sucked into the main intake port 110a collides with the rotating plate 311 during the operation of the vortex forming device 300, the resistance generated at this time causes the rotating plate 311 and the wing The rotational speed of the main intake ports 317 and 318 may be lowered and the vortex formation may not be performed properly. In addition, the intake of air through the main intake port 110a may be interrupted.

In consideration of this, the vortex forming apparatus 300 of the present embodiment is formed with a through-hole 319 which forms a passage through the wing 315, as shown in Figs. 5 and 10. A part of the air flowing into the wing portion 315 side of the swirler 310 is pushed outwardly of the rotating plate 311 by the action of the vanes 317 and 318 to form a vortex, Passes through the wing portion 315 through the hole portion 319, and flows out to the upper portion of the swaller 310.

This reduces the resistance caused by the collision between the air sucked into the main intake port 110a and the rotary plate 311, thereby further improving the performance of the vortex-forming device 300, and further improving the performance of the vortex-forming device 300 through the main intake port 110a The air can be sucked more smoothly.

[Other Embodiments of Vortex Forming Apparatus]

On the other hand, the local exhaust device having the above-described structure and the vortex forming device provided therein are merely one preferred embodiment of the present invention, and various embodiments that can replace them are possible.

Fig. 11 is a perspective view showing another example of the vortex forming apparatus shown in Fig. 5, Fig. 12 is a front view of the vortex forming apparatus shown in Fig. 11, Fig.

Hereinafter, other embodiments of the present invention will be described with reference to FIGS. 11 to 13. FIG.

Here, the same reference numerals as those shown in the drawings denote the same members having the same function, and a duplicate description will be omitted here.

11 and 12, the vortex forming apparatus 400 according to another embodiment of the present invention is similar to the vortex forming apparatus 300 (see FIG. 3) of the above- (415) is provided in a different form.

The wings 417 and 418 of the wing portion 415 include the first wing 417 and the second wing 418 and the first wing 417 and the second wing 418 are perpendicular to the plane portion 316, And is formed to protrude downward so as to form an acute angle or an obtuse angle with the flat surface portion 316. This is compared with the configuration in which the wings 317, 318 (see FIG. 5) in the above-described embodiment are bent so as to be perpendicular to the plane portion 316.

The first wing 417 and the second wing 418 are formed by being bent obliquely downward from the planar portion 316 and are disposed on the rotation plate 311 in the direction of rotation.

For example, if the rotation of the rotary plate 311 in the front direction is from the left to the right, the first wing 417 located on the left side of the plane portion 316 has an acute angle with the plane portion 316 And the second wing 418 located on the right side of the plane portion 316 protrudes downward from the plane portion 316 to form an obtuse angle with the plane portion 316 .

The first wing 417 located on the left side of the plane portion 316 is positioned at an obtuse angle with the plane portion 316 so that the plane of the plane portion 316 is parallel to the plane of the plane portion 316. In other words, And the second wing 418 located on the right side of the plane portion 316 may protrude downward from the plane portion 316 so as to protrude downward from the plane portion 316, .

The vortex forming apparatus 400 of the present embodiment is configured to form the vortex portion 415 and the wing portion 415 using the flow velocity energy of the air flowing into the vane portion 415 side, ) Can be induced efficiently.

According to the present embodiment, a part of the air flowing into the vane portion 415 side of the vortex forming device 400 is blown by the action of the vanes 417 and 418, as shown in Figs. 11 and 13, And the remaining portion of the air is passed through the wing portion 315 through the through hole portion 319 and flows to the upper portion of the vortex forming device 400.

A part of the air flow passing through the wing portion 315 through the through hole 319 is formed by a first wing 417 or a second wing 418 formed to protrude at an acute angle with the plane portion 316, The flow velocity energy of the air impinging on the inclined surface of the first vane 417 or the second vane 418 is transmitted to the rotating plate 311 through the through hole portion 319, And the wing portion 415, as shown in Fig.

A part of the air flow pushed outwardly of the rotary plate 311 by the action of the blades 417 and 418 is formed in a first part of the air flow which is projected so as to form an obtuse angle with the plane part 316 before being pushed out by the blades 417 and 418 The flow velocity energy of the air colliding with the inclined surface of the first wing 417 or the second wing 418 is also applied to the rotating plate 311 and the second wing 418, And can act as an element for promoting the rotation of the wing portion 415.

As described above, the vortex forming apparatus 400 of the present embodiment can efficiently increase the rotational speed of the rotating plate 311 and the wing portion 415 using the flow velocity energy of the air flowing into the wing portion 415 side , It is possible to reduce the power consumption required for the driving, thereby reducing the noise generated during the driving process.

[Structure of suction grill]

Fig. 14 is a perspective view showing the suction grille and the filter shown in Fig. 3, and Fig. 15 is a sectional view taken along line "B-B" in Fig. 16 is a bottom view showing a state in which the suction grill is coupled to the main body part, and FIGS. 17 and 18 are sectional views showing a state in which the filter is installed on the suction grill.

14 to 16, the filter 500 is disposed at the inlet ports 110a and 110b, more specifically, at the main inlet port 110a. The filter 500 is provided to filter the air sucked into the main body 100 through the main air inlet 110a.

The filter 500 may be formed in a circular plate shape or may have various shapes corresponding to the shape of the main air inlet 110a and may be formed into various shapes according to needs.

In this embodiment, the filter 500 is exemplified as being formed of a flexible material having a flat circular plate shape in the up-and-down direction and being able to bend in the up-and-down direction.

The suction grill 600 is disposed at a lower portion of the swirler 310, and the filter 500 is detachably installed in the suction grille 600. The suction grill 600 serves as a blocking wall for blocking the user's finger or other foreign matter from approaching the swallow 310 (FIG. 3) side, and also serves as a support frame for the installation of the filter 500 .

In this embodiment, it is illustrated that the suction grill 600 is formed in the form of a grill of a circular plate shape. The suction grill 600 may be installed at a lower portion of the vortex forming device 300 while being coupled to the lower panel 115 of the lower housing 110 so as to cover the main air inlet 110a from the bottom, A concentric member 620, and an outer frame member 630. [0064]

The radial member 610 is provided in a form in which a plurality of ribs are radially connected. For example, the radial member 610 may be formed in a " * " shape in which a plurality of ribs are radially connected, and each rib may be formed into a rod shape in a linear shape.

The concentric member 620 is connected to the radial member 610 by arranging a plurality of ribs concentrically. For example, the concentric member 620 may be formed in the shape of "? &Quot; in which a plurality of ribs are arranged in a concentric circle shape, and each rib may be formed into a circular ring shape having a different size from each other.

Each of the ribs constituting the concentric member 620 is spaced apart from each other by a predetermined distance along the radial direction, and thus a through hole 621 is formed between a plurality of ribs constituting the concentric member 620. The through hole 621 formed as described above forms a passageway through which the air below the main air intake port 110a passes through the suction grill 600 and can be introduced into the main body 100 through the main air intake port 110a.

A plurality of through holes 621 may be arranged concentrically like a plurality of ribs constituting the concentric member 620 so that a plurality of ribs and through holes 621 are formed in the concentric member 620, 600 in the radial direction.

Each of the ribs constituting the concentric member 620 is connected to each of the ribs constituting the radial member 610 with each other. In this embodiment, it is exemplified that the radial member 610 and the concentric member 620 are integrally formed.

The outer frame member 630 is disposed on the outer side of the concentric member 620 to form the outermost frame of the suction grill 600. The outer frame member 630 may be formed in a circular ring shape having a larger diameter than the concentric member 620 and may be connected to the outer ends of the ribs constituting the radial member 610, And is engaged with the concentric member 620.

In this embodiment, the radial member 610, the concentric member 620, and the outer frame member 630 are integrally formed to form one suction grill 600. That is, the suction grill 600 of this embodiment can be manufactured in such a manner that the radial member 610, the concentric member 620, and the outer frame member 630 are integrally formed, so that the suction grill 600 can be easily and quickly And can be easily mass-produced.

The outer frame member 630 forms an outermost frame of the suction grill 600 and provides a coupling surface between the suction grill 600 and the main body 100 to the outer periphery of the suction grill 600.

The outer frame member 630 is coupled to the lower panel 115 of the lower housing 110 with the suction grill 600 covering the main air inlet 110a from the bottom, The coupling between the grill 600 and the main body 100 can be performed.

In this embodiment, the suction grill 600 is illustrated as being coupled to the lower panel 115 in a manner to be bolted. The outer frame member 630 is formed with a fastening hole 631 for fastening between the body portion 100 and more specifically the lower panel 115 of the lower housing 110 and the outer frame member 630 do.

A plurality of fastening holes 631 are arranged in the outer frame member 630 at a specified interval along the circumferential direction of the outer frame member 630 formed in a circular ring shape. The fastening holes corresponding to the lower panel 115 may be provided at the same number and spacing as the fastening holes 631 of the outer frame member 630.

The fastening between the lower panel 115 of the lower housing 110 and the outer frame member 630 is performed by sucking in the position where the fastening holes of the fastening hole 631 of the outer frame member 630 and the fastening holes of the lower panel 115 coincide with each other The grill 600 may be coupled to the fastening hole 631 such that a fastening member such as a bolt is brought into contact with the lower panel 115.

In order to ensure smooth engagement between the outer frame member 630 and the lower panel 115, the fastening holes of the fastening holes 631 of the outer frame member 630 and the lower panel 115 are made to coincide with each other, It is necessary to align the position of the grill 600.

To this end, an alignment feature 635 is provided on the outer edge of the outer frame member 630. The alignment feature 635 interferes with the alignment structure 115a provided in the main body 100 and more specifically the lower panel 115 so that the fastening holes 631 are positioned at the designated positions with respect to the main body 100 To guide the installation position of the suction grill 600 so that the installation hole 631 of the outer frame member 630 is aligned with the fastening hole of the lower panel 115.

In this embodiment, the outer frame member 630 is formed in the shape of a circular ring, and the alignment feature 635 is formed in a shape in which a part of the outer frame of the outer frame member 630 is cut in a linear shape, 630 are illustrated as having a pair of alignment features 635 disposed facing each other about the lateral center of the suction grill 600.

The installation position of the suction grill 600 is guided to a position where the pair of alignment features 635 interfere with the alignment structure 115a provided in the lower panel 115. In this position, The installation position of the suction grill 600 can be guided in a state where the fastening holes of the fastening holes 631 of the upper panel 630 and the fastening holes of the lower panel 115 are aligned with each other.

Since the installation position of the suction grill 600 can be easily and conveniently guided so that the fastening hole 631 is arranged at the position specified with respect to the main body 100, the installation of the suction grill 600 is easier and quicker .

Meanwhile, the radial member 610 may be divided into an inner section 611 and an outer section 615. The inner section 611 is a section including the lateral center of the radial member 610 and the outer section 615 is a section disposed outside the inner section 611. [

A first connection portion 613 is formed between the inner side portion 611 and the outer side portion 615 to connect the inner side portion 611 and the outer side portion 615 in a vertical direction. The first connection portion 613 connects the inner portion 611 and the outer portion 615 such that the inner portion 611 is positioned above the outer portion 615. [ In this embodiment, the inner section 611 and the outer section 615 are each formed in a bar shape extending in the lateral direction, that is, in the lateral direction, and the first connection section 613 is formed as a bar extending in the vertical direction, As shown in FIG.

A step is formed between the inner section 611 and the outer section 615 in this manner so that the inner section 611 and the first connection section 613 are formed in the lower portion of the inner section 611 in the suction grill 600, Is formed. The space formed inside the suction grill 600 may be provided as a space in which the filter 500 can be mounted in the suction grill 600. [

The inner section 611 together with the concentric member 620 connected at the corresponding position forms an upper boundary surface of the filter 500 mounting space. The upper interface thus formed not only serves as a blocking wall for blocking the user's fingers or other foreign substances from approaching the swallow 310, but also functions as a filter 500 installed in the filter 500 mounting space, 600 of the first embodiment.

A second connection portion 617 is formed between the outer frame member 630 and the outer frame portion 615 so that the outer frame member 615 and the outer frame member 630 are vertically stacked. The second connection portion 617 connects between the outer section 615 and the outer frame member 630 such that the outer section 615 is positioned below the outer frame member 630. In this embodiment, the inner section 611, the outer section 615, and the outer frame member 630 are formed in the shape of a rod extending in the lateral direction, that is, in the transverse direction, and the first connection section 613, (615) is formed in a bar shape extending in the up-and-down direction, that is, the longitudinal direction.

The second connection portion 617 may be formed to have a length that allows the outer frame member 630 and the inner portion 611 to be disposed at the same height. For example, the second connection portion 617 may be formed to have a longitudinal length corresponding to the longitudinal length of the first connection portion 613, so that the outer frame member 630 and the inner portion 611 have the same height .

When the outer frame member 630 and the inner frame portion 611 are disposed at the same height as described above, the coupling surface between the suction grille 630 and the main body portion 100 provided by the outer frame member 630 and the inner surface of the inner frame 611 The separation barrier walls provided by the filter 500 can be arranged at the same height.

That is, the filter 500 detachment prevention wall provided by the inner section 611 of the suction grill 600 is not disposed at a position where it is further inserted above the main intake port 110a, and the suction grille 630 and the main body section 100, The width of the suction grill 600 in the vertical direction is shortened and the width of the suction grill 600 in the vertical direction within the main body 100 is shortened.

The gap between the suction grill 600 and the swirler 310 can be increased as the width of the suction grille 600 in the vertical direction is shortened in the main body 100. [ Accordingly, the possibility of interference between the suction grill 600 and the swirler 310 is reduced, so that improved safety of the apparatus can be secured.

When the suction grill 600 has a shorter vertical width in the main body 100 as described above, a space for installing other parts or devices in the main body 100 is further provided inside the main body 100 It is possible to reduce the vertical width of the main body 100, particularly the lower housing 110, so that it is possible to provide a more slim form of local area So that the exhaust device 1 can be provided.

The inner section 611 and the outer section 615 are connected to each other by the first connection section 613 and the second connection section 617 is connected between the outer section 615 and the outer frame member 630, The suction grill 600 formed in a structure in which the suction grill 600 is formed so as to be connected to each other in a stepped manner is formed in the shape of an oblique convex structure rather than a flat plate shape, so that the suction grille 600 has high rigidity, And has low characteristics.

The suction grill 600 of the present embodiment may further include a protrusion 625 provided so that the filter 500 can be detachably installed on the suction grill 600.

The protrusion 625 is formed to protrude from the concentric member 620 and is formed to protrude from the ribs of the concentric member 620 connected to the outer section 615 toward the lateral center of the radial member 610 Thereby supporting the filter 500 at the bottom.

The protrusions 625 are spaced apart from each other along the circumferential direction of the ribs of the concentric member 620 formed in the shape of a circular ring, and the filter 500, which is seated on the plurality of protrusions 625 arranged in this manner, Can be stably supported by the plurality of protrusions 625 while being inserted into the space for mounting the filter 500 surrounded by the inner section 611 and the first connection section 613 at the lower portion of the inner section 611.

The operation of installing the filter 500 on the suction grill 600 can be performed as follows.

First, as shown in FIG. 17, the filter 500 is inserted into the filter 500 mounting space from the lower portion of the suction grill 600 through the open lower portion of the filter 500 mounting space.

According to the present embodiment, the suction grill 600 can be divided into a first area and a second area. The first region is defined as an area located inside the suction grille 600 along the radial direction of the main air inlet 110a. The second region is defined as a region located outside the first region, that is, a region located on the rim side of the main air inlet 110a.

When the suction grill 600 is formed in a disk shape, the first area is an area including the inside section 611 inside, and when the suction grill 600 is formed in a region of the center circle shape including the center of the suction grill 600 .

The second area is an area including the outer section 615 and is disposed in the edge area of the suction grill 600, that is, outside the first area, when the suction grill 600 is formed in a disk shape. Shaped region.

That is, the suction grill 600 is provided in a shape in which the first area on the inner side and the second area on the outer side are arranged in a concentric form, and the first connection part 613 disposed between the inner part 611 and the outer part 615 Forms a boundary between the first region and the second region.

The space for mounting the filter 500 is a space surrounded by the inner section 611 and the first connection section 613 at the lower part of the inner section 611, .

In this embodiment, the filter 500 is illustrated as being formed in a shape and size corresponding to the lateral planar shape of the space in which the filter 500 is mounted. Therefore, when the filter 500 is bent upward in inserting the filter 500 into the mounting space of the filter 500, the lower inlet portion of the filter 500 mounting space, that is, the protruding portion of the protrusion 625, 500 can easily pass through, and insertion of the filter 500 can be performed more smoothly.

If the operator releases the filter 500 while the filter 500 is inserted into the mounting space of the filter 500 so that the rim portion of the filter 500 is positioned on the upper side of the protrusion 625, The filter 500 formed of a flexible material is returned to the form of a circular plate.

The filter 500 thus restored is seated on the upper portion of the plurality of protrusions 625 in the space for mounting the filter 500 so that the filter 500 can be stably held by the plurality of protrusions 625 in the space for mounting the filter 500 The filter 500 can be detachably installed in the suction grill 600 in a supported form.

In order to separate the installed filter 500 from the suction grill 600, the operator grasps the filter 500 installed on the suction grill 600 and bends the filter 500 in the upward direction, and pulls the filter 500 downward. That is, the installation and replacement of the filter 500 can be easily and quickly performed by a simple and easy operation of holding the filter 500 by the operator and fitting it in the upper direction or pulling it in the lower direction.

On the other hand, the projecting portion 625 disposed at the lower inlet portion of the space for mounting the filter 500 may be formed to protrude in a rounded shape. In this embodiment, it is exemplified that the projecting portion 625 is formed to project in a semicircular shape.

When the protrusions 625 are rounded and the filter 500 is inserted into the suction grill 600 or drawn out from the suction grill 600, It is possible to prevent the filter 500 from being scratched and damaged by the protrusion 625 in the process.

Next, the flow of the airflow related to the suction grill 600 being divided into the first area and the second area will be described.

As described above, the suction grill 600 can be divided into a first area including the inner area 611 and a second area including the outer area 615, A filter 500 is mounted in a first region that is a region including the center. The second region, which is a radially outer region of the suction grill 600, corresponds to an area where the filter 500 is not mounted.

The main inlet port 110a in which the suction grill 600 is installed is covered by the filter section 500 and the inner section 611 located in the first area of the suction grill 600, The peripheral edge region is covered by the second region of the suction grill 600, that is, only the outer region 615 of the suction grill 600 is covered without the filter 500.

According to the present embodiment, the suction of the air by the operation of the air blowing device 200 and the discharge of the vortex due to the operation of the vortex forming device 300 are all performed through the main air inlet 110a.

When the operation of the air blowing device 200 and the operation of the vortex forming device 300 are performed at the same time, the suction of air by the operation of the air blowing device 200 is mainly performed in the central region of the main air inlet 110a, The discharge of the vortex due to the operation of the main body 300 is generally performed in the edge region of the main air inlet 110a.

In this embodiment, the first region of the suction grill 600 on which the filter 500 is mounted is positioned in the central region of the main air inlet 110a, that is, And the second region of the suction grill 600 in which the filter 500 is not mounted is disposed in the region where the vortex generating device 300 is disposed and the edge region of the main air inlet 110a, Is formed.

If the filter 500 is attached to the second region disposed in the region where the eddy current is discharged by the operation of the vortex forming device 300, The filtering of the air to be sucked is not performed so much that the flow of the vortex generated by the operation of the vortex forming device 300 is not properly discharged to the lower portion of the main air inlet 110a due to the filter 500. [

In contrast, according to the present embodiment, the shape of the suction grille 600 is determined so that the outer region is disposed in a peripheral region of the main air inlet 110a where vortex is mainly discharged.

The first region of the suction grill 600 and the second region of the suction grill 600 are positioned such that the second region of the suction grill 600 on which the outer section 615 is formed is positioned below the wing portion 315 of the swaller 310, Can be determined. More preferably, the second area of the suction grill 600 in which the outer section 615 is formed is sucked by the suction grill 600 so that the vortex generated by the operation of the vortex forming device 300 is placed on the path through the suction grill 600 A boundary between the first region and the second region of the grill 600 can be determined.

Thus, the local exhaust system 1 of the present embodiment can prevent the vortex of the vortex due to the suction of the air by the operation of the air blowing device 200 and the operation of the vortex forming device 300 even when the suction grille 600 and the filter 500 are mounted Can be effectively provided.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the true scope of protection of the present invention should be defined by the following claims.

1: Local exhaust
100:
110: Lower housing
110a: main intake port
110b: auxiliary intake port
111: Suction duct
115: Lower panel
116:
120: upper housing
200: blower
210: scroll housing
210a: suction hole
215:
220: Impeller
221: Hub
223: First blade
225: second blade
230: first driving unit
300,400: vortex forming device
310,410: Swallar
311: Spindle
312:
313: Connection
315, 415:
316:
317, 318, 417, 418:
319: through hole portion
320:
330: Flow guide
500: filter
600: suction grill
610: Radial member
611: Inner section
613: first connection portion
615: Outer section
617: second connection portion
620: concentric member
621: Through hole
625:
630: outer frame member
631: fastening hole
635:

Claims (10)

A main body portion having an intake port formed on a lower surface thereof;
A swirl-generating device disposed at the intake port and having a swirl rotor rotated to form a vortex;
A filter disposed in the intake port for filtering air sucked into the main body through the intake port; And
And a suction grille installed at the suction port and disposed at a lower portion of the swirler, wherein the filter is detachably installed,
Wherein the suction grille is divided into a first region located on the inner side of the suction grille along a radial direction of the suction port and a second region located on the outer side of the first region,
Wherein the first region is provided with the filter and the second region is formed with a passage through which the vortex formed in the swirler passes through the suction grille.
The air conditioner according to claim 1,
A radial member in which a plurality of ribs are radially connected;
A concentric member having a plurality of ribs arranged in a concentric form and connected to the radial member; And
And an outer frame member disposed on the outer side of the concentric member and connected to the radial member and coupled to the body portion.
3. The method of claim 2,
Wherein the radial member is divided into an inner section including the lateral center of the radial member and the outer section located outside the inner section,
A first connection part is formed between the inner section and the inner section so as to step-link the inner section and the outer section in a vertical direction,
Wherein the first connection portion connects the inner section and the outer section such that the inner section is located above the outer section.
The method of claim 3,
Wherein the first area is an area including the inside section,
Wherein the second area is an area including the outer section inside,
Wherein the first region and the second region are arranged in a concentric form,
Wherein the first connection portion forms a boundary between the first region and the second region.
The method of claim 3,
A second connection portion is formed between the outer frame member and the outer frame to connect the outer frame and the outer frame member such that the outer frame is located below the outer frame member,
Wherein the outer frame member and the inner section are disposed at the same height.
The method of claim 3,
Wherein the suction grille further comprises protrusions formed to protrude from the concentric member connected to the outer section toward the lateral center of the radial member to support the filter from below.
The method according to claim 6,
Wherein a plurality of protrusions are arranged at predetermined intervals along the circumferential direction of the concentric member.
The method according to claim 6,
Wherein the projecting portion is formed to protrude in a rounded shape.
3. The method of claim 2,
Wherein the outer frame member is formed in a circular ring shape,
Wherein the outer frame member is formed with a fastening hole for fastening between the body portion and the outer frame member.
10. The method of claim 9,
Wherein a plurality of the fastening holes are arranged in the outer frame member so as to be spaced apart from each other along the circumferential direction of the outer frame member,
Wherein an outer edge of the outer frame member is provided with an alignment portion for guiding an installation position of the suction grille so as to interfere with the alignment structure provided at the main body portion and to locate the coupling hole at a position specified relative to the main body portion, .

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