KR101905582B1 - Exhaust gas treatment device - Google Patents

Abstract

The present invention relates to an exhaust air purifying apparatus. The apparatus for purifying exhaust air according to the present invention comprises a filter unit for removing particles of polluted air containing particles to purify the polluted air, A buffer unit for buffering the flow of the polluted air introduced from the fuel cell; An ion generator for ionizing the particles of the contaminated air introduced from the duct; And a filter disposed behind the ion generator and separating the particles from the polluted air, the polluted air being introduced from the duct and sequentially passing through the buffer unit, the ion generator, and the filter.

Description

[0001] Exhaust gas treatment device [0002]

The present invention relates to an exhaust air purifying apparatus for purifying air discharged to the outside.

Generally, an exhaust air purifying device such as a ventilator is used to maintain clean indoor air by discharging contaminated indoor air to the outside. For example, the contaminated air generated in a room such as a catering business is purified and discharged to the outside. At this time, the fan provided inside the exhaust air purifying device allows the air to flow to the outside, thereby inducing the flow of air only from one room to the other. However, when the polluted air in the room is discharged to the outside, the concentration of fine dust or pollutant in the air is increased, resulting in a risk of living environment. Therefore, when the polluted air in the room is discharged to the outside, the polluted air is not discharged as it is, but is discharged to the outside after passing through the filter. Such an exhaust air purifying apparatus is configured to remove contaminating particles, that is, particles of polluted air.

1 schematically shows a typical exhaust air purification device. Referring to FIG. 1, a general exhaust air purifying apparatus has a structure in which polluted air introduced from a room flows through a duct to a fan through a fan 2, passes through a filter member 3 vertically, Loses. For example, referring to Fig. 2, the filter member 3 may be formed in a lattice structure. The air that has passed through the filter member 3 is removed and discharged to the outside. However, in order to increase the particle removing effect, the spaces between the filter members 4 in the lattice structure must be compact. That is, referring to FIG. 2, as the size of the holes 5 formed in the filter member 4 is smaller, the filtering effect can be improved. However, as the hole 5 becomes smaller, the flow of the air toward the outside receives strong resistance, so that it is difficult to exhaust air actively to the outside. Therefore, it is necessary to make the air flow actively by raising the rotation speed RPM of the fan 2 or the like. In this case, there is a problem that more energy than necessary is injected and energy is wasted. Conversely, if the rotational speed RPM of the fan 2 is reduced to save energy, it is difficult to actively discharge polluted air as described above. Further, if the size of the hole 5 formed in the filter member 4 is increased, the effect of filtering the contaminated air is deteriorated.

The present invention is to provide an energy saving type exhaust air purifying apparatus having a high filtering effect while maintaining the flow rate of air discharged to the outside at an appropriate level when exhausting polluted air.

The present invention is intended to provide an exhaust air purification apparatus capable of reducing energy for driving a fan when exhausting contaminated air.

The objects of the present invention are not limited thereto, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

The present invention provides an exhaust air purifying apparatus.

According to an embodiment of the present invention, there is provided an exhaust air purifying apparatus for removing particles from polluted air, comprising: a filter unit for removing and purifying particles of polluted air containing particles, wherein the filter unit comprises: A buffer unit for buffering the flow of the contaminated air; An ion generator for ionizing the particles of the contaminated air introduced from the duct; And a filter disposed behind the ion generator and separating the particles from the polluted air, the polluted air being introduced from the duct and sequentially passing through the buffer unit, the ion generator, and the filter.

According to an embodiment, the buffer unit may include: a blocking unit that interrupts the flow of the contaminated air; And an open portion having a space through which the contaminated air can pass and flow back to the blocking portion.

According to one embodiment, the blocking portion includes a plurality of blocking members provided to be spaced apart from each other, and the opening portion is a space formed between each of the blocking members, and the contamination of the contaminated air, The air bypasses the side of the blocking member and flows through the opening.

According to one embodiment, the blocking member is disposed perpendicular to the flow direction of the contaminated air.

According to one embodiment, the respective blocking members are polygonal or cylindrical.

According to one embodiment, a curvature is formed on the surfaces of the respective blocking members.

According to one embodiment, the filter includes at least one dust collecting portion provided in parallel with the flow direction of the contaminated air, and the dust collecting portion is provided so as to be able to receive an electric charge.

According to one embodiment, the filter unit further includes a blowing fan disposed between the duct and the buffer unit, the blowing fan promoting the flow of the polluted air in the duct backward.

According to an embodiment of the present invention, there is further provided a controller for controlling the ion generator and the filter, wherein the controller drives the ion generator and the filter when the polluted air flows into the duct, When passing through the generator, particles of the contaminated air are charged, and while the polluted air passes through the filter, charged particles are attached to the dust collection part.

According to an embodiment of the present invention, there is further provided a cover unit disposed behind the filter unit, the cover unit preventing foreign matter from entering the filter unit from the outside.

According to one embodiment, the cover unit includes a protective portion formed with a cut surface cut in a flow direction of the clean air from which the particles are removed, in a lattice pattern.

According to one embodiment, the cover unit further includes a shielding portion disposed behind the protective portion and preventing foreign matter from entering from the outside, wherein the shielding portion includes at least one ventilation hole through which the clean air passes; And a shielding member corresponding to each of the vent holes and shielding the respective vent holes; And the shielding member extends downwardly from an upper end of the ventilation hole.

According to an embodiment of the present invention, when the polluted air is discharged, the air discharge to the outside may be maintained at a proper level, but the filtering effect may be high.

The present invention can reduce the energy for driving the fan when the polluted air is discharged.

The effects of the present invention are not limited to the above-mentioned effects, and the effects not mentioned can be clearly understood by those skilled in the art from the present specification and attached drawings.

1 is a schematic view showing a general exhaust air purifying apparatus.
Fig. 2 is a view showing a filter member provided in Fig. 1. Fig.
3 is a side sectional view showing an exhaust air purifying apparatus according to the present invention.
4 is a front view showing the buffer unit of FIG.
Figs. 5 to 9 are modifications of the buffer unit of Fig.
Figure 10 is a front view showing the filter of Figure 3;
11 is a front view showing the protection unit of Fig.
FIG. 12 is a perspective view showing the shielding portion of FIG. 3. FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more fully describe the present invention to those skilled in the art. The shape of the elements in the figures is therefore exaggerated to emphasize a clearer description.

Hereinafter, an example of the present invention will be described in detail with reference to FIGS. 3 to 12. FIG.

3 is a side sectional view showing an exhaust air purifying apparatus according to the present invention. Referring to FIG. 3, the exhaust air purification apparatus 100 includes a filter unit 200 and a cover unit 300.

The filter unit 200 functions to clean the polluted air that has flowed in the room and has passed through the duct 10. The filter unit 200 removes particles 20, such as fine particles, which are contained in the polluted air. The filter unit 200 includes a housing 210, a blowing fan 220, a buffer unit 230, an ion generator 240, a filter 250, an exhaust fan 260, a controller 270, ).

The housing 210 forms the appearance of the filter unit 200. The housing 210 may be provided in a shape extending from the duct 10.

The blowing fan 220 is provided in the housing 210. The blowing fan 220 is located behind the duct 10. In the present invention, the contaminated air flows through the duct from the inside of the room, and is discharged to the outside through the exhaust air purifying device (100). Hereinafter, the front side refers to a side relatively closer to the duct 10, and the rear side refers to a side relatively closer to the outside. That is, the front side is the side on which the contaminated air is introduced, and the rear side is the side on which the air is discharged. The air blowing fan 220 passes polluted air flowing into the duct 10 from inside the room. The air blowing fan 220 guides the air flowing into the duct 10 to flow backward.

4 shows a buffer unit according to the present invention. Referring to FIGS. 3 and 4, the buffer unit 230 is provided in the housing 210. The buffer unit 230 serves to delay the flow of air passing through the blowing fan 220. The flow rate of the contaminated air is reduced before entering the filter 250, which will be described later, so that the particles 20 can be sufficiently removed while passing through the filter 250.

The buffer portion 230 includes a blocking portion 232 and an opening portion 236. The blocking portion 232 may include a plurality of blocking members 234. The respective blocking members 234 are provided spaced apart from each other. Each blocking member 234 may be provided in a polygonal columnar or cylindrical shape. However, this is not necessarily the case. Each of the blocking members 234 may be disposed perpendicular to the flow direction of the polluted air. The longitudinal direction of the blocking member 234 may be arranged so as to be perpendicular to the flow direction of the contaminated air in the blocking member 234 of a prismatic or cylindrical shape. Therefore, the flow of the polluted air passing through the blowing fan 220 is interrupted by the blocking member 234, and the flow velocity can be slowed down. The contaminated air that has been disturbed travels along the surface of the blocking member 234 to the side of the blocking member 234 and moves.

An opening portion 236 is formed between the respective blocking members 234. The contaminated air flows backward through the openings 236. That is, as described above, the flow air obstructed by the blocking member 234 flows through the opening 236 along the side surface of the blocking member 234.

5 to 9 are views showing a modification of the buffer unit. 5 and 6 show a first modification of the buffer unit. Fig. 5 is a front view of the buffer unit, and Fig. 6 is a plan view of the blocking member of the buffer unit.

5 and 6, the blocking member 1234 may have a convex portion 1234a and a concave portion 1234b on its surface. A plurality of convex portions and concave portions may be provided. The convex portion and the concave portion are provided alternately and repeatedly. The concave portion is provided between the two convex portions. The convex portion is provided between the two concave portions. With this structure, when the polluted air passes through the blocking member, the resistance against the flow of polluted air can be increased. Therefore, the flow of polluted air can be slowed down. Further, impurities or particles mixed in the contaminated air adhere to the surface of the concave portion or the convex portion, so that the effect of primarily filtering the particles before entering the filter 250 described later can be obtained. The contaminated air flows through the openings 1236.

FIGS. 7 to 9 are views showing other modified examples of the buffer unit. As shown in FIGS. 7 to 9, the surfaces of the blocking members 2234, 3234, and 4234 of the buffer units 2230, 3330, and 4330 may be curved. The curvature is formed on the surfaces of the blocking members 2234, 3234, and 4234, so that the effect of the flow air being resisted by the flow can be increased. Therefore, the effect that the polluted air is obstructed by the blocking members 2234, 3234, and 4234 becomes larger, and the effect of slowing the flow rate of polluted air can be further increased. Openings 2236,3236 and 4236 are formed between the respective blocking members 2234,3234 and 4234 and polluted air flows through the openings 2236,3236 and 4236. [

Referring again to FIG. 3, the ion generator 240 may be provided inside the housing 210. A plurality of ion generators 240 may be provided. For example, the ion generators 240 may be provided on the inner surface of the housing 210 so as to face each other. The ion generator 240 supplies ions to the contaminated air passing through the inside of the housing 210. Particles of contaminated air can be charged by the ion generator 240. The ions supplied by the ion generator 240 may be positive ions and negative ions.

The ion generator 240 may be disposed behind the buffer unit 230. When the flow rate of the contaminated air is slowed by the buffer unit 230, the particles 20 of contaminated air can be sufficiently ionized by the ion generator 240.

10 is a front view showing a filter according to the present invention. Referring to FIG. 10, a filter 250 is provided in the housing 210. The filter 250 filters contaminant particles such as particles 20 contained in the contaminated air. The filter 250 includes a support portion 252 and one or more dust collecting portions 254. Support 252 may be provided at the inlet and outlet of filter 250. The support portion 252 supports the dust collecting portion 254 described later.

The dust collecting part 254 is provided so as to be capable of charging. The dust collecting part 254 may be provided in a plurality of layers. Each of the dust collecting parts 254 may be provided separately from each other. Each of the dust collecting portions 254 is provided in parallel to the flow direction of the polluted air. That is, the longitudinal direction of the dust collecting section 254 is provided in parallel to the flow direction of the contaminated air. One end of the dust collecting part 254 is supported by a support part 252 provided on the inlet side of the filter 250.

The dust collecting portion 254 may include a dust collector 256 and a dust collecting material 258 provided on the surface of the dust collector 256. [ The dust collector 256 constitutes the main body of the dust collecting part 254. The strap 256 is provided so that its longitudinal direction is parallel to the flow direction of the contaminated air. Further, the dust collector 258 is attached to the surface of the dust collector 256. The bulk material 258 may be attached to one side or both sides of the surface of the collector 256. In this case, however, the direction in which the dust-collecting members 258 are arranged is provided in the same direction along the flow direction of the contaminated air. Therefore, the filtering effect can be generated without significantly interfering with the flow of polluted air.

The bulk material 258 may be provided as a polypropylene fiber. The bulk material 258 may be provided in an electrostatically charged state.

As described above, the particles of the polluted air are charged by the ion generator. As the particles pass through the filter 250 in the charged state and the particulate 258 is also charged, the particles of the polluted air adhere to the particulate filter 258 and consequently the particles 20 are filtered.

The dust collecting part 254 may be provided interchangeably. That is, the dust collecting unit 254 is provided so as to be replaced with a new dust collecting unit 254 after performing the filtering effect for a predetermined time.

On the other hand, the accumulator 256 may be omitted. In this case, the longitudinal direction of the dust-collecting material 258 is provided in parallel to the flow direction of the contaminated air. or. In addition, the dust collector 256 and the dust collector 258 may have any form or arrangement as long as they are disposed in parallel with the flow direction of the polluted air.

The exhaust fan 260 guides the flow of the air that has passed through the filter 250 to the rear. The polluted air is clean after passing through the filter 250. In order to discharge the clean air to the outside, the flow of the clean air is guided to the rear side.

The controller 270 controls the ion generator 240. The controller 270 controls the ion generator 240 to drive the duct 10 when the inflow of contaminated air is detected. Thus, when the contaminated air passes through the point where the ion generator 240 in the housing 210 is installed, ions are supplied to the contaminated air. Therefore, the polluted particles of polluted air, that is, the particles 20, are charged.

The measurement sensor 280 measures the flow rate or pressure of the clean air that has passed through the filter 250. The user can determine the appropriate replacement timing of the filter 250 through the measurement values of the measurement sensor 280.

Particularly, when the filter 250 is used for a predetermined period of time, the particles 20 accumulate in the dust-collecting material 258 in the filter 250 and adhere in a large amount. This results in a deterioration of the filtering effect. Also in this case, the flow rate or pressure of the clean air passing through the filter 250 will be reduced.

The user prepares a reference value for the flow rate or pressure of the clean air passing through the filter 250. When the measured value of the flow rate or pressure of the clean air passed through the filter becomes less than the reference value, . At this time, the user can replace the filter 250.

The cover unit 300 prevents foreign matter from entering the filter unit 200 from the outside. The cover unit 300 includes a protective portion 310 and a shielding portion 320. The cover unit 300 is located behind the filter unit 200. That is, the cover unit 300 is disposed adjacent to the outside. The clean air (hereinafter referred to as clean air) is discharged to the outside through the cover unit 300.

Fig. 11 is a front view showing the protection part. Fig. Referring to FIGS. 3 and 11, the protection unit 310 is disposed at the rear of the cover unit 300 in close proximity to the cover unit 300. The protection unit 310 may block the solidified foreign matter from the outside from entering the filter unit 200. For example, the protection unit 310 may function as an insect screening network. The protective portion 310 is provided so as to be perpendicular to the flow direction of the clean air. The protective portion 310 may be provided in a grid pattern. Specifically, the cut surface perpendicular to the direction in which the clean air flows can be formed to have a lattice pattern.

12 is a perspective view showing a shielding portion. Referring to FIGS. 3 and 12, the shield 320 is provided at the rear of the protective portion 310. The shield 320 blocks the solidified or liquidified foreign matter from entering the filter unit 200 from the outside. For example, rainwater can be prevented from permeating the filter unit 200 from the outside in rainy weather.

The shield 320 may include a vent hole 322 and a shield member 324. One or more vent holes 322 may be provided. The vent hole 322 serves as a passage through which clean air is discharged to the outside.

The shielding member 324 prevents foreign substances from entering. The shielding member 324 may be formed to be inclined downward from the upper end of the vent hole 322 toward the lower end of the vent hole 322. [ The oblique direction is the direction toward the outside of the exhaust air purifying apparatus 100 according to the present invention. Therefore, it is possible to block foreign substances such as rainwater falling down during rain. Specifically, the rainwater falls along the inclined surface of the shielding member 324 to the ground. Therefore, rainwater or the like can be prevented from flowing through the vent hole 322.

In the following, a method of purifying indoor air and discharging it to the outside using the above-described exhaust air purifying apparatus 100 will be described.

When the contaminated air in the room flows into the duct 10, the blowing fan 220 guides the polluted air to the rear. The polluted air passes through the buffer unit 230 and the flow velocity is slowed down. This is because if the flow velocity of polluted air is too fast, the particles 2 are not properly filtered by the dust-collecting material 258 such that the particles 20 are not sufficiently attached to the dust-collecting material 258 when passing through the filter 250 to be. Accordingly, by buffering the polluted air by the buffer 230, a further improved filtering effect can be obtained. Further, when convex portions and concave portions are formed in the buffer portion, the particles can be primarily filtered.

When contaminated air is introduced through the duct 10, the controller 270 can drive the ion generator 240. Or the controller 270 may drive the ion generator 240 whenever contaminated air is present before the point at which the ion generator 240 is installed. The ion generator 240 supplies ions into the housing 210. Particles 20 of the contaminated air can be charged and activated when the contaminated air passes through the inside of the housing 210 and passes through the point where the ion generator 240 is installed.

The polluted air passing through the buffer unit 230 is supplied with ions by the ion generator 240. As a result, the particles 20 of polluted air are charged. The polluted air passes through the filter 250. As described above, the vibration damping material 258 is provided in an electrostatically charged state. The particles 20 are filtered in such a manner that the polluted air passes through the filter 250 and the particles 20 are attached to the dust collecting material 258. [ Since the particles 20 of polluted air and the dust-collecting material 258 are charged, a force of pulling each other by static electricity acts. Therefore, the particles 20 can be more effectively attached to the dust-collecting material 258. [ Further, since the flow rate of the contaminated air is reduced while passing through the buffer unit 230, the particles 20 can be sufficiently attached to the dust-collecting member 258, and the filtering effect can be improved.

Since the lengthwise direction of the dust collecting portion 254 is provided in parallel to the flow direction of the contaminated air, as described above, the flow rate of the contaminated air is not disturbed, and the rotational speed RPM of the blowing fan 220 is increased There is no need to set it high. Therefore, excessive energy consumption can be saved.

The clean air from which the particles 20 have been removed moves backward past the filter 250 and the backward flow is promoted by the exhaust fan 260. Clean air passes through the protective portion 310 and is discharged to the outside through the vent hole 322 formed in the shielding portion 320. [ At this time, foreign matter such as rainwater is blocked by the shielding part 320. In addition, the protection unit 310 can prevent the foreign matter from flowing in, such as the insect proof effect.

Accordingly, the exhaust air purifying apparatus 100 according to the present invention can smoothly flow the dust collecting unit 254 of the filter 250 in parallel with the flow direction of the polluted air, Do not consume more energy than necessary. Further, the particles 20 can be sufficiently filtered by the dust-collecting material 258 because filtering is performed using the electrostatic method, and the flow velocity of the contaminated air is reduced in front of the filter 250.

In the above-described embodiment, the blower fan and the exhaust fan are included. However, the blower fan and the exhaust fan may be omitted.

Although the cover unit is described as being included in the above-described embodiment, the cover unit is not necessarily required, and the cover unit may be omitted.

In the above-described embodiment, the dust collecting part includes the dust collecting part, but the dust collecting part may be omitted.

In the above-described embodiment, the ion generator is described as being provided between the buffer unit and the filter, but the present invention is not limited thereto. The ion generator may be arranged further forward than the buffer portion.

In the above-described embodiment, when the contaminated air flows into the duct, the controller drives the ion generator. However, the present invention is not limited to this, and it is sufficient to drive the ion generator before passing through the point where the ion generator is installed. Alternatively, the controller may be omitted and the ion generator may always operate in the ON state.

The foregoing detailed description is illustrative of the present invention. In addition, the foregoing is intended to illustrate and explain the preferred embodiments of the present invention, and the present invention may be used in various other combinations, modifications, and environments. That is, it is possible to make changes or modifications within the scope of the concept of the invention disclosed in this specification, within the scope of the disclosure, and / or within the skill and knowledge of the art. The above-described embodiments illustrate the best mode for carrying out the technical idea of the present invention, and various modifications required for specific application fields and uses of the present invention are also possible. Accordingly, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. It is also to be understood that the appended claims are intended to cover such other embodiments.

100: exhaust air purification device 200: filter unit
220: blower fan 230: buffer unit
232: breaking portion 234: blocking member
236: opening part 240: ion generator
250: Filter 260: Exhaust fan
270: Controller 300: Cover unit
310: protection unit 320: shielding unit

Claims (12)

1. An exhaust air purification apparatus for removing particles from polluted air and discharging the polluted air,
And a filter unit for removing particles of polluted air and purifying the polluted air,
The filter unit includes:
A buffer unit for buffering the flow of the polluted air introduced from the duct;
An ion generator for ionizing the particles of the contaminated air introduced from the duct;
A filter disposed behind the ion generator and separating particles from the polluted air; And
And a controller for controlling the ion generator and the filter,
The contaminated air flows in from the duct, passes sequentially through the buffer unit, the ion generator, and the filter,
The buffer unit includes:
A blocking unit for blocking the flow of the contaminated air; And
And an opening formed in the space to allow the contaminated air to flow to the rear of the blocking portion,
Wherein the blocking portion includes a plurality of blocking members spaced apart from each other in a direction perpendicular to the flow direction of the contaminated air,
Wherein the opening portion is a space formed between each of the blocking members,
Wherein the blocking member is disposed perpendicular to the flow direction of the contaminated air,
Wherein a plurality of protrusions and recesses are alternately and repeatedly provided on the surface of each of the blocking members,
The contaminated air that has been obstructed by the respective blocking members of the contaminated air flows to the side of the blocking member and flows through the opening,
The filter includes:
And at least one dust collecting portion provided in parallel to the flow direction of the contaminated air,
Wherein the dust collecting part is provided so as to be able to be replaced,
Wherein the controller drives the ion generator and the filter when the polluted air flows into the duct,
When the contaminated air passes through the ion generator, particles of the polluted air are charged,
While the contaminated air passes through the filter, charged particles are attached to the dust collecting part,
And a measurement sensor for measuring the flow rate or pressure of the clean air that has passed through the filter,
And sets a time at which the value measured by the measurement sensor becomes less than or equal to a reference value as a replacement time of the dust collecting unit.
delete delete delete delete delete delete delete The method according to claim 1,
The filter unit includes:
A blowing fan disposed between the duct and the buffer unit for promoting the flow of the polluted air in the duct to the rear;
And a cover unit disposed at the rear of the filter unit to prevent foreign matter from entering the filter unit from the outside,
The cover unit includes:
A protective portion formed in a lattice pattern of a cut surface cut with respect to a flowing direction of clean air from which particles have been removed; And
And a shielding portion disposed behind the protective portion and preventing foreign matter from entering from the outside,
The shielding portion
At least one vent hole through which the clean air passes; And
And a shielding member corresponding to each vent hole and shielding the vent holes, respectively,
Wherein the shielding member extends downwardly from an upper end of the ventilation hole.
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