KR102532717B1 - Filter structure for air cleaner - Google Patents

Abstract

The present invention relates to a filter structure for a tower-type air purifier configured to smoothly flow airflow sucked into the air purifier and airflow discharged from the air purifier.
The filter structure for a tower-type air purifier of the present invention is installed inside the air purifier and deodorizes dust, germs, and odors in the air flowing into the filter unit by driving a blower,
The filter unit includes a filter body having a cylindrical shape with both ends open, and a lower cap and an upper cap coupled to lower and upper ends of the filter body, respectively. It provides a filter structure for a tower-type air purifier consisting of a conical tapered surface.

Description

Filter structure for tower type air purifier {FILTER STRUCTURE FOR AIR CLEANER}

The present invention relates to a filter structure for a tower-type air purifier, and more particularly, to a filter structure for a tower-type air purifier configured so that the flow of air sucked into the air purifier and air flow discharged from the air purifier can be made quickly and smoothly.

In general, an air purifier is a device that purifies indoor air by deodorizing odors contained in indoor air while removing various dusts and germs contained in indoor air.

These air purifiers are typically composed of a blower device that sucks in indoor air and forcibly blows it, and a filter unit that filters dust or bacteria in the circulating air or deodorizes odors by driving the blower device.

The blower unit is composed of a motor and a fan that sucks and discharges indoor air into and out of the air purifier by rotation of the motor. It acts as a filter or deodorizer for dust or germs.

Recently, tower-type air purifiers have been widely used to purify air in a large area of the room. Tower-type air purifiers have high air purification efficiency because they can suck and purify air in a 360-degree direction.

That is, in the tower-type air purifier, indoor air is introduced in a horizontal direction along the circumferential surface of the lower part, purified in the filter unit, and then the purified air is discharged into the room through an upper blower.

However, since the inflow and discharge of air is performed in the orthogonal direction, the air intake and discharge amount is reduced due to the flow of unnatural air flow as well as the initial vacuum state when the air purifier is initially operated, lowering the energy efficiency of the air purifier and also purifying it. Efficiency decreases.

In order to increase the performance of the application area to solve this problem, the volume of the air purifier can be increased because a large amount of air must be sucked in and discharged, but this is accompanied by an increase in the separation between the filter unit and the blower installed on the upper side. Therefore, a disadvantage occurs in that efficiency is reduced due to the antinomian structure that eventually increases the vertical air flow. Of course, it can be compensated by increasing the motor capacity of the blower, but it affects energy consumption efficiency and increases the manufacturing cost of the air purifier.

Korean Patent Publication No. 10-2019-0025882 Korean Utility Model Publication No. 20-2020-0000231

The present invention has been proposed to solve the conventional problems as described above, and an object of the present invention is to provide a filter structure for a tower type air purifier configured so that the flow of air sucked and discharged into the air purifier can be made quickly and smoothly. there is.

The filter structure for a tower-type air purifier proposed by the present invention is installed inside the air purifier and deodorizes dust, germs, and odors in the air flowing into the filter unit by driving a blower,

The filter unit includes a filter body having a cylindrical shape with both ends open, and a lower cap and an upper cap coupled to lower and upper ends of the filter body, respectively, and the lower cap increases the speed of the air flow flowing into and discharged from the filter body. It provides a filter structure for a tower-type air purifier consisting of a conical tapered surface.

A plurality of spiral protrusions may be formed on the tapered surface of the lower cap while maintaining intervals, and one side of the lower cap is formed as a flange portion so as to be detachably coupled to the filter body.

A plurality of blades are formed on the upper cap while maintaining intervals, and these blades are formed in a form corresponding to the tapered surface of the lower cap.

One side of the upper cap is formed as a flange portion so as to be detachably coupled to the filter body, and a handle is formed on the flange portion of the upper cap.

The filter body has a structure in which fold lines are continuously formed in opposite directions while maintaining intervals along the longitudinal direction, and the interval between the fold lines is dense on the inner surface of the filter body and the outer surface is smaller than the inner surface. It is folded to have a wider gap.

In the filter structure for a tower-type air purifier according to the present invention, air introduced into the filter unit is rapidly discharged while forming a vortex, so that more air can be purified and purification efficiency can be increased.

In addition, without increasing the capacity of the motor, the flow of the airflow discharged after being introduced into the filter unit is smooth, so that energy efficiency and performance of the application area can be improved.

1 is a perspective view of a filter unit for explaining a filter structure for a tower type air cleaner according to the present invention.
2 is an exploded perspective view of a filter unit for explaining a filter structure for a tower type air cleaner according to the present invention.
3 is a view for explaining a filter main body provided in a filter structure for a tower type air cleaner according to the present invention.
4 is a perspective view of a lower cap and an upper cap provided in the filter structure for a tower type air cleaner according to the present invention.
Figure 5 is a front view of Figure 4;
6 is a perspective view of an air purifier provided with a filter structure for a tower type air purifier according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 and 2 are a perspective view and an exploded perspective view of a filter unit for explaining a filter structure for a tower type air purifier according to the present invention, and FIG. 3 is a view for explaining a filter main body provided in a filter structure for a tower type air purifier according to the present invention. 4 and 5 show a perspective view and a front view of a lower cap and an upper cap provided in the filter structure for a tower type air purifier according to the present invention.

In the filter structure for an air purifier of the present invention, indoor air is introduced in the horizontal direction along the lower circumferential surface of the filter unit 2 by driving a blower (not shown) and then purified toward the upper part of the filter unit 2. It can be applied to a tower type air purifier through which air is discharged.

The blower may consist of a motor and a fan that sucks and discharges indoor air to and from the filter unit 2 installed inside the air purifier by rotation of the motor, or may have a structure similar thereto.

The filter unit 2 includes a filter body 4 having a cylindrical shape with a space formed therein, and a lower cap 6 and an upper cap 8 assembled to the lower and upper ends of the filter body 4, respectively.

The filter body 4 may be formed by forming a cylindrical shape while maintaining a space along the longitudinal direction and forming a filter member in which fold lines are continuously formed in opposite directions to each other while forming a space therein.

In such a filter body 4, the inner surface of the filter body 4 is densely spaced and the outer surface maintains a wider spacing than the inner surface, so that the outer surface of the filter body 4 On the side, the mountains formed by the fold line are spaced apart from each other to increase the amount of air inflow, and on the inner surface of the filter body 4, when the mountains formed by the fold line are in close contact with each other, the incoming air passes through. It also removes foreign matter.

The lower cap 6 and the upper cap 8 are detachably assembled at the lower end and the upper end of the filter body 4, and these lower cap 6 and upper cap 8 are separated from each other as described in detail later. As it is made of a corresponding conical shape, these lower cap 6 and upper cap 8 are configured to be detachably coupled to each other at one end.

The lower cap 6 is formed in a closed structure, and the upper cap 8 is formed in an open structure so that air can flow in from the side of the filter body 4 and be discharged through the upper cap 8.

The lower cap 6 has one end portion made of a flange portion 10 so that the lower portion of the filter body 4 can be assembled in an interference fit method, and a handle 12 is provided on one side of the flange portion 10. It is formed so that the filter body 4 can be easily assembled and separated by holding the handle 12 when assembling or separating.

And the lower cap 6 is composed of a conical tapered surface 14 on the inside of the flange portion 10 so that the flow of air flowing into the filter body 4 and discharged toward the top thereof can be accelerated.

The tapered surface 14 of the lower cap 6 is formed to be positioned toward the inside of the filter body 4, and air flows into the filter body 4 due to the tapered surface 14 formed on the lower cap 6. As it flows toward the top, the speed of the air flow increases, so a large amount of air can be purified.

The conical tapered surface 14 of the lower cap may have a different length depending on the position of the blower installed on the upper side of the filter unit 2. For example, if the distance between the filter body 4 and the blower is close The length of the tapered surface 14 may be made short, and the length of the tapered surface 14 may be formed longer than above as the distance between the filter main body 4 and the blower increases further than above.

In this structure, the suction power of air decreases as the blower of the air purifier moves away from the filter body 4. By compensating for smooth flow to the upper discharge port of the blower, the vacuum generation part can be minimized, and the application area performance and energy consumption efficiency of the air purifier can be increased by increasing the number of suction-discharge circulation cycles.

In addition, spiral protrusions 16 may be formed at regular intervals on the tapered surface 14 of the lower cap 6. When the spiral protrusions 16 are further formed on the tapered surface 14 in this way, the filter body 4 Since air is introduced into the inside and flows toward the top, a vortex is generated, so that a larger amount of air can be purified compared to the case where only the tapered surface 14 is formed, and thus the air purification efficiency can be greatly increased.

The upper cap 8 combined with the lower cap 6 has one end portion made of a flange portion 18 so that the upper cap 8 can be assembled to the upper end of the filter body 4 in an interference fit method, A handle 20 is formed on one side of the flange portion 18 so that the upper cap 8 can be easily assembled and separated by holding the handle 20 when assembling or separating the upper cap 8 from the filter body 4. there is.

In addition, the upper cap 8 has blades 22 having a tapered shape corresponding to the tapered surface of the lower cap 6 and is formed while maintaining a gap so that air can be discharged.

The blade 22 of the upper cap 8 causes a vortex due to the tapered surface 14 and the spiral protrusion 16 of the lower cap 6, which is the lower side of the filter body 4, and the air flow moving toward the upper side once again While causing a vortex, it allows it to be discharged to the outside of the filter body (4).

Accordingly, as the vortex passes through the upper cap 8, the air inside the filter body 4 is quickly discharged to the outside of the filter body 4 as the eddy current becomes stronger, so the air purification efficiency can be maximized.

In this way, when the tapered surface 14, the spiral protrusion 16, and the blade 22 are formed on the lower cap 6 and the upper cap 8 while extending toward the center of the filter body 4 and corresponding to each other, the lower cap Compared to when the cap and the upper cap are straight, air is rapidly introduced and discharged into the filter body (4), resulting in vortex flow. Therefore, the air purification efficiency can be greatly increased compared to the prior art.

That is, due to the tapered surface 14 of the lower cap 6, when air flows into the inside from the circumferential surface of the filter body 4, it can be quickly introduced, and the spiral protrusion 16 generates a vortex, so that the filter body (4) It can make the air flow more rapidly toward the top. In addition, since the blade 22 of the upper cap 8 is formed in a spiral shape, the air current moving toward the upper side while causing a vortex at the lower side of the filter body 4 causes another vortex to quickly move outward of the filter body 4. As the air is discharged, a larger amount of air can be purified, which increases the efficiency of air purification.

Also, for this reason, it is possible to increase the performance of the applied area and energy consumption efficiency of the air purifier by increasing the number of circulation cycles for inhaling and discharging air through the filter unit 4 .

In addition, the vacuum generation part can be minimized by smoothly connecting the air flow sucked into the filter body 4 due to the vortex phenomenon to the discharge part of the blower (not shown) installed on the upper side of the filter part 2.

[Table 1] below compares the performance of the filter structure for air purifiers according to the prior art and the present invention, and the performance of the air purifier to which the filter structure of the prior art and the filter structure of the present invention are applied in the same area is higher than that of the prior art. indicates excellent.

Performance test result item Based on Φ290 X Φ217 X 280mm filter size
A. Normal top/bottom cap
B. Normal upper cap / conical lower cap
result Applicable area m ² (pyeong)
71.28 (21.6)
73.59 (22.3)
energy
consumption efficiency Rating 1st class 1st class Power consumption (W) 31W 31W conclusion When applying a conical lower cap, the application area is increased by about 0.6 pyeong at the same power consumption.

When the air purifier provided with the filter structure for a tower type air purifier according to the present invention as described above is operated, the air purifier (not shown) installed on the upper side of the filter unit 2 is driven along the circumferential surface of the filter body 4. As the air is introduced into the inside, various dust and germs contained in the air are removed, and then discharged to the outside of the filter body 4 through between the blades 22 of the upper cap 8, and then the tower type air purifier 100 It is discharged through the discharge port 110 formed on the top of (see FIG. 6).

At this time, as the air flows into the filter body 4, the speed of the air flow increases due to the tapered surface 14 and the spiral protrusion 16 of the lower cap 6, and at the same time rises while causing a vortex phenomenon, and the upper cap 8 ) while forming a larger vortex due to the spiral blades 22, the purified air is quickly discharged to the outside of the filter unit 2 and discharged into the room.

As the air passes through the filter unit 2, the speed increases and vortices are generated, and more air can be introduced and discharged into the filter body 4 due to the increase in the speed and vortex of the air flow. efficiency can be greatly increased.

In addition, by smoothly connecting the air sucked into the filter body 4 due to the speed increase and vortex phenomenon of the air flow to the discharge part of the blower (not shown) installed on the upper side of the filter part 2, the vacuum generation part can be minimized. there is.

In the above, the preferred embodiment of the present invention has been described for illustrative purposes, but is not limited thereto, and it is also possible to carry out various modifications within the scope of the claims and detailed description of the invention and the accompanying drawings.

2: filter unit
4: filter body
6: lower cap
8: top cap
10, 18: flange part
12, 20: handle
14: tapered surface
16: spiral projection
22: blade
100: air purifier
110: discharge port

Claims (7)

A filter structure for a tower-type air purifier that is installed inside the air purifier and deodorizes dust, germs, and odors in the air flowing into the filter unit by driving a blower,
The filter unit includes a filter body having a cylindrical shape with both ends open, and a lower cap and an upper cap respectively coupled to lower and upper ends of the filter body,
The lower cap is made of a conical closed tapered surface to increase the speed of the air flow flowing into and discharged from the filter body,
The upper cap is composed of a plurality of blades formed in an inverted cone shape corresponding to the lower cap,
A plurality of spiral protrusions are formed on the conical tapered surface of the lower cap while maintaining intervals,
The filter structure for a tower-type air purifier configured such that the lower cap and the upper cap are detachably coupled to one end facing each other.
delete The method of claim 1,
The tapered surface of the lower cap has a filter structure for a tower type air purifier, characterized in that the length is different from the installation distance between the blower and the filter body. delete The method of claim 1,
A filter structure for a tower-type air purifier, characterized in that one side of the upper cap is formed as a flange portion so that it can be detachably coupled to the filter body. The method of claim 5,
A filter structure for a tower-type air purifier, characterized in that a handle is formed on the flange portion of the upper cap. The method of claim 1,
The filter body has a structure in which fold lines are continuously formed in opposite directions while maintaining intervals along the longitudinal direction, and the interval between the fold lines is dense on the inner surface of the filter body and the outer surface is smaller than the inner surface. A filter structure for a tower-type air purifier, characterized in that folded to have a wider gap.

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