KR102665442B1 - Ceiling type air purification system - Google Patents

Abstract

The present invention relates to a ceiling-type air purification system, comprising: a casing (10) in which an intake port (12) and an exhaust port (14) are formed; A filter unit 20 installed inside the casing 10 and positioned in correspondence with the intake port 12; A lighting fixture (30) connected to the casing (10); An air distribution duct (40) whose one end communicates with the casing (10) and the other end which communicates with the indoor space; It includes a fan unit 50 that is installed inside the casing 10 and sucks air through the intake port 12 and discharges it through the exhaust port 14 and the air distribution duct 40.
Accordingly, the functionality and usability of the ceiling-type air purification system can be further improved.

Description

Ceiling type air purification system {CEILING TYPE AIR PURIFICATION SYSTEM}

The present invention relates to a ceiling-type air purification system, and more specifically, to a ceiling-type air purification system that is installed on the ceiling and can efficiently purify indoor air.

In general, air purification systems are installed in a certain location to purify and re-supply indoor air, and are classified into various types depending on their purpose and use.

The demand for these air purification systems is increasing as interest in air quality increases.

In particular, research and development on air purification systems installed on the ceiling are actively being conducted.

A conventional ceiling-type air purification system includes a body having an air intake chamber and an air blowing chamber; A blower installed in the air intake chamber of the body, sucking air into the air intake chamber and discharging air into the air blowing chamber; A filter means installed at the entrance of the air intake chamber; It is composed of lighting means provided on the body.

In addition, the air blowing room has an outlet for receiving air from the air intake room and discharging it to the outside.

A ceiling-type air purification system with this configuration is disclosed in Registered Patent Publication No. 10-1842003.

However, since the ceiling-type air purification system above discharges air only through the outlet of the air blowing room, if the indoor space is larger than a certain level, air circulation does not occur properly, which limits the ability to purify the air evenly in the entire area. there is. In other words, air is smoothly supplied to the indoor space adjacent to the blower, but air is not smoothly supplied to the indoor space away from the blower, resulting in a problem of low air purification efficiency.

In addition, when increasing the size and/or rotational power of the blower to solve the above problems, there is a disadvantage in that not only does power consumption increase relatively, but noise is generated.

This ultimately results in a decrease in the functionality and usability of the ceiling-type air purification system.

The present invention was developed to solve the above problems, and the problem to be solved by the present invention is to provide a ceiling-type air purification system that can purify air uniformly in all areas of indoor space.

A ceiling-type air purification system according to the present invention to solve the above problems includes a casing formed with an intake port and an exhaust port; a filter unit installed inside the casing and positioned corresponding to the intake port; a lighting fixture connected to the casing; an air distribution duct that has one end in communication with the casing and the other end in communication with the indoor space; Its technical feature is that it includes a fan unit installed inside the casing, which sucks air through the intake port and discharges it through the exhaust port and the air distribution duct.

The ceiling-type air purification system according to the present invention can purify air uniformly throughout the entire indoor space by dispersing and supplying air through the exhaust port and air distribution duct of the casing.

Additionally, the time required to purify the air in indoor spaces can be relatively shortened.

Accordingly, the functionality and usability of the ceiling-type air purification system can be further improved.

1 is a schematic configuration diagram of a ceiling-type air purification system according to the present invention;
Figure 2 is a cross-sectional view showing the casing structure of the ceiling-type air purification system according to the present invention;
Figure 3 is a cross-sectional view showing the structure of the filter unit of the ceiling-type air purification system according to the present invention;
Figure 4 is a schematic diagram showing another embodiment of the air distribution duct of the ceiling-type air purification system according to the present invention;
Figure 5 is a cross-sectional view showing the structure of the auxiliary filter unit of the ceiling-type air purification system according to the present invention.

Below, the ceiling-type air purification system according to the present invention will be described in detail through drawings.

As shown in Figures 1 to 5, the ceiling-type air purification system according to the present invention is installed on the ceiling (C) and serves to purify the air in the indoor space (S) in real time.

This ceiling-type air purification system includes a casing (10); A filter unit (20) installed inside the casing (10); A lighting fixture (30) connected to the casing (10); An air distribution duct (40) at one end communicating with the casing (10) and at the other end communicating with the indoor space (S); A fan unit 50 installed inside the casing 10; Open/close valve 60 installed in the air distribution duct 40; An auxiliary filter unit (70) installed on the air distribution duct (40); It is comprised of a foreign matter inflow blocking cover (80) installed in the air distribution duct (40).

The casing 10 has a roughly square shape and is made of synthetic resin material with excellent physical properties.

An intake port 12 through which air from the indoor space S is sucked is formed on the front of the casing 10, and an exhaust port 14 through which air is discharged into the indoor space S is formed on the side thereof.

And at the rear of the casing 10, a communication hole 16 with a certain size is formed.

In addition, the inside of the casing 10 is provided with at least one flow guide 18 that communicates with the air distribution duct 40 and guides the air discharged through the fan unit 50 to the communication hole 16. This flow guide 18 is intended to distribute air to the exhaust port 14 and the air distribution duct 40 depending on the structure (centrifugal or axial flow type) of the fan unit 50.

Meanwhile, Figure 2 shows the arrangement of the flow guide 18 when the fan unit 50 is of a centrifugal type, and when the axial flow type is applied to the fan unit 50, the arrangement may be different.

The filter unit 20 is located to correspond to the intake port 12 of the casing 10, and thus serves to cleanly purify the air of the indoor space (S) sucked through the intake port 12 of the casing 10.

This filter unit 20 includes a frame portion 22; It consists of a photocatalyst filter unit 24 installed inside the frame unit 22.

The frame portion 22 has a rectangular frame shape and is made of metal or synthetic resin material with excellent physical properties.

The photocatalyst filter unit 24 is fitted into the frame unit 22 and includes a pair of mesh nets 24a and 24b coated with a photocatalyst; At least one LED (24c) coupled to the frame portion (22) and positioned between a pair of mesh networks (24a, 24b); It consists of an LED protection cover (24d) installed in front of the LED (24c).

Each of the pair of mesh networks 24a and 24b includes a first mesh network A; A second mesh network (B) spaced apart from the first mesh network (A); It consists of a third mesh network (C) in the form of a wave pattern interposed between the first mesh network (A) and the second mesh network (B). Due to the structural characteristics of the mesh networks 24a and 24b, air purification efficiency can be further enhanced by maximizing contact with air passing through the mesh networks 24a and 24b.

And the LED 24c is for activating the photocatalyst coated on the pair of mesh networks 24a and 24b. In particular, by irradiating a complex wavelength consisting of ultraviolet rays and visible rays, it reacts not only in ultraviolet rays but also in visible rays, thereby increasing the activity of the photocatalyst. can be maximized. In addition, visible light has the advantage of being able to indirectly perform the function of lighting.

Meanwhile, as a photocatalyst material, a catalyst is used that mixes titanium dioxide (Tio2), a metal oxide, with other metal oxides such as iron (Fe), tungsten trioxide (Wo3), and platinum (Pt) in a certain ratio.

Additionally, the LED protection cover 24d is intended to protect the LED 24c from foreign substances contained in the air, and has a structure capable of sufficiently covering the LED 24c. This LED protective cover 24d is made of a light-transmissive (transmissive) material such as glass, and considering usability and processability, it is preferable to use a fluorine-based film.

The lighting device 30 is installed on the front outer edge of the casing 10, and its installation location can be appropriately changed as needed.

Meanwhile, since the lighting fixture 30 applies known technology, its detailed description will be omitted.

The air distribution duct 40 evenly distributes the air that has passed through the filter unit 20 into the indoor space (S), making it possible to quickly and uniformly purify the air in all areas of the indoor space.

This air distribution duct 40 is made of metal or synthetic resin material with excellent physical properties, and its shape can be changed in various ways as needed.

For example, the air distribution duct 40 includes a main duct 42 communicating with the communication hole 16 of the casing 10, as shown in FIG. 4; It may be composed of a plurality of branch ducts 44 communicating with the main duct 42.

Additionally, an impermeable adhesive coating layer (not shown) may be formed on the inner surface of the air distribution duct 40 to additionally remove foreign substances remaining in the air that are not removed through the filter unit 20.

The fan unit 50 is arranged to correspond to the rear of the filter unit 20, and serves to suck air through the intake port 12 of the casing 10 and discharge it through the exhaust port 14 and the air distribution duct 40. .

Meanwhile, as the fan unit 50, various known types, including centrifugal type and axial flow type, can be selectively applied, and of course, the number of them can also be adjusted appropriately.

The opening/closing valve 60 serves to control the inflow of air into the air distribution duct 40.

The opening and closing operation of this opening and closing valve 60 is controlled by a sensor (not shown) that measures air quality. That is, the opening and closing valve 60 is opened and closed according to the air quality of the indoor space (S) measured by a sensor (not shown).

For example, when the air quality in the indoor space (S) is above a certain level, the opening/closing valve (60) is closed to block air inflow into the air distribution duct (40), and when the air quality in the indoor space (S) is below a certain level, the opening/closing valve (60) is closed. 60) is opened to allow air to flow into the air distribution duct 40.

Additionally, the opening/closing valve 60 can be installed inside the air distribution duct 40 or installed in the communication hole 16 of the casing 10, and its installation location can be appropriately changed as needed.

Meanwhile, as the on-off valve 60, various known types can be selectively applied.

The auxiliary filter unit 70 is used to auxiliary purify the air flowing into the air distribution duct 40.

This auxiliary filter unit 70 includes a cover 72 having an inlet 72a and an outlet 72b; A mesh net 74 installed inside the cover 72 and coated with a photocatalyst; A reflector 76 installed to surround the mesh network 74; It is installed inside the cover 72 and consists of an LED 78 that irradiates a complex wavelength consisting of ultraviolet rays and visible rays to the mesh net 74.

The inlet 72a and outlet 72b of the cover 72 communicate with the air distribution duct 40.

In addition, the mesh network 74 has a spiral shape and is arranged in a plurality in a row, and the reflector 76 is used to relatively increase the irradiation efficiency of the LED 76 into the mesh network 74.

Meanwhile, a fan unit 79 may be additionally provided inside the cover 72 to suck in air and exhaust it, and thus the air flow in the air distribution duct 40 can be implemented more smoothly.

The foreign matter inflow prevention cover 80 serves to prevent foreign matter from entering from the indoor space (S).

This foreign matter inflow prevention cover 80 is installed at the outlet of the air distribution duct 40, and opens and closes automatically according to the air flow in the air distribution duct 40. That is, the foreign matter inflow prevention cover 80 has a spring (torsion coil spring) hinge structure, so that when air flow occurs in the air distribution duct 40, it opens itself by the force and also opens the air distribution duct (40). If the air flow at 40) is blocked, it closes itself by elastic force (restoring force).

The operation of the ceiling air purification system described above is briefly explained as follows.

First, the air in the indoor space (S) is sucked through the intake port 12 of the casing 10 by driving the fan unit 50, and the air sucked into the casing 10 passes through the filter unit 20. After being purified primarily, it is discharged into the work area of the indoor space (S) through the exhaust port (14).

In addition, some of the air sucked into the casing (10) is guided by the flow path guide (18) inside it and flows into the air distribution duct (40), and the air flowing into the air distribution duct (40) flows into the auxiliary filter unit (70). ), it is purified secondarily and then discharged to another area of the indoor space (S).

At this time, the air flow into the air distribution duct 40 is controlled according to the opening and closing operation of the opening and closing valve 60.

Meanwhile, when air flows into the air distribution duct 40, the foreign matter inflow prevention cover 80 remains open, otherwise, the foreign matter inflow prevention cover 80 remains closed.

10: Casing 12: Intake port
14: exhaust port 18: euro guide
20: filter unit 22: frame part
24: photocatalyst filter unit 24a, 24b: mesh network
24c: LED 24d: LED protective cover
30: Lighting fixture 40: Air distribution duct
50: fan unit 60: open/close valve
70: Auxiliary filter unit

Claims (6)

In the ceiling-type air purification system installed on the ceiling (C) and purifying the air in the indoor space (S),
A casing (10) in which an intake port (12), an exhaust port (14), and a communication hole (16) are formed; A filter unit (20) installed inside the casing (10) and positioned in correspondence with the intake port (12); A lighting fixture (30) connected to the casing (10); an air distribution duct (40) whose end is in communication with the communication hole (16) and whose other end is in communication with the indoor space (S); Installed inside the casing 10, it includes a fan unit 50 that sucks air into the intake port 12 and discharges it through the exhaust port 14 and the air distribution duct 40, and the casing 10 ) is provided inside the fan unit 50 with a flow guide 18 that guides the air discharged through the communication hole 16, and an opening/closing valve ( 60); An auxiliary filter unit (70) installed on the air distribution duct (40); It further includes a foreign matter inflow prevention cover 80 installed at the outlet of the air distribution duct 40, and the auxiliary filter unit 70 has an inlet 72a and an outlet 72b communicating with the air distribution duct 40. ) is formed on the cover (72); A plurality of mesh nets 74 arranged in a line in a spiral shape inside the cover 72 and coated with a photocatalyst; A reflector 76 installed to surround the mesh network 74; It is installed inside the cover 72 and consists of an LED 78 that irradiates a complex wavelength consisting of ultraviolet rays and visible rays to the mesh net 74,
The filter unit 20 includes a frame portion 22; It consists of a photocatalytic filter unit 24 installed inside the frame unit 22,
The photocatalyst filter unit 24 is fitted with the frame unit 22 and includes a pair of mesh nets 24a and 24b coated with a photocatalyst; An LED (24c) coupled to the frame portion (22) and positioned between the pair of mesh nets (24a, 24b) and irradiating ultraviolet rays and visible light to the pair of mesh nets (24a, 24b); It is installed in front of the LED (24c) and consists of an LED protection cover (24d) made of a light-transmitting material to protect the LED (24c),
Each of the pair of mesh networks (24a, 24b) includes a first mesh network (A); a second mesh network (B) spaced apart from the first mesh network (A); It consists of a third mesh network (C) in the form of a wave pattern interposed between the first mesh network (A) and the second mesh network (B),
A foreign matter adhesive coating layer is formed on the inner surface of the air distribution duct 40 to adhesively remove foreign substances remaining in the air that are not removed through the filter unit 20,
The ceiling-type air purification system is characterized in that the foreign matter inflow prevention cover (80) has a spring hinge structure so that the opening and closing operation is automatically performed according to the air flow in the air distribution duct (40). delete delete delete delete delete