KR101153398B1 - Room air cleaning system - Google Patents

Abstract

PURPOSE: A room air conditioning system using a ventilation unit is provided to effectively sanitize circulation air by increasing a contact area with the circulation air. CONSTITUTION: A room air conditioning system using a ventilation unit comprises a body, an indoor ventilation unit, an outdoor ventilation unit, a first flow path unit(1), a second flow path unit(2), a bypass unit(3), and an UV(Ultraviolet Ray) lamp. The body is placed on a boundary between an inside and an outside, and comprises heat exchange elements. The indoor ventilation unit is installed in one side of the body, and comprises an inlet of an inner side and an outlet of the inner side. The outdoor ventilation unit is installed in the other side of the body, and comprises the inlet of an outer side and the outlet of the outer side. The first flow path links the outlet of the inner side and the inlet of the outer side. The second flow path links the inlet of the inner side and the outlet of the outer side. The bypass unit links the outlet of the inner side and the outlet of the outer side. The UV lamp is installed inside the body and sanitizes the air flowing into inside the body.

Description

Room air purification system using ventilation unit {ROOM AIR CLEANING SYSTEM}

The present invention relates to an indoor air purification system using a ventilation unit.

In general, the air in a closed room is gradually polluted over time, such as by a person's breathing in the room. Therefore, the polluted air in the indoor should be replaced with fresh air in the outdoor from time to time. For this purpose, a general heat exchanger and a ventilation system using the same are used.

The total heat exchanger is a device for supplying outside air and exhausting the indoor air while maintaining the temperature of the indoor air.

A prior art document related to the present invention is Korean Patent No. 10-0628058, which discloses a technology for a ventilation system.

An object of the present invention is to provide an indoor air purification system using a ventilation unit capable of performing sterilization and odor removal of indoor air using a photocatalyst.

Another object of the present invention is to provide an indoor air purification system using a ventilation unit that can effectively sterilize circulated air by increasing the contact area with circulated air.

The present invention provides an indoor air purification system using a ventilation unit.

The indoor air purification system includes a main body disposed at a boundary between indoor and outdoor and having a heat exchange element disposed therein; An indoor ventilation unit installed at one side of the main body and having an indoor suction port and an indoor discharge port; An outdoor vent installed on the other side of the main body and having an outdoor suction port and an outdoor discharge port; A first passage connecting the indoor outlet and the outdoor suction port; A second flow path connecting the indoor suction port and the outdoor discharge port; A bypass flow path unit connecting the indoor outlet and the outdoor outlet; And a UV lamp installed in the main body and sterilizing air flowing into the main body.

The present invention has the effect of performing sterilization and odor removal of indoor air using a photocatalyst.

In addition, the present invention has the effect of increasing the contact area with the air circulated to effectively sterilize the air circulated.

1 is a view showing an indoor air purification system using the ventilation unit of the present invention.
FIG. 2 is a view showing a lamp in the yub shown in FIG. 1.
3 to 5 are views showing the state of various air flows according to the present invention.

Hereinafter, the ventilation unit of the present invention will be described with reference to the accompanying drawings.

1 shows a ventilation unit of the invention. 2 shows a ventilation unit control method of the present invention.

First, the structure of the ventilation unit of this invention is demonstrated.

Referring to FIG. 1, the ELV ventilation system according to the present invention includes a main body 100, an indoor ventilation unit, an outdoor ventilation unit, first and second flow passage units 1 and 2, and a bypass flow passage unit 3. It consists of The main body 100 is formed in a rectangular box shape.

Inside the main body 100, a heat exchange element 110 is formed in a rectangular plate shape having a predetermined thickness.

The inner space of the main body 100 is formed with two spaces divided up and down by the boundary of the heat exchange element (110).

The main body 100 is preferably installed on the wall 10 that borders the indoor and outdoor.

In addition, a pollution meter 460 is installed in the indoor space. The pollution meter 460 is preferably a carbon dioxide meter. The pollution meter 460 measures the amount of carbon dioxide in the room. The pollution meter 460 transmits the amount of carbon dioxide measured to the controller 410 to be described later.

A UV lamp 800 for sterilizing air flowing in the first flow path part 1, the second flow path part 2, and the bypass flow path part 3 is installed inside the main body 100.

The UV lamp 800 is installed inside the main body 100, and is connected to a rail 900 installed at an edge of the heat exchange element 110.

Therefore, the UV ramp 800 may be variably moved along the rail 900.

Although not shown in the figure, the rail 900 has a driver. The driver is driven to move the rail 900 by receiving an electrical signal from the controller 410.

Therefore, the UV lamp 800 may be variably moved in position by the movement of the rail 900.

2 shows a UV lamp.

The UV lamp 800 is provided with a catalyst coating metal mesh 810 coated with titanium dioxide having a predetermined thickness.

A plurality of radiation guide grooves 811 are further formed in the catalyst coated metal mesh 810.

The UV lamp 800 may irradiate dual wavelengths of 184.9 nm and 253.7 nm.

The outer surface of the catalyst coating metal mesh 810 is further formed with a pleat (not shown) at regular intervals along the longitudinal direction of the UV lamp (800).

The catalyst coated metal net 810 includes gold, silver, zinc oxide, and cadmium sulfide including titanium dioxide.

The indoor ventilation unit is composed of an indoor side suction port 212 and an indoor side discharge port 211. These are formed on the indoor side, which is one side of the main body 100.

The outdoor side ventilation part includes an outdoor side inlet 222 and an outdoor side outlet 221. These are formed on the outdoor side, which is the other side of the main body 100.

The first flow path part 1 is provided inside the main body 100.

The first flow path part 1 is a path connecting the indoor outlet 211 and the outdoor suction port 222, which is a flow path through which air can flow.

The second flow path part 2 is provided inside the main body 100.

The second flow path part 2 is a path connecting the indoor suction port 212 and the outdoor discharge port 221, and this path is a flow path through which air can flow.

The first and second flow paths 1 and 2 may be formed using a means such as a plastic duct.

The first and second flow paths 1 and 2 are provided in the upper space partitioned by the heat exchange element 110 inside the main body 100.

The bypass flow path part 3 is a path connecting the indoor outlet 211 and the outdoor outlet 221, and this path is a path through which air can flow.

The bypass flow path part 3 may also be formed using a means such as a plastic duct.

The bypass flow path part 3 is provided in the lower space partitioned by the heat exchange element 110 inside the main body 100.

Therefore, the bypass flow path part 3 is formed in a space different from the first flow path part 1 and the second flow path part 2 inside the main body 100 with respect to the heat exchange element 110. Can be.

The air flange 400 is disposed inside the main body 100 of the outdoor side outlet 221 and receives an electrical signal from the outside to open or close the second channel part 2 or the second channel part 2. And the bypass flow path 3 may be connected or closed with each other.

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The fan 430 may be installed in the bypass flow path part 3 near the air flange 300.

The fan 430 may be installed in the main body 100 to generate a forced flow in the first flow path part 1, the second flow path part 2, and the bypass flow path part 3.

The controller 410 may receive the selection mode signal from the outside to control the driving of the air flange 300 and the fan 430.

The selector 450 is electrically connected to the controller 410 and opens and closes the first flow path 1 or opens and closes the second flow path 2 or the first flow path 1 and the second. A selector 450 may be provided to transmit the selection mode signal for selecting whether to connect the flow path unit 2 and the bypass flow path unit 3 to the controller 410.

Here, the selector 450 is set to the total heat exchange mode, the external air cutoff mode, and the bypass mode.

The heat exchange mode is a mode for transmitting an electrical signal to the controller 410 to open the first flow path part 1 and the second flow path part 2, and the external air blocking mode is the first flow path part. Closes (1) and transmits an electrical signal to the controller 410 to open the second flow path part 2, and the bypass mode is the first flow path part 1 and the bypass flow path. It may be a mode for transmitting an electrical signal to the controller 410 to connect the unit (3).

The configuration of the air flange 300 may be the same.

The air flange 300 has a flange body 310 in which the openings O1, O2, and O3 are formed in three directions, and an opening / closing member that opens and closes as each opening is rotated by forming a rotation center in the flange body 310. And a motor 420 axially connected to the rotation center of the opening and closing member 320 and receiving the electrical signal from the controller 410 to rotate the opening and closing member 320 to a predetermined position. .

The air flange 300 has openings in three directions on the second flow path part 2 side, the outdoor side, and the bypass flow path part 3 side.

On the other hand, the indoor space is further provided with a pollution meter 460 for measuring the amount of carbon dioxide contained in the indoor air, and transmits the measured amount of carbon dioxide to the controller 410.

The controller 410 may control the driving speed of the fan 430 to be proportional to the amount of carbon dioxide transmitted.

In addition, the UV lamp 800 may be installed in a plurality of the main body 100.

The controller 410 may control the number of operation of the UV lamp 800 to be proportional to the amount of carbon dioxide measured.
Reference numeral 470 denotes an indicator, which is electrically connected to the controller 410.

The indoor air purification system of the present invention will be described with reference to the above configuration.

 In the air circulation, the UV lamp 800 coated with a photocatalyst on the outer surface may be used to sterilize the circulated air.

That is, the catalyst coating metal mesh 810 having a plurality of radiation guide grooves 811 is provided on the outer circumferential surface of the UV lamp 800 to promote the reaction with the catalyst.

The UV lamp 800 is a lamp to which dual wavelengths of 184.9 nm and 253 nm are irradiated.

The catalyst coated metal mesh 810 is formed with a pleat (not shown). The pleats may be installed at equal intervals along the longitudinal direction of the lamp 800.

Accordingly, by increasing the contact area between the catalyst coating metal mesh 810 and the air, the circulated air can be sterilized or coated quickly.

In addition, in the present invention, the catalyst coating metal mesh 810 may be formed by mixing and molding gold, silver, zinc oxide, and cadmium sulfide containing titanium dioxide.

Embodiment according to the present invention is to install a UV or UV lamp and a photocatalyst in the body to sterilize, deodorize a series of indoor air, to provide indoor air purification, as well as in the air cleaning and heat exchanger such as sterilization, deodorization of indoor air It removes odors by removing bio-film formed by bacteria such as molds that grow easily and improves heat exchange efficiency to provide energy saving function.

The embodiment according to the present invention is formed so that the ultraviolet radiation is smoothly irradiated to the heat exchange element, while the catalyst coating metal network provided with a plurality of radiation induction grooves on the outer circumferential surface of the lamp to facilitate the reaction with the catalyst including titanium dioxide (TiO2) To be possible.

Embodiment of the present invention is formed to decompose and remove the photocatalytic reaction by the photocatalyst and UV LAMP to sterilize, deodorize, VOCs (volatile organic compounds), etc. can improve the indoor air quality.

In addition, the determination of the air circulation state according to the indoor pollution degree as described above can be explained by the following three examples.

Heat exchange mode

Referring to FIG. 3, the selector 450 transmits a selection signal for the full heat exchange mode to the controller 410.

The controller 410 operates the air flange 300 to open the first and second flow path parts 1 and 2.

That is, one of the openings in the three directions of the air flange 300, the opening and closing member 320 so that the first channel portion 1 and the indoor space is connected, the second channel portion 2 and the outdoor space is connected. Rotate). Thus, the opening O3 is closed. O3 is an opening connected to the bypass flow passage part 3.

At this time, the fan 430 receives the electrical signal from the controller 410 is driven to rotate at a constant rotation speed.

Accordingly, the first and second flow path parts 1 and 2 are opened, the indoor air is discharged to the outdoor side along the second flow path part 2, and the outdoor air is indoors along the first flow path part 1. Flows into.

That is, indoor and outdoor air can be continuously ventilated and circulated.

External air shutoff mode

Referring to FIG. 4, the selector 450 transmits a selection signal for the full heat exchange mode to the controller 410.

The controller 410 operates the air flange 300 to open the second flow path part 2.

That is, the controller 410 rotates the opening / closing member 320 to close the opening O1, which is one of three openings of the air flange 300.

At this time, the fan 430 receives the electrical signal from the controller 410 is driven to rotate at a constant rotation speed.

Accordingly, the second channel part is closed, the outdoor air is blocked from entering the room, and as the second channel part is opened, the indoor air can be discharged to the outside along the second channel part.

That is, the indoor air may be continuously discharged while the inflow of outdoor air is blocked.

Bypass mode

Referring to FIG. 5, the selector 450 transmits a selection signal for the bypass mode to the controller 410.

The controller 410 operates the air flange 300 so that the second flow path part 2 and the bypass flow path part 3 are connected to each other.

That is, the controller 410 rotates the opening / closing member 320 to close the opening O2, which is one of the three directions of the opening of the air flange 300.

Therefore, the opening O3 is connected with the bypass flow path part 3.

Therefore, the opening O2 of the air flange 300 is connected to the bypass flow passage part 3.

At this time, the fan 430 receives the electrical signal from the controller 410 is driven to rotate at a constant rotation speed.

Accordingly, the indoor air flowing through the indoor suction port 212 flows along the second flow path part 2, and passes through the openings O1 and O2 of the air flange 300 to the bypass flow path part 3. Is moved. The indoor air introduced into the bypass flow path part 3 is discharged back to the indoor space through the indoor discharge port 211.

That is, indoor air may be circulated several times through the bypass flow path part 3.

100: main body 110: heat exchange element
300: air flange 310: flange body
320: opening and closing member

Claims (9)

A main body disposed at a boundary between indoor and outdoor and having a heat exchange element disposed therein;
An indoor ventilation unit installed at one side of the main body and having an indoor suction port and an indoor discharge port;
An outdoor vent installed on the other side of the main body and having an outdoor suction port and an outdoor discharge port;
A first passage connecting the indoor outlet and the outdoor suction port;
A second flow path connecting the indoor suction port and the outdoor discharge port;
A bypass flow path unit connecting the indoor outlet and the outdoor outlet;
A UV lamp installed inside the main body and sterilizing air flowing into the main body;
The air is disposed inside the main body of the outdoor side outlet and receives an electrical signal from the outside, and opens or closes the first flow path or opens or closes the second flow path, or connects or closes the second flow path and the bypass flow path to each other. flange;
A fan installed in the main body and configured to generate forced flow in the first flow path part, the second flow path part, and the bypass flow path part;
A controller for controlling the driving of the air flange and the fan by receiving a selection mode signal from the outside;
The selection mode signal that is electrically connected to the controller and selects whether to open or close the first channel part or to open or close the second channel part, or to connect the first channel part to the second channel part and the bypass channel part; A selector for transmitting to the controller,
The air flange is axially connected to the flange body and the opening and closing member for opening and closing the respective openings in accordance with the position rotated to form a rotation center on the flange body, the opening in three directions, the rotation center of the opening and closing member, A motor which receives the electrical signal from a controller and rotates the opening / closing member to a predetermined position;
The openings in the three directions are composed of the second flow path side opening, the first flow path side outdoor side opening, and the bypass flow path side opening,
Opening and closing of the first flow path portion is formed by opening and closing the first flow path side outdoor opening by rotation of the opening and closing member,
Opening and closing of the second channel portion is formed by opening and closing the second channel portion side opening by the rotation of the opening and closing member,
And the connection between the second flow path part and the bypass flow path part is formed by closing the outdoor side opening by rotation of the opening / closing member. The method of claim 1,
The UV lamp is an indoor air purification system using a ventilation unit, characterized in that the catalyst coating metal net is coated with a predetermined thickness of titanium dioxide. The method of claim 2,
The catalyst coating metal net is a room air purification system using a ventilation unit, characterized in that a plurality of radiation guide groove is further formed. The method of claim 1,
The UV lamp,
An indoor air purification system using a ventilation unit, characterized by irradiating dual wavelengths of 184.9 nm and 253.7 nm. The method of claim 2,
Indoor air purification system using a ventilation unit, characterized in that the outer surface of the catalyst-coated metal net is further formed with a pleated band at regular intervals along the longitudinal direction of the UV lamp. The method of claim 2,
The catalyst coating metal net is indoor air purification system using a ventilation unit, characterized in that it comprises gold, silver, zinc oxide, cadmium sulfide containing titanium dioxide. delete The method of claim 1,
The indoor space further comprises a pollution meter for measuring the amount of carbon dioxide contained in the indoor air, and transmits the measured amount of carbon dioxide to the controller,
And the controller controls the drive speed of the fan to be proportional to the amount of carbon dioxide transmitted. The method of claim 8,
The controller is electrically connected to the indicator, and two or more lamps are installed in the main body,
And controlling the number of operation of the UV lamp so as to be proportional to the amount of carbon dioxide to be measured.

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