KR101147406B1 - Fan coil air cleaning apparatus - Google Patents

Abstract

PURPOSE: An air purifier using a fan coil unit is provided to improve a sterilization capacity by sterilizing indoor air in an area independent from a heat exchange unit and to easily perform a water supply of a sterilization unit. CONSTITUTION: An air purifier using a fan coil unit comprises a inhalation unit(100), a heat exchange unit, a sterilization unit, and a discharging unit(200). The inhalation unit is detachably installed in an outer case(10) fixed to a ceiling, thereby inhaling indoor air. The heat exchange unit is installed in the upper part of the outer case to be inserted into inside the ceiling. The sterilization unit is arranged in four edge portions of the outer case to be spatially partitioned with the heat exchange unit. The sterilization unit receives the heat exchanged indoor air from the heat exchanger, thereby sterilizing the indoor air in the other space spatially partitioned with the heat exchange unit.

Description

Air Purification System using Fan Coil Unit {FAN COIL AIR CLEANING APPARATUS}

The present invention relates to an air purifying apparatus using a fan coil unit, and more particularly, to an air purifying apparatus using a fan coil unit which enables to disinfect indoor air sucked at the outer side of the heat exchanger and then discharge the indoor air. It is about.

In general, an air conditioner such as a ceiling air conditioner is installed on the ceiling of an indoor space, and the use and development of recent years has increased due to the advantage that the indoor space can be used more widely and the advantage of allowing the interior space to be more quickly harmonized. have. The ceiling air conditioner is provided with a blowing fan, a heat exchanger, and the like in an approximately hexahedral space.

Only one surface of the ceiling air conditioner is exposed to the outside, and thus a suction part for sucking air and a discharge part for discharging air exchanged with the heat exchanger are disposed on one surface. It is common to have one to four discharge parts.

The blowing fan installed in the ceiling air conditioner forms a forced flow to promote the suction of air through the suction unit and the discharge of the heat-exchanged air through the discharge unit.

The air in a closed room is gradually polluted over time, such as by the breathing of a person active 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 air purifier using a fan coil unit that can be discharged to the room after additionally sterilized in a separate space after the heat exchange by sucking the air in the room.

Another object of the present invention is to provide an air purifying apparatus using a fan coil unit which sterilizes indoor air in an area independent of the heat exchanger to improve sterilization capability, and facilitates the airborne work of the sterilization unit.

The present invention provides an air purifying apparatus using a fan coil unit.

The air conditioner includes a suction unit for sucking air in the room; A heat exchanger provided at one side of the suction unit so as to be inserted into the ceiling, and heat-exchanging the indoor air to be sucked to a predetermined temperature; A sterilization unit disposed at predetermined intervals along the outer edge of the heat exchanger and receiving and sterilizing air from the heat exchanged room; And a discharge unit for discharging the air of the sterilized room from the sterilization unit to the room.

The sterilization unit is connected between the first heat exchanger and the first pipe to deliver the air in the heat-exchanged room, and the second pipe that is connected to the discharge part and delivers the air in the sterilized room to the discharge part. It is preferred to be connected.

Preferably, the sterilizing unit includes a sterilizing lamp installed between the first tube and the second tube, and a cylindrical photocatalyst coating network surrounding the outer circumference of the sterilizing lamp and coated with a photocatalyst on the outer surface. .

The germicidal lamp is preferably any one of a UV lamp or an ultraviolet lamp operated by receiving power from the outside.

In the photocatalyst coating network, it is preferable that a plurality of radiation guide grooves are further formed.

The sterilization unit includes a pollution meter for measuring the amount of carbon dioxide, and a controller for receiving the amount of carbon dioxide measured from the pollution meter and controlling the illuminance of the sterilization lamp.

The controller preferably receives the measured amount of carbon dioxide and controls the illuminance of the germicidal lamp with an illuminance corresponding to a predetermined amount of carbon dioxide.

The suction part is a suction grille formed in a central portion of an outer case exposed to the outside of the ceiling, and the discharge part is formed in plural around an outer circumference of the suction part, and the heat exchange part is inserted into the ceiling at one side of the outer case. It is preferable that the case is provided so as to protrude, and the sterilizing portion is disposed at four corners of the case.

The present invention has an effect that can be discharged to the room after additionally sterilized in a separate space after the heat exchange by sucking the air in the room.

In addition, the present invention has the effect of sterilizing the air in the room in an area independent of the heat exchanger to improve the sterilization treatment capacity, and facilitate the airborne operation of the sterilization unit.

1 is a bottom view showing an air purification apparatus using the fan coil unit of the present invention.
2 is a plan view showing an air purification apparatus using the fan coil unit of the present invention.
3 is a side view showing an air purification apparatus using the fan coil unit of the present invention.
Figure 4 is another side view showing an air purification apparatus using a fan coil unit of the present invention.
5 is an enlarged view of a symbol A of FIG. 3.

Hereinafter, an air purifying apparatus using the fan coil unit of the present invention will be described with reference to the accompanying drawings.

1 is a bottom view showing an air purification apparatus using the fan coil unit of the present invention. 2 is a plan view showing an air purification apparatus using the fan coil unit of the present invention. 3 is a side view showing an air purification apparatus using the fan coil unit of the present invention.

1 to 3, the air purifying apparatus using the fan coil unit of the present invention includes a suction part 100, a heat exchange part 300, a sterilization part 400, and a discharge part 200. do.

The suction part 100 is installed in the outer case 10.

The outer case 10 is disposed on the ceiling and is a case exposed to the room.

The suction part 100 is a suction grill and provides a flow path for sucking air in the room.

The suction part 100 is detachably installed on the outer case 10. The detachable manner may be hook type coupling.

2 and 3, the heat exchange part 300 is installed inside the case 310 installed at the upper end of the outer case 10. The heat exchanger 300 is a device for heat-exchanging the indoor air sucked from the suction unit 100 to a predetermined temperature.

The case 310 in which the heat exchange part 300 is installed is a part inserted into the ceiling.

Engagement brackets 20 that can be suspended from the ceiling are formed on the outer circumference of the case 310.

Here, a predetermined region is formed at the outer circumference of the case 310 in which the heat exchange part 300 is installed to expose the upper end of the outer case 10.

The sterilization unit 400 is disposed in the region.

3 to 5, the sterilization unit 400 is connected to the heat exchange unit 300, the first pipe 311 and the discharge unit 200 to deliver the air in the heat exchanged room and It is connected between the second pipe 312 for transmitting the sterilized indoor air to the discharge unit 200.

Here, the discharge part 200 is formed at a plurality of positions surrounding the suction part 100 in the outer case 10.

1 and 2, the discharge unit 200 is composed of a discharge port 210, the opening and closing wing 220 for opening and closing the discharge port 210. The opening and closing wing 220 is a member capable of swinging, and is connected to the swing motor 230.

The swing motor 230 receives the electrical signal from the outside to implement the swing operation of the opening and closing member 220.

Referring to FIG. 5, the sterilization unit 400 includes a sterilization lamp 410 and a photocatalyst coating network 420.

The germicidal lamp 410 is installed between the first tube 311 and the second tube 312.

The photocatalyst coating network 420 surrounds the outer circumference of the germicidal lamp 410 and is formed in a cylindrical shape in which a photocatalyst is coated on an outer surface thereof.

The germicidal lamp 410 may be any one of a UV lamp or an ultraviolet lamp operated by receiving power from the outside.

In addition, a plurality of radiation guide grooves 421 are further formed in the photocatalyst coating network 420.

On the other hand, the sterilization unit 400, the pollution meter 500 for measuring the amount of carbon dioxide, the controller 600 for controlling the illuminance of the sterilization lamp 410 receives the amount of carbon dioxide measured from the pollution meter. ).

The controller 600 may receive the measured amount of carbon dioxide and control the illuminance of the germicidal lamp 410 with an illuminance corresponding to a preset amount of carbon dioxide.

In addition, although not shown in the drawings, the air suction to the suction unit 100 and the discharge of air through the discharge unit 200 is implemented by the operation of the blower fan.

Next, the operation of the air purifier using the fan coil unit configured as described above will be described.

5 is an enlarged view of a symbol A of FIG. 3.

1 to 5, due to the operation of the blowing fan (not shown), the air in the room is transferred to the heat exchange part 300 through the suction part 100.

The heat exchange part 300 is a state enclosed with a case inserted inside the ceiling.

The heat exchanger 300 heat exchanges the sucked air to a set temperature.

The air in the heat-exchanged room is delivered to the plurality of sterilization units 400 disposed outside the case 310 through the first pipe 311.

The sterilization unit 400 exposes the heat-exchanged indoor air to a sterilization lamp 410 which is a UV lamp or an ultraviolet lamp having a predetermined illuminance.

The UV lamp can irradiate dual wavelengths of 184.9 nm and 253 nm.

Therefore, the indoor air is first sterilized by a sterilization lamp.

In addition, the indoor air is exposed to the photocatalyst coating network 420.

The photocatalyst coated on the photocatalyst coating network 420 secondaryly sterilizes the indoor air.

In addition, the radiation guide grooves 421 formed in the photocatalyst coating network 420 may further promote the reaction of the indoor air with the photocatalyst.

In addition, although not shown in the drawings, the photocatalyst coating network 420 further includes a pleated band (not shown). The pleated strip may be installed at equal intervals along the longitudinal direction of the germicidal lamp.

Accordingly, by increasing the contact area between the photocatalyst coating network 420 and the air in the room, the circulated air can be sterilized or coated in a short time.

In the present invention, the photocatalyst coating network 420 may be formed by mixing and molding gold, silver, zinc oxide, and cadmium sulfide containing titanium dioxide.

Air in the room sterilized in multiple times as described above may be discharged back to the room through the discharge unit (200).

Through the above process, the indoor air may be recycled by sequentially performing heat exchange and sterilization treatment.

On the other hand, the pollution meter 500 according to the present invention measures the pollution degree for the air in the room that is heat exchanged and flows to the first pipe (311).

The pollution level is the amount of carbon dioxide.

The pollution meter 500 transmits the measured amount of carbon dioxide to the controller 600.

Subsequently, the controller 600 receives the measured amount of carbon dioxide and controls the illuminance of the germicidal lamp 410 with an illuminance corresponding to a preset amount of carbon dioxide.

Therefore, in the present invention, by controlling the illuminance of the sterilization lamp 410 in proportion to the amount of carbon dioxide to the heat exchanged indoor air, the sterilization efficiency of the indoor air can be varied in real time.

The embodiment according to the present invention may additionally sterilize in a separate space after the heat exchange by sucking the air in the room and then discharge it into the room.

Embodiment according to the present invention can sterilize the air in the area independent from the heat exchanger to improve the sterilization treatment capacity, and facilitate the airborne operation of the sterilization unit.

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.

10: outer case 100: suction part
200: discharge part 300: heat exchange part
310: case 400: sterilization unit
410: germicidal lamp 420: photocatalytic coating network
421: radiation guide groove 500: pollution meter
600: controller

Claims (7)

A suction unit detachably installed at an outer case fixed to the ceiling and sucking air in the room;
A heat exchanger installed at an upper end of the outer case so as to be inserted into a ceiling, and heat-exchanging the indoor air to be sucked to a predetermined temperature, and surrounded by a case installed at an upper end of the outer case;
A sterilization unit disposed at four corners of the case so as to be spatially partitioned from the heat exchanger and sterilizing in another space spatially partitioned from the heat exchanger by receiving air from the heat exchanged room from the heat exchanger;
A discharge part for discharging the air of the sterilized room from the sterilization part to the room,
The sterilization unit,
A first pipe connected to the heat exchange part through the case and protruding to an outer region of the case to transfer the air in the heat-exchanged room, and to discharge the air of the room which has been sterilized and connected to the discharge part; Connected between the second pipe to transfer to the negative,
The sterilization unit,
A sterilization lamp installed between the first pipe and the second pipe;
It is provided with a cylindrical photocatalyst coating network surrounding the outer circumference of the germicidal lamp, coated with a photocatalyst on the outer surface, and having a pleated band along the longitudinal direction of the germicidal lamp.
The germicidal lamp,
An air purifier using a fan coil unit, characterized in that any one of a UV lamp or an ultraviolet lamp for irradiating a dual wavelength of 184.9nm, 253nm operated by receiving power from the outside. delete delete delete The method of claim 1,
The photocatalyst coating network, the air purification apparatus using a fan coil unit, characterized in that a plurality of radiation guide groove is further formed. The method of claim 1,
The sterilization unit, the pollution meter for measuring the amount of carbon dioxide,
The controller receives the amount of carbon dioxide measured from the pollution meter, and controls the illuminance of the sterilization lamp,
The controller,
The air purifier using the fan coil unit, characterized in that for receiving the measured amount of carbon dioxide to control the illuminance of the sterilization lamp in accordance with the predetermined amount of carbon dioxide. The method of claim 1,
The suction part is a suction grille formed in the center of the outer case exposed to the outside of the ceiling,
The discharge portion is formed in plurality around the outer periphery of the suction portion,
The heat exchange part has a case protruding to be inserted into the ceiling at one side of the outer case,
The sterilizing unit, the air purification device using a fan coil unit, characterized in that arranged in the four corners of the case.

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