KR20240048767A - Antivirus air conditioning module system to prevent the spread of infectious disease at indoor facilities - Google Patents

Abstract

This technology relates to an air conditioning system that can kill viruses or bacteria existing in the indoor air of a closed facility by selecting the circulation mode or the outdoor air mode depending on the carbon dioxide concentration value. More specifically, the indoor air where cooling and heating are performed. The total heat exchange module unit discharges air to the outdoors but supplies fresh outside air indoors, and prevents load loss for cooling and heating by recovering the heat energy wasted when discharging indoor air from the heat exchange element (Air-to-Air Heat Exchange). and a heating and cooling module unit that sterilizes indoor and outdoor air flowing into the room through the heat exchange module unit and simultaneously adjusts the temperature, and at least one of the heat exchange module unit and the heating and cooling module unit based on the set indoor temperature value and carbon dioxide concentration value. It is characterized by including a control unit that controls one.

Description

Antivirus air conditioning module system to prevent the spread of infectious disease at indoor facilities}

This technology relates to an air conditioning system that can kill viruses or bacteria existing in the indoor air of a closed facility by selecting the circulation mode or the outdoor air mode depending on the carbon dioxide concentration value.

Recently, there have been reports of coronavirus spreading in indoor spaces where air conditioning is running and spreading as a group infection.

When using an indoor air conditioner like this, some of the air flows to the side or convection currents or vortices are formed, which can increase the probability that infectious bacteria from a person's respiratory tract can be directly transmitted to the respiratory tract of another person.

Additionally, infected air is sucked back into the air conditioner and discharged, which can instantly spread infectious bacteria throughout the entire internal space.

Furthermore, infected air can spread infectious bacteria to other indoor spaces through vents.

In this way, airborne infectious agents such as coronavirus can be easily spread in indoor spaces where air conditioning is running.

Separate air purifiers or sterilizing devices are installed and operated indoors to improve indoor air quality and remove viruses/bacteria in these enclosed indoor facilities.

However, existing air purifiers and sterilizing devices have a risk of spreading indoor viruses/bacteria in that they are devices that circulate indoor air, and as the level of virus/bacteria contamination increases, there is a limit to their removal ability.

Therefore, there is an urgent need for an air conditioning system that discharges indoor air to an external device but can supply air back into the room after cooling/heating and sterilization.

Domestic Public Patent No. 10-2022-58407 (Publication date: 2022.05.09.) Domestic registered patent No. 10-2426021 (announcement date: 2022.08.01.) Domestic registration utility No. 20-0164653 (announcement date: 2000.02.15.)

In order to solve the above-described conventional problems, the present invention is an air conditioning system that can discharge viruses and bacteria to the outdoors in a small sports facility, which is a sealed indoor structure, or allow indoor air from which viruses and bacteria have been removed through a sterilizing device to be introduced into the room. The purpose is to provide.

In order to solve the above-mentioned technical problems, the air conditioning system for preventing the spread of infectious agents in indoor facilities according to the present invention discharges indoor air that is cooled and heated to the outdoors, supplies fresh outdoor air to the indoors, and discards the waste when discharging indoor air. A heat exchange module unit 100 that recovers heat energy from a heat exchange element (Air-to-Air Heat Exchange) to prevent load loss for cooling and heating, and indoor and outdoor air flowing into the room through the heat exchange module unit 100. A control unit ( 300).

In addition, the total heat exchange module unit 100 includes a casing 110 equipped with a plurality of blowers 111 and 113 capable of supplying or exhausting indoor and outdoor air, respectively, and is installed inside the casing 110 to heat the indoor air by a heat exchange element. It includes a heat recovery member 120 that recovers heat energy for polluted air by a heat exchange element and a sensor member that measures indoor temperature and carbon dioxide concentration, and the cooling and heating module unit 200 includes a blower 111 for supplying air. ) is preferably connected to the casing 110 so that it can communicate with each other.

In addition, the cooling and heating module unit 200 includes a housing 210 connected to the heat exchange module unit 100 by a pipe and having a bypass damper 211 formed therein, and a housing 210 that provides protection against indoor and outdoor air flowing into the housing 210. It includes an air conditioner 220 that controls the temperature and a sterilizing member 230 that sterilizes the indoor and outdoor air supplied into the room through the housing 210, wherein the sterilizing member 230 is a UV lamp using ultraviolet rays. , the control unit 300 preferably controls the bypass damper 211 to be opened when the air conditioner 220 is not operating.

In addition, it is preferable that at least one of the total heat exchange module unit 100 or the cooling and heating module unit 200 is further provided with a filter 130.

In addition, the control unit 300 includes a circulation mode 310 that circulates indoor air and an outdoor air mode 320 that exhausts indoor air to the outdoors but introduces outdoor air into the indoor room. The circulation mode 310 It is operated below the set carbon dioxide concentration value, and the outdoor air mode 320 is preferably operated when the carbon dioxide concentration value is exceeded.

Additionally, it is desirable to set the carbon dioxide concentration value based on the number of occupants compared to the indoor volume.

According to the present invention, different from the prior art, there is a circulation mode in which indoor air can be sterilized based on the setting information set through the control unit based on the number of occupants in the sports facility and the carbon dioxide concentration value transmitted from the sensor member to the control unit. By selectively applying and using the all-outdoor air mode, which exhausts indoor air to the outdoors and at the same time introduces sterilized outdoor air into the indoors, it has the effect of preventing the presence of viruses and bacteria in the sports facility.

1 is a diagram showing an air conditioning system device and components for preventing the spread of infectious agents in indoor facilities according to the present invention.
Figures 2 and 3 are conceptual diagrams showing the operational relationship in a circulation mode with respect to Figure 1.
Figures 4 and 5 are conceptual diagrams showing the operation relationship in the external air mode with respect to Figure 1.

Hereinafter, various embodiments will be described in more detail with reference to the attached drawings. The embodiments described herein may be modified in various ways. Specific embodiments may be depicted in the drawings and described in detail in the detailed description. However, the specific embodiments disclosed in the attached drawings are only intended to facilitate understanding of the various embodiments. Accordingly, the technical idea is not limited to the specific embodiments disclosed in the attached drawings, and should be understood to include all equivalents or substitutes included in the spirit and technical scope of the invention.

Hereinafter, with reference to the attached drawings, the air conditioning system for preventing the spread of infectious agents in indoor facilities according to the present invention (hereinafter simply referred to as 'air conditioning system') will be described in detail.

Prior to explanation, the indoor air described below refers to small or larger sports facilities (for example, indoor sports stadiums, etc.) that are sealed.

First, as shown in FIG. 1, the air conditioning system 1 according to the present invention largely includes a heat exchange module unit 100, a cooling and heating module unit 200, and a control unit 300 that controls these components.

In more detail, the heat exchange module unit 100 discharges the indoor air of the sports facility where cooling and heating are performed to the outdoors while supplying fresh outside air to the indoor space, and recovers the heat energy wasted when discharging the indoor air to provide cooling and heating. It is configured to minimize load loss according to and includes a casing 110, a heat recovery member 120, a sensor member, and a filter 130.

For example, as shown, the casing 110 is formed by combining a plurality of plates having lengths in vertical and horizontal directions to form a housing, and is made of metal.

A plurality of through holes for supplying and exhausting indoor and outdoor air are formed on the outer surface of the casing 110 to communicate with the interior, and for this purpose, blowers 111 and 113 are installed in each through hole.

For example, the air supply blower 111 is installed in the casing 110 so that it can be connected to the housing 210, which will be described later, and the exhaust blower 113 is symmetrical to the air supply blower 111. ) is fixedly installed inside.

A mode damper 141 may be separately provided inside the casing 110, and the mode damper 141 is in an OPEN state in the case of the circulation mode 310 among the modes executed by the control unit 300, which will be described later. This allows circulation of indoor air.

The inside of the casing 110 forms a space divided by a plurality of partition plates, and is equipped with a heat recovery member 120 as well as a plurality of filters 130 for filtering out foreign substances contained in indoor and outdoor air.

The filter 130 may be formed inside the housing 210 as needed, and a HEPA filter is preferably used. In addition, a damper 140 may be installed in the through hole formed toward the outdoor side. .

In addition, the heat recovery member 120 is configured to prevent load loss for cooling and heating by recovering heat energy contained in exhausted indoor air from a heat exchange element (Air-to-Air Heat Exchange).

For this purpose, the heat recovery member 120 is installed so as to be located in the inner central part of the casing 110, so that not only the outdoor air introduced by the air supply blower 111 but also the indoor air exhausted to the outdoors through the exhaust blower 113 Allows air to move through the heat recovery member 120.

Additionally, the sensor member includes a temperature sensor that measures the temperature of the indoor air of the sports facility and a carbon dioxide sensor that measures the carbon dioxide concentration in the room.

The sensor member is electrically connected to the control unit 300 to convert the measured measurement information into data and transmit it. The control unit 300 compares the transmitted measurement information with the set value and selects the circulation mode 310 or the external air mode ( 320), any one of the modes can be executed, which will be explained in more detail below.

In addition, the cooling and heating module unit 200 is configured to sterilize and simultaneously control the temperature of indoor and outdoor air flowing into the room through the heat exchange module unit 100 described above, and includes a housing 210, an air conditioner 220 and a sterilizing member. It includes 230, and although not shown, an outdoor unit (not shown) connected to the air conditioner 220 may be further provided.

For example, as shown, the housing 210 can be molded into the shape of a box using a steel material so that the air conditioner 220 and the sterilizing member 230 can be installed on the inside, and the outer surface has an air supply blower 111 and The pipe is connected in communication so that outdoor air can be introduced into the room through the heat recovery member 120 through the air supply blower 111 or indoor air can be circulated, depending on the mode selection of the control unit 300. I order it.

At this time, it is preferable to further include a bypass damper 211 inside the housing 210, which is opened when the air conditioner 220 is not in operation and can achieve energy savings by minimizing the power of the blower provided in the air conditioner 220. .

In addition, the air conditioner 220 connected to the outdoor unit adjusts the temperature of the air introduced into the housing 210 so that it has cold or warm air and is supplied indoors. As shown, the air conditioner 220 and the air conditioner 220 are connected to the outdoor unit. The bypass damper 211 can also be installed in multiple configurations in one housing 210 (see Figure 3 or Figure 5).

In addition, the sterilizing member 230 is installed inside the housing 210 to be located at the output end where the air flowing into the housing 210 is discharged, and sterilizes harmful bacteria contained in the air to be supplied indoors.

For example, the sterilizing member 230 may be a UV lamp using ultraviolet rays. In the detailed description of the present invention, it is described as being installed in the housing 210, but if necessary, it may also be provided on the output side of the casing 110 described above. Note that there is

In addition, the control unit 300 automatically selects a mode based on the measurement information and setting information transmitted from the above-described sensor member to control the heat exchange module unit 100 and the cooling and heating module unit 200 to operate. It includes a circulation mode 310 and an outdoor air mode 320, and the mode is preferably determined through the concentration value of carbon dioxide.

For example, as shown in Figures 2 and 3, the circulation mode 310 operates when the concentration value of carbon dioxide included in the measurement information is lower than the set value compared to the setting information set in the control unit 300. The air supply blower 111 is operated so that the indoor air within the sports facility can be circulated.

In addition, as shown in FIGS. 4 and 5, the outdoor air mode 320 operates the exhaust blower 113 and the air supply blower 111 together when the concentration value of carbon dioxide exceeds the set value to provide sports The indoor air within the facility is exhausted to the outdoors, and the outdoor air is operated so that it can be introduced indoors.

At this time, it is desirable to set the carbon dioxide concentration value through the control unit 300 based on the number of occupants compared to the internal volume of the sports facility.

As described above, the air conditioning system 1 according to the present invention is different from the conventional one by using setting information set through the control unit 300 based on the number of occupants in the sports facility and carbon dioxide transmitted from the sensor member to the control unit 300. By selectively using the circulation mode that allows sterilization of indoor air based on the concentration value or the all-outdoor air mode that exhausts indoor air to the outdoors and at the same time introduces sterilized outdoor air into the room, the It has the effect of preventing the presence of viruses and bacteria.

As described above, the present invention has been described with specific details such as specific components and limited embodiments and drawings, but this is only provided to facilitate a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , those skilled in the art can make various modifications and variations from this description.

Accordingly, the spirit of the present invention should not be limited to the described embodiments, and the scope of the patent claims described later as well as all things that are equivalent or equivalent to the scope of this patent claim shall fall within the scope of the spirit of the present invention. .

1: Air conditioning system for preventing the spread of infectious agents in indoor facilities according to the present invention
100: Heat exchange module part
110: Casing 111: Air supply blower
113: exhaust blower 120: heat recovery member
130: filter 140: damper
141: Mode damper
200: Cooling and heating module unit
210: Housing 211: Bypass damper
220: Air conditioner 230: Sterilization member
300: Control unit
310: circulation mode 320: electric outdoor mode

Claims (6)

The cooled and heated indoor air is discharged to the outdoors, while fresh outdoor air is supplied indoors, and the heat energy wasted when discharging indoor air is recovered from the heat exchange element (Air-to-Air Heat Exchange) to prevent load loss for cooling and heating. A heat exchange module unit (100) that performs;
A heating and cooling module unit (200) that sterilizes and simultaneously regulates the temperature of indoor and outdoor air flowing into the room through the heat exchange module unit (100); and
A control unit 300 that controls at least one of the heat exchange module unit 100 or the cooling and heating module unit 200 based on the set indoor temperature value and carbon dioxide concentration value. Air conditioning system to prevent spread.
According to paragraph 1,
The heat exchange module unit 100 is
A casing (110) equipped with a plurality of blowers (111, 113) capable of supplying or exhausting indoor and outdoor air, respectively;
A heat recovery member 120 installed inside the casing 110 to recover heat energy from indoor polluted air using a heat exchange element; and
Including a sensor member that measures indoor temperature and carbon dioxide concentration,
An air conditioning system for preventing the spread of infectious agents in indoor facilities, wherein the heating and cooling module unit (200) is connected to the casing (110) by a pipe so as to communicate with the blower (111) for air supply.
According to paragraph 1,
The cooling and heating module unit 200 is
A housing (210) connected to the heat exchange module unit (100) by a tube and having a bypass damper (211) formed therein;
An air conditioner 220 that controls the temperature of indoor and outdoor air flowing into the housing 210; and
Includes a sterilizing member 230 that sterilizes the indoor and outdoor air supplied into the room through the housing 210,
The sterilizing member 230 is a UV lamp using ultraviolet rays,
An air conditioning system for preventing the spread of infectious agents in indoor facilities, wherein the control unit 300 controls the bypass damper 211 to be opened when the air conditioner 220 is not operating.
According to paragraph 3,
An air conditioning system for preventing the spread of infectious agents in indoor facilities, characterized in that at least one of the heat exchange module unit (100) or the cooling and heating module unit (200) is further provided with a filter (130).
According to paragraph 1,
The control unit 300 is
Circulation mode 310 for circulating indoor air; and
Including an electric outdoor air mode (320) that exhausts indoor air to the outdoors but introduces outdoor air into the indoor room,
The circulation mode 310 operates below the set carbon dioxide concentration value,
An air conditioning system for preventing the spread of infectious agents in indoor facilities, wherein the outdoor air mode (320) is operated when the carbon dioxide concentration value is exceeded.
According to clause 5,
An air conditioning system for preventing the spread of infectious agents in indoor facilities, wherein the carbon dioxide concentration value is set based on the number of occupants compared to the indoor volume.