KR102445311B1 - Anti-Virus Heat Recovery Ventilator - Google Patents

Abstract

a heat recovery ventilation device housing each having an indoor air inlet, an outdoor air inlet, an indoor air outlet, and an outdoor air outlet formed on an outer surface thereof; The heat transfer heat received in the heat recovery ventilator housing so that the element suction passage in which the indoor air inlet and the outdoor air outlet communicate with each other and the element discharge passage through which the outdoor air inlet and the indoor air outlet communicate are connected to each other to exchange heat and moisture with small children; a sterilization device installed to sterilize at least a portion of the air discharged through the indoor air outlet; an exhaust fan for discharging the air sucked into the indoor air intake port through the heat transfer element to the outdoor air discharge port; A supply fan for supplying the air sucked through the outdoor air inlet to the indoor air outlet through the heat transfer element; Disclosed is an antivirus total heat exchange ventilation system comprising a. Accordingly, it is possible to sterilize bacteria or viruses remaining in the indoor air, thereby preventing the spread of infectious diseases through the indoor air conditioning system.

Description

Anti-Virus Heat Recovery Ventilator

The present invention relates to a ventilation system, and more particularly, discharges indoor air to the outside and supplies outdoor air to the room, as well as heat exchange between the discharged indoor air and the supplied outdoor air, so as to be used for heating and cooling. It relates to an anti-virus total heat exchange ventilation system that can save energy and can be sterilized.

In general, a ventilation system using a total heat exchanger is used to exhaust polluted indoor air from buildings such as apartment houses, offices, department stores, and large marts to the outside and to supply new air from the outside to the indoor space.

That is, the general total heat exchanger is a device that first exchanges outdoor air with indoor air discharged to the outdoors so that sudden cold and hot air do not flow into the interior when ventilating the indoor air. Therefore, the total heat exchanger discharges the volatile organic compounds generated in the room through exhaust, and maintains the indoor air pleasantly by sucking the filtered fresh air into the room.

Therefore, when explaining the operation of a general total heat exchanger, when exhausting the air from the conditioned room to the outside, the exhaust fan installed in the total heat exchanger operates, and at this time, the air polluted from the indoor to the outdoor is removed while passing through the total heat exchanger element at the positive pressure. discharged to the outside

Conversely, when the air supply fan installed in the total heat exchanger operates, air is sucked into the room while passing through the total heat exchanger element from the outside with a static pressure generated. At this time, heat and mass are transferred through the total heat exchanger element and energy loss through ventilation is minimized. And, when the air supply fan and the exhaust fan of the total heat exchanger are simultaneously operated, it is formed so that the indoor static pressure and the outdoor static pressure are constantly maintained.

However, when the total heat exchanger is constantly operated, there is a problem in that excessive energy is consumed for heating and cooling, so it is usually operated intermittently in consideration of indoor pollution, etc. However, recently, contagious diseases occur frequently, and when air conditioning is performed in an enclosed environment, there is a problem in that infectious diseases are spread to the public crowded in the enclosed space. For this purpose, it is recommended to cool the air in a condition that is always ventilated, but this has a problem in that it may cause excessive energy wastage.

In addition, even when heating and cooling is not performed, it is insufficient to prevent the virus that causes infectious diseases from circulating in the room by simply operating the total heat exchanger to ventilate the indoor air.

An embodiment of the present invention has been devised to solve the above problems, and provides an anti-virus total heat exchange ventilation system that can prevent the spread of infectious diseases even in a closed environment, as well as efficiently perform heating and cooling want to

In order to solve the above problems, an embodiment of the present invention includes: a heat recovery ventilation device housing each having an indoor air inlet, an outdoor air inlet, an indoor air outlet and an outdoor air outlet formed on an outer surface thereof; The heat transfer heat received in the heat recovery ventilator housing so that the element suction passage in which the indoor air inlet and the outdoor air outlet communicate with each other and the element discharge passage through which the outdoor air inlet and the indoor air outlet communicate are connected to each other to exchange heat and moisture with small children; a sterilization device installed to sterilize at least a portion of the air discharged through the indoor air outlet; an exhaust fan for discharging the air sucked into the indoor air intake port through the heat transfer element to the outdoor air discharge port; It provides an antivirus total heat exchange ventilation system comprising a;

The sterilizer includes a sterilizer air inlet through which air is introduced into the sterilizer, and an air outlet for the sterilizer communicating with the air inlet of the sterilizer, and is installed between the sterilizer air inlet and the sterilizer air outlet. , a sterilizing unit for sterilizing flowing air, and an air forced flow device installed in the sterilizer to force air to flow between an air inlet of the sterilizer and an air outlet of the sterilizer.

The sterilizer is installed on an indoor circulation passage in which the indoor air inlet and the indoor air outlet communicate with each other.

The indoor circulation passage is formed so as not to pass through the heat transfer element.

The housing may include: an outdoor air outlet opening/closing damper configured to open and close the outdoor air outlet; and an indoor air outlet opening/closing damper configured to open and close the indoor air outlet.

The housing may include: a communication passage opening/closing damper configured to open and close an indoor/outdoor communication passage communicating between the indoor air intake port and the outdoor air intake port without passing through the heating element; include more

It further includes; a first filter installed on the indoor air intake side of the sterilizer.

The sterilizer includes: a UV-C/A LED installed between the air inlet of the sterilizer and the air outlet of the sterilizer; and a porous ceramic substrate formed to generate active oxygen by UV rays emitted from the UV-C/A LED.

According to the problem solving means of the present invention as described above, various effects including the following items can be expected. However, the present invention is not established only when exhibiting all of the following effects.

The anti-virus total heat exchange ventilation system of an embodiment of the present invention can sterilize bacteria or viruses remaining in the indoor air, thereby preventing the spread of infectious diseases through the indoor air conditioning system.

In particular, since sterilization can be performed when used in the internal circulation mode, there is an advantage that sterilization can be performed even in a state that does not lower the heating and cooling energy efficiency.

In addition, there is an advantage in that it is possible to sterilize the heat transfer element and filter in which bacteria or viruses can proliferate in the total heat exchanger.

1 is a plan view of a heat recovery ventilation device according to an embodiment of the present invention;
Figure 2 is a cut-away perspective view of the sterilizer of Figure 1;
3 is a conceptual perspective view of the UV-C/A LED of FIG. 2 and a porous ceramic substrate;
4 is a conceptual diagram when driving FIG. 1 in an air cleaning mode;
5 is a conceptual diagram when sterilizing the discharge passage of the device;
6 is a conceptual diagram when sterilizing an element suction passage;

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

1 is a plan view of a heat recovery ventilation device according to an embodiment of the present invention.

1, the heat recovery ventilation device of an embodiment of the present invention has an indoor air inlet 101, an outdoor air inlet 103, an indoor air outlet 104 and an outdoor air outlet 102 on the outer surface. Each formed heat recovery ventilation device housing 100, the element suction passage 210 through which the indoor air inlet 101 and the outdoor air outlet 102 communicate with each other, the outdoor air inlet 103 and the indoor air outlet ( 104) communicated with each other so that the heat transfer element 200 accommodated in the heat recovery ventilator housing and the air discharged to the indoor air outlet 104 are connected to each other to exchange heat and moisture. A sterilizing device 300 installed to sterilize, an exhaust fan 410 for discharging air sucked into the indoor air intake 102 through the heating element 200 to the outdoor air outlet 102; and a supply fan 420 for supplying the air sucked in through the air inlet 103 to the indoor air outlet 104 through the heat transfer element.

The housing 100 is usually coupled to an upper plate and a lower plate, and FIG. 1 is a plan view of the upper plate separated. The housing 100 is formed so that the heating element 200 is seated. In addition, the housing 100 includes a space communicating with the indoor air inlet 101, a space communicating with the outdoor air inlet 103, a space communicating with the indoor air outlet 103, and outdoor air based on the heat transfer element 200. A plurality of partition walls 106 are formed so that the space through which the discharge port 102 communicates is separated from each other.

However, in order to sterilize the element suction passage 210, an indoor/outdoor communication passage 112 that communicates between the indoor air intake 101 and the outdoor air intake 103 without passing through the heat transfer element is formed, and the indoor/outdoor communication A communication passage opening/closing damper 125 for opening and closing the passage 112 is installed.

In addition, an indoor circulation passage 111 through which the indoor air inlet 101 and the indoor air outlet 104 communicate is formed, and the sterilizer 300 is installed on the indoor circulation passage 111 . It is preferable that the indoor circulation passage 111 is formed so as not to pass through the heating element 200 .

The housing 100 includes an outdoor air outlet opening/closing damper 122 for opening and closing the outdoor air outlet 102, an indoor air outlet opening/closing damper 124 for opening and closing the indoor air outlet 104, and an indoor air intake The indoor air intake opening/closing damper 121 for opening and closing 101 and the outdoor air intake opening/closing damper 123 for opening and closing the outdoor air intake 103 are included.

The heating element 200 is formed such that the element suction passage 210 and the element discharge passage 220 cross each other and flow. Since many detailed configurations of the heating element 200 are well known, a detailed description thereof will be omitted. Paper material is used as the material for forming the element suction passage 210 and element discharge passage 220 of the heat transfer element, whereby moisture permeation and air permeation occur through the paper material, and a certain amount of temperature and humidity are exchanged.

In addition, a filter 130 for preventing contamination of the heating element 200 is installed at the inlet side of the element suction passage 210 of the heat transfer element 200 and the inlet side of the element discharge passage 220 . As the filter 130 , a pre-filter, a HEPA filter, or the like is usually used.

In addition, the circulation filter 131 is also installed on the upstream side (indoor air intake side) of the sterilizer 300 of the indoor circulation passage 111 . The circulation filter 131 also uses a pre-filter and a HEPA filter.

Figure 2 is a cut-away perspective view of the sterilizer of Figure 1;

The sterilizer 300 has a sterilizer air inlet 311 through which air is introduced into the sterilizer 300, and a sterilizer air outlet 312 communicating with the sterilizer air inlet 311 is formed, A sterilizing unit 310 installed between the sterilizer air inlet 311 and the sterilizing device air outlet 312 to sterilize flowing air, and installed in the sterilizing device, the sterilizing device air inlet 311 and It includes an air forced flow device 320 for forcibly flowing air between the air outlets 312 of the sterilizer, and a first filter 317 installed at the indoor air intake side of the sterilizer 300 .

The sterilization unit 310 is a UV-C/A LED 313 installed between the air inlet of the sterilizer and the air outlet of the sterilizer, and UV rays emitted from the UV-C/A LED 313. A porous ceramic substrate 315 formed to generate active oxygen, a reflector 314 reflecting the light irradiated from the UV-C/A LED 313, and a low-temperature catalyst filter 316 for removing ozone include

The forced air flow device 320 may be implemented as a blower fan fixed to the sterilizer 300 .

The UV-C/A LED 313 irradiates UV-A rays in a wavelength range of 315 nm to 400 nm or UV-C rays in a wavelength range of 200 nm to 280 nm. In addition, for high sterilization, it is important that the inhaled air can be irradiated for a long time, and the porous ceramic substrate 315 is used to achieve this purpose.

3 is a conceptual perspective view of the UV-C/A LED and the porous ceramic substrate 315 of FIG. 2 .

As shown in FIG. 3 , the porous ceramic substrate 315 is formed so that viruses or bacteria harmful to the human body in the air sucked into the UV-C/A LED 313 can be irradiated for a long time. The porous ceramic substrate 315 has a plurality of holes formed in the hexahedron in the longitudinal direction.

TiO2 is coated on the surface of the porous ceramic substrate. Therefore, electrons are excited by the UV-C/A LED to generate active oxygen to sterilize harmful organic matter.

Hereinafter, the operation of the heat recovery ventilation device of an embodiment of the present invention will be described.

FIG. 4 is a conceptual diagram when FIG. 1 is driven in an air cleaning mode.

4, the outdoor air outlet opening/closing damper 122 and the outdoor air inlet opening/closing damper 123 are closed, and the indoor air intake opening/closing damper 121 and the indoor air outlet opening/closing damper 124 are opened. In one state, the supply fan 420 is operated. At this time, the sterilizer 300 is operated.

In this way, in the case of operation, the indoor air is sucked in through the indoor air inlet 101, sterilized by the sterilizer 300, and then discharged through the indoor air outlet 104 to remove infectious bacteria existing in the room. It can be sterilized, reducing the risk of mass infection. In particular, it is possible to sterilize in a mode that circulates indoor air rather than a regular ventilation mode, so energy required for heating and cooling can be saved.

In the case of a heat transfer element, since it is made of a paper material, there is a problem in that it is easy to survive because bacteria or viruses are attached. In addition, bacteria or viruses can easily multiply in the filter 130 installed on the inlet side of the element suction passage 210 and the element discharge passage 220 of the heat transfer element. The present invention is formed to sterilize the heating element and the filter 130 in order to solve this problem. That is, FIG. 5 is a conceptual diagram for sterilizing the discharge passage of the device, and FIG. 6 is a conceptual diagram for sterilizing the device suction passage.

5, when sterilizing the element discharge path, the indoor air intake opening/closing damper 121, the outdoor air outlet opening/closing damper 122, the outdoor air intake opening/closing damper 123, and the indoor air outlet opening/closing In a state in which all dampers 124 are closed and the communication passage opening/closing damper 125 is opened, the forced air flow device 320 and the sterilization unit 310 of the sterilizer are driven.

In this way, in the case of driving, the air sterilized by the sterilization unit 310 circulates as shown by the arrow V through the element discharge passage 220 and the filter 130 of the heating element. Accordingly, there is an advantage that the filter 130 of the heat transfer element can be sterilized.

6, when sterilizing the element suction flow path, the indoor air intake opening/closing damper 121 and the indoor air outlet opening/closing damper 124 are closed, and the outdoor air intake opening/closing damper 123 and the outdoor air are closed. The discharge port opening/closing damper 122 is opened, and the exhaust fan 410 is operated.

In this way, when the operation is performed, the air introduced through the outdoor air inlet 103 flows as indicated by the arrow VI, so that the air sterilized by the sterilization unit 310 passes through the element suction passage 210 . Thus, it is discharged to the outdoor air outlet (102). Accordingly, it is possible to sterilize the element suction passage 210 of the heat transfer element and the filter 130 installed on the inlet side of the element suction passage 210 .

The driving as shown in FIGS. 5 and 6 may be performed at regular operating time intervals, but the time intervals may be determined using various logics according to the concentration of fine dust or the amount of dust collected in the filter.

After sensing or calculating the amount of dust collected by the filters 130 and 131 , the initial operating time is shortened or the operating time interval is increased. If the amount of dust collected thereafter is large, the operating time is lengthened.

As described above, the ventilation system of one embodiment of the present invention can sterilize bacteria or viruses remaining in the indoor air, thereby preventing the spread of infectious diseases through the indoor air conditioning system.

In particular, since sterilization can be performed when used in the internal circulation mode, there is an advantage that sterilization can be performed even in a state that does not lower the heating and cooling energy efficiency.

In addition, there is an advantage in that it is possible to sterilize the heat transfer element and filter in which bacteria or viruses can proliferate in the total heat exchanger.

In the above, preferred embodiments of the present invention have been exemplarily described, but the scope of the present invention is not limited to such specific embodiments, and can be appropriately changed within the scope described in the claims.

100: heat recovery ventilation device housing 101: indoor air intake
103: outdoor air inlet 104: indoor air outlet
102: outdoor air outlet 106: bulkhead
111: indoor circulation flow path 112: indoor/outdoor communication flow path
121: indoor air intake opening/closing damper
122; Outdoor air outlet opening/closing damper
123: outdoor air intake opening/closing damper
124: indoor air outlet opening/closing damper
125: communication channel opening/closing damper 200: electric heating element
210: element suction passage 220: element discharge passage
300: sterilizer 310: sterilization unit
311: sterilizer air inlet
312: sterilizer air outlet 313: UV-C/A LED
315: porous ceramic substrate 317: first filter
320: air forced flow device 410: exhaust fan
420: supply fan

Claims (8)

a heat recovery ventilator housing 100 having an indoor air inlet 101, an outdoor air inlet 103, an indoor air outlet 104 and an outdoor air outlet 102 formed on the outer surface, respectively;
An element suction passage 210 through which the indoor air intake 101 and the outdoor air discharge port 102 communicate with each other, and an element discharge passage 220 through which the outdoor air intake 103 and the indoor air discharge port 104 communicate with each other. a heat transfer element 200 accommodated in the heat recovery ventilation device housing so as to connect with each other to exchange heat and moisture;
a sterilizer (300) installed to sterilize at least a portion of the air discharged to the indoor air outlet (104);
an exhaust fan (410) for discharging the air sucked into the indoor air inlet (101) to the outdoor air outlet (102) through the heating element (200);
a supply fan (420) for supplying the air sucked into the outdoor air inlet (103) to the indoor air outlet (104) through the heating element;
including,
The sterilizer 300 is installed on an indoor circulation passage 111 through which the indoor air intake 101 and the indoor air outlet 104 communicate,
The indoor circulation passage 111 is formed so as not to pass through the heating element 200, and at the same time, when the indoor air outlet 104 and the indoor air inlet 101 are closed, the air that has passed through the sterilization device 300 is Antivirus total heat exchange ventilation system, characterized in that it is formed to flow to the heat transfer element (200).
The method of claim 1,
The sterilizer 300 is
A sterilizer air inlet 311 through which air is introduced into the sterilizer 300 and a sterilizer air outlet 312 communicating with the sterilizer air inlet 311 are formed,
a sterilizing unit 310 installed between the sterilizer air inlet 311 and the sterilizing device air outlet 312 to sterilize flowing air;
An air forced flow device 320 installed in the sterilization unit 310 to force air to flow between the air inlet 311 of the sterilizer and the air outlet 312 of the sterilizer.
Anti-virus total heat exchange ventilation system, characterized in that it comprises.
delete delete The method of claim 1,
The sterilizer 300 is
A sterilizer air inlet 311 through which air is introduced into the sterilizer 300 and a sterilizer air outlet 312 communicating with the sterilizer air inlet 311 are formed,
a sterilizing unit 310 installed between the sterilizer air inlet 311 and the sterilizing device air outlet 312 to sterilize flowing air;
An air forced flow device 320 installed in the sterilizer 300 to force air to flow between the sterilizer air inlet 311 and the sterilizer air outlet 312 is provided.
including,
The housing 100 is
an outdoor air outlet opening/closing damper 122 for opening and closing the outdoor air outlet 102;
an indoor air outlet opening/closing damper (124) for opening and closing the indoor air outlet (104);
Anti-virus total heat exchange ventilation system, characterized in that it further comprises.
6. The method of claim 5,
The housing 100 is
a communication passage opening/closing damper (125) for opening and closing the indoor/outdoor communication passage (112) that communicates between the indoor air inlet (101) and the outdoor air inlet (103) without passing through the heating element;
Anti-virus total heat exchange ventilation system, characterized in that it further comprises.
7. The method according to claim 5 or 6,
a first filter (317) installed at the indoor air intake side of the sterilizer (300);
Anti-virus total heat exchange ventilation system, characterized in that it further comprises.
3. The method of claim 2,
The sterilization unit 310,
a UV-C/A LED (313) installed between the air inlet of the sterilizer and the air outlet of the sterilizer;
a porous ceramic substrate 315 formed to generate active oxygen by UV rays emitted from the UV-C/A LED 313;
Anti-virus total heat exchange ventilation system, characterized in that it comprises.

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