KR102115696B1 - Waste Heat Recovery Ventilation System with Air Purification Function - Google Patents

Abstract

The present invention relates to a waste heat recovery type ventilation device having a purification function which enables indoor ventilation by recovering energy wasted to the outside by ventilation. More particularly, the present invention is to provide a ventilation device suitable for a small room such as a small efficency apartment or a studio apartment which is to promote energy saving by double heat exchange of ventilation inside the building through a heat exchange element and a thermoelectric element and, at the same time, to purify indoor air by reducing the amount of outdoor air introduced and recirculating indoor air to reduce the inflow of fine dust from the outside of the building.

Description

Waste Heat Recovery Ventilation System with Air Purification Function

The present invention relates to a waste heat recovery type ventilation device having a clean function that enables indoor ventilation by recovering energy that is wasted to the outside by ventilation, and more specifically, ventilation of a building interior through a heat exchange element and a thermoelectric element. It is intended to purify the indoor air by heat exchange to reduce energy while reducing the amount of outdoor air introduced and recirculating indoor air to reduce the inflow of fine dust from the inside of the building. It is intended to provide a ventilation device suitable for a small room such as a studio or a studio.

It can be seen that the indoor air in the building decreases the amount of remaining oxygen and increases the amount of carbon dioxide over time and becomes turbid by artificially generated odor and dust. Therefore, the fresh indoor air must be periodically supplied to the interior of the building to maintain a fresh and pleasant indoor environment.

However, in a typical apartment or house, a separate ventilation device is not installed, and therefore, ventilation is required through a window such as a living room for indoor ventilation.

However, ventilation through the opening of a window in a living room, etc. has the advantage that the outside air is rapidly introduced into the room and ventilation is performed quickly, but since most of the air in the room is easily lost, the temperature of the room changes rapidly. This causes the problem of not being able to efficiently use energy such as re-operation of cooling and heating devices such as boilers and air conditioners. In addition, for cooling and heating, the heat of refrigerant is used to take the energy of the indoor air and circulate the indoor air. Since the method of cooling and heating is adopted, the problem of poor ventilation is pointed out, and recently, a heat exchange element, such as Korean Patent No. 10-1689869 (Patent Document 1), was adopted to heat indoor and outdoor air. Ventilation devices are disclosed to ventilate indoor air by replacing and recover waste energy, but the prior art in this case is sufficient because heat exchange between indoor and outdoor air through an electrothermal exchange element generates an efficiency of about 70%. The problem that heat exchange is not made can be pointed out, and since the indoor air is exhausted to the outside by the blower fan and the indoor air is introduced into the room by the suction fan, the ventilation circulation of the indoor air is slow and rapid ventilation is achieved. It is pointed out that the problem that is not supported and that the smell of food or cigarettes or fine dust contained in the outside air is highly likely to flow into the room is very insufficient to purify the indoor air.

On the other hand, in general commercial buildings and officetels, for the internal ventilation of buildings, air supply ducts that suck the outside air of the building into the ceiling and the inside air of the building are external, as in Korean Patent No. 10-0925706 (Patent Document 2). The exhaust duct to be discharged is installed, and an air supply fan and an exhaust fan are respectively installed in the air supply duct and the exhaust duct. In addition, in order to prevent heat loss through the exhaust duct, a centralized heat recovery device connected to each exhaust duct is conventionally installed. Such a ventilation device has an advantage in that it is possible to recover waste heat through total heat exchange, but there is a problem in that power consumption is increased because the construction cost is high and the power of the blower must be large due to supply and exhaust air flowing in and out through the duct.

In addition, the ventilation device not only points out a problem that is difficult to process such as cleaning in the case of internal contamination of the duct, but also when a strong wind pressure is accompanied when external air flows in, severe noise is generated due to air pressure with air inside the supply duct. , These noises are introduced into the room, and various problems such as causing discomfort of indoor residents are pointed out.

Registered Patent No. 10-1689869 Registered Patent No. 10-0925706

The present invention doubles the heat exchange through the heat exchange element and the thermoelectric element inside the building to promote energy saving while reducing the amount of outdoor air introduced and recirculating the indoor air to re-circulate the indoor air, thereby smelling food, cigarettes and the outside of the building. The technical task is to purify the indoor air by reducing the inflow of fine dust.

The present invention is to install a heat exchange element inside the first housing coupled to the lower cover having an air discharge hole and an air inlet hole, a suction port is installed on one side of the first enclosure, and a second coupled to the upper portion of the first enclosure A dual blower and a thermoelectric element are installed inside the enclosure, and an exhaust port is installed on one side of the second enclosure, and the indoor and outdoor air heat-exchanged by the heat exchange element is discharged and sucked through the exhaust port and the intake vent by the dual blower. However, the first housing has a first air residence chamber, a second air residence chamber, and third air inside the first enclosure by a four-way support member for fixing the heat exchange element installed on the upper central bottom surface of the lower cover. It is divided into a residence chamber and a fourth air residence chamber, and a hepa filter is installed close to one side of the heat exchange element in the third air residence chamber, but the air guide tube is projected upward to the upper portion of the air inlet hole of the lower cover. It is configured to fit into the air inlet hole drilled in the bottom surface of the enclosure to allow outdoor air to enter the room, to install a bypass damper on the bottom surface of the lower cover of the second air residence room, and to An air hole corresponding to the intake port for outdoor air intake of the first blower fan cover and the intake port for indoor air intake of the second blower fan cover is formed on the bottom bottom surface by forming a dual blower, and the second enclosure is provided on the bottom surface. The first and second partition plates in the vertical direction and the first and second partition plates in the horizontal direction protruding the 1-1 air residence chamber, the 2-1 air residence chamber, the 3-1 air residence chamber, and the first It is divided into 4-1 air residence chambers, and the first and second partition plates of the first and second blower fan covers installed in each of the 2-1 air residence chambers and 4-1 air residence chambers are respectively vertically divided. It is configured to communicate with the air discharge hole drilled in the air so that the exhaust air by the blower flows into the 1-1 and 4-1 air retention chambers, and a damper for air cleaning is installed on the bottom surface of the 3-1 air retention chamber. , Cooling fin of the thermoelectric element inserted in the fitting hole in the center of the first partition plate in the horizontal direction And it characterized in that the heat dissipation fins are configured to be exposed to the 1-1 and 3-1 air retention chamber.

The present invention provides energy saving by efficiently using waste heat by allowing heat to be matched to the cooling and heating temperature by secondary heat exchange through a total heat exchange element and a thermoelectric element during indoor cooling and heating. By including the air cleaning function in the device, it not only promotes the purification of indoor air, but also quickly processes the flow of indoor air, but minimizes the inflow of outside air to prevent the inflow of fine dust, and condensation generated in the thermoelectric element. The effect is greatly reduced to prevent damage to the ventilation system due to condensation.

1 is a combined perspective view of a ventilation device according to the present invention.
2 is an exploded perspective view of a ventilation device according to the present invention.
Figure 3 is a perspective view of the interior of the ventilation device according to the present invention.
4 is a plan view of a first enclosure of a ventilation device according to the present invention.
4A and 4B are cross-sectional views of an operating state of a bypass damper of a ventilation device according to the present invention.
5 is a plan view of a second enclosure of a ventilation device according to the present invention.
5A and 5B are cross-sectional views of an operating state of a damper for cleaning air in a ventilation device according to the present invention.
Figure 6 is a side view of the interior of the ventilation device according to the present invention.
Figure 6a is a cross-sectional side view of the installation state according to another embodiment of the thermoelectric element of the ventilation device according to the present invention.
7 is a perspective view of the interior of the first housing of the ventilation device according to the present invention.
8 is a schematic diagram of air flow during cooling of a ventilation device according to the present invention.
9 is a schematic diagram of air flow during heating of a ventilation device according to the present invention.
10 is a flow schematic diagram of air cleaning of a ventilation device according to the present invention.
11 is a schematic diagram of air flow during ventilation of a ventilation device according to the present invention.
12 is a schematic diagram of air flow when recirculating indoor air of a ventilation device according to the present invention.

1 is a combined perspective view of the ventilation device according to the present invention, FIG. 2 is an exploded perspective view of the ventilation device according to the present invention, FIG. 3 is a perspective view of the interior of the ventilation device according to the present invention, and FIG. 4 is according to the present invention Top view of the first enclosure of the ventilation system, Figures 4a, 4b is a cross-sectional view of the operating state of the bypass damper of the ventilation system according to the present invention, Figure 5 is a plan view of the second enclosure of the ventilation system according to the present invention, Figure 5a, Figure 5b is a cross-sectional view of an operating state of a damper for air cleaning of a ventilation device according to the present invention, FIG. 6 is a side view of the inside of the ventilation device according to the present invention, and FIG. 6a is a view showing another embodiment of the thermoelectric element of the ventilation device according to the present invention. 7 is a perspective view of the interior of the first enclosure of the ventilation system according to the present invention, FIG. 8 is a schematic diagram of air flow during cooling of the ventilation system according to the present invention, and FIG. 9 is a ventilation system according to the present invention. Schematic diagram of the air flow during heating, FIG. 10 is a schematic flow diagram of the air of the ventilation apparatus according to the present invention, FIG. 11 is a schematic diagram of the air flow during ventilation of the ventilation apparatus according to the invention, and FIG. 12 is the indoor air of the ventilation apparatus according to the invention Schematic diagram of air flow during recirculation.

Hereinafter, the present invention will be described in detail through the accompanying drawings.

In the present invention, the heat exchange element 30 is installed inside the first enclosure 20 coupled to the lower cover 10 in which the air discharge hole 11 and the air inlet hole 12 are formed, and the first enclosure 20 ) A suction port 21 is installed on one side, a dual blower 50 and a thermoelectric element 60 are installed inside the second enclosure 40 coupled to the upper portion of the first enclosure 20, and the second enclosure ( 40) An exhaust port 41 is installed on one side, and exhaust and suction of indoor and outdoor air heat-exchanged by the heat exchange element 30 through the exhaust port 41 and the intake port 21 by the dual blower 50 However, the first housing 20 is a four-way support member (20A), (20B), (20C) for fixing the heat exchange element (30) installed on the top of the central bottom surface (10A) of the lower cover (10) ), (20D) by the first housing 20 inside the first air retention chamber (20-1), the second air retention chamber (20-2), the third air retention chamber (20-3) and the 4 It is divided into an air retention chamber (20-4), and a hepa filter (70) is installed close to one side of the heat exchange element (30) on one side of the third air retention chamber (20-3), but the lower cover ( 10) The air guide tube 12A protrudes upward to the top of the air inlet hole 12 of the 10, so that the outdoor air is inserted into the air inlet hole 211A drilled in the upper bottom surface 211 of the first housing 20. It is configured to be introduced, and the bypass damper 80 is installed in the air hole 10A 'drilled in the bottom surface 10A of the lower cover 10 of the second air retention chamber 20-2, and the second and The intake port 51A for the outdoor air discharge of the first blower fan cover 51 constituting the dual blower 50 on the bottom surface 10A of the fourth air retention chamber 20-2 (20-4) and the second An air hole (10A-1) (10A-2) corresponding to the indoor air intake port (52A) of the blower fan cover (52) is formed by drilling, and the second housing (40) is vertically projected downward to the bottom surface First and second partition plates 40-1 and 40-2 in the direction and first and second partition plates in the horizontal direction By (40-3) (40-4), the 1-1 air residence chamber 40A, the 2-1 air residence chamber 40B, the 3-1 air residence chamber 40C and the 4-1 air The outlets of the first and second blowing fan covers 51 and 52, which are divided into the residence chamber 40D and installed in the 2-1 air residence chamber 40B and the 4-1 air residence chamber 40D, respectively. Blower (51B) (52B) in communication with the air discharge holes (40-1 ') (40-2') drilled in each of the first and second partition plates (40-1) (40-2) in the vertical direction ( The exhaust air by 50) is configured to flow into the 1-1 and 4-1 air retention chambers 40A and 40D, and is pierced in the bottom surface 211 of the 3-1 air retention chamber 40C. An air cleaning damper 90 is installed in the air hole 211-1, but the thermoelectric element 60 inserted into the fitting hole 40-3 'in the center of the horizontal first partition plate 40-3 ) Cooling fins (60-1) and heat dissipation fins (60-2) are configured to be exposed to the 1-1 and 3-1 air retention chambers (40A) (40C) to provide a ventilation system (100). In particular, in the above configuration, the configuration in which the heat exchange element 30 is installed inside the first enclosure 20 and the thermoelectric element 60 is installed inside the second enclosure 40 is described in the air flow described later. The air flow due to heat exchange of indoor and outdoor air through the heat exchange element 30 and the air flow due to heat exchange of indoor and outdoor air through the thermoelectric element 60 collide with each other, hindering air flow or deteriorating heat exchange efficiency. It is to provide a two-layer structure to prevent things.

In the drawing, 10B is a supporting frame coupled with the lower cover 10, 50A is a motor unit for driving the blower, and a sirocco fan is installed inside the first and second blowing fan covers 51, 52, and the motor The portion 50A can be installed by fitting it into a hole drilled in the second partition plate 40-4 in the horizontal direction.

In the above, each operation of the thermoelectric element 60, the bypass damper 80, and the air cleaning damper 90 is a control program of a microprocessor unit in an unillustrated operation control unit controlling the ventilation device 100 of the present invention. In particular, the thermoelectric element 60 is supplied so that the current direction is reversed to each other during cooling and heating ventilation, so that the functions of the cooling fins 60-1 and the radiating fins 60-2 are reversed. 2 The air hole (10A ') drilled in the bottom cover (10A) of the lower cover (10) of the air residence chamber (20-2) allows indoor air to be recirculated more quickly without heat exchange, reducing the degree of outdoor fine dust inflow and also spring Alternatively, in the autumn, an air hole through which indoor air is introduced without heat exchange so that outdoor cool air flows into the room, which is sucked through the intake port 51A for the outdoor air discharge of the first blower fan cover 51 of the blower 50 To make.

And, inside the 1-1 air residence chamber (40A) and 3-1 air residence chamber (40C), a thermoelectric element (60) is provided by installing a dome-shaped condensation preventing cover (60A) covering the thermoelectric element (60). The moisture caused by water droplets, etc., generated during operation may be prevented from sticking to the inner surface of the second enclosure 40 to prevent damage to the second enclosure 40 due to condensation, and cooling of the thermoelectric element 60 The fins 60-1 and the heat dissipation fins 60-2 are inclined inwards on both sides, respectively, as shown in FIG. 6A, so that the discharge holes 60-1 'and 60-2' are formed in the center. Drain holes 211B on the upper bottom surface 211 of the first enclosure 20 directly below the discharge holes 60-1 'and 60-2' of each of the fins 60-1 and the heat dissipation fins 60-2. ) (211C) by dropping water droplets due to condensation generated on the cooling fins 60-1 and the radiating fins 60-2 to the upper portion of the heat exchange element 30 formed of paper to dry by heat generated during heat exchange. Condensation may be prevented, and both ends of the cooling fins 60-1 and the heat dissipation fins 60-2 of the thermoelectric element 60 are formed to be inclined inward, so that the ventilator 100 according to the present invention When the thermoelectric element 60 is operated for indoor cooling, the cooling fins 60-1 are cooled and water droplets due to a temperature difference are formed on the cooling fins 60-1. It is to fall to the discharge hole (60-1 ') along the inclined surface, on the contrary, when the ventilator 100 according to the present invention operates the thermoelectric element 60 for indoor heating, the heat dissipation fin 60-2 is cooled. As it is converted and cooled, water droplets due to the temperature difference are formed on the cooling fins 60-2, and the water droplets fall to the discharge holes 60-2 'along the inclined surface of the inclined heat sink fins 60-2. It is to prevent the dew condensation inside the enclosure 40.

On the other hand, the configuration of the bypass damper 80 is a configuration in which the circular plate having the sealing portion 81 and the opening portion 82 is rotated by the small motor 83, and is driven by the driving of the small motor 83. By rotating the circular plate material, the air hole 10A 'of the lower cover 10 is closed by the sealing portion 81 or opened by the opening portion 82, and the circular plate material is provided with the lower cover 10 ) Can be configured to fit on a circular guide rail at the top of the air hole (10A '), and the configuration of the air cleaning damper (90) is a compact circular plate having a closed portion (91) and an open portion (92). With the configuration to be rotated by the motor 93, the circular plate is rotated by driving the small motor 93 to close the air hole 211-1 of the upper bottom surface 211 of the first enclosure 20. To be closed by the part 91 or to be opened by the opening part 92, the circular plate material is circular to the upper air hole 211-1 of the upper bottom surface 211 of the first enclosure 20 It can be configured to fit on the guide rail.

The present invention of this configuration will be described in accordance with the air flow diagram of the ventilator 100 according to the present invention when the indoor condition shown in FIG. 8 is cooled as follows.

When the blower 50 is operated by the control program of the microprocessor unit in the operation control unit (not shown) and the thermoelectric element 60 is operated, the indoor air having a low temperature in the room is the first through the air discharge hole 11. Rising through the first air residence chamber 20-1 of the enclosure 20 and flowing into the second air residence chamber 20-2 through one side of the heat exchange element 30 through the suction hole 10A-1. The thermoelectric element 60 inside the 3-1 air residence chamber 40C of the second enclosure 40 is sucked through the inlet 51A for the outdoor air discharge of the blower 50 through the outlet 51B of the blower 50 ) While being heat exchanged by the heat dissipation fins 60-2, the air is discharged to the outdoors through the exhaust port 41, and at the same time, the outdoor air is through the intake port 21 to the third air retention chamber 20-3 of the first enclosure 20. After passing through the heat exchange element 30 after filtering the external fine dust or odor by the HEPA filter 70, it flows into the fourth air residence chamber 20-4 of the first enclosure 20, and The introduced outdoor air is sucked through the suction hole 10A-1 to the indoor air suction inlet 52A of the blower 50 and passes through the outlet 52B of the blower 50 to the first of the second enclosure 40 -1 The air purified into the room through the air inlet hole 12 through the air induction tube 12A while being heat exchanged by the cooling fins 60-1 of the thermoelectric element 60 inside the air residence chamber 40A It is introduced at a low temperature.

In the above, the indoor air having a low temperature in the room rises through the first air residence chamber 20-1 of the first enclosure 20 through the air discharge hole 11 to pass through the heat exchange element 30 side. At this time, the outdoor air having a high temperature flowing into the other side of the heat exchanger element 30 is heat exchanged by the low temperature air passing through the heat exchanger element 30, and heat exchanged to a temperature lower than the outdoor high temperature. Since the exchange efficiency is about 70% of the heat exchange due to the characteristics of the total heat exchange element 30, the present invention primarily compensates the outdoor high temperature air by the heat exchange element 30 as described above to compensate for this. After heat exchange with the furnace, the heat is exchanged to a lower temperature by the cooling fin 60-1 of the thermoelectric element 60 and supplied to the room, so it is possible to set the room temperature appropriately for cooling. It is possible to use waste heat efficiently and to significantly reduce energy savings.

In addition, when applying the present invention when heating as shown in FIG. 9, it has the air flow as shown in FIG. 8, but the functions of the cooling fins 60-1 and the radiating fins 60-2 of the thermoelectric element 60 are reversed. As a result, the cooling efficiency can be improved by secondarily compensating for air having a low temperature outside to allow air having a higher temperature to enter the room.

10 is an air flow diagram for purifying indoor air using the ventilator 100 according to the present invention. In this case, it is intended to purify indoor air by minimizing outdoor air inflow and rapidly recirculating indoor air. , When the operation of the thermoelectric element 60 is stopped, and the blower 50 and the damper 90 for cleaning air are operated, the damper 90 for cleaning the air is operated, and the upper bottom surface 211 of the first housing 20 ), The air hole 211-1 is opened by the opening part 92, and in this state, the indoor air is the first air residence chamber of the first enclosure 20 through the air discharge hole 11. As it goes up through (20-1), it enters the second air retention chamber (20-2) through one side of the heat exchanger element (30) and discharges the outdoor air from the blower (50) through the suction hole (10A-1). It is sucked through the suction port 51A and flows into the 3-1 air retention chamber 40C of the second enclosure 40 through the discharge port 51B of the blower 50, and a part of the introduced indoor air is exhaust port 41 ), And at the same time, the remaining part is third through the air hole 211-1 of the upper bottom surface 211 of the first enclosure 20 opened by the operation of the air cleaning damper 90. At the same time as entering the air residence chamber 20-3, outdoor air also flows into the third air residence chamber 20-3 of the first enclosure 20 through the intake port 21 and is external by the HEPA filter 70. And after filtering the fine dust or odor in the room, passes through the heat exchange element 30 and flows into the fourth air residence chamber 20-4 of the first enclosure 20, and the introduced outdoor air is a suction hole ( 1-1 air retention chamber 40A of the second enclosure 40 through the outlet 52B of the blower 50 by being sucked through the inlet 52A for indoor air intake of the blower 50 through 10A-1) It is possible to purify the indoor air through recirculation of the indoor air by allowing the purified air to flow into the room through the air inlet hole 12 through the air induction pipe 12A through the inside. , This allows the indoor and outdoor air to be filtered into the room while being filtered by the HEPA filter 70, so that a faster air flow is achieved and the outdoor air containing a lot of fine dust can be purified together with the indoor air, so that it is practically outdoor air. The inflow of the air can purify the indoor air in a small state, thereby performing an air cleaning function. At this time, the temperature of the indoor air is properly adjusted by heat exchange of the heat exchange element 30.

11 is an air flow diagram of a state in which indoor air is vented using the ventilation device 100 according to the present invention, but maintains the air flow as shown in FIGS. 8 and 9, but only the operation of the thermoelectric element 60 is stopped Ventilation takes place in a closed state, and detailed operation description is omitted.

12 is a ventilation for use in the spring and autumn to allow cool air from outside to enter the room without heat exchange by the heat exchange element 30 and the thermoelectric element 60 using the ventilation device 100 according to the present invention As a flow diagram of air flow and recirculation of indoor air, in this case, by operating the bypass damper 80, the circular plate is rotated by the driving of the small motor 83, and the air hole 10A 'of the lower cover 10 is rotated. ) To be opened by the opening 82, and then the air in the room is introduced into the second air retention chamber 20-2, and then the intake port for the outdoor air discharge of the blower 50 through the suction hole 10A-1. It is sucked into (51A) and is introduced into the 3-1 air residence chamber (40C) of the second enclosure (40) through the outlet (51B) of the blower (50), and the introduced indoor air through the exhaust port (41) It is discharged to the outdoors, and the outdoor air is introduced into the third air residence chamber (20-3) of the first housing 20 through the intake port 21 to generate fine dust or odor from outside and indoor by the HEPA filter 70. After filtration, it passes through the heat exchange element 30 and flows into the fourth air residence chamber 20-4 of the first enclosure 20, and the introduced outdoor air is blower through the suction hole 10A-1 ( The air induction pipe 12A through the inside of the 1-1 air residence chamber 40A of the second enclosure 40 through the outlet 52B of the blower 50 is sucked through the inlet 52A for indoor air suction of 50) ) Through which the purified air is introduced into the room through the air inlet hole 12, wherein the air discharged through the air hole 10A 'of the lower cover 10 does not pass through the heat exchange element 30. Since the outside air does not exchange heat even though it passes through the heat exchange element 30, it is possible to supply fresh air outside in the spring and autumn to the room. In this state, the bypass damper 80 When the damper 90 for air cleaning is operated as well as the operation, it is possible to minimize the inflow of fine dust from outside through rapid recirculation of indoor air as shown in FIG. 10. Becomes

Although the embodiments have been mainly described above, these are merely examples and do not limit the present invention, and those skilled in the art to which the present invention pertains are not exemplified above in the range that does not depart from the essential characteristics of the present embodiment. It will be appreciated that various modifications and applications are possible.

And, the differences related to these modifications and applications should be construed as being included in the scope of the invention defined in the appended claims.

Although the embodiments have been mainly described above, these are merely examples and do not limit the present invention, and those skilled in the art to which the present invention pertains are not exemplified above in the range that does not depart from the essential characteristics of the present embodiment. It will be appreciated that various modifications and applications are possible.

And, the differences related to these modifications and applications should be construed as being included in the scope of the invention defined in the appended claims.

10: lower cover 20: first housing
21: suction port 30: heat exchange element
40: second housing 41: exhaust
50: dual blower 60: thermoelectric element
70: HEPA filter 80: Bypass damper
90: air cleaner damper 100: ventilation

Claims (8)

An air heat exchange element 30 is installed inside the first enclosure 20 coupled to the lower cover 10 in which the air discharge holes 11 and the air intake holes 12 are formed, and on the one side of the first enclosure 20 A dual blower 50 and a thermoelectric element 60 are installed inside the second enclosure 40 coupled to the upper portion of the first enclosure 20, and one side of the second enclosure 40 is installed. The exhaust port 41 is installed, and the indoor and outdoor air heat-exchanged by the heat exchange element 30 is discharged and sucked through the exhaust port 41 and the intake port 21 by the dual blower 50, The first housing 20 is a four-way support member (20A), (20B), (20C), (4) for fixing the heat exchange element 30 installed on the top of the central bottom surface (10A) of the lower cover (10), ( The interior of the first enclosure 20 by 20D) is a first air residence chamber 20-1, a second air residence chamber 20-2, a third air residence chamber 20-3 and a fourth air residence It is divided into a seal (20-4), and a hepa filter (70) is installed close to one side of the heat exchange element (30) on one side of the third air residence room (20-3), but of the lower cover (10). The air induction pipe 12A protrudes upward to the upper portion of the air inflow hole 12 and is inserted into the air inflow hole 211A drilled in the upper bottom surface 211 of the first enclosure 20 so that outdoor air is introduced into the room. And, the bypass damper 80 is installed in the air hole 10A 'drilled in the bottom surface 10A of the lower cover 10 of the second air residence chamber 20-2, and the second and fourth air The intake port 51A and the second air blower fan cover for outdoor air discharge of the first air blower fan cover 51 constituting the dual air blower 50 on the bottom surface 10A of the residence chamber 20-2 (20-4) An air hole (10A-1) (10A-2) corresponding to the inlet (52A) for indoor air intake (52) is formed by drilling, and the second enclosure (40) is formed in a vertical direction protruding downward to the bottom surface. 1st and 2nd partitioning plates 40-1 and 40-2 and 1st and 2nd partitioning plates 40-3 in a horizontal direction By (40-4), the 1-1 air residence chamber 40A, the 2-1 air residence chamber 40B, the 3-1 air residence chamber 40C, and the 4-1 air residence chamber 40D And the outlets 51B and 52B of the first and second blowing fan covers 51 and 52 installed in the 2-1 air residence chamber 40B and the 4-1 air residence chamber 40D, respectively. ) Is discharged by the blower 50 by communicating with the air discharge holes 40-1 'and 40-2' drilled in each of the first and second partition plates 40-1 and 40-2 in the vertical direction. It is configured to allow air to flow into the 1-1 and 4-1 air retention chambers 40A and 40D, and the air holes 211- drilled in the bottom surface 211 of the 3-1 air retention chamber 40C. A cooling fin of the thermoelectric element 60 inserted into the fitting hole 40-3 'in the center of the first partition plate 40-3 in the horizontal direction, while the damper 90 for air cleaning is installed in 1) ( 60-1) and heat radiation fins (60-2) are installed to be exposed to the 1-1 and 3-1 air retention chambers (40A) (40C) to clean the air, characterized in that it constitutes a ventilation system (100) A waste heat recovery type ventilation device having a function. The method according to claim 1, wherein the dome-shaped condensation preventing cover (60A) covering the thermoelectric element (60) is installed inside the 1-1 air residence chamber (40A) and the 3-1 air residence chamber (40C). Waste heat recovery type ventilation device having an air cleaning function, characterized in that. The method according to claim 1, wherein the cooling fins (60-1) and the heat dissipation fins (60-2) of the thermoelectric element (60) are inclined inwards on each side and discharge holes (60-1 ') (60-2') at the center. Waste heat recovery type ventilation device having an air cleaning function characterized in that it is configured to be formed. According to claim 3, The cooling fins (60-1) and the heat sink fins (60-2) of each discharge hole (60-1 ') (60-2') directly below the upper bottom surface of the first enclosure (20) Drain holes 211B and 211C are drilled in 211 so that water droplets caused by condensation generated in the cooling fins 60-1 and the heat sink fins 60-2 fall to the upper portion of the heat exchange element 30 formed of paper. Waste heat recovery type ventilation device having an air cleaning function, characterized in that. The method of claim 1, wherein the air is exhausted and sucked by the heat exchange element (30) primarily by using a ventilation device (100) and heat exchanged by the thermoelectric element (60) to heat indoor air. A waste heat recovery type ventilation device having an air cleaning function, characterized in that it is configured to keep the temperature of the air cold and heated. According to claim 1, characterized in that configured to supply air to the room by operating the air cleaning damper (90) to purify and heat exchange a part of the indoor air through the HEPA Peter (70) and the total heat exchange element (30) Waste heat recovery type ventilation device with air cleaning function. According to claim 1, By operating the bypass damper (80), air clean, characterized in that configured to allow the outside cool air to flow into the room without heat exchange by the heat exchange element (30) and the thermoelectric element (60) A waste heat recovery type ventilation device having a function. According to claim 1, By operating the bypass damper (80) and the air cleaning damper (90) a part of the indoor air through the HEPA Peter (70) and the heat exchange element (30) to purify and heat exchange to the room A waste heat recovery type ventilation device having an air cleaning function, characterized in that it is configured to supply.

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