KR101083598B1 - an inlet and outlet extension type heat exchanging ventilation system - Google Patents

Abstract

The present invention is the upper grill 102 and the lower grill 103, the main body case 100 consisting of a controller 101 and the rear cover 106; and four lines of independent vertical openings in a sine wave to expand the upper and lower sides Stand-type corrugated heat exchange element (301), an air flow path distribution plate (302) for separating and blocking the openings formed on the upper and lower surfaces of the corrugated heat exchange element, and indoor air that is heat-exchanged with indoor air intaken on the upper surface of the corrugated heat exchange element. A total heat exchange element module (300) comprising an upper air flow path separation cover (304) for separating and entering the gas, and a lower air flow path cover (303) for returning and returning indoor air sucked from the lower surface of the corrugated heat exchange element; Assembling the electrothermal exchange element module 300 in the left and right longitudinal direction, the indoor and outdoor air passing through the upper grill 102 and the lower grill 103, respectively, in the vertical and vertical directions and sides of the corrugated heat exchange element 301. An indoor air exhaust socket 202 for discharging to the outside of the body case 100 through a sinusoidal opening formed through the V-shaped gap; It is an entrance and exit expansion type heat exchange ventilation device having a high heat exchange effect, which can be applied to various shapes of the outer structure, characterized in that it comprises a total heat exchange element module case (200) including an outdoor air intake socket (204) for intake. .

Inlet and outlet, expansion, heat exchange, ventilation

Description

An inlet and outlet extension type heat exchanging ventilation system

The present invention relates to an inlet / outlet expansion-type total heat exchange ventilation apparatus, and in particular, to set the opening direction of the intake and exhaust pores freely. The present invention relates to an entrance / exit expansion-type heat exchange ventilation device for exchanging indoor heat to fresh outdoor air while preheating heat exchange in a direct flow manner.

In general, for the purification of indoor air, the air contaminated with an anion air purifier is sucked into the fan, and dust and microorganisms up to 0.01 μm are collected by the filter to deodorize body odor or tobacco smell, (Iii) Ions are recovered by ion generators. There are three types of filters: a mechanical filter which collects using mortene or glass fibers, a high performance filter which collects fine particles using glass fibers and cellulose fibers, and a deodorizing filter using activated carbon. In addition, an electrostatic precipitator which is added to these filters to collect dust by charging dust by a high pressure discharge may be used together.

Within 2 years of building sick house syndrome, it is harmful to the human body from building materials and cement, and it releases substances such as leaky birds, paper grass, paint aldehydes and other indoor pollutants, and environmental hormones. It is easily exposed to skin diseases such as atopy and respiratory diseases by contact and inhalation. To this end, the heating temperature is increased, it is good to open and close the windows frequently from several hours to several days to sufficiently ventilate.

However, ventilation due to the opening and closing of the windows and doors has the disadvantage of losing the noise and inflow of the indoor air and the heat edge of the indoor air. Recently, the ceiling-mounted type and the floor-mounted type are designed to reduce the loss of thermal energy by ventilation as well as indoor and outdoor ventilation. There is a window installation type.

The heat exchange element of the ceiling type or floor top type has low recovery rate of heat energy exhausted by the cross-crossing type, and it is necessary to construct the duct equipment through the inner wall and the outer wall of the building, so as to secure the installation space, equipment price, construction cost and installation space. It is pointed out that the fan motor power is also frequently used due to the construction cost burden and static pressure caused by the duct construction.

 Therefore, recently, a separate installation of the heat exchanger installation space in the existing windows, or grafting or applying the ventilation system to the windows or windows frame is as follows.

Document 1 KR 10-2008-0051643 A 2008.06.11 FIGS. 3,4,5

[Document 2] KR 10-0698516 B1 2007.03.15 FIGS. 1,3,6

[Document 3] KR 20-0424420 Y1 2006.08.14 FIGS. 5,6

Document 4 KR 10-2006-0020641 A 2006.03.06 FIGS. 1,2,3

In Document 1 of the above example, the window frame of the hollow body corresponding to the circumference of the window opening formed on the building wall by the window ventilation system is formed in the intake flow passage and the exhaust flow passage partitioned adjacent by the partition wall, the partition wall In one region of the plural element mounting holes for installing the total heat exchange elements are provided at predetermined intervals, the heat exchange element is at least one intake passage through the air passing through the intake passage of the window frame, window frame At least one exhaust passage via the air passing through the exhaust passage of the gas is integrated in the heat exchange element in a counterflow manner in which the inlet and the outlet of the intake passage are opposite to each other in a state where a plurality of the exhaust passages are alternately stacked. Doing.

In this manner, as shown in Fig. 4 of Document 1, the production cost rises to the structure that the window frame member of the standard that extends to the entire window opening part must form a top and bottom window frame in a tightly sealed corner portion, It is necessary to embed the heat exchanger elements at regular intervals in the device mounting holes provided between the internally spaced partitions, or to separately install an intake and exhaust fan, and then perform complicated machining steps with the upper and lower limit tightly sealed. This is accompanied by an increase in production costs.

In addition, the total heat exchange element is not able to maximize the total heat exchange area of the total heat exchange element built in the same standard because the spacing between the heat exchange elements to be assembled in the device installation is formed in a window spaced apart at regular intervals.

On the other hand, in Document 2, the main body installed in the window with the window type heat exchanger is located in the indoor part and the part located in the outdoor area, the indoor air intake port and the external air exhaust port for discharging the outside air is installed on the upper upper surface located in the room, In the lower part of the main body, which is located outdoors, the outside air inlet and the indoor air outlet are installed inside. As shown in Figs. 5 and 8 of Document 2, the window is a heat exchanger using a known heat exchanger in which indoor air and external air flow to both sides of the heat exchange membrane. It is pointed out that the main body is installed in the upper part protrudes out and out of the room, the appearance is not good, and the problem as described in the document 1 can not maximize the total heat exchange area efficiency compared to the installation space.

Meanwhile, as shown in Document 3, the ventilation system and the outdoor unit integrated ventilation system of the air conditioner have an outdoor unit casing having a compressor and a heat exchanger installed at one side of the window installed in the window frame, and the noise of the compressor is transmitted to the room. When not in use, as shown in Fig. 5 of Document 3, after closing the shutters of the upper and lower heat exchangers, the lower casing fan is operated to introduce external air directly into the room through a filter inside the casing, or the indoor air is supplied to the upper casing fan. By operating the exhaust to the outside through the exhaust port of the upper layer, by installing the outdoor unit of the air conditioner in the window, and ventilating the indoor outdoor air through the intake and exhaust fan can not expect the effect of heat transfer.

On the other hand, Document 4 is an integrated air conditioner built-in integrated air conditioner including a compressor, an indoor heat exchanger, an expansion mechanism, an outdoor heat exchanger and a circulating pipe built into the inside of the wall, or the air conditioner and the window is integrated in a manner according to the ventilation system The total heat exchange effect cannot be expected, and in the case of the window body shown in FIG. 2 of Document 4, the interior heat exchange outer part may protrude from the window frame, or the compressor and the heat exchange pipe should be embedded in the window frame lower wall. Due to the problem of the built-in circulation pipe in the inside, there is a problem in that, in the event of a failure, the entire pipe must be replaced, or the wall must be damaged.

Accordingly, an object of the present invention is to maximize the heat exchanger exchange area by maximizing the total heat exchanger area with the total heat exchanger that extends the entrance and exit of the cross-crossing type heat exchanger. It is an object of the present invention to provide an energy-saving entrance / exit expansion-type total heat exchange ventilation device for easy installation at an installation cost.

In order to achieve the above object, in the present invention, each of the upper grill 102 and the lower grill 103 in the upper and lower ends of the rectangular box body; A main body case (100) formed of a rear cover (106) for screwing on one side with a controller (101) on the back; The main body case has a sinusoidal wave shape having four independent rows of vertical openings and extending up and down, and an air flow distribution plate for separating and blocking the openings formed on the upper and lower surfaces of the waveform heat exchange device. 302, the upper air flow path separating cover 304 separating and entering the indoor air sucked from the upper surface of the corrugated heat exchange element and the indoor heat exchanged with the heat exchange element, and the lower portion from which the indoor air sucked from the lower surface of the corrugated heat exchange element is returned. An electrothermal exchange element module (300) comprising an air flow channel cover (303); An upper air flow path separating cover accommodating part 200a from above into a divided case for accommodating the heat exchange element module 300; An upper expansion passage 208 which forms a space around the V-shaped gap and the front and rear slopes formed on the left and right sides of the upper portion of the corrugated heat exchange element; A waveform heat exchange element accommodating part 200b in which an intermediate portion of the waveform heat exchange element is accommodated; A lower expansion flow passage 209 having an expansion flow path partition wall 209a which separates the surrounding space into the front and rear slope portions from the middle of the left and right V-shaped gap side surfaces of the lower wave heat exchange element; Lower air flow path cover unit 200a 'is integrally formed, and the heat transfer for assembling the bracket 212 formed in the vertical direction to the case assembly bolt 210a, case assembly nut 210b, and case assembly washer 210c. The entrance / exit expansion-type electrothermal exchange ventilator includes an exchange element module case (200). To maximize the total heat exchange effect to preserve the heat energy of the indoor air, while providing an entrance and exit expansion type total heat exchange ventilator that can be applied to various shapes of the exterior structure.

Inlet / outlet expansion type heat exchange ventilation device according to the present invention by the waveform heat exchange element of the conventional cross-crossing type heat exchange element by the flow method to increase the heat exchange effect by maximizing the total heat exchange volume area and to reduce the use of indoor energy In particular, the V-shaped gap formed by extending the lower and upper side surfaces of the corrugated heat exchange element, which is an indoor air inlet and outlet, has a space formed by the lower expansion passage 209 and the upper expansion passage 208 formed in the heat exchange element 200. The outdoor air exhaust vent 203, the outdoor air intake vent 206, the indoor air intake vent 201, or the indoor air exhaust vent 205 can be opened at any position on each side, so that the heat exchange ventilation is installed in a stand type indoors. It is a useful invention that can be installed in any position, regardless of obstacles, etc., or can be applied to various shapes of the outer structure.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of an entrance / exit expansion-type total heat exchange ventilation apparatus according to the present invention, FIG. 2 is an external casing longitudinal sectional view showing an internal installation structure of the present invention, and FIG. 3 is a perspective view of a state of use of a total heat exchange element module case of the present invention; Figure 4 is an exploded perspective view of Figure 3, Figure 5 is an assembled state perspective view of the main part of the present invention.

As shown in these drawings, the entrance and exit expansion-type total heat exchange ventilation apparatus according to the present invention is a rectangular box body, the upper grille and the upper grille 102 and the lower grille 103; A main body case (100) formed of a rear cover (106) for screwing on one side with a controller (101) on the back; The main body case has a sinusoidal wave shape having four independent rows of vertical openings and extending up and down, and an air flow distribution plate for separating and blocking the openings formed on the upper and lower surfaces of the waveform heat exchange device. 302, the upper air flow path separating cover 304 separating and entering the indoor air sucked from the upper surface of the corrugated heat exchange element and the indoor heat exchanged with the heat exchange element, and the lower portion from which the indoor air sucked from the lower surface of the corrugated heat exchange element is returned. An electrothermal exchange element module (300) comprising an air flow channel cover (303); An upper air flow path separating cover accommodating part 200a from above into a divided case for accommodating the heat exchange element module 300; An upper expansion passage 208 which forms a space around the V-shaped gap and the front and rear slopes formed on the left and right sides of the upper portion of the corrugated heat exchange element; A waveform heat exchange element accommodating part 200b in which an intermediate portion of the waveform heat exchange element is accommodated; A lower expansion flow passage 209 having an expansion flow path partition wall 209a which separates the surrounding space into the front and rear slope portions from the middle of the left and right V-shaped gap side surfaces of the lower wave heat exchange element; Lower air flow path cover unit 200a 'is integrally formed, and the heat transfer for assembling the bracket 212 formed in the vertical direction to the case assembly bolt 210a, case assembly nut 210b, and case assembly washer 210c. Exchange device module case 200 is included.

The controller 101 of the main body case 100 is driven by a power supplied from a power supply unit (not shown), and it is preferable to provide and control an on / off switch of a fan that exhausts indoor air or intakes outdoor air. .

In addition, the upper grill 102 of the front upper side of the main body case 100; The lower grill 103 at the lower side is detached by magnetic force, and the indoor air is extruded from the total heat exchange element module 300 inside the main body case through the upper grill 102 and then protrudes on the top of the rear cover 106. It is discharged to the outside through the indoor air outlet 202, the outdoor air and the indoor air in the heat exchange element module 300 inside the body case through the outdoor air intake socket 204 protruding to the bottom of the rear cover 106 After the total heat exchange, it is discharged to the room over the filter 105 inherent in the lower grill (103).

The waveform heat exchange element 301 of the total heat exchange element module 300 is a sinusoidal total heat exchange waveform plate 301a partitioned into four waveform boundary sheets 301b over the entire rectangular rectangular tube body made of pulp material. Each compartment has a half arc-shaped opening, and a portion of the upper and lower ends is separated by the heat exchange waveform plate 301a and the corrugated boundary sheet 301b of each side to form a V-shaped gap.

On the other hand, the air flow path distribution plate 302 that separates and cuts the openings formed on the upper and lower surfaces of the waveform heat exchange element, respectively, is in close contact with the total heat exchange waveform plate 301a and the waveform boundary sheet 301b formed on the upper and lower surfaces of the waveform heat exchange element 301. The injection plate opening portion 302 ′ is injection-molded into the plate-shaped body only at the half arc-shaped opening position formed.

In addition, the lower air flow path cover 303 is two spaces different from the indoor air introduced through the distribution plate opening 302 ′ of the two air flow path distribution plates 302 arranged in close contact with the bottom surface of the corrugated heat exchange element 301. The upper surface returned through the distribution plate opening 302 ′ of the upper surface is formed as an open rectangular box.

The upper air flow path separating cover 304 is divided into a separation wall 304a at the center and an indoor air intake hole 304b for inhaling indoor air into a rectangular box opened downward is opened at one side of the compartment, and the rear side of the compartment. The indoor air exhaust hole 304c is opened in the upper air flow path to which the indoor air exhaust fan 304d for discharging the indoor air that is heat-exchanged through the corrugated heat exchange element 301 is attached.

The heat exchange element module case 200 for assembling and accommodating the heat exchange element module 300 in left and right longitudinal directions will be described in detail as follows.

4 and 5 are exploded perspective views of the total heat exchange element module case which is the main part of the present invention.

The heat exchange element module case 200 is assembled to the heat exchange element module 300 by assembling the bracket 212 formed in the vertical direction to the case assembly bolt (210a), case assembly nut (210b), case assembly washer (210c). The upper air flow path separating cover receiving portion 200a from above into a divided case for storing; An upper expansion passage 208 for forming the same space around the V-shaped gap and the front and rear slopes formed on the left and right sides of the upper portion of the corrugated heat exchange element; A waveform heat exchange element accommodating part 200b in which an intermediate portion of the waveform heat exchange element is accommodated; A lower expansion flow passage 209 having an expansion flow path partition wall 209a which separates the space around the front and rear slope portions from the middle of the left and right V-shaped gap side surfaces of the lower wave heat exchange element; The lower air passage cover accommodation part 200a 'is integrally formed.

The upper air flow path separating cover receiving portion (200a) protrudes to form an indoor air intake vent (201) fitted with a packing member (201a) on a border on one side facing each other; On this side, the indoor air exhaust hole 205 is opened and the indoor air exhaust socket 202 is attached to the outer side with an assembly screw 211.

In addition, the lower air flow path cover receiving portion (200a ') protruding to form an outdoor air vent 203, which is fitted with a packing member (203a) on the edge on one side facing each other; The outdoor air intake hole 206 is opened on this side, and the outdoor air intake fan 207 is attached to the inside, and the outdoor air intake socket 204 is attached to the outside by the assembly screw 211.

Inlet and outlet expansion type heat exchange ventilation device indoor and outdoor air ventilation process of the present invention configured as described above through the reference perspective view showing the indoor and outdoor air flow of the total heat exchange element module according to the present invention shown in FIG. Same as

When the indoor air exhaust fan 304d and the outdoor air intake fan 207 of the inlet / outlet expansion-type heat exchange ventilator according to the present invention are operated, the heat flow of the indoor air is determined by the upper grill 102 provided above the main body case 100. Through the inside of the main body case, the upper air flow path of the upper air flow path separating cover 304 received through the indoor air inlet 201 protruded to the upper air flow path separating cover receiving portion 200a of the heat exchange element module case 200 through It is introduced into the indoor air intake hole (304b).

The warm and muddy indoor air flowed in is introduced through the distribution plate opening 302 'which is an arcuate opening closely contacted to the bottom of the air flow distribution plate 302 divided into two spaces by the separation wall 304a. Waveform heat exchange element 301 The daily part is formed in a yearly spaced apart state by a sinusoidal electrothermal heat exchange waveform plate 301a and the corrugated boundary sheet 301b, the top is downward through the opening of the two spaces extending back and forth Then, after flowing into the lower air flow path cover 303 through the distribution plate openings 302 'of two compartments of the air flow distribution plate 302 disposed in close contact with the bottom surface of the corrugated heat exchange element 301, the air again Waveforms formed successively in a state spaced apart from each other by the two heat exchanger waveform plates 301a and the corrugated boundary sheet 301b through the distribution plate openings 302 ′ of two sides of the flow path distribution plate 302. It is discharged to the upper end via the total heat exchange element 301, two by the separation wall 304a Is discharged to the outdoors through the indoor air exhaust socket 202 by the indoor air discharge fan (304d) formed inside the upper air passage separating cover 304 is separated by a space.

On the other hand, the heat transfer flow of the outdoor air is the outdoor air on the lower expansion passage 209 of the total heat exchange element module case 200 with the outdoor air intake socket 204 protruding from the bottom of the back cover 106 of the main body case 100 Fresh and cold air introduced through the intake hole 206 is taken in by the outdoor air intake fan 207 installed inside the outdoor air intake hole 206.

The outdoor air that is intaken by the outdoor air intake fan 207 is separated by the V-shaped gap on the side and the slope of one side by the expansion flow path partition wall 209a based on the middle of the left and right V-shaped gap sides below the corrugated heat exchange element 301. Through the surrounding space, a space between the sinusoidal electrothermal heat exchange waveform plate 301a and the corrugated boundary sheet 301b formed vertically in the corrugated heat exchange element 301 formed on the air flow distribution plate 302 is spaced apart from each other. After the heat is exchanged while the indoor air is discharged through the openings formed in the flow direction in the flow direction between the openings, the air is discharged into the V-shaped gaps in the left and right two spaces below the upper air flow distribution plate 302, and the upper expansion flow path Another two spaces V separated by the expansion flow path partition 209a after being introduced into another V space between two adjacent left and right spaces by 208, and positioned under the wave heat transfer element 301. Discharged downward into the gap, finally Through the outdoor air exhaust port 203 and the filter 105 formed on a lower extension passage 209 is the front side, is discharged to the lower grill 103 is to ventilate the room air.

In the above, the filter 105 serves to filter out foreign substances such as yellow dust in the outdoors, and is inserted into the lower grill 103 which is detached by magnetic force to be washed at any time.

The polluted and warm air in the room and the fresh and cold air in the outdoor are correlated with each other by the corrugated heat exchange element 301 disposed in a vertically perpendicular manner to the heat exchange element. Compared to this, the total heat exchanger area is maximized, and the waveform heat exchange element with high heat exchange effect is used to ventilate the indoor air while preserving the heat energy of the indoor air.

On the other hand, as described above, the V-type gap formed by extending the lower and upper side surfaces of the corrugated heat exchange element, which is the indoor air inlet and outlet, is provided as the lower expansion passage 209 and the upper expansion passage 208 formed in the heat exchange element 200. The outdoor air exhaust vent 203, the outdoor air intake vent 206, the indoor air intake vent 201, or the indoor air exhaust vent 205 can be opened at any position on each side of the formed space part, so that it is installed in a stand type indoors. The air inlet / outlet duct of the inlet / outlet expansion type heat exchange ventilator can be installed at any position regardless of obstacles or the like, or it can be conveniently applied to various shapes of the external structure.

1 is a perspective view of the entrance and exit expansion-type total heat exchange ventilation apparatus according to the present invention.

Figure 2 is a longitudinal cross-sectional view of the outer casing showing the internal installation structure of the present invention.

Figure 3 is a perspective view of the state of use of the total heat exchange element module case of the present invention

4 is an exploded perspective view of FIG. 3;

Figure 5 is a perspective view of the main assembly state of the present invention.

Figure 6 is a reference perspective view showing the indoor and outdoor air flow of the total heat exchange element module according to the present invention.

※ Explanation of symbols for main parts of drawing

100 : body case

101: controller 102: upper grill

103: lower grill 104: adjustable leg

105: filter 106: rear cover

200 : electrothermal exchange element module case

201: Indoor air intake 201a; 203a: Packing member

202: indoor air exhaust socket 203: outdoor air exhaust

204: outdoor air intake socket 205: indoor air exhaust

206: outdoor air intake fan 207: outdoor air intake fan

208: upper extension euro 209: lower extension euro

209a: Expansion Euro Bulkhead 210a: Case Assembly Bolt

210b: Case assembly nut 210c: Case assembly washer

211: Assembly Screw

300 : electrothermal exchange element module

301: waveform heat exchange element 301a: total heat exchange waveform plate

301b: Waveplate boundary sheet

302: air flow distribution plate 302 ': distribution plate opening

303: lower air flow path cover

304: upper air flow path separation cover 304a: separation wall

304b: Upper air flow path Indoor air intake ball

304c: Upper air flow path Indoor air exhaust hole

304d: indoor air exhaust fan

Claims (7)

In the rectangular box body, the upper and lower portions of the upper grill 102 and the lower grill 103, respectively; A main body case (100) formed of a rear cover (106) for screwing on one side with a controller (101) on the back; The main body case has a sinusoidal wave shape having four independent rows of vertical openings and extending up and down, and an air flow distribution plate for separating and blocking the openings formed on the upper and lower surfaces of the waveform heat exchange device. 302, the upper air flow path separating cover 304 separating and entering the indoor air sucked from the upper surface of the corrugated heat exchange element and the indoor heat exchanged with the heat exchange element, and the lower portion from which the indoor air sucked from the lower surface of the corrugated heat exchange element is returned. An electrothermal exchange element module (300) comprising an air flow channel cover (303); An upper air flow path separating cover accommodating part 200a from above into a divided case for accommodating the heat exchange element module 300; An upper expansion passage 208 which forms a space around the V-shaped gap and the front and rear slopes formed on the left and right sides of the upper portion of the corrugated heat exchange element; A waveform heat exchange element accommodating part 200b in which an intermediate portion of the waveform heat exchange element is accommodated; A lower expansion flow passage 209 having an expansion flow path partition wall 209a which separates the surrounding space into the front and rear slope portions from the middle of the left and right V-shaped gap side surfaces of the lower wave heat exchange element; Lower air flow path cover unit 200a 'is integrally formed, and the heat transfer for assembling the bracket 212 formed in the vertical direction to the case assembly bolt 210a, case assembly nut 210b, and case assembly washer 210c. Entrance and exit expansion-type total heat exchange ventilation apparatus comprising a replacement element module case (200). According to claim 1, The waveform heat exchange element 301 is a pulp material, each of the square heat exchange waveform plate (301a) of the sinusoidal waveform partitioned into four corrugated boundary sheets (301b) over the entire rectangular rectangular tube body; An entrance / exit expansion-type total heat exchange ventilator having a half arc-shaped opening, each of which has a V-shaped gap formed by separating the heat exchange waveform plate (301a) and the corrugated boundary sheet (301b) on one side of each compartment. According to claim 1, The air flow path distribution plate 302 is a corrugated heat exchange element 301 of the expanded heat exchange waveform plate 301a side of the corrugated boundary sheet 301b is separated body body extended upper and lower opening portion is closed ; An entrance / exit expansion-type total heat exchange ventilator, characterized in that the distribution plate opening portion 302 ', which is an independent opening in a half arc shape, is injection molded into an integral plate-shaped body. According to claim 1, wherein the upper air flow path separating cover 304 is an air intake hole (304b) for inhaling the indoor air in a rectangular box which is partitioned by the separation wall (304a) in the center and opened downward, the opening on one side of the compartment And an indoor air exhaust hole 304c is opened at a side surface of the compartment with an upper air flow path having an indoor air exhaust fan 304d for discharging the indoor air heat-exchanged through the corrugated heat exchange element 301. Expandable total heat exchange ventilator. delete According to claim 1, The upper air flow path separating cover receiving portion (200a) protruding to form an indoor air intake vent (201) fitted with a packing member (201a) on the edge on one side facing each other; Inlet and outlet expansion type heat exchange ventilation device characterized in that the indoor air exhaust hole 205 is opened on this side and the indoor air exhaust socket 202 is fastened to the assembly screw 211 on the outside. According to claim 1, The lower air flow path cover receiving portion (200a ') protruding to form an outdoor air exhaust port (203) sandwiching the packing member (203a) on one side facing each other; The outdoor air intake hole 206 is opened on this side, and the outdoor air intake fan 207 is attached to the inside, and the outdoor air intake socket 204 is fastened to the outside by an assembly screw 211. Total heat exchange ventilator.

Images