KR101289373B1 - Heat exchange ventilating system - Google Patents

Abstract

PURPOSE: A total heat exchange ventilation system is provided to ventilate an indoor space while preserving the thermal energy of indoor air. CONSTITUTION: A total heat exchange ventilation system comprises a primary total heat exchange member, a secondary total heat exchange member, and a third total heat exchange member. The primary heat exchange member is installed inside the total heat exchange ventilation system primarily exchanges the thermal energy of the polluted indoor air. The secondary total heat exchange member secondarily exchanges the thermal energy of the polluted indoor air with a radiator (210) in which heat pipes (220a,220b) are mounted. The third total heat exchange member exchanges the thermal energy of the polluted indoor air by using the heat pipes.

Description

Heat Exchange Ventilating System

The present invention relates to a total heat exchange ventilator, wherein the first warm heat exchanger in the room with the polluted air installed inside the heat exchange ventilator, the first heat exchange, the second heat dissipation heat pipe attached to the heat exchange heat pipe This is a total heat exchange ventilation device that has high heat exchange efficiency by the third heat exchange means by the total heat exchange and the total heat exchange heat pipe close to the two sides of the total heat exchange element. Relates to a total heat exchange ventilator.

Generally, in order to purify the indoor air, the air contaminated by the negative ion air cleaner is sucked into the fan, the fine dust or bacterium up to about 0.01 mu m is collected by the filter to deodorize the body odor and the smell of tobacco, (Negative) ions are recovered by the ion generator. 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.

In addition to the improvement of indoor air quality due to deodorization or dust collection by anion generator or electrostatic precipitator as described above, new house syndrome occurs in which harmful substances such as indoor building interior materials, cement-plating paste, and prohmaldehyde by paint painting are released within 2 years In order to improve the condition, the ventilation of indoor air from time to time is very helpful in preventing skin diseases such as atopy and respiratory diseases due to inhalation of contaminant particles or environmental hormones into the body.

In order to improve sick house syndrome, it is desirable to increase the heating temperature at the beginning of the new house, and to open and close the windows frequently for several hours to several days to provide sufficient ventilation.In the old house or indoor office space, the indoor air is frequently ventilated. It is desirable to improve the

In order to improve the air quality of a residential or office space, it is easy to ventilate by opening and closing a window. However, by opening and closing a window, external noise, dust, and thermal energy of indoor air are lost. To this end, in recent years, indoor and outdoor ventilation system considering the loss of indoor heat energy, there are duct type ceiling installation type, ductless floor mounting type, window installation type.

In general, in duct type ceiling type or floor-mounted ventilation system, duct equipment should be installed through the inner wall and outer wall of the building. Therefore, the construction cost burden according to the installation space, equipment price, construction cost, installation space, and static pressure according to the duct construction Power generation requires a lot of fan motor power.

In view of the problems in duct ventilation systems, ventilation systems have been proposed recently in which a total heat exchanger is installed in a room-free manner or a ventilation system is applied to a window or window frame.

In the ventilation system for reducing indoor energy and improving indoor air quality as in the background art, a ventilation system such as Documents 1 to 4, which is presented below, includes an internal heat exchange element inside a window or frame to ventilate indoor and outdoor air. It is a ventilation system that does not occupy the interior space in a manner, but to apply it, the economic burden of replacing the entire existing window frame is accompanied. On the other hand, in Document 5, the body installed on the window with the window-type heat exchanger is not very beautiful in appearance due to the protrusion of the upper part to the indoor and outdoor spaces, and the efficiency of the total heat exchange area can not be maximized compared to the installation space. On the other hand, Document 6 is a ventilation system and the outdoor unit integrated ventilation system of the air conditioner is installed in the outdoor unit casing with a compressor and a heat exchanger installed at the front window of the window frame, the noise of the compressor is transmitted to the room, when not using the air conditioner, Close the shutters at the top and bottom of the heat exchanger and operate the casing lower fan to direct outside air through the filter inside the casing, or exhaust the indoor air to the outside through the exhaust port of the upper layer by operating the casing upper fan. In addition, by installing the outdoor unit of the air conditioner on the window and ventilating the outdoor air through the intake and exhaust fan, the heat loss of the indoor air is large. On the other hand, Document 7 is an integrated air conditioner as shown in Figure 1, the integrated air conditioner including a compressor, an indoor heat exchanger, an expansion mechanism, an outdoor heat exchanger and a circulation pipe built-in inside the wall surface, or the air conditioner and the window is integrated in a manner The heat exchange effect according to the ventilation system can not be expected, and even in the case of the whole window shown in FIG. 2, the interior heat exchange outer part protrudes from the window frame, or the compressor and the heat exchange pipe should be built into the window frame lower wall and the window frame. 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 body must be replaced, or the wall must be damaged. On the other hand, the documents 8 and 9 is a heat exchanger ventilation device to be installed in any place in the room as a stand-type ventilation system, the installation cost is cheaper than the window frame type, and the waveform of the cross-crossing type heat exchange element to flow The total heat exchange effect is maximized by the total heat exchange element, which increases the total heat exchange effect, thereby reducing the use of indoor energy.However, the manufacturing cost of the flow-flow type total heat exchange element module and the initial cost due to the casing or accompanying units are excessive. Improvements in competitiveness in production and assembly processes remain a problem. [Document 1] KR 10-2008-0051643 A 2008.06.11 [Document 2] KR 10-1089708 B1 2011.11.29 [Document 3] KR 10-1144591 B1 2012.05.03 [Document 4] KR 10-1126788 B1 2012.03.07 [Document 5] KR 10-0698516 B1 2007.03.15 [Document 6] KR 20-0424420 Y1 2006.08.14 [Document 7] KR 10-2006-0020641 A 2006.03.06 [Document 8] KR 10-1083598 B1 2011.11.09 [Document 9] KR 10-1127006 B1 Mar. 03, 2012

In view of the above, in the present invention, while adopting a relatively low-cost cross-type electrothermal heat exchanger compared to the flow-type electrothermal heat exchanger in which the warm and polluted air in the room is installed inside the housing, the heat exchange efficiency is improved. It is an object of the present invention to provide an economical and high-efficiency total heat exchange ventilator that can be applied in various ways in a ductless window or window frame type, or a stand type considering an indoor design.

In order to achieve the above object, the total heat exchange ventilation apparatus according to the present invention includes a rear portion orthogonal to the housing assembly rib (110c) formed with two rows of gasket grooves (110g); Opposite side of the housing fitting rib 110c, the inner side of the side portion integrally orthogonal to the rear portion, and the other end inside of the side portion in which the heat insulating layer 110f is filled in the resin filling recess 110e adjacent to the first cover screw assembly hole 110a. Two aluminum profile housings 110 having a housing front panel rib 110d having a gasket groove 110g 'formed on the outside with a second cover screw assembly hole 110b provided at a corner are cut to the same length, A gasket 112a is fitted into the gasket groove 110g between the housing assembly rib 110c in which the housing assembly ribs 110c of the upper and lower layers of the housing 110 are removed, respectively, and the housing assembly ribs 110c are fitted. The exhaust damper blower 150a by attaching the grill 111 to the inside of the indoor exhaust port 110h which is perforated in the upper portion of the upper side of the right housing where the) is removed; The grills 111 are attached to the inside of the outdoor air inlet 110i perforated in the lower left housing, and the housing assembly rib 110c is removed and the welded gap is caulked from the inside, and the housing assembly rib 110c is provided. The upper portion of the housing 110 on the right side of which is removed has a rectangular cutout at the corner of the housing rear portion side and the stepped portion inside the resin filling recess 110e; An exhaust partition plate 170 formed of a triangular cutout is disposed on the rear side side opposite side edge adjacent to the side portion of the upper portion of the housing 110 on the left side, and a PCB circuit board 160 is installed at the bottom of the exhaust partition plate 170. On the lower layer of the housing 110, in which the housing fitting rib 110c is removed, an air supply partition plate 180 having a rear side side opposite side edge adjacent to the right housing side part is formed of a triangular cutout, and a triangular cutout border of the exhaust partition plate is disposed. And assembling the indoor exhaust partition 190 with the indoor exhaust partition and fixing rib 190a so as to separate the space from the outdoor exhaust ventilation chamber 101 in a state spaced apart from each other in the opposite side border line with the rear side, and the exhaust disqualification. Heat sink base 211 having a rectangular plate shape having a V-groove 210c formed in a longitudinal direction at the center of the front surface in close contact with the housing fitting rib 110c of the inner plate 110 of the section 170 and the air supply partition plate 180. Back side center Three cross radiating fins 210b are formed on each side based on the integrally projecting central separating plate 210a, and each of the cross radiating fins is removed by removing the heat sink base and the cross radiating fins of the upper left and lower right corners, respectively, based on the central separating plate. A heat dissipation plate 210 for disposing one strand of the total heat exchange heat pipe 220a to the left and right ends of the resin filling recesses 110e on both sides; Zigzag excavation of one strand of the total heat exchange heat pipe (220b) to the heat sink length standard, bending the middle to not bend at a 95 ° bend angle to be bonded to the V groove (210c) of the heat sink base 211 is fixed with a sealing material In this way, the stacked longitudinal sides are supported by the corner protection frame 202 and the heat exchange element 200 having the filter 201 attached to the Velcro rod 203 is attached to the heat transfer heat pipe 220b. A gasket 112b inserted into the housing front panel rib 110d of the left and right housings 110, which are installed and welded together, and the indoor exhaust grill 120a with a filter above the height of the exhaust partition plate 170; Inside the interior air supply grill (120b) with the filter formed below the height of the air supply partition plate (180), the front panel (120) with the air supply damper blower (150b) is piece-assembled to the assembled housing (110) front part, The upper and lower layers of the assembled housing 110 are provided with a total heat exchange ventilation device module 100 for assembling an upper cover 130 and a lower cover 140 made of a resin material. Secondary total heat exchange by heat dissipation plate which is installed inside the housing and in which a total heat exchange heat pipe is installed, as compared with the total heat exchange ventilation device of the primary total heat exchange method according to the present invention; The third heat exchange is added by the total heat exchange heat pipe disposed on the two sides of the heat exchange element, and the heat exchange efficiency is greatly improved, and contaminated indoor air is freshly preserved while preserving the heat energy of the indoor air. It is to provide a total heat exchange ventilator.

The total heat exchange ventilation apparatus module according to the present invention is a heat dissipation plate in which a heat exchange heat pipe is installed in addition to the first heat exchange ventilation device of the first heat exchange method by a conventional heat exchange element of a cross type or a flow type. Secondary total heat exchange by; The 3rd total heat exchange is added by the total heat exchange heat pipes arranged on the two sides of the total heat exchange element, which greatly improves the total heat exchange efficiency and ventilates the contaminated indoor air freshly while preserving the heat energy of the indoor air. To provide a highly efficient total heat exchange ventilator.

In addition, the electrothermal exchange ventilator module according to the present invention as an electrothermal exchange ventilator to be applied to various types of stand-type total heat exchange ventilation case considering the interior design, with the advantage of easy installation and installation in the windowless or window frame of the ductless method. It is intended to be provided as a useful invention that maximizes industrial applicability with various models of high heat exchange efficiency with high heat exchange efficiency combined with interior decoration.

1 is an external perspective view of the total heat exchange ventilation apparatus according to the present invention.
Figure 2 is an exploded perspective view of Figure 1;
Figure 3 is an internal batch disassembled perspective view showing the total heat exchange air flow path according to the present invention.
4 is a heat sink adopting a heat pipe attached to the total heat exchange element according to the present invention; Reference perspective view of a total heat exchange heat pipe disposed on two sides of a total heat exchange element.
Figure 5 is a perspective view of the total heat exchange ventilation device housing profile of the present invention.
Figure 6 is a heat sink profile perspective view according to the present invention.
Figure 7 is a cross-sectional view of the use state according to the window installation according to the invention.
8 is a cross-sectional view of the stand-type use state according to the indoor installation according to the present invention.

Referring to the accompanying drawings, a detailed description of the present invention for achieving the above object is as follows.

1 is an external perspective view of the total heat exchange ventilation apparatus according to the present invention shown in FIG. 1, an exploded assembly perspective view of FIG. 1 shown in FIG. 2, and a heat pipe installed in the total heat exchange element according to the present invention shown in FIG. A heat sink; Reference perspective view of the total heat exchange heat pipe disposed on the two sides of the total heat exchange element, perspective view of the heat exchange ventilation device housing profile according to the present invention shown in FIG. 5, heat sink profile perspective view according to the present invention shown in FIG. The total heat exchange ventilator of the present invention is as follows.

A rear portion orthogonal to the housing mating rib 110c in which two rows of gasket grooves 110g are formed; Opposite side of the housing fitting rib 110c, the inner side of the side portion integrally orthogonal to the rear portion, and the other end inside of the side portion in which the heat insulating layer 110f is filled in the resin filling recess 110e adjacent to the first cover screw assembly hole 110a. Two aluminum profile housings 110 having a housing front panel rib 110d having a gasket groove 110g 'formed on the outside with a second cover screw assembly hole 110b provided at a corner are cut to the same length, A gasket 112a is fitted into the gasket groove 110g between the housing assembly rib 110c in which the housing assembly ribs 110c of the upper and lower layers of the housing 110 are removed, respectively, and the housing assembly ribs 110c are fitted. ) Attach the grill 111 to the inside of the indoor exhaust port 110h perforated on the upper right side of the housing, and the exhaust damper blower 150a is attached, and the grill 111 to the inside of the outdoor air intake 110i perforated on the lower side of the left housing. ) And attach the housing The lip rib 110c is removed and the treated gap is caulked inside, and the housing rear side of the housing 110 on the right side from which the housing assembly rib 110c is removed is located inside the housing back side and the resin filling recess 110e. A rectangular incision in the corner up to the step; An exhaust partition plate 170 having a rear side side opposite side edge adjacent to the side portion of the upper portion of the housing 110 on the left side is formed of a triangular cutout, and the right housing is provided on the lower layer of the housing 110 in which the housing fitting rib 110c is removed. The air supply partition plate 180 having a rear side side opposite side edge adjacent to the side portion is formed of a triangular incision, and the outdoor exhaust air blower is spaced inward from the triangular cutout border and the rear side side opposite side edge line of the exhaust partition plate. In order to isolate the space from the chamber 101, the indoor exhaust partition and the indoor exhaust partition 190 with the fixing ribs 190a are piece-assembled, and the exhaust partition plate 170 and the air supply partition plate 180 section of the inner housing 110 A V-groove 210c in the longitudinal direction at the center of the front surface of the heat sink base 211 of the rectangular plate type in close contact with the housing assembly rib 110c; Cross heat radiation fins 210b are formed on both sides based on the central separator 210a protruding integrally from the rear surface, and the heat sink base and the cross heat radiation fins of the upper left and lower right corners are respectively removed on the basis of the center separator. A heat dissipation plate 210 for disposing one strand of the total heat exchange heat pipes 220a from side to side, in close contact with inner end portions of the resin filling recesses 110e on both sides; Zigzag excavation of one strand of the total heat exchange heat pipe (220b) to the heat sink length standard, bending the middle so as not to bend at a 95 ° bend angle, and affixed to the V groove (210c) of the heat sink plate 211 by a sealing material, The stacked longitudinal sides are supported by the corner protection frame 202 and the heat exchange element 200 having the filter 201 attached to and detached from the Velcro rod 203 is installed in close contact with the heat transfer heat pipe 220b. , Inserting the gasket (112b) into the housing front panel rib (110d) of the left and right housing 110, which is assembled to the hospital, and the indoor exhaust grill (120a) with a filter is attached to the upper side of the exhaust partition plate (170) or more, and the air supply partition plate ( 180) Inside the interior air supply grill 120b with the filter formed below the height, the front panel 120 with the air supply damper blower 150b is piece-assembled to the assembled housing 110, and the assembled housing ( 110) the upper cover 130 and the PCB circuit board of the resin material on the upper and lower layers 160 is a constituting the lower cover 140, the total heat-exchanging ventilation device module 100 to assemble the upper anchakhan.

For reference, the illustration of the wiring and power supply code between the exhaust damper blower 150a and the air supply damper blower 180 and the PCB circuit board 170 of the electrothermal exchange ventilator module 100 assembled above is omitted. By the exhaust damper blower (150a) and the air supply damper blower (180) air volume control and operation time adjustment is made.

In addition, the housing 110, the rectangular rectangular cut-out portion to the step of the inner side of the back portion and the resin filling recess (110e) inside; An air flow path of the exhaust partition plate 170 having a triangular cutout at a rear side side opposite edge adjacent to the side portion of the upper portion of the housing 110 on the left side; Means installed in the housing 110 on the left and right sides assembled together except for the air flow passage and the wiring hole, which are triangular cutouts of the opposite side edges of the rear side adjacent to the side of the right housing 110 are exhausted. Caulking each of the plate 170 and the air supply chamber partition plate 180, the heat exchange element installation room 103, the indoor air supply air blower 101, the heat exchange element 210 and the heat exchange element 200 is installed The indoor and outdoor air passing through the seal 102 is kept unmixed.

In addition, the resin filling main portion provided on the side surface of the housing 110 as a means for blocking the heat transfer between the housing on the rear side of the total heat exchange ventilation device module 100 according to the present invention and the housing on the front side where the front panel 120 is assembled ( 110e) is provided with a heat insulating layer (110f) that is a heat insulating resin.

As described above, one embodiment of the electrothermal exchange ventilator module is configured in detail by the accompanying drawings as follows.

3 is an exploded perspective view of the internal arrangement showing the total heat exchange air flow path according to the present invention, the main part of the left side housing 110, the top cover 130 and the front panel 120 are omitted. The air flow path ⓐ-ⓑ shown in the housing 110 is a heat sink base of the heat sink 210 installed in the heat exchange element installation chamber 103 with external air flowing through the outdoor air inlet 110i provided at the bottom of the rear side of the left housing ( 211) The cross-heat radiation fin 210b provided in the right isolation space through the heat exchange heat pipe 220a disposed in the cross-heat radiation fin 210b provided in the left isolation space based on the central separator 210a protruding integrally into the rear surface. Primary air heat exchange is performed to the external heat exchange heat pipe (220a).

The external air secondary heat exchange is to the heat exchange installation room (103) through the ventilation section where the upper left corner of the heat dissipation base base (211) provided with only the heat exchanger heat pipe (220a) with the heat dissipation base and the cross heat dissipation fins removed. The introduced outside air passes through the zigzag-exposed electrothermal heat exchange pipe 220b fixed to the V-groove 210c of the heat sink base 211 as a sealing material, and the second electrothermal heat exchange is performed on the opposite side.

The external air 3rd electrothermal exchange is assembled to be spaced apart from the heat exchanger heat pipe 220b which is bent so as not to be bent at a 95 ° bend angle to the V groove 210c of the heat sink base 211 and is fixed with a sealing material. External air passing from the first side of the total heat exchange element 200 to the third side and 'na⇒ra' flowing from the second side to the fourth side of the total heat exchange element 200 As the indoor air passing through the surface crosses each other, tertiary electrothermal exchange takes place.

The outside air in which the third total heat exchange is made through the 'go ⇒ many' surface of the heat exchange element 200 is performed by a triangular cutout formed in the air supply partition plate 180 under the heat exchange element installation chamber 103. It is introduced into the chamber 102 and discharged into the room through the indoor air supply grill 120b with the filter provided under the front panel 120 shown in FIG. 2 by the operation of the air supply damper blower 150b.

On the other hand, the air flow path ⓒ-ⓓ shown in the housing 110 is the indoor air introduced through the indoor exhaust grill 120a with a filter provided in the upper portion of the front panel 120 shown in FIG. The second surface of the heat exchange element 200 installed in the heat exchange installation chamber 103 through the triangular cutout of the corner of the exhaust chamber partition plate 170 by the indoor exhaust partition 190 which separates the space from the 101. The primary air heat exchange is performed between the outside air and the indoor air where the third heat transfer is carried out through the 'na ⇒ la' plane flowing through the four planes, and the 'ga' and 'da' planes flowing from the first plane to the third plane.

The secondary air heat exchange of the indoor air is the second air heat exchange of the indoor air while contacting the heat exchange heat pipe 220b disposed close to the 'la' plane of the fourth surface of the heat exchange element 200 in which the external air is secondarily heated from the opposite side. This is done.

The second heat exchanger indoor air is the heat sink base of the heat sink 210 through the lower right vent of the heat sink base 211 where the heat sink base and the heat dissipation heat pipe 220a are removed, and the corners of the heat sink are removed. (211) By the primary air heat exchange of the external air that is heat-exchanged to the heat exchange heat pipe (220a) disposed in the cross heat radiation fin (210b) provided in the left isolation space based on the central separation plate (210a) integrally protruding in the center of the back surface Indoor air tertiary heat exchange is performed through the heat exchange heat pipe (220a) disposed in the cross heat dissipation fin (210b) provided in the right isolation space where heat is transferred.

After the third indoor heat exchange is performed, the indoor exhaust compartment 190 is formed through a rectangular cutout provided at the corner of the rear side of the right housing 110 and the step of the inner side of the resin filling recess 110e provided in the exhaust partition plate 170. The indoor air is discharged to the outside by the operation of the exhaust damper blower 150a assembled in the outdoor exhaust pipe 110h in the outdoor exhaust chamber blowing chamber 101 which is isolated from the outdoor exhaust chamber.

For reference, in the exhaust damper blower 150a and the air supply damper blower 150b applied to the present invention, dampers are integrally installed in the discharge port, respectively, the damper is opened when the blower is operated, and the damper is closed when the blower is stopped. Even when the blower and the air supply damper blower are not operated, the outside air is prevented from entering the room or the air from the room is discharged to the outside to improve energy efficiency.

In the longitudinal edge of the electrothermal exchange element 200 of the present invention, a corner protector 202 attached with a velcro rod 203 having good adhesion to the wool of the filter is attached to facilitate the replacement of the filter 201.

In addition, the heat dissipation plate 210 according to the present invention shown in FIG. 4 includes a heat dissipation base 211 provided with a V-groove 210c in the middle of the rear surface of the heat dissipation plate 210 as shown in FIG. 6; A central separator 210a orthogonally formed in the middle of the V groove; A screw assembly hole 210d formed in the middle of the central separator plate; Cross radiating fins (210b) which are mutually symmetrical to both sides based on the central separation plate is composed of an aluminum material that is integrally extruded in the longitudinal direction.

The screw assembly holes 210d of the heat dissipation plate 210 are screw assembly bits 171 and 181 for convenience of locating the screws when the indoor exhaust partition plate 170 and the air supply partition plate 180 are assembled up and down the heat sink. ) Was formed.

In addition, a thermoelectric element is disposed in the heat exchanger heat pipe in which one strand of the heat exchanger heat pipe 220a is disposed at each end of the central heat dissipation plate 210a of the heat dissipation plate 210 and the cross heat radiation fins 210b formed at both sides thereof. Filled with a good heat medium, both ends are press-sealed.

Similarly, the heat conductivity is good even in the heat exchanger heat pipe 220b formed of one strand that is zigzag-exposed to the V-groove 210c of the heat sink 210 by the heat sink length standard and is not bent at a 95 ° bending angle. It is filled with heat medium and pressed and sealed at both ends, which improves workability compared to installing with independent total heat exchange heat pipes.

 The heat exchanger heat pipe 220b is fixed to the V groove 210c of the heat sink base 211 which is zigzag-exposed to the heat sink length standard and is not bent at a 95 ° bending angle. It blocks the inflow of air through the gap between the groove portion bent at an angle of bending and the total heat exchange element 200 is treated, and only the heat exchange through the heat exchange heat pipe 220b.

Type according to the embodiment according to the present invention made as described above is as follows.

Figure 7 is a cross-sectional view of the use state according to the window installation according to the present invention, the box type to install the heat exchange ventilation device module 100 standing on one side of the window frame, the outdoor disposed on the upper side of the housing 110 disposed on the outdoor side Attached to the exhaust port 110h and the outdoor air inlet 110i disposed below, a rainwater prevention cover 113 having an open bottom is attached to prevent rainwater inflow through the outdoor air outlet 110h and the outdoor air inlet 110i exposed to the outside. do.

In addition, by replacing the open rain rain prevention cover 113 attached to the outdoor exhaust port (110h) and the outdoor air intake (110i), the general air opened in different directions so that external air inflow and indoor air discharge are not mixed with each other. Attaching the socket is also a foreseeable embodiment in accordance with the present invention and details of the air socket are omitted.

As described above, the total heat exchange ventilation apparatus according to the embodiment in which the total heat exchange ventilation apparatus module 100 is installed on one side of the window frame has an advantage of being easily installed in an existing window without the need for a connection duct as a ductless type.

On the other hand, Figure 8 is a cross-sectional view of the stand-type use state according to the indoor installation according to the present invention, the case where the total heat exchange ventilation device module 100 according to the present invention is installed in the room corner, the corner of the room like an aesthetically shaped stand air conditioner Install the electrothermal exchange ventilation case 300 in a diamond type in the upper and lower partitions to form an indoor exhaust grill with a filter and an indoor air supply grill with a filter, respectively, to form the front panel 120 of the total heat exchange ventilation device module 100. The respective ducts connected from the indoor exhaust grill 120a with the filter and the indoor air supply grill 120b with the filter are connected to each other, and each of the outdoor exhaust port 110h and the outdoor intake port 110i provided at the rear portion of the housing 110 are connected. Connect the duct to penetrate the outer wall behind the interior corners.

In addition to the stand type according to the above-described indoor corners, in consideration of the interior interior, if installed in the lobby or indoors, any one type of heat exchange ventilation case is adopted among corners, cylinders, and polygons that forget the floor and the ceiling. Inside the heat exchange ventilation device module 100 according to the present invention 300 and the ventilation case attached to the upper and lower case of the total heat exchange ventilation device module 100 and the internal exhaust grill with a filter attached to the ventilation case (300a) and the indoor air supply grill with a filter attached to the ventilation case ( 300b) and communicate with each other from the indoor exhaust grill 120a with the filter provided in the front panel 120 of the electrothermal exchange ventilator module 100 and the indoor exhaust grill 120b with the filter, respectively, and at the rear portion of the housing 110. The provided outdoor exhaust port 110h and the outdoor air intake port 110i may be a means selected from a duct-free air supply, a duct guided into the ceiling, or a separate exposure duct by processing the rear wall surface. It is to install an external exhaust port (110h) and outside the inlet port (110i) duct.

100: total heat exchange ventilation module
101: outdoor exhaust ventilation room 102: indoor air supply ventilation room
103: electric heat exchange element installation room
110: Housing
110a: 1st cover screw assembly 110b: 2nd cover screw assembly
110c: housing rib assembly 110d: housing front panel rib
110e: Resin filling
110f: Heat shield layer 110g; 110g ': Gasket groove
110h: outdoor exhaust vent 110i: outdoor exhaust vent
111: grill 112a; 112b: gasket
113: rainwater prevention cover
120: front panel
120a: Indoor exhaust grill with filter 120b: Indoor exhaust grill with filter
130: upper cover 140: lower cover
150a: Exhaust damper blower 150b: Air supply damper blower
160: PCB circuit board 170: exhaust failure plate
171; 181: Screw assembly bit
180: supply air partition plate 190: indoor exhaust partition
190a: indoor exhaust partition fixed rib
200: electrothermal exchange element 201: filter
202: corner guard frame 203: Velk road
210: heat sink 211: heat sink base
210a: V groove 210b: Cross radiating fin
210c: heat sink screw assembly
220a; 220b: electric heat exchange heat pipe
300: Ventilation case for electric heat exchange 300a: Ventilation case with a filter attached to the room exhaust grill
300b: Indoor supply grill with filter with ventilation case

Claims (5)

A rear portion orthogonal to the housing mating rib 110c in which two rows of gasket grooves 110g are formed; Opposite side of the housing fitting rib 110c, the inner side of the side portion integrally orthogonal to the rear portion, and the other end inside of the side portion in which the heat insulating layer 110f is filled in the resin filling recess 110e adjacent to the first cover screw assembly hole 110a. Two aluminum profile housings 110 having a housing front panel rib 110d having a gasket groove 110g 'formed on the outside with a second cover screw assembly hole 110b provided at a corner are cut to the same length, A gasket 112a is fitted into the gasket groove 110g between the housing assembly rib 110c in which the housing assembly ribs 110c of the upper and lower layers of the housing 110 are removed, respectively, and the housing assembly ribs 110c are fitted. ) Attach the grill 111 to the inside of the indoor exhaust port 110h perforated on the upper right side of the housing, and the exhaust damper blower 150a is attached, and the grill 111 to the inside of the outdoor air intake 110i perforated on the lower side of the left housing. ), Housing assembly The gap 110b is removed and the welded gap is caulked from the inside, and the upper side of the housing 110 on the right side from which the housing assembly rib 110c is removed is stepped inside the housing rear side and the resin filling recess 110e. With a rectangular incision in the corners up to; An exhaust partition plate 170 having a rear side side opposite side edge adjacent to the side portion of the upper portion of the housing 110 on the left side is formed of a triangular cutout, and the right housing is provided on the lower layer of the housing 110 in which the housing fitting rib 110c is removed. The air supply partition plate 180 having a rear side side opposite side edge adjacent to the side portion is formed of a triangular incision, and the outdoor exhaust air blower is spaced inward from the triangular cutout border and the rear side side opposite side edge line of the exhaust partition plate. In order to isolate the space from the chamber 101, the indoor exhaust partition and the indoor exhaust partition 190 with the fixing ribs 190a are piece-assembled, and the exhaust partition plate 170 and the air supply partition plate 180 section of the inner housing 110 A V-groove 210c in the longitudinal direction at the center of the front surface of the heat sink base 211 of the rectangular plate type in close contact with the housing assembly rib 110c; Cross heat radiation fins 210b are formed on both sides based on the central separator 210a protruding integrally from the rear surface, and the heat sink base and the cross heat radiation fins of the upper left and lower right corners are respectively removed on the basis of the center separator. A heat dissipation plate 210 for disposing one strand of the total heat exchange heat pipes 220a from side to side, in close contact with inner end portions of the resin filling recesses 110e on both sides; Zigzag excavation of one strand of the total heat exchange heat pipe (220b) to the heat sink length standard, bending the middle so as not to bend at a 95 ° bend angle, and affixed to the V groove (210c) of the heat sink plate 211 by a sealing material, The stacked longitudinal sides are supported by the corner protection frame 202 and the heat exchange element 200 having the filter 201 attached to and detached from the Velcro rod 203 is installed in close contact with the heat transfer heat pipe 220b. , Inserting the gasket (112b) into the housing front panel rib (110d) of the left and right housing 110, which is assembled to the hospital, and the indoor exhaust grill (120a) with a filter is attached to the upper side of the exhaust partition plate (170) or more, and the air supply partition plate ( 180) Inside the interior air supply grill 120b with the filter formed below the height, the front panel 120 with the air supply damper blower 150b is piece-assembled to the assembled housing 110, and the assembled housing ( 110) the upper cover 130 and the PCB circuit board of the resin material on the upper and lower layers Total heat exchange ventilation apparatus (160) characterized by doeeojim composed of the lower cover 140, the total heat-exchanging ventilation device module 100 to assemble the upper anchakhan. According to claim 1, wherein the housing 110 is a side portion of the housing 110 as a means for blocking the heat transfer between the housing on the rear side of the heat exchange ventilation device module 100 and the housing on the front side side assembled with the front panel 120 Electrothermal heat exchange and ventilation device characterized in that the heat insulating layer (110f) is installed in the heat insulating resin filling recess (110e) spaced apart cutting in the longitudinal direction. According to claim 1, The heat exchange element 200 is a four corners of the total heat exchange element to the corner protection frame 202 is attached to the velcro rod 203 with good adhesion of the wool of the filter to facilitate the replacement of the filter 201 Total heat exchange ventilation apparatus characterized in that installed in. The heat dissipation plate 210 of claim 1, further comprising: a heat dissipation base base 211 provided with a V groove 210c in the middle of the rear surface thereof; A central separator 210a orthogonally formed in the middle of the V groove; A screw assembly hole 210d formed in the middle of the central separator plate; Cross heat dissipation fin (210b) mutually symmetrical to both sides based on the central separator plate integrally extruded in the longitudinal direction, characterized in that the total heat exchange ventilation device. The method of claim 1, wherein the total heat exchange ventilator module 100 is placed in the electrothermal exchange vent case 300 of any one of the corner type, cylinder type, polygonal shape and opened separately on the upper and lower surfaces of the total heat exchange ventilation case. An indoor exhaust grill 300a with a filter attached to the ventilation case and an indoor exhaust grill 300b with a filter attached to the ventilation case are formed, and an indoor exhaust grill 120a with a filter provided in the front panel 120 and an internal supply grill 120b with a filter are provided. Are in communication with each other, and the outdoor exhaust port 110h and the outdoor air intake port 110i provided at the rear portion of the housing 110 are processed from the back wall by a ductless air supply, a duct leading to the ceiling, or a separate exposure duct. An electric heat exchange ventilator, characterized in that for installing the outdoor exhaust pipe (110h) and the outdoor air inlet (110i) duct.

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