KR20180123367A - Heat Exchanger - Google Patents

Abstract

The present invention relates to a heat exchanger which can be conveniently and safely assembled, installed, and disassembled. The heat exchanger of the present invention comprises: a first case (110); a second case (120); an exhaust ventilation fan (331); a feed ventilation fan (332); a bypass entrance (421); a bypass exit (422); an eccentric bypass damper (430); and a central heat damper (442).

Description

Heat Exchanger {Heat Exchanger}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrothermal heat exchanger, and more particularly, to an electrothermal heat exchanger including an electrothermal heat exchanger having a bypass passage separated from a first case by a second casing, Pass damper and a central heat damper so that the bypass ventilation can be stably and clearly performed.

It is another object of the present invention to provide an air conditioner in which an indoor duct plate coupled to a side cover of a base frame of a first case and an outdoor duct plate are coupled by a supporting engagement structure to perform an electric heating operation according to the operation of the air supply fan and the air discharge fan To minimize the resonance vibration of the first case, and to improve the assemblability of the indoor duct plate and the outdoor duct plate by cooperating with each other.

It is another object of the present invention to provide a dehumidifying device capable of preventing the generation of mold due to moisture condensation during the heating process.

Generally, the total enthalpy heat exchanger is to supply fresh outside air to the room so that the room air can transfer energy to the incoming air to minimize the heat loss due to the supply of the outside air.

The total enthalpy heat exchanger as described above includes a case forming a housing space, an total heat-exchanging element accommodated in the housing space of the case, an outside air intake port and an outside air supply device formed respectively in the case, an indoor vent and an indoor vent, An air blowing fan formed in the indoor air outlet space, a controller for controlling the air blowing fan and the air blowing fan according to the user's operation, and a control unit And a remote controller.

In the conventional total enthalpy heat exchanger configured as described above, the controller controls the operation of the air supply blowing fan and the exhaust blowing fan in accordance with the operation of the remote controller of the user to discharge the contaminated room air outdoors, The temperature of the outdoor air is controlled by indirect contact with the indoor air, thereby minimizing the change of the room temperature by the supply of the external air, thereby preventing the heat loss.

On the other hand, as disclosed in Patent No. 10-1117523-0000, when the temperature difference between indoor and outdoor is not so large as in spring and autumn, the total heat exchanger does not pass the room air through the heat transfer element but passes through a separate bypass passage So that it can be discharged to an indoor exhaust port.

However, in the case of the total enthalpy heat exchanger as described above, when the temperature difference between the indoor and the indoor air is not so large as in spring and fall, the bypass flow of the indoor air is not stable and clearly caused due to interference with the bypass damper, There is a problem that it is complicatedly formed.

In addition, there is a problem in that the bypass passage is located inside the apparatus, so that all of the apparatus must be separated in cleaning and maintenance of the bypass passage.

In addition, the conventional total enthalpy heat exchanger has a structure in which the case assembly structure is assembled by the pieces, so that the durability thereof is weak, and there is a problem that the vibration is generated in the electric heating operation process according to the operation of the air supply fan and the air discharge fan.

In addition, in the conventional total enthalpy heat exchanger, there is a problem that mold caused by condensation is generated due to the temperature difference between indoor air and outdoor air in the total heat exchanging element.

Korean Patent Publication No. 10-1117523-0000

Accordingly, as described above, in the conventional total enthalpy heat exchanger, the bypass flow of the indoor air when the temperature difference between indoor and indoor air is not so large as in spring and autumn is stably and clearly performed due to interference with the bypass damper So that the structure of the bypass damper is complicated and the bypass damper is located inside the apparatus, thereby solving the inconvenience of cleaning and maintenance of the passage.

In addition, since the case assembly structure is structured by assembling the pieces, the durability thereof is weak, and there is a problem such as occurrence of ringing vibration in the process of electric heating operation due to the operation of the air supply fan and the air discharge fan, And it is possible to solve the problem that mold due to condensation occurs due to temperature difference of air.

That is, according to the present invention, there is provided an total enthalpy heat exchanger comprising: indoor and outdoor duct plates respectively coupled to a left and a right side cover of a basic frame; and a first case composed of a lid covering the upper and lower portions of the basic frame, And a second case coupled to a lower portion of the first case to form a bypass passage.

The first case of the present invention constitutes a total heat-exchanging element which is supported at the center by four device-guiding parts and element-guiding parts which divide the accommodation space inside and which is mounted in a rhombic shape, and the outside air intake port and the air- And an indoor ventilation hole and an outdoor air supply device are formed on the side of the indoor duct plate.

The present invention is characterized in that it comprises an exhaust air blowing fan configured in an indoor exhaust accommodating space on the indoor exhaust side of the first case, an air supply blowing fan configured in an outdoor air supply air accommodating space on the outdoor air supply side of the first case, A bypass outlet formed through the first case bottom plate of the indoor exhaust accommodation space of the indoor exhaust-side compartment, a bypass outlet formed through the bypass inlet formed at the bypass inlet, An eccentric bypass damper, a central electrothermal damper for causing air to flow through the heat transfer damper plate of the indoor ventilation space, and a control box at one side of the first case.

The supporting joint structure of the present invention comprises duct supporting bosses and duct supporting bosses at both ends of the upper and lower duct supporting plates of the indoor and outdoor duct plates, side supporting grooves for supporting the duct supporting jaws at both ends of the upper side supporting plate of the side cover, A side fastening plate and a lower fastening plate constituting a side fastening insertion groove for inserting and supporting the duct supporting projections and supporting the outer surfaces of the indoor and outdoor duct plates at both ends of the upper side cover and the lower surface, will be.

The second case may include a bypass main plate formed in a plate shape at the bottom and a bypass side plate bent at a right angle along the edge of the bypass main plate, And a case binding portion formed to be bent.

The present invention is characterized in that a drawer bypass filter plate coupled to a bypass main plate on the bypass inlet side of the second case through a bypass side plate in a drawable manner is formed.

The present invention is characterized in that the element guide portion comprises a plate-shaped divided plate member vertically erected, a bar-shaped element guide bar coupled to the divided plate member, and a plate-shaped element fixing plate for preventing the total heat- A device guide groove for inserting the total heat-exchanging element in one corner, and a filter coupling groove for inserting an air filter in both corners.

The present invention is characterized in that an outside air heater and an outside air electrostatic filter unit are constituted.

The present invention is characterized in that a dehumidifying device for removing moisture generated in an indoor ventilation accommodating space or an outside air intake accommodating space is constituted.

Therefore, the present invention is characterized in that, in the total enthalpy heat exchanger

Because the body having the structure separated into the first case and the second case, when the temperature difference between the indoor and the indoor air is not excessive, or when the indoor air is bypassed as needed, it is stably and clearly performed without interference with the bypass damper And the convenience of installation and disconnection of the bypass by the simple structure is provided. In addition, the bypass passage is formed separately from the outside, thereby facilitating the cleaning and maintenance of the bypass passage. In addition, in the assembled structure of the case, assembly is performed by a supporting binding structure to increase durability and to reduce vibrations during the heat transfer operation according to the operation of the air supply fan and the air discharge fan. Also, due to the internal dehumidifying device, the problem of condensation due to condensation due to the temperature difference between indoor air and outdoor air in the total heat exchanging element is solved.

1 is an exploded perspective view showing a temporal example of the present invention.
2 is a top view of the internal structure of the present invention.
FIG. 3 is an exploded bottom perspective view showing a lower surface for showing a bypass passage according to the present invention. FIG.
4 is a schematic view of a bypass passage according to the present invention.
5 is an exploded view showing an internal structure in which an air filter and an electrothermal heat exchanging element according to the present invention are separated.
6 is an exploded view showing the configuration of a first case and a second case according to the present invention;
7 is an exemplary view showing an example of the operation of the eccentric bypass damper and the central electro-thermal damper according to the present invention.
Figure 8 is a perspective view of an embodiment with an air supply damper according to the present invention;
Fig. 9 is an exemplary view showing a support binding structure according to the present invention; Fig.
10 is an exemplary view showing a configuration of a second case according to the present invention;
11 is an exemplary view and an enlarged view showing a configuration of a device guide portion according to the present invention.
12 is an exemplary view showing an embodiment of the operation of the element fixing plate according to the present invention.
13 is an exemplary view showing an embodiment having an outside heater according to the present invention.
14, 15 and 16 are views showing various examples of the bending support plate according to the present invention.
17 is an exemplary view showing an example of a dehumidifying device having a dehumidifying compressor according to the present invention.
18 is an exemplary view showing an example of a dehumidifying device having a thermoelectric-element exchanging device according to the present invention.
19 is an illustration showing an example of a drawer bypass filter plate according to the present invention.

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

The present invention aims to improve convenience and stability in assembly, installation, and separation by constituting the total heat exchanger in a simple structure having high robustness in the bypass structure and the whole assembly. It is to be understood that the words are not to be construed in a limiting sense in a generic or dictionary sense and that the inventive concept of the term can be properly defined in order to explain its invention in its best way, Should be construed as meaning and concept consistent with.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

That is, the present invention relates to a total enthalpy heat exchanger comprising: a basic frame plate 111 bent in a 'C' shape having a bottom plate 111a so as to form an accommodation space for total heat exchange; A first case 110 formed of an indoor and outdoor duct plate 113b and a lid 114 covering the upper end of the base plate 111 and coupled to the first case 110b and the second case 110b, And the second case 120 is formed to form the bypass passage 410. The second case 120 is formed of a synthetic resin.

The first case 110 includes four device guide parts 220 for dividing the accommodating space into four parts and a total enthalpy heat exchanging device 210 which is supported at the center by the device guide part 220, An indoor air outlet 311 and an indoor air outlet 312 formed on the side of the air duct 230 connected to the indoor duct hole of the outdoor duct plate 113b and the indoor duct plate 113a, And an indoor air supply port 321 and an ambient air supply air supply mechanism 322 formed on the side of the air pipe 230 connected to the two indoor duct holes.

Here, the inner space divided by the device guide unit 220 is as follows.

The direction of the outdoor duct plate 113b is a direction in which the indoor air is sucked into the indoor air supply port 321 side of the indoor air supply port 321, And the direction of the indoor duct plate 113a is composed of an outside air intake accommodation space 115a on the side of the outside air intake port 311 for taking in outdoor air into the apparatus and a room air intake space 115a on the side of the outside air intake port 311, And an indoor exhaust accommodating space 115b on the indoor exhaust port 312 side for exhausting to the outside.

The exhaust air blowing fan 331 is formed in the indoor exhaust receiving space 115b on the side of the indoor exhaust port 312 of the first case 110 and the exhaust air blowing fan 331 is formed on the outer air exhausting device 322 of the first case 110, And constitutes a supply air blowing fan 332 formed in the outside air supply space 115d.

A bypass inlet 421 is formed through the bottom plate 111a of the first case 110 of the indoor ventilation space 115c on the side of the indoor ventilation opening 321, And a bypass outlet 422 formed through the bottom plate 111a of the first case 110 of the accommodation space 115b.

And an eccentric bypass damper 430 for guiding the air introduced through the indoor ventilation opening 321 to the bypass inlet 421 and allowing the air to bypass by opening the bypass inlet 421, The central heat transfer damper 442 is configured to allow the air introduced into the indoor air vent 321 formed in the heat transfer damper plate 441, which is vertically obliquely formed in the ventilation space 115c, to pass therethrough.

It is also possible to constitute an outside air heater 610 for applying heat to the outside air intake accommodation space 115a on the outside air intake port 311 side and an outside air static electricity filter portion.

The control box 500 has a controller unit for controlling the heat transfer and the bypass ventilation according to the remote control operation of the user on one side of the first case 110.

Here, the support binding structure

A duct supporting plate 116 bent at the upper end of the indoor and outdoor duct plates 113b and a duct supporting projection 116a formed at both ends of the duct supporting plate 116 and the duct supporting projections 116a, And a duct supporting boss 116b formed on the inner side of the duct supporting boss 116b,

A side support plate 117 is formed at the upper end of the side cover 111b. A side support groove 117a is formed at both ends of the side support plate 117 to support the duct support tab 116b. Side fastening insertion grooves 117b for inserting and supporting the duct supporting projections 116a into the outer ends of the indoor and outdoor duct plates 113b at both ends of the upper side cover 111b, And a lower fastening plate 119b that supports the outer surfaces of the indoor and outdoor duct plates 113b at both ends of the lower surface to be fastened by pieces.

The second case 120 includes a bypass main plate 121 formed in a plate shape at a lower portion thereof, a bypass side plate 122 bent at a right angle along the periphery of the bypass main plate 121, And a case binding portion 123 which is bent to be horizontal with the bypass main plate 121 inwardly from the side plate 122.

The total heat-exchanging element 210 includes a total heat-exchanging vent 211 as a body through which the total heat is exchanged, a heat-receiving corner bar 211a surrounding the corner, a bottom, a lid 212 covering the top, 212 may be formed by cutting an incision knob 212a.

The device guide part 220 includes a vertically erected plate-shaped parting plate 221 having a divided support plate 221a formed by bending the inside of the device and bent at right angles along the rim of the parting plate 221, A device type fixing plate 223 having a plate shape for fixing one side thereof to the upper part of the divided plate to prevent the total heat-exchanging element 210 from being separated by rotation, As shown in FIG.

The device guide bar 222 includes an element guide groove 222a formed by two element guide plates perpendicular to one another to sandwich the total heat exchange element 210 therebetween, And a filter coupling groove 222b formed of a filter guide plate protruding in parallel with the guide groove 222a.

In addition, the inner heat radiating pad is configured to radiate heat inside the first case 110 and inside the divided plate body 221.

The front air preventing door 230a is formed inside the tubular air pipe 230 of the outside air intake port 311, the room air exhaust port 312 and the indoor air intake port 321, And an air supply cutoff damper 332a is provided between the fan 332 and the indoor duct plate 113a.

In addition, a dehumidifying device for selectively removing indoor moisture generated in the season can be configured in the indoor ventilation space 115c and the outdoor air intake space 115a.

Here, the dehumidifying device can be configured by an indoor ventilation heat exchanger 711 formed in the indoor ventilation space 115c, and an outdoor air intake heat exchanger 712 configured in the outdoor air intake space.

Here, refrigerant supply means for supplying heat exchange refrigerant to the indoor ventilation heat exchanger 711 or the outside air intake heat exchanger 712 under the control of the controller according to the room temperature is provided at one side of the first case 110, The refrigerant supply means can be implemented by selectively configuring a dehumidifying compressor 721 having a switch valve or a thermoelectric element and a thermoelectric element exchanger 722 having thermoelectric refrigerant heat exchangers on both sides thereof.

Further, in order to further increase the supporting force, the support binding structure may selectively constitute a bending projection support plate formed by bending the edge of the duct support projection 116a or the edge of the side engagement insertion groove 117b which are meshed with each other, And a bending chin supporting plate formed by bending the edge of the duct supporting bump 116b or the side edge of the side supporting plate, which are meshed with each other, can be selectively constructed.

It is also possible to constitute a temperature sensor for measuring the temperature of indoor air and outdoor air on the surface side of the central heat transfer damper 442 and the air supply cutoff damper 332a.

The drawer bypass filter plate 124 coupled to the bypass main plate 121 on the side of the bypass inlet 421 of the second case 120 through the bypass side plate 122 is formed You can.

Hereinafter, the operation and effect of the application of the present invention will be described.

In the embodiment of the present invention, as described above, if the internal accommodation space is divided into four parts and the total heat-exchanging element 210 is provided in the form of rhombus at the center,

First, indoor air is discharged through the indoor-> indoor ventilation space 115c, the total heat-exchanging element 210, the indoor space 115b, and the outdoor air- The outdoor air is discharged to the outside through the outdoor air inlet space 115a, the total heat exchange element 210, the outdoor air supply space 115d, And flows into the inside. The total heat-exchanging operation through the total heat-exchanging in the total heat-exchanging element 210 in the above-described process is performed.

A second case 120 is formed below the first case 110 and a bypass inlet 421 and an outlet are formed at the bottom of the indoor ventilation space 115c and the indoor space 115b, A central electrothermal damper 442 for guiding the air to the total heat exchanging element 210 and an eccentric bypass damper 430 for guiding the air to the bypass passage 410 are provided in the indoor ventilation space 115c. Thus, ventilation without heat exchange is performed. At this time, the second case 120 is formed outside the first case 110 to facilitate the cleaning and maintenance of the bypass.

Here, the eccentric bypass damper 430 is disposed at a position farther away from the inlet of the room air, so that the air introduced when the damper plate is opened is guided by the damper plate so as to be bent downward, So that the discharge through the bypass passage 410 is efficiently performed.

In addition, by providing the air supply damper 332a, it is possible to prevent inflow of polluted air, worms and other contaminants by blocking inflow of outside air other than operation of the apparatus, To prevent the inflow of air.

In addition, in the practice of the present invention, when the outside air heater 610 for applying heat to the outside air intake space 115a and the outside air static electricity filter unit are constructed, the loss of heat generated during the ventilation process is controlled by the outside heater 610, And the outside air static electricity filter unit primarily removes the dust from the outside.

In the embodiment of the present invention, the supporting-and-binding structure includes duct-supporting bosses 116a and duct-supporting bosses 116b at both ends of the upper duct support plate 116 of the indoor and outdoor duct plates 113b, Side support grooves 117a for supporting the duct support brackets 116b and side engaging insertion grooves 117b for inserting and supporting the duct support projections 116a are provided at both ends of the upper side support plate 117 of the side cover 111b The indoor and outdoor duct plates 113b are rigidly supported by the side covers 111b so that the sealing force and the durability of the indoor and outdoor ducts 113b are improved. And the exhaust blowing fan (331).

Further, a bending projection supporting plate formed by bending at the corner of the duct supporting projection 116a or the side of the side coupling insertion groove 117b, which are held in mesh with each other, is selectively formed, and the edge of the duct supporting boss 116b If the bending chin support plate formed by bending the side edge of the side support paper is selectively constructed, the supporting binding structure is supported on the surface, the face, or the face and the edge, so that the supporting force is further increased.

In the practice of the present invention, the side fastening plate 119a and the lower fastening plate 119b, which support the outer surfaces of the indoor and outdoor duct plates 113b at both ends of the lower surface, And the second case 120 is constructed by the bypass main plate 121, the bypass side plate 122 and the case binding part 123, the simplicity and robustness of the coupling and the manufacture of the case .

In the embodiment of the present invention, the total heat-exchanging element 210 includes a total heat-exchanging vent 211 as a body, a heat-absorbing corner bar 211a surrounding the corner, a bottom, a lid 212 covering the top, When the heat dissipating member 212 is cut off and the heat dissipating member 212 is cut off and the heat dissipating member 212 is cut and attached to the heat dissipating member 212a, It is easy to attach and detach by raising and holding as needed.

In the embodiment of the present invention, the element guide portion 220 includes a plate-shaped divided plate body 221 vertically erected and a bar-shaped element guide bar 222 coupled to a protruding support plate of the divided plate body 221 The device guide groove 222 may be formed by providing a device guide groove 222a formed at one side edge of the device guide plate 222 and a filter connecting groove 222b formed by a filter guide plate at both corners, The heat exchange element 210 can be guided by using the filter coupling groove 222b, and the filter coupling groove 222b can be used by filtering the air through a filter necessary for use.

In particular, if the device-fixing unit 223 is formed of a plate-shaped member that rotates unidirectionally on the device guide unit 220, the device is combined with the total heat-exchanging element 210 and the filter, 210 and the filter in place to prevent dislodgement.

In addition, in the practice of the present invention, if the dehumidifying device for removing the moisture generated in the indoor ventilation space 115c or the outside air intake space 115a is selectively constructed, To prevent fungal growth and bacterial growth.

In the embodiment of the present invention, if a temperature sensor for measuring the temperature of indoor air and outdoor air is provided on the surface side of the central heat damper 442 and the air supply cutoff damper 332a, the indoor temperature and the outdoor temperature coincide with each other A primary ventilation using the bypass passage 410 is performed.

In addition, in the practice of the present invention, a dehumidifying device for selectively removing moisture generated in the room in the indoor ventilation space 115c and the ambient air intake space 115a may be constructed, The indoor air heat exchanger 711 constituted in the space 115c and the outdoor air intake heat exchanger 712 constituted in the outdoor air suction accommodating space 115a constitute refrigerant supply means for supplying heat exchange refrigerant thereto The indoor ventilation heat exchanger 711 of the indoor ventilation accommodating space operates when the outdoor temperature is higher than that of the indoor space and the outdoor air intake heat exchanger of the outdoor air intake accommodating space 712 operate to remove moisture in the air passing through the total enthalpy heat exchanging element 210 in advance to prevent condensation on the total heat exchanging element 210.

In the embodiment of the present invention, the drawer bypass filter plate 124, which is coupled to the bypass main plate 121 on the side of the bypass inlet 421 of the second case 120 via the bypass side plate 122 in a draw- It is possible to easily remove contaminants which have been accumulated in the bypass passage 410. [

110: first case
111: base frame 111a: bottom frame 111b: side cover
113a: indoor duct plate 113b: outdoor duct plate 114: lid
(Accommodation space)
115a: outside air intake space 115b: indoor exhaust space
115c: indoor ventilation space 115d: outdoor air supply space
(Supported binding structure)
116: duct supporting plate 116a: duct supporting projection 116b: duct supporting jaw
117: side support plate 117a: side support groove 117b: side fastening insertion groove
118: bending support plate
119a: Side fastening plate 119b: Lower fastening plate
120: Second case
121: bypass main plate 122: bypass side plate
123: Case coupling part 124: Drawer bypass filter plate
210: Total heat exchanging element
211: Total heat exchanger vent 211a: Heat transfer corner bar 212:
212a: incision handle 213: air filter
220:
221: a divided plate body 221a:
222: Element guide bar
222a: element guide groove 222b: filter coupling groove 223: element fixing plate
230: Air pipe 230a: Anti-wind door
311: outside air inlet port 312: indoor air outlet port
321: Indoor ventilation hole 322:
331: exhaust blower fan 332: air supply blower 332a: air supply damper
410: Bypass passage 421: Bypass inlet 422: Bypass outlet
430: eccentric bypass damper 441: heat transfer damper plate 442: central heat transfer damper
500: Control box (500) 610: Outdoor heater
(Dehumidifier)
711: indoor ventilation heat exchanger 712: outdoor air intake heat exchanger
721: Dehumidification compressor 722: Thermoelectric device switching device

Claims (5)

In the total heat exchanger,
A base frame 111 bent in a 'C' shape having a bottom plate 111a so as to form a receiving space for total heat exchange, a pair of left and right side covers 111b of the base frame 111, A first case 110 composed of an indoor and an outdoor duct plate 113b to be coupled to each other and a lid 114 covering the upper and lower sides of the basic frame 111; A second case 120 coupled to a lower portion of the first case 110 to form a bypass passage 410;

Four element guide portions 220 for dividing the accommodating space into four parts in the first case 110 and a total heat exchanging element 210 mounted in a rhombic shape supported at the center by the element guide portion 220;
Two indoor duct holes passing through the outdoor duct plate 113b, an outside air inlet 311 and an indoor air outlet 312 formed at the air pipe 230 side connected thereto; Two indoor duct holes passing through the indoor duct plate 113a, an indoor ventilation port 321 and an outside air supply mechanism 322 formed on an air pipe 230 side connected thereto;

An exhaust air blowing fan (331) configured in the indoor air exhaust space (115b) on the side of the indoor air exhaust port (312) of the first case (110); An air supply blowing fan 332 formed in the outside air supply receiving space 115d on the outside air supply mechanism 322 side of the first case 110;

A bypass inlet 421 formed through the bottom plate 111a of the first case 110 of the indoor ventilation space 115c at the indoor ventilation opening 321 side; A bypass outlet 422 formed through the bottom plate 111a of the first case 110 of the room ventilation space 115b on the side of the room vent 312;

An eccentric bypass damper 430 for guiding the air introduced through the indoor ventilation port 321 to the bypass inlet 421 to bypass the bypass inlet 421; A central electrothermal damper 442 for allowing the air introduced into the indoor ventilation port 321 formed in the heat transfer damper plate 441 vertically obliquely formed in the indoor ventilation space 115c to pass therethrough;

And a control box 500 having a controller device for controlling the heat transfer and the bypass ventilation in accordance with a user's remote control operation on one side of the first case 110,

The support binding structure
A duct supporting plate 116 bent at the upper end of the indoor and outdoor duct plates 113b, duct supporting projections 116a formed at both ends of the duct supporting plate 116, A duct supporting jaw 116b formed at an incision in the duct;

A side support plate 117 formed to be bent at the upper end of the side cover 111b and a side support groove 117a formed at both ends of the side support plate 117 to support the duct support tab 116b, A side fastening insertion groove 117b for inserting and supporting the duct supporting projections 116a at the ends of the upper and lower side plates 117a and 117a to support the outer surfaces of the indoor and outdoor duct plates 113b at both ends of the upper side cover 111b A side fastening plate 119a which is fastened to the side fastening plate 119 by a piece; And a lower fastening plate 119b for supporting the outer surfaces of the indoor and outdoor duct plates 113b at both ends of the lower surface to be fastened to each other,

The second case 120 includes a bypass main plate 121 formed in a plate shape at the bottom, a bypass side plate 122 bent at a right angle along a rim of the bypass main plate 121, (122) and a case binding portion (123) bent in a horizontal direction with the bypass main plate (121) inwardly. The method according to claim 1,

The total heat-exchanging element 210 includes a total heat-exchanging vent 211 as a body through which the total heat is exchanged, a heat-receiving corner bar 211a surrounding the corner, a lid 212 covering the bottom, A cutting knob 212a is formed by cutting the cutting knife 212a,

The device guide unit 220 includes a vertically erected plate-shaped partition plate 221 having a divided support plate 221a which is divided at right angles along the rim of the partition plate 221, the upper and lower partition plate 221a, Shaped device guide bar 222 coupled to the protruding support plate for preventing the total heat exchange element 210 and the air filter 213 from being separated by rotation of one side of the partition plate, A fixing plate 223,

The device guide bar 222 includes an element guide groove 222a formed by two element guide plates perpendicular to each other to sandwich the total heat exchange element 210 at one corner, A filter engagement groove 222b formed of a filter guide plate protruding in parallel with the groove 222a,

The present invention constitutes an outside air heater 610 for applying heat to the outside air intake accommodation space 115a on the outside air intake port 311 side and an outside air electrostatic filter portion,

And an internal heat dissipating pad which is radiated inside the first case 110 and inside the dividing plate 221,

The back air preventing door 230a is formed on the inside of the tubular air pipe 230 of the outside air intake port 311, the room exhaust port 312 and the indoor ventilation port 321, and the air supply fan 332 and an indoor duct plate (113a), and an air supply cutoff damper (332a) The method according to claims 1 and 2,

A dehumidifying device for selectively removing indoor moisture generated in the season is provided in the indoor ventilation space 115c and the outdoor air intake space 115a,

The dehumidifying device includes an indoor ventilation heat exchanger 711 formed in the indoor ventilation space 115c and an outdoor air intake heat exchanger 712 configured in the outdoor air intake space,

And refrigerant supply means for supplying heat exchange refrigerant to the indoor ventilation heat exchanger 711 or the outside air intake heat exchanger 712 under the control of a controller according to the room temperature on one side of the first case 110,

Wherein the refrigerant supply means selectively constitutes a dehumidifying compressor (721) having a switch valve or a thermoelectric element exchange device (722) having a thermoelectric element and a thermoelectric refrigerant heat exchanger on both sides thereof. The method according to claims 1 and 2,

The support binding structure;

A bending support plate 118 formed by bending at the edge of the duct support boss 116a or the side of the side boss insertion boss 117b, which are meshed with each other,

And a bending support plate (118) formed by bending at the edge of the duct support boss (116b) or the side support plate groove edge which are meshed with each other are selectively constituted.
The method according to claims 1 and 2,

A temperature sensor for measuring the temperature of indoor air and outdoor air is formed on the surface side of the central heat transfer damper 442 and the air supply cutoff damper 332a,

The drawer bypass filter plate 124 coupled to the bypass main plate 121 on the bypass inlet side of the second case 120 through the bypass side plate 122 in a draw- Total heat exchanger.

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